Пакет: gcc

GCC(1)				      GNU				GCC(1)



NAME
       gcc - GNU project C and C++ compiler

SYNOPSIS
       gcc [-c|-S|-E] [-std=standard]
	   [-g] [-pg] [-Olevel]
	   [-Wwarn...] [-Wpedantic]
	   [-Idir...] [-Ldir...]
	   [-Dmacro[=defn]...] [-Umacro]
	   [-foption...] [-mmachine-option...]
	   [-o outfile] [@file] infile...

       Only the most useful options are listed here; see below for the
       remainder.  g++ accepts mostly the same options as gcc.

DESCRIPTION
       When you invoke GCC, it normally does preprocessing, compilation,
       assembly and linking.  The "overall options" allow you to stop this
       process at an intermediate stage.  For example, the -c option says not
       to run the linker.  Then the output consists of object files output by
       the assembler.

       Other options are passed on to one or more stages of processing.	 Some
       options control the preprocessor and others the compiler itself.	 Yet
       other options control the assembler and linker; most of these are not
       documented here, since you rarely need to use any of them.

       Most of the command-line options that you can use with GCC are useful
       for C programs; when an option is only useful with another language
       (usually C++), the explanation says so explicitly.  If the description
       for a particular option does not mention a source language, you can use
       that option with all supported languages.

       The usual way to run GCC is to run the executable called gcc, or
       machine-gcc when cross-compiling, or machine-gcc-version to run a
       specific version of GCC.	 When you compile C++ programs, you should
       invoke GCC as g++ instead.

       The gcc program accepts options and file names as operands.  Many
       options have multi-letter names; therefore multiple single-letter
       options may not be grouped: -dv is very different from -d -v.

       You can mix options and other arguments.	 For the most part, the order
       you use doesn't matter.	Order does matter when you use several options
       of the same kind; for example, if you specify -L more than once, the
       directories are searched in the order specified.	 Also, the placement
       of the -l option is significant.

       Many options have long names starting with -f or with -W---for example,
       -fmove-loop-invariants, -Wformat and so on.  Most of these have both
       positive and negative forms; the negative form of -ffoo is -fno-foo.
       This manual documents only one of these two forms, whichever one is not
       the default.

       Some options take one or more arguments typically separated either by a
       space or by the equals sign (=) from the option name.  Unless
       documented otherwise, an argument can be either numeric or a string.
       Numeric arguments must typically be small unsigned decimal or
       hexadecimal integers.  Hexadecimal arguments must begin with the 0x
       prefix.	Arguments to options that specify a size threshold of some
       sort may be arbitrarily large decimal or hexadecimal integers followed
       by a byte size suffix designating a multiple of bytes such as "kB" and
       "KiB" for kilobyte and kibibyte, respectively, "MB" and "MiB" for
       megabyte and mebibyte, "GB" and "GiB" for gigabyte and gigibyte, and so
       on.  Such arguments are designated by byte-size in the following text.
       Refer to the NIST, IEC, and other relevant national and international
       standards for the full listing and explanation of the binary and
       decimal byte size prefixes.

OPTIONS
   Option Summary
       Here is a summary of all the options, grouped by type.  Explanations
       are in the following sections.

       Overall Options
	   -c  -S  -E  -o file -dumpbase dumpbase  -dumpbase-ext auxdropsuf
	   -dumpdir dumppfx  -x language -v  -###  --help[=class[,...]]
	   --target-help  --version -pass-exit-codes  -pipe  -specs=file
	   -wrapper @file  -ffile-prefix-map=old=new  -fcanon-prefix-map
	   -fplugin=file  -fplugin-arg-name=arg -fdump-ada-spec[-slim]
	   -fada-spec-parent=unit  -fdump-go-spec=file

       C Language Options
	   -ansi  -std=standard	 -aux-info filename -fno-asm -fno-builtin
	   -fno-builtin-function  -fcond-mismatch -ffreestanding  -fgimple
	   -fgnu-tm  -fgnu89-inline  -fhosted -flax-vector-conversions
	   -fms-extensions -foffload=arg  -foffload-options=arg -fopenacc
	   -fopenacc-dim=geom -fopenmp	-fopenmp-simd
	   -fopenmp-target-simd-clone[=device-type]
	   -fpermitted-flt-eval-methods=standard -fplan9-extensions
	   -fsigned-bitfields  -funsigned-bitfields -fsigned-char
	   -funsigned-char  -fstrict-flex-arrays[=n] -fsso-struct=endianness

       C++ Language Options
	   -fabi-version=n  -fno-access-control -faligned-new=n
	   -fargs-in-order=n  -fchar8_t	 -fcheck-new -fconstexpr-depth=n
	   -fconstexpr-cache-depth=n -fconstexpr-loop-limit=n
	   -fconstexpr-ops-limit=n -fno-elide-constructors
	   -fno-enforce-eh-specs -fno-gnu-keywords -fno-immediate-escalation
	   -fno-implicit-templates -fno-implicit-inline-templates
	   -fno-implement-inlines -fmodule-header[=kind] -fmodule-only
	   -fmodules-ts -fmodule-implicit-inline -fno-module-lazy
	   -fmodule-mapper=specification -fmodule-version-ignore
	   -fms-extensions -fnew-inheriting-ctors -fnew-ttp-matching
	   -fno-nonansi-builtins  -fnothrow-opt	 -fno-operator-names
	   -fno-optional-diags -fno-pretty-templates -fno-rtti
	   -fsized-deallocation -ftemplate-backtrace-limit=n
	   -ftemplate-depth=n -fno-threadsafe-statics  -fuse-cxa-atexit
	   -fno-weak  -nostdinc++ -fvisibility-inlines-hidden
	   -fvisibility-ms-compat -fext-numeric-literals
	   -flang-info-include-translate[=header]
	   -flang-info-include-translate-not -flang-info-module-cmi[=module]
	   -stdlib=libstdc++,libc++ -Wabi-tag  -Wcatch-value  -Wcatch-value=n
	   -Wno-class-conversion  -Wclass-memaccess -Wcomma-subscript
	   -Wconditionally-supported -Wno-conversion-null
	   -Wctad-maybe-unsupported -Wctor-dtor-privacy	 -Wdangling-reference
	   -Wno-delete-incomplete -Wdelete-non-virtual-dtor
	   -Wno-deprecated-array-compare -Wdeprecated-copy
	   -Wdeprecated-copy-dtor -Wno-deprecated-enum-enum-conversion
	   -Wno-deprecated-enum-float-conversion -Weffc++
	   -Wno-elaborated-enum-base -Wno-exceptions -Wextra-semi
	   -Wno-global-module -Wno-inaccessible-base
	   -Wno-inherited-variadic-ctor	 -Wno-init-list-lifetime
	   -Winvalid-constexpr -Winvalid-imported-macros -Wno-invalid-offsetof
	   -Wno-literal-suffix -Wmismatched-new-delete -Wmismatched-tags
	   -Wmultiple-inheritance  -Wnamespaces	 -Wnarrowing -Wnoexcept
	   -Wnoexcept-type  -Wnon-virtual-dtor -Wpessimizing-move
	   -Wno-placement-new  -Wplacement-new=n -Wrange-loop-construct
	   -Wredundant-move -Wredundant-tags -Wreorder	-Wregister
	   -Wstrict-null-sentinel  -Wno-subobject-linkage  -Wtemplates
	   -Wno-non-template-friend  -Wold-style-cast -Woverloaded-virtual
	   -Wno-pmf-conversions -Wself-move -Wsign-promo -Wsized-deallocation
	   -Wsuggest-final-methods -Wsuggest-final-types  -Wsuggest-override
	   -Wno-template-id-cdtor -Wno-terminate  -Wno-vexing-parse
	   -Wvirtual-inheritance -Wno-virtual-move-assign  -Wvolatile
	   -Wzero-as-null-pointer-constant

       Objective-C and Objective-C++ Language Options
	   -fconstant-string-class=class-name -fgnu-runtime  -fnext-runtime
	   -fno-nil-receivers -fobjc-abi-version=n -fobjc-call-cxx-cdtors
	   -fobjc-direct-dispatch -fobjc-exceptions -fobjc-gc -fobjc-nilcheck
	   -fobjc-std=objc1 -fno-local-ivars
	   -fivar-visibility=[public|protected|private|package]
	   -freplace-objc-classes -fzero-link -gen-decls -Wassign-intercept
	   -Wno-property-assign-default -Wno-protocol -Wobjc-root-class
	   -Wselector -Wstrict-selector-match -Wundeclared-selector

       Diagnostic Message Formatting Options
	   -fmessage-length=n -fdiagnostics-plain-output
	   -fdiagnostics-show-location=[once|every-line]
	   -fdiagnostics-color=[auto|never|always]
	   -fdiagnostics-urls=[auto|never|always]
	   -fdiagnostics-format=[text|sarif-stderr|sarif-file|json|json-
	   stderr|json-file] -fno-diagnostics-json-formatting
	   -fno-diagnostics-show-option	 -fno-diagnostics-show-caret
	   -fno-diagnostics-show-labels	 -fno-diagnostics-show-line-numbers
	   -fno-diagnostics-show-cwe -fno-diagnostics-show-rule
	   -fdiagnostics-minimum-margin-width=width
	   -fdiagnostics-parseable-fixits  -fdiagnostics-generate-patch
	   -fdiagnostics-show-template-tree  -fno-elide-type
	   -fdiagnostics-path-format=[none|separate-events|inline-events]
	   -fdiagnostics-show-path-depths -fno-show-column
	   -fdiagnostics-column-unit=[display|byte]
	   -fdiagnostics-column-origin=origin
	   -fdiagnostics-escape-format=[unicode|bytes]
	   -fdiagnostics-text-art-charset=[none|ascii|unicode|emoji]

       Warning Options
	   -fsyntax-only  -fmax-errors=n  -Wpedantic -pedantic-errors
	   -fpermissive -w  -Wextra  -Wall  -Wabi=n -Waddress
	   -Wno-address-of-packed-member  -Waggregate-return -Walloc-size
	   -Walloc-size-larger-than=byte-size  -Walloc-zero -Walloca
	   -Walloca-larger-than=byte-size -Wno-aggressive-loop-optimizations
	   -Warith-conversion -Warray-bounds  -Warray-bounds=n
	   -Warray-compare -Warray-parameter  -Warray-parameter=n
	   -Wno-attributes  -Wattribute-alias=n -Wno-attribute-alias
	   -Wno-attribute-warning -Wbidi-chars=[none|unpaired|any|ucn]
	   -Wbool-compare  -Wbool-operation -Wno-builtin-declaration-mismatch
	   -Wno-builtin-macro-redefined	 -Wc90-c99-compat  -Wc99-c11-compat
	   -Wc11-c23-compat -Wc++-compat  -Wc++11-compat  -Wc++14-compat
	   -Wc++17-compat -Wc++20-compat -Wno-c++11-extensions
	   -Wno-c++14-extensions -Wno-c++17-extensions -Wno-c++20-extensions
	   -Wno-c++23-extensions -Wcalloc-transposed-args -Wcast-align
	   -Wcast-align=strict	-Wcast-function-type  -Wcast-qual
	   -Wchar-subscripts -Wclobbered  -Wcomment
	   -Wcompare-distinct-pointer-types -Wno-complain-wrong-lang
	   -Wconversion	 -Wno-coverage-mismatch	 -Wno-cpp -Wdangling-else
	   -Wdangling-pointer  -Wdangling-pointer=n -Wdate-time
	   -Wno-deprecated  -Wno-deprecated-declarations  -Wno-designated-init
	   -Wdisabled-optimization -Wno-discarded-array-qualifiers
	   -Wno-discarded-qualifiers -Wno-div-by-zero  -Wdouble-promotion
	   -Wduplicated-branches  -Wduplicated-cond -Wempty-body
	   -Wno-endif-labels  -Wenum-compare  -Wenum-conversion
	   -Wenum-int-mismatch -Werror	-Werror=*  -Wexpansion-to-defined
	   -Wfatal-errors -Wflex-array-member-not-at-end -Wfloat-conversion
	   -Wfloat-equal  -Wformat  -Wformat=2 -Wno-format-contains-nul
	   -Wno-format-extra-args -Wformat-nonliteral  -Wformat-overflow=n
	   -Wformat-security  -Wformat-signedness  -Wformat-truncation=n
	   -Wformat-y2k	 -Wframe-address -Wframe-larger-than=byte-size
	   -Wno-free-nonheap-object -Wno-if-not-aligned
	   -Wno-ignored-attributes -Wignored-qualifiers
	   -Wno-incompatible-pointer-types  -Whardened -Wimplicit
	   -Wimplicit-fallthrough  -Wimplicit-fallthrough=n
	   -Wno-implicit-function-declaration  -Wno-implicit-int
	   -Winfinite-recursion -Winit-self  -Winline  -Wno-int-conversion
	   -Wint-in-bool-context -Wno-int-to-pointer-cast
	   -Wno-invalid-memory-model -Winvalid-pch  -Winvalid-utf8
	   -Wno-unicode	 -Wjump-misses-init -Wlarger-than=byte-size
	   -Wlogical-not-parentheses  -Wlogical-op -Wlong-long
	   -Wno-lto-type-mismatch -Wmain  -Wmaybe-uninitialized
	   -Wmemset-elt-size  -Wmemset-transposed-args
	   -Wmisleading-indentation  -Wmissing-attributes  -Wmissing-braces
	   -Wmissing-field-initializers	 -Wmissing-format-attribute
	   -Wmissing-include-dirs  -Wmissing-noreturn  -Wno-missing-profile
	   -Wno-multichar  -Wmultistatement-macros  -Wnonnull
	   -Wnonnull-compare -Wnormalized=[none|id|nfc|nfkc]
	   -Wnull-dereference  -Wno-odr -Wopenacc-parallelism -Wopenmp
	   -Wopenmp-simd -Wno-overflow	-Woverlength-strings
	   -Wno-override-init-side-effects -Wpacked
	   -Wno-packed-bitfield-compat	-Wpacked-not-aligned  -Wpadded
	   -Wparentheses  -Wno-pedantic-ms-format -Wpointer-arith
	   -Wno-pointer-compare	 -Wno-pointer-to-int-cast -Wno-pragmas
	   -Wno-prio-ctor-dtor	-Wredundant-decls -Wrestrict
	   -Wno-return-local-addr  -Wreturn-type -Wno-scalar-storage-order
	   -Wsequence-point -Wshadow  -Wshadow=global  -Wshadow=local
	   -Wshadow=compatible-local -Wno-shadow-ivar
	   -Wno-shift-count-negative  -Wno-shift-count-overflow
	   -Wshift-negative-value -Wno-shift-overflow  -Wshift-overflow=n
	   -Wsign-compare  -Wsign-conversion -Wno-sizeof-array-argument
	   -Wsizeof-array-div -Wsizeof-pointer-div  -Wsizeof-pointer-memaccess
	   -Wstack-protector  -Wstack-usage=byte-size  -Wstrict-aliasing
	   -Wstrict-aliasing=n	-Wstrict-overflow  -Wstrict-overflow=n
	   -Wstring-compare -Wno-stringop-overflow -Wno-stringop-overread
	   -Wno-stringop-truncation  -Wstrict-flex-arrays
	   -Wsuggest-attribute=[pure|const|noreturn|format|malloc] -Wswitch
	   -Wno-switch-bool  -Wswitch-default  -Wswitch-enum
	   -Wno-switch-outside-range  -Wno-switch-unreachable  -Wsync-nand
	   -Wsystem-headers  -Wtautological-compare  -Wtrampolines
	   -Wtrigraphs -Wtrivial-auto-var-init	-Wno-tsan  -Wtype-limits
	   -Wundef -Wuninitialized  -Wunknown-pragmas
	   -Wunsuffixed-float-constants	 -Wunused -Wunused-but-set-parameter
	   -Wunused-but-set-variable -Wunused-const-variable
	   -Wunused-const-variable=n -Wunused-function	-Wunused-label
	   -Wunused-local-typedefs -Wunused-macros -Wunused-parameter
	   -Wno-unused-result -Wunused-value  -Wunused-variable
	   -Wuse-after-free  -Wuse-after-free=n	 -Wuseless-cast -Wno-varargs
	   -Wvariadic-macros -Wvector-operation-performance -Wvla
	   -Wvla-larger-than=byte-size	-Wno-vla-larger-than
	   -Wvolatile-register-var  -Wwrite-strings -Wno-xor-used-as-pow
	   -Wzero-length-bounds

       Static Analyzer Options
	   -fanalyzer -fanalyzer-call-summaries -fanalyzer-checker=name
	   -fno-analyzer-feasibility -fanalyzer-fine-grained
	   -fanalyzer-show-events-in-system-headers -fno-analyzer-state-merge
	   -fno-analyzer-state-purge -fno-analyzer-suppress-followups
	   -fanalyzer-transitivity -fno-analyzer-undo-inlining
	   -fanalyzer-verbose-edges -fanalyzer-verbose-state-changes
	   -fanalyzer-verbosity=level -fdump-analyzer
	   -fdump-analyzer-callgraph -fdump-analyzer-exploded-graph
	   -fdump-analyzer-exploded-nodes -fdump-analyzer-exploded-nodes-2
	   -fdump-analyzer-exploded-nodes-3 -fdump-analyzer-exploded-paths
	   -fdump-analyzer-feasibility -fdump-analyzer-infinite-loop
	   -fdump-analyzer-json -fdump-analyzer-state-purge
	   -fdump-analyzer-stderr -fdump-analyzer-supergraph
	   -fdump-analyzer-untracked -Wno-analyzer-double-fclose
	   -Wno-analyzer-double-free
	   -Wno-analyzer-exposure-through-output-file
	   -Wno-analyzer-exposure-through-uninit-copy
	   -Wno-analyzer-fd-access-mode-mismatch -Wno-analyzer-fd-double-close
	   -Wno-analyzer-fd-leak -Wno-analyzer-fd-phase-mismatch
	   -Wno-analyzer-fd-type-mismatch -Wno-analyzer-fd-use-after-close
	   -Wno-analyzer-fd-use-without-check -Wno-analyzer-file-leak
	   -Wno-analyzer-free-of-non-heap
	   -Wno-analyzer-imprecise-fp-arithmetic -Wno-analyzer-infinite-loop
	   -Wno-analyzer-infinite-recursion -Wno-analyzer-jump-through-null
	   -Wno-analyzer-malloc-leak -Wno-analyzer-mismatching-deallocation
	   -Wno-analyzer-null-argument -Wno-analyzer-null-dereference
	   -Wno-analyzer-out-of-bounds -Wno-analyzer-overlapping-buffers
	   -Wno-analyzer-possible-null-argument
	   -Wno-analyzer-possible-null-dereference
	   -Wno-analyzer-putenv-of-auto-var -Wno-analyzer-shift-count-negative
	   -Wno-analyzer-shift-count-overflow
	   -Wno-analyzer-stale-setjmp-buffer
	   -Wno-analyzer-tainted-allocation-size
	   -Wno-analyzer-tainted-assertion -Wno-analyzer-tainted-array-index
	   -Wno-analyzer-tainted-divisor -Wno-analyzer-tainted-offset
	   -Wno-analyzer-tainted-size -Wanalyzer-symbol-too-complex
	   -Wanalyzer-too-complex -Wno-analyzer-undefined-behavior-strtok
	   -Wno-analyzer-unsafe-call-within-signal-handler
	   -Wno-analyzer-use-after-free
	   -Wno-analyzer-use-of-pointer-in-stale-stack-frame
	   -Wno-analyzer-use-of-uninitialized-value
	   -Wno-analyzer-va-arg-type-mismatch -Wno-analyzer-va-list-exhausted
	   -Wno-analyzer-va-list-leak -Wno-analyzer-va-list-use-after-va-end
	   -Wno-analyzer-write-to-const -Wno-analyzer-write-to-string-literal

       C and Objective-C-only Warning Options
	   -Wbad-function-cast	-Wmissing-declarations
	   -Wmissing-parameter-type -Wdeclaration-missing-parameter-type
	   -Wmissing-prototypes -Wmissing-variable-declarations
	   -Wnested-externs -Wold-style-declaration  -Wold-style-definition
	   -Wstrict-prototypes	-Wtraditional  -Wtraditional-conversion
	   -Wdeclaration-after-statement  -Wpointer-sign

       Debugging Options
	   -g  -glevel	-gdwarf	 -gdwarf-version -gbtf -gctf  -gctflevel -ggdb
	   -grecord-gcc-switches  -gno-record-gcc-switches -gstrict-dwarf
	   -gno-strict-dwarf -gas-loc-support  -gno-as-loc-support
	   -gas-locview-support	 -gno-as-locview-support -gcodeview
	   -gcolumn-info  -gno-column-info  -gdwarf32  -gdwarf64
	   -gstatement-frontiers  -gno-statement-frontiers
	   -gvariable-location-views  -gno-variable-location-views
	   -ginternal-reset-location-views  -gno-internal-reset-location-views
	   -ginline-points  -gno-inline-points -gvms -gz[=type] -gsplit-dwarf
	   -gdescribe-dies  -gno-describe-dies -fdebug-prefix-map=old=new
	   -fdebug-types-section -fno-eliminate-unused-debug-types
	   -femit-struct-debug-baseonly	 -femit-struct-debug-reduced
	   -femit-struct-debug-detailed[=spec-list]
	   -fno-eliminate-unused-debug-symbols	-femit-class-debug-always
	   -fno-merge-debug-strings  -fno-dwarf2-cfi-asm -fvar-tracking
	   -fvar-tracking-assignments

       Optimization Options
	   -faggressive-loop-optimizations -falign-functions[=n[:m:[n2[:m2]]]]
	   -falign-jumps[=n[:m:[n2[:m2]]]] -falign-labels[=n[:m:[n2[:m2]]]]
	   -falign-loops[=n[:m:[n2[:m2]]]] -fmin-function-alignment=[n]
	   -fno-allocation-dce -fallow-store-data-races -fassociative-math
	   -fauto-profile  -fauto-profile[=path] -fauto-inc-dec
	   -fbranch-probabilities -fcaller-saves -fcombine-stack-adjustments
	   -fconserve-stack -ffold-mem-offsets -fcompare-elim
	   -fcprop-registers  -fcrossjumping -fcse-follow-jumps
	   -fcse-skip-blocks  -fcx-fortran-rules -fcx-limited-range
	   -fdata-sections  -fdce  -fdelayed-branch
	   -fdelete-null-pointer-checks	 -fdevirtualize
	   -fdevirtualize-speculatively -fdevirtualize-at-ltrans  -fdse
	   -fearly-inlining  -fipa-sra	-fexpensive-optimizations
	   -ffat-lto-objects -ffast-math  -ffinite-math-only  -ffloat-store
	   -fexcess-precision=style -ffinite-loops -fforward-propagate
	   -ffp-contract=style	-ffunction-sections -fgcse
	   -fgcse-after-reload	-fgcse-las  -fgcse-lm  -fgraphite-identity
	   -fgcse-sm  -fhoist-adjacent-loads  -fif-conversion -fif-conversion2
	   -findirect-inlining -finline-stringops[=fn] -finline-functions
	   -finline-functions-called-once  -finline-limit=n
	   -finline-small-functions -fipa-modref -fipa-cp  -fipa-cp-clone
	   -fipa-bit-cp	 -fipa-vrp  -fipa-pta  -fipa-profile  -fipa-pure-const
	   -fipa-reference  -fipa-reference-addressable -fipa-stack-alignment
	   -fipa-icf  -fira-algorithm=algorithm -flive-patching=level
	   -fira-region=region	-fira-hoist-pressure -fira-loop-pressure
	   -fno-ira-share-save-slots -fno-ira-share-spill-slots
	   -fisolate-erroneous-paths-dereference
	   -fisolate-erroneous-paths-attribute -fivopts
	   -fkeep-inline-functions  -fkeep-static-functions
	   -fkeep-static-consts	 -flimit-function-alignment
	   -flive-range-shrinkage -floop-block	-floop-interchange
	   -floop-strip-mine -floop-unroll-and-jam  -floop-nest-optimize
	   -floop-parallelize-all  -flra-remat	-flto  -flto-compression-level
	   -flto-partition=alg	-fmerge-all-constants -fmerge-constants
	   -fmodulo-sched  -fmodulo-sched-allow-regmoves
	   -fmove-loop-invariants  -fmove-loop-stores  -fno-branch-count-reg
	   -fno-defer-pop  -fno-fp-int-builtin-inexact	-fno-function-cse
	   -fno-guess-branch-probability  -fno-inline  -fno-math-errno
	   -fno-peephole -fno-peephole2	 -fno-printf-return-value
	   -fno-sched-interblock -fno-sched-spec  -fno-signed-zeros
	   -fno-toplevel-reorder  -fno-trapping-math
	   -fno-zero-initialized-in-bss -fomit-frame-pointer
	   -foptimize-sibling-calls -fpartial-inlining	-fpeel-loops
	   -fpredictive-commoning -fprefetch-loop-arrays -fprofile-correction
	   -fprofile-use  -fprofile-use=path -fprofile-partial-training
	   -fprofile-values -fprofile-reorder-functions -freciprocal-math
	   -free  -frename-registers  -freorder-blocks
	   -freorder-blocks-algorithm=algorithm -freorder-blocks-and-partition
	   -freorder-functions -frerun-cse-after-loop
	   -freschedule-modulo-scheduled-loops -frounding-math
	   -fsave-optimization-record -fsched2-use-superblocks
	   -fsched-pressure -fsched-spec-load  -fsched-spec-load-dangerous
	   -fsched-stalled-insns-dep[=n]  -fsched-stalled-insns[=n]
	   -fsched-group-heuristic  -fsched-critical-path-heuristic
	   -fsched-spec-insn-heuristic	-fsched-rank-heuristic
	   -fsched-last-insn-heuristic	-fsched-dep-count-heuristic
	   -fschedule-fusion -fschedule-insns  -fschedule-insns2
	   -fsection-anchors -fselective-scheduling  -fselective-scheduling2
	   -fsel-sched-pipelining  -fsel-sched-pipelining-outer-loops
	   -fsemantic-interposition  -fshrink-wrap  -fshrink-wrap-separate
	   -fsignaling-nans -fsingle-precision-constant
	   -fsplit-ivs-in-unroller  -fsplit-loops -fsplit-paths
	   -fsplit-wide-types  -fsplit-wide-types-early	 -fssa-backprop
	   -fssa-phiopt -fstdarg-opt  -fstore-merging  -fstrict-aliasing
	   -fipa-strict-aliasing -fthread-jumps	 -ftracer  -ftree-bit-ccp
	   -ftree-builtin-call-dce  -ftree-ccp	-ftree-ch -ftree-coalesce-vars
	   -ftree-copy-prop  -ftree-dce	 -ftree-dominator-opts -ftree-dse
	   -ftree-forwprop  -ftree-fre	-fcode-hoisting -ftree-loop-if-convert
	   -ftree-loop-im -ftree-phiprop  -ftree-loop-distribution
	   -ftree-loop-distribute-patterns -ftree-loop-ivcanon
	   -ftree-loop-linear  -ftree-loop-optimize -ftree-loop-vectorize
	   -ftree-parallelize-loops=n  -ftree-pre  -ftree-partial-pre
	   -ftree-pta -ftree-reassoc  -ftree-scev-cprop	 -ftree-sink
	   -ftree-slsr	-ftree-sra -ftree-switch-conversion  -ftree-tail-merge
	   -ftree-ter  -ftree-vectorize	 -ftree-vrp  -ftrivial-auto-var-init
	   -funconstrained-commons -funit-at-a-time  -funroll-all-loops
	   -funroll-loops -funsafe-math-optimizations  -funswitch-loops
	   -fipa-ra  -fvariable-expansion-in-unroller  -fvect-cost-model
	   -fvpt -fweb	-fwhole-program	 -fwpa	-fuse-linker-plugin
	   -fzero-call-used-regs --param name=value -O	-O0  -O1  -O2  -O3
	   -Os	-Ofast	-Og  -Oz

       Program Instrumentation Options
	   -p  -pg  -fprofile-arcs  --coverage	-ftest-coverage
	   -fcondition-coverage -fprofile-abs-path -fprofile-dir=path
	   -fprofile-generate  -fprofile-generate=path -fprofile-info-section
	   -fprofile-info-section=name -fprofile-note=path
	   -fprofile-prefix-path=path -fprofile-update=method
	   -fprofile-filter-files=regex -fprofile-exclude-files=regex
	   -fprofile-reproducible=[multithreaded|parallel-runs|serial]
	   -fsanitize=style  -fsanitize-recover	 -fsanitize-recover=style
	   -fsanitize-trap   -fsanitize-trap=style -fasan-shadow-offset=number
	   -fsanitize-sections=s1,s2,...  -fsanitize-undefined-trap-on-error
	   -fbounds-check -fcf-protection=[full|branch|return|none|check]
	   -fharden-compares -fharden-conditional-branches  -fhardened
	   -fharden-control-flow-redundancy  -fhardcfr-skip-leaf
	   -fhardcfr-check-exceptions  -fhardcfr-check-returning-calls
	   -fhardcfr-check-noreturn-calls=[always|no-xthrow|nothrow|never]
	   -fstack-protector  -fstack-protector-all  -fstack-protector-strong
	   -fstack-protector-explicit  -fstack-check
	   -fstack-limit-register=reg  -fstack-limit-symbol=sym
	   -fno-stack-limit  -fsplit-stack -fstrub=disable  -fstrub=strict
	   -fstrub=relaxed -fstrub=all	-fstrub=at-calls  -fstrub=internal
	   -fvtable-verify=[std|preinit|none] -fvtv-counts  -fvtv-debug
	   -finstrument-functions  -finstrument-functions-once
	   -finstrument-functions-exclude-function-list=sym,sym,...
	   -finstrument-functions-exclude-file-list=file,file,...
	   -fprofile-prefix-map=old=new -fpatchable-function-entry=N[,M]

       Preprocessor Options
	   -Aquestion=answer -A-question[=answer] -C  -CC  -Dmacro[=defn] -dD
	   -dI	-dM  -dN  -dU -fdebug-cpp  -fdirectives-only
	   -fdollars-in-identifiers -fexec-charset=charset
	   -fextended-identifiers -finput-charset=charset
	   -flarge-source-files -fmacro-prefix-map=old=new
	   -fmax-include-depth=depth -fno-canonical-system-headers  -fpch-deps
	   -fpch-preprocess -fpreprocessed  -ftabstop=width
	   -ftrack-macro-expansion -fwide-exec-charset=charset
	   -fworking-directory -H  -imacros file  -include file -M  -MD	 -MF
	   -MG	-MM  -MMD  -MP	-MQ  -MT -Mno-modules -no-integrated-cpp  -P
	   -pthread  -remap -traditional  -traditional-cpp  -trigraphs -Umacro
	   -undef -Wp,option  -Xpreprocessor option

       Assembler Options
	   -Wa,option  -Xassembler option

       Linker Options
	   object-file-name  -fuse-ld=linker  -llibrary -nostartfiles
	   -nodefaultlibs  -nolibc  -nostdlib  -nostdlib++ -e entry
	   --entry=entry -pie  -pthread	 -r  -rdynamic -s  -static
	   -static-pie	-static-libgcc	-static-libstdc++ -static-libasan
	   -static-libtsan  -static-liblsan  -static-libubsan -shared
	   -shared-libgcc  -symbolic -T script	-Wl,option  -Xlinker option -u
	   symbol  -z keyword

       Directory Options
	   -Bprefix  -Idir  -I- -idirafter dir -imacros file  -imultilib dir
	   -iplugindir=dir  -iprefix file -iquote dir  -isysroot dir  -isystem
	   dir -iwithprefix dir	 -iwithprefixbefore dir -Ldir
	   -no-canonical-prefixes  --no-sysroot-suffix -nostdinc  -nostdinc++
	   --sysroot=dir

       Code Generation Options
	   -fcall-saved-reg  -fcall-used-reg -ffixed-reg  -fexceptions
	   -fnon-call-exceptions  -fdelete-dead-exceptions  -funwind-tables
	   -fasynchronous-unwind-tables -fno-gnu-unique
	   -finhibit-size-directive  -fcommon  -fno-ident -fpcc-struct-return
	   -fpic  -fPIC	 -fpie	-fPIE  -fno-plt -fno-jump-tables
	   -fno-bit-tests -frecord-gcc-switches -freg-struct-return
	   -fshort-enums  -fshort-wchar -fverbose-asm  -fpack-struct[=n]
	   -fleading-underscore	 -ftls-model=model -fstack-reuse=reuse_level
	   -ftrampolines -ftrampoline-impl=[stack|heap] -ftrapv	 -fwrapv
	   -fvisibility=[default|internal|hidden|protected]
	   -fstrict-volatile-bitfields	-fsync-libcalls

       Developer Options
	   -dletters  -dumpspecs  -dumpmachine	-dumpversion -dumpfullversion
	   -fcallgraph-info[=su,da] -fchecking	-fchecking=n -fdbg-cnt-list
	   -fdbg-cnt=counter-value-list -fdisable-ipa-pass_name
	   -fdisable-rtl-pass_name -fdisable-rtl-pass-name=range-list
	   -fdisable-tree-pass_name -fdisable-tree-pass-name=range-list
	   -fdump-debug	 -fdump-earlydebug -fdump-noaddr  -fdump-unnumbered
	   -fdump-unnumbered-links -fdump-final-insns[=file] -fdump-ipa-all
	   -fdump-ipa-cgraph  -fdump-ipa-inline -fdump-lang-all
	   -fdump-lang-switch -fdump-lang-switch-options
	   -fdump-lang-switch-options=filename -fdump-passes -fdump-rtl-pass
	   -fdump-rtl-pass=filename -fdump-statistics -fdump-tree-all
	   -fdump-tree-switch -fdump-tree-switch-options
	   -fdump-tree-switch-options=filename -fcompare-debug[=opts]
	   -fcompare-debug-second -fenable-kind-pass -fenable-kind-pass=range-
	   list -fira-verbose=n -flto-report  -flto-report-wpa
	   -fmem-report-wpa -fmem-report  -fpre-ipa-mem-report
	   -fpost-ipa-mem-report -fopt-info  -fopt-info-options[=file]
	   -fmultiflags	 -fprofile-report -frandom-seed=string
	   -fsched-verbose=n -fsel-sched-verbose  -fsel-sched-dump-cfg
	   -fsel-sched-pipelining-verbose -fstats  -fstack-usage
	   -ftime-report  -ftime-report-details
	   -fvar-tracking-assignments-toggle  -gtoggle
	   -print-file-name=library  -print-libgcc-file-name
	   -print-multi-directory  -print-multi-lib  -print-multi-os-directory
	   -print-prog-name=program  -print-search-dirs	 -Q -print-sysroot
	   -print-sysroot-headers-suffix -save-temps  -save-temps=cwd
	   -save-temps=obj  -time[=file]

       Machine-Dependent Options
	   AArch64 Options -mabi=name  -mbig-endian  -mlittle-endian
	   -mgeneral-regs-only -mcmodel=tiny  -mcmodel=small  -mcmodel=large
	   -mstrict-align  -mno-strict-align -momit-leaf-frame-pointer
	   -mtls-dialect=desc  -mtls-dialect=traditional -mtls-size=size
	   -mfix-cortex-a53-835769  -mfix-cortex-a53-843419
	   -mlow-precision-recip-sqrt  -mlow-precision-sqrt
	   -mlow-precision-div -mpc-relative-literal-loads
	   -msign-return-address=scope -mbranch-protection=none|standard|pac-
	   ret[+leaf +b-key]|bti -mharden-sls=opts -march=name	-mcpu=name
	   -mtune=name -moverride=string  -mverbose-cost-dump
	   -mstack-protector-guard=guard -mstack-protector-guard-reg=sysreg
	   -mstack-protector-guard-offset=offset -mtrack-speculation
	   -moutline-atomics -mearly-ldp-fusion -mlate-ldp-fusion

	   Adapteva Epiphany Options -mhalf-reg-file  -mprefer-short-insn-regs
	   -mbranch-cost=num  -mcmove  -mnops=num  -msoft-cmpsf -msplit-lohi
	   -mpost-inc  -mpost-modify  -mstack-offset=num -mround-nearest
	   -mlong-calls	 -mshort-calls	-msmall16 -mfp-mode=mode
	   -mvect-double  -max-vect-align=num -msplit-vecmove-early
	   -m1reg-reg

	   AMD GCN Options -march=gpu -mtune=gpu -mstack-size=bytes

	   ARC Options -mbarrel-shifter	 -mjli-always -mcpu=cpu	 -mA6
	   -mARC600  -mA7  -mARC700 -mdpfp  -mdpfp-compact  -mdpfp-fast
	   -mno-dpfp-lrsr -mea	-mno-mpy  -mmul32x16  -mmul64  -matomic -mnorm
	   -mspfp  -mspfp-compact  -mspfp-fast	-msimd	-msoft-float  -mswap
	   -mcrc  -mdsp-packa  -mdvbf  -mlock  -mmac-d16  -mmac-24  -mrtsc
	   -mswape -mtelephony	-mxy  -misize  -mannotate-align	 -marclinux
	   -marclinux_prof -mlong-calls	 -mmedium-calls	 -msdata
	   -mirq-ctrl-saved -mrgf-banked-regs  -mlpc-width=width  -G num
	   -mvolatile-cache  -mtp-regno=regno -malign-call  -mauto-modify-reg
	   -mbbit-peephole  -mno-brcc -mcase-vector-pcrel  -mcompact-casesi
	   -mno-cond-exec  -mearly-cbranchsi -mexpand-adddi  -mindexed-loads
	   -mlra  -mlra-priority-none -mlra-priority-compact
	   -mlra-priority-noncompact  -mmillicode -mmixed-code	-mq-class
	   -mRcq  -mRcw	 -msize-level=level -mtune=cpu	-mmultcost=num
	   -mcode-density-frame -munalign-prob-threshold=probability
	   -mmpy-option=multo -mdiv-rem	 -mcode-density	 -mll64	 -mfpu=fpu
	   -mrf16  -mbranch-index

	   ARM Options -mapcs-frame  -mno-apcs-frame -mabi=name
	   -mapcs-stack-check  -mno-apcs-stack-check -mapcs-reentrant
	   -mno-apcs-reentrant -mgeneral-regs-only -msched-prolog
	   -mno-sched-prolog -mlittle-endian  -mbig-endian -mbe8  -mbe32
	   -mfloat-abi=name -mfp16-format=name -mthumb-interwork
	   -mno-thumb-interwork -mcpu=name  -march=name	 -mfpu=name
	   -mtune=name	-mprint-tune-info -mstructure-size-boundary=n
	   -mabort-on-noreturn -mlong-calls  -mno-long-calls -msingle-pic-base
	   -mno-single-pic-base -mpic-register=reg -mnop-fun-dllimport
	   -mpoke-function-name -mthumb	 -marm	-mflip-thumb -mtpcs-frame
	   -mtpcs-leaf-frame -mcaller-super-interworking
	   -mcallee-super-interworking -mtp=name  -mtls-dialect=dialect
	   -mword-relocations -mfix-cortex-m3-ldrd
	   -mfix-cortex-a57-aes-1742098 -mfix-cortex-a72-aes-1655431
	   -munaligned-access -mneon-for-64bits -mslow-flash-data
	   -masm-syntax-unified -mrestrict-it -mverbose-cost-dump -mpure-code
	   -mcmse -mfix-cmse-cve-2021-35465 -mstack-protector-guard=guard
	   -mstack-protector-guard-offset=offset -mfdpic
	   -mbranch-protection=none|standard|pac-ret[+leaf] [+bti]|bti[+pac-
	   ret[+leaf]]

	   AVR Options -mmcu=mcu  -mabsdata  -maccumulate-args
	   -mbranch-cost=cost  -mfuse-add=level -mcall-prologues
	   -mgas-isr-prologues	-mint8	-mflmap -mdouble=bits
	   -mlong-double=bits -mn_flash=size  -mno-interrupts
	   -mmain-is-OS_task  -mrelax  -mrmw  -mstrict-X  -mtiny-stack
	   -mrodata-in-ram  -mfract-convert-truncate -mshort-calls  -mskip-bug
	   -nodevicelib	 -nodevicespecs -Waddr-space-convert  -Wmisspelled-isr

	   Blackfin Options -mcpu=cpu[-sirevision] -msim
	   -momit-leaf-frame-pointer  -mno-omit-leaf-frame-pointer
	   -mspecld-anomaly  -mno-specld-anomaly  -mcsync-anomaly
	   -mno-csync-anomaly -mlow-64k	 -mno-low64k  -mstack-check-l1
	   -mid-shared-library -mno-id-shared-library  -mshared-library-id=n
	   -mleaf-id-shared-library  -mno-leaf-id-shared-library -msep-data
	   -mno-sep-data  -mlong-calls	-mno-long-calls -mfast-fp
	   -minline-plt	 -mmulticore  -mcorea  -mcoreb	-msdram -micplb

	   C6X Options -mbig-endian  -mlittle-endian  -march=cpu -msim
	   -msdata=sdata-type

	   CRIS Options -mcpu=cpu  -march=cpu -mtune=cpu -mmax-stack-frame=n
	   -metrax4  -metrax100	 -mpdebug  -mcc-init  -mno-side-effects
	   -mstack-align  -mdata-align	-mconst-align -m32-bit	-m16-bit
	   -m8-bit  -mno-prologue-epilogue -melf  -maout  -sim	-sim2
	   -mmul-bug-workaround	 -mno-mul-bug-workaround

	   C-SKY Options -march=arch  -mcpu=cpu -mbig-endian  -EB
	   -mlittle-endian  -EL -mhard-float  -msoft-float  -mfpu=fpu
	   -mdouble-float  -mfdivdu -mfloat-abi=name -melrw  -mistack  -mmp
	   -mcp	 -mcache  -msecurity  -mtrust -mdsp  -medsp  -mvdsp -mdiv
	   -msmart  -mhigh-registers  -manchor -mpushpop  -mmultiple-stld
	   -mconstpool	-mstack-size  -mccrt -mbranch-cost=n  -mcse-cc
	   -msched-prolog -msim

	   Darwin Options -all_load  -allowable_client	-arch
	   -arch_errors_fatal -arch_only  -bind_at_load	 -bundle
	   -bundle_loader -client_name	-compatibility_version
	   -current_version -dead_strip -dependency-file  -dylib_file
	   -dylinker_install_name -dynamic  -dynamiclib
	   -exported_symbols_list -filelist  -flat_namespace
	   -force_cpusubtype_ALL -force_flat_namespace
	   -headerpad_max_install_names -iframework -image_base	 -init
	   -install_name  -keep_private_externs -multi_module
	   -multiply_defined  -multiply_defined_unused -noall_load
	   -no_dead_strip_inits_and_terms -nodefaultrpaths -nofixprebinding
	   -nomultidefs	 -noprebind  -noseglinkedit -pagezero_size  -prebind
	   -prebind_all_twolevel_modules -private_bundle  -read_only_relocs
	   -sectalign -sectobjectsymbols  -whyload  -seg1addr -sectcreate
	   -sectobjectsymbols  -sectorder -segaddr  -segs_read_only_addr
	   -segs_read_write_addr -seg_addr_table  -seg_addr_table_filename
	   -seglinkedit -segprot  -segs_read_only_addr	-segs_read_write_addr
	   -single_module  -static  -sub_library  -sub_umbrella
	   -twolevel_namespace	-umbrella  -undefined -unexported_symbols_list
	   -weak_reference_mismatches -whatsloaded  -F	-gused	-gfull
	   -mmacosx-version-min=version -mkernel  -mone-byte-bool

	   DEC Alpha Options -mno-fp-regs  -msoft-float -mieee
	   -mieee-with-inexact	-mieee-conformant -mfp-trap-mode=mode
	   -mfp-rounding-mode=mode -mtrap-precision=mode  -mbuild-constants
	   -mcpu=cpu-type  -mtune=cpu-type -mbwx  -mmax	 -mfix	-mcix
	   -mfloat-vax	-mfloat-ieee -mexplicit-relocs	-msmall-data
	   -mlarge-data -msmall-text  -mlarge-text -mmemory-latency=time

	   eBPF Options -mbig-endian -mlittle-endian -mframe-limit=bytes
	   -mxbpf -mco-re -mno-co-re -mjmpext -mjmp32 -malu32 -mv3-atomics
	   -mbswap -msdiv -msmov -mcpu=version -masm=dialect
	   -minline-memops-threshold=bytes

	   FR30 Options -msmall-model  -mno-lsim

	   FT32 Options -msim  -mlra  -mnodiv  -mft32b	-mcompress  -mnopm

	   FRV Options -mgpr-32	 -mgpr-64  -mfpr-32  -mfpr-64 -mhard-float
	   -msoft-float -malloc-cc  -mfixed-cc	-mdword	 -mno-dword -mdouble
	   -mno-double -mmedia	-mno-media  -mmuladd  -mno-muladd -mfdpic
	   -minline-plt	 -mgprel-ro  -multilib-library-pic -mlinked-fp
	   -mlong-calls	 -malign-labels -mlibrary-pic  -macc-4	-macc-8 -mpack
	   -mno-pack  -mno-eflags  -mcond-move	-mno-cond-move
	   -moptimize-membar  -mno-optimize-membar -mscc  -mno-scc
	   -mcond-exec	-mno-cond-exec -mvliw-branch  -mno-vliw-branch
	   -mmulti-cond-exec  -mno-multi-cond-exec  -mnested-cond-exec
	   -mno-nested-cond-exec  -mtomcat-stats -mTLS	-mtls -mcpu=cpu

	   GNU/Linux Options -mglibc  -muclibc	-mmusl	-mbionic  -mandroid
	   -tno-android-cc  -tno-android-ld

	   H8/300 Options -mrelax  -mh	-ms  -mn  -mexr	 -mno-exr  -mint32
	   -malign-300

	   HPPA Options -march=architecture-type -matomic-libcalls
	   -mbig-switch -mcaller-copies	 -mdisable-fpregs  -mdisable-indexing
	   -mordered  -mfast-indirect-calls  -mgas  -mgnu-ld   -mhp-ld
	   -mfixed-range=register-range -mcoherent-ldcw -mjump-in-delay
	   -mlinker-opt	 -mlong-calls -mlong-load-store	 -mno-atomic-libcalls
	   -mno-disable-fpregs -mno-disable-indexing  -mno-fast-indirect-calls
	   -mno-gas -mno-jump-in-delay	-mno-long-load-store
	   -mno-portable-runtime  -mno-soft-float -mno-space-regs
	   -msoft-float	 -mpa-risc-1-0 -mpa-risc-1-1  -mpa-risc-2-0
	   -mportable-runtime -mschedule=cpu-type  -mspace-regs	 -msoft-mult
	   -msio  -mwsio -munix=unix-std  -nolibdld  -static  -threads

	   IA-64 Options -mbig-endian  -mlittle-endian	-mgnu-as  -mgnu-ld
	   -mno-pic -mvolatile-asm-stop	 -mregister-names  -msdata  -mno-sdata
	   -mconstant-gp  -mauto-pic  -mfused-madd
	   -minline-float-divide-min-latency
	   -minline-float-divide-max-throughput -mno-inline-float-divide
	   -minline-int-divide-min-latency -minline-int-divide-max-throughput
	   -mno-inline-int-divide -minline-sqrt-min-latency
	   -minline-sqrt-max-throughput -mno-inline-sqrt -mdwarf2-asm
	   -mearly-stop-bits -mfixed-range=register-range  -mtls-size=tls-size
	   -mtune=cpu-type  -milp32  -mlp64 -msched-br-data-spec
	   -msched-ar-data-spec	 -msched-control-spec -msched-br-in-data-spec
	   -msched-ar-in-data-spec  -msched-in-control-spec -msched-spec-ldc
	   -msched-spec-control-ldc -msched-prefer-non-data-spec-insns
	   -msched-prefer-non-control-spec-insns
	   -msched-stop-bits-after-every-cycle
	   -msched-count-spec-in-critical-path
	   -msel-sched-dont-check-control-spec	-msched-fp-mem-deps-zero-cost
	   -msched-max-memory-insns-hard-limit	-msched-max-memory-insns=max-
	   insns

	   LM32 Options -mbarrel-shift-enabled	-mdivide-enabled
	   -mmultiply-enabled -msign-extend-enabled  -muser-enabled

	   LoongArch Options -march=arch-type  -mtune=tune-type -mabi=base-
	   abi-type -mfpu=fpu-type -msimd=simd-type -msoft-float
	   -msingle-float -mdouble-float -mlsx -mno-lsx -mlasx -mno-lasx
	   -mbranch-cost=n  -mcheck-zero-division -mno-check-zero-division
	   -mcond-move-int  -mno-cond-move-int -mcond-move-float
	   -mno-cond-move-float -memcpy	 -mno-memcpy -mstrict-align
	   -mno-strict-align -mmax-inline-memcpy-size=n
	   -mexplicit-relocs=style -mexplicit-relocs -mno-explicit-relocs
	   -mdirect-extern-access -mno-direct-extern-access -mcmodel=code-
	   model -mrelax -mpass-mrelax-to-as -mrecip  -mrecip=opt -mfrecipe
	   -mno-frecipe -mdiv32 -mno-div32 -mlam-bh -mno-lam-bh -mlamcas
	   -mno-lamcas -mld-seq-sa -mno-ld-seq-sa -mtls-dialect=opt

	   M32R/D Options -m32r2  -m32rx  -m32r -mdebug -malign-loops
	   -mno-align-loops -missue-rate=number -mbranch-cost=number
	   -mmodel=code-size-model-type -msdata=sdata-type -mno-flush-func
	   -mflush-func=name -mno-flush-trap  -mflush-trap=number -G num

	   M32C Options -mcpu=cpu  -msim  -memregs=number

	   M680x0 Options -march=arch  -mcpu=cpu  -mtune=tune -m68000  -m68020
	   -m68020-40  -m68020-60  -m68030  -m68040 -m68060  -mcpu32  -m5200
	   -m5206e  -m528x  -m5307  -m5407 -mcfv4e  -mbitfield	-mno-bitfield
	   -mc68000  -mc68020 -mnobitfield  -mrtd  -mno-rtd  -mdiv  -mno-div
	   -mshort -mno-short  -mhard-float  -m68881  -msoft-float  -mpcrel
	   -malign-int	-mstrict-align	-msep-data  -mno-sep-data
	   -mshared-library-id=n  -mid-shared-library  -mno-id-shared-library
	   -mxgot  -mno-xgot  -mlong-jump-table-offsets

	   MCore Options -mhardlit  -mno-hardlit  -mdiv	 -mno-div
	   -mrelax-immediates -mno-relax-immediates  -mwide-bitfields
	   -mno-wide-bitfields -m4byte-functions  -mno-4byte-functions
	   -mcallgraph-data -mno-callgraph-data	 -mslow-bytes  -mno-slow-bytes
	   -mno-lsim -mlittle-endian  -mbig-endian  -m210  -m340
	   -mstack-increment

	   MicroBlaze Options -msoft-float  -mhard-float  -msmall-divides
	   -mcpu=cpu -mmemcpy  -mxl-soft-mul  -mxl-soft-div  -mxl-barrel-shift
	   -mxl-pattern-compare	 -mxl-stack-check  -mxl-gp-opt	-mno-clearbss
	   -mxl-multiply-high  -mxl-float-convert  -mxl-float-sqrt
	   -mbig-endian	 -mlittle-endian  -mxl-reorder	-mxl-mode-app-model
	   -mpic-data-is-text-relative

	   MIPS Options -EL  -EB  -march=arch  -mtune=arch -mips1  -mips2
	   -mips3  -mips4  -mips32  -mips32r2  -mips32r3  -mips32r5 -mips32r6
	   -mips64  -mips64r2  -mips64r3  -mips64r5  -mips64r6 -mips16
	   -mno-mips16	-mflip-mips16 -minterlink-compressed
	   -mno-interlink-compressed -minterlink-mips16	 -mno-interlink-mips16
	   -mabi=abi  -mabicalls  -mno-abicalls -mshared  -mno-shared  -mplt
	   -mno-plt  -mxgot  -mno-xgot -mgp32  -mgp64  -mfp32  -mfpxx  -mfp64
	   -mhard-float	 -msoft-float -mno-float  -msingle-float
	   -mdouble-float -modd-spreg  -mno-odd-spreg -mabs=mode
	   -mnan=encoding -mdsp	 -mno-dsp  -mdspr2  -mno-dspr2 -mmcu
	   -mmno-mcu -meva  -mno-eva -mvirt  -mno-virt -mxpa  -mno-xpa -mcrc
	   -mno-crc -mginv  -mno-ginv -mmicromips  -mno-micromips -mmsa
	   -mno-msa -mloongson-mmi  -mno-loongson-mmi -mloongson-ext
	   -mno-loongson-ext -mloongson-ext2  -mno-loongson-ext2 -mfpu=fpu-
	   type -msmartmips  -mno-smartmips -mpaired-single
	   -mno-paired-single  -mdmx  -mno-mdmx -mips3d	 -mno-mips3d  -mmt
	   -mno-mt  -mllsc  -mno-llsc -mlong64	-mlong32  -msym32  -mno-sym32
	   -Gnum  -mlocal-sdata	 -mno-local-sdata -mextern-sdata
	   -mno-extern-sdata  -mgpopt  -mno-gopt -membedded-data
	   -mno-embedded-data -muninit-const-in-rodata
	   -mno-uninit-const-in-rodata -mcode-readable=setting
	   -msplit-addresses  -mno-split-addresses -mexplicit-relocs
	   -mno-explicit-relocs -mexplicit-relocs=release
	   -mcheck-zero-division  -mno-check-zero-division -mdivide-traps
	   -mdivide-breaks -mload-store-pairs  -mno-load-store-pairs
	   -mstrict-align  -mno-strict-align -mno-unaligned-access
	   -munaligned-access -mmemcpy	-mno-memcpy  -mlong-calls
	   -mno-long-calls -mmad  -mno-mad  -mimadd  -mno-imadd	 -mfused-madd
	   -mno-fused-madd  -nocpp -mfix-24k  -mno-fix-24k -mfix-r4000
	   -mno-fix-r4000  -mfix-r4400	-mno-fix-r4400 -mfix-r5900
	   -mno-fix-r5900 -mfix-r10000	-mno-fix-r10000	 -mfix-rm7000
	   -mno-fix-rm7000 -mfix-vr4120	 -mno-fix-vr4120 -mfix-vr4130
	   -mno-fix-vr4130  -mfix-sb1  -mno-fix-sb1 -mflush-func=func
	   -mno-flush-func -mbranch-cost=num  -mbranch-likely
	   -mno-branch-likely -mcompact-branches=policy -mfp-exceptions
	   -mno-fp-exceptions -mvr4130-align  -mno-vr4130-align	 -msynci
	   -mno-synci -mlxc1-sxc1  -mno-lxc1-sxc1  -mmadd4  -mno-madd4
	   -mrelax-pic-calls  -mno-relax-pic-calls  -mmcount-ra-address
	   -mframe-header-opt  -mno-frame-header-opt

	   MMIX Options -mlibfuncs  -mno-libfuncs  -mepsilon  -mno-epsilon
	   -mabi=gnu -mabi=mmixware  -mzero-extend  -mknuthdiv
	   -mtoplevel-symbols -melf  -mbranch-predict  -mno-branch-predict
	   -mbase-addresses -mno-base-addresses	 -msingle-exit
	   -mno-single-exit

	   MN10300 Options -mmult-bug  -mno-mult-bug -mno-am33	-mam33
	   -mam33-2  -mam34 -mtune=cpu-type -mreturn-pointer-on-d0 -mno-crt0
	   -mrelax  -mliw  -msetlb

	   Moxie Options -meb  -mel  -mmul.x  -mno-crt0

	   MSP430 Options -msim	 -masm-hex  -mmcu=  -mcpu=  -mlarge  -msmall
	   -mrelax -mwarn-mcu -mcode-region=  -mdata-region= -msilicon-errata=
	   -msilicon-errata-warn= -mhwmult=  -minrt  -mtiny-printf
	   -mmax-inline-shift=

	   NDS32 Options -mbig-endian  -mlittle-endian -mreduced-regs
	   -mfull-regs -mcmov  -mno-cmov -mext-perf  -mno-ext-perf -mext-perf2
	   -mno-ext-perf2 -mext-string	-mno-ext-string -mv3push  -mno-v3push
	   -m16bit  -mno-16bit -misr-vector-size=num -mcache-block-size=num
	   -march=arch -mcmodel=code-model -mctor-dtor	-mrelax

	   Nios II Options -G num  -mgpopt=option  -mgpopt  -mno-gpopt
	   -mgprel-sec=regexp  -mr0rel-sec=regexp -mel	-meb -mno-bypass-cache
	   -mbypass-cache -mno-cache-volatile  -mcache-volatile
	   -mno-fast-sw-div  -mfast-sw-div -mhw-mul  -mno-hw-mul  -mhw-mulx
	   -mno-hw-mulx	 -mno-hw-div  -mhw-div -mcustom-insn=N
	   -mno-custom-insn -mcustom-fpu-cfg=name -mhal	 -msmallc
	   -msys-crt0=name  -msys-lib=name -march=arch	-mbmx  -mno-bmx	 -mcdx
	   -mno-cdx

	   Nvidia PTX Options -m64  -mmainkernel  -moptimize

	   OpenRISC Options -mboard=name  -mnewlib  -mhard-mul	-mhard-div
	   -msoft-mul  -msoft-div -msoft-float	-mhard-float  -mdouble-float
	   -munordered-float -mcmov  -mror  -mrori  -msext  -msfimm  -mshftimm
	   -mcmodel=code-model

	   PDP-11 Options -mfpu	 -msoft-float  -mac0  -mno-ac0	-m40  -m45
	   -m10 -mint32	 -mno-int16  -mint16  -mno-int32 -msplit  -munix-asm
	   -mdec-asm  -mgnu-asm	 -mlra

	   PowerPC Options See RS/6000 and PowerPC Options.

	   PRU Options -mmcu=mcu  -minrt  -mno-relax  -mloop -mabi=variant

	   RISC-V Options -mbranch-cost=N-instruction -mplt  -mno-plt
	   -mabi=ABI-string -mfdiv  -mno-fdiv -mdiv  -mno-div -misa-spec=ISA-
	   spec-string -march=ISA-string -mtune=processor-string
	   -mpreferred-stack-boundary=num -msmall-data-limit=N-bytes
	   -msave-restore  -mno-save-restore -mshorten-memrefs
	   -mno-shorten-memrefs -mstrict-align	-mno-strict-align
	   -mcmodel=medlow  -mcmodel=medany -mexplicit-relocs
	   -mno-explicit-relocs -mrelax	 -mno-relax -mriscv-attribute
	   -mno-riscv-attribute -malign-data=type -mbig-endian
	   -mlittle-endian -mstack-protector-guard=guard
	   -mstack-protector-guard-reg=reg
	   -mstack-protector-guard-offset=offset -mcsr-check -mno-csr-check
	   -mmovcc  -mno-movcc -minline-atomics	 -mno-inline-atomics
	   -minline-strlen  -mno-inline-strlen -minline-strcmp
	   -mno-inline-strcmp -minline-strncmp	-mno-inline-strncmp
	   -mtls-dialect=desc  -mtls-dialect=trad

	   RL78 Options -msim  -mmul=none  -mmul=g13  -mmul=g14	 -mallregs
	   -mcpu=g10  -mcpu=g13	 -mcpu=g14  -mg10  -mg13  -mg14
	   -m64bit-doubles  -m32bit-doubles  -msave-mduc-in-interrupts

	   RS/6000 and PowerPC Options -mcpu=cpu-type -mtune=cpu-type
	   -mcmodel=code-model -mpowerpc64 -maltivec  -mno-altivec
	   -mpowerpc-gpopt  -mno-powerpc-gpopt -mpowerpc-gfxopt
	   -mno-powerpc-gfxopt -mmfcrf	-mno-mfcrf  -mpopcntb  -mno-popcntb
	   -mpopcntd  -mno-popcntd -mfprnd  -mno-fprnd -mcmpb  -mno-cmpb
	   -mhard-dfp  -mno-hard-dfp -mfull-toc	  -mminimal-toc
	   -mno-fp-in-toc  -mno-sum-in-toc -m64	 -m32  -mxl-compat
	   -mno-xl-compat  -mpe -malign-power  -malign-natural -msoft-float
	   -mhard-float	 -mmultiple  -mno-multiple -mupdate  -mno-update
	   -mavoid-indexed-addresses  -mno-avoid-indexed-addresses
	   -mfused-madd	 -mno-fused-madd  -mbit-align  -mno-bit-align
	   -mstrict-align  -mno-strict-align  -mrelocatable -mno-relocatable
	   -mrelocatable-lib  -mno-relocatable-lib -mtoc  -mno-toc  -mlittle
	   -mlittle-endian  -mbig  -mbig-endian -mdynamic-no-pic  -mswdiv
	   -msingle-pic-base -mprioritize-restricted-insns=priority
	   -msched-costly-dep=dependence_type -minsert-sched-nops=scheme
	   -mcall-aixdesc  -mcall-eabi	-mcall-freebsd -mcall-linux
	   -mcall-netbsd  -mcall-openbsd -mcall-sysv  -mcall-sysv-eabi
	   -mcall-sysv-noeabi -mtraceback=traceback_type -maix-struct-return
	   -msvr4-struct-return -mabi=abi-type	-msecure-plt  -mbss-plt
	   -mlongcall  -mno-longcall  -mpltseq	-mno-pltseq
	   -mblock-move-inline-limit=num -mblock-compare-inline-limit=num
	   -mblock-compare-inline-loop-limit=num -mno-block-ops-unaligned-vsx
	   -mstring-compare-inline-limit=num -misel  -mno-isel -mvrsave
	   -mno-vrsave -mmulhw	-mno-mulhw -mdlmzb  -mno-dlmzb -mprototype
	   -mno-prototype -msim	 -mmvme	 -mads	-myellowknife  -memb  -msdata
	   -msdata=opt	-mreadonly-in-sdata  -mvxworks	-G num -mrecip
	   -mrecip=opt	-mno-recip  -mrecip-precision -mno-recip-precision
	   -mveclibabi=type  -mfriz  -mno-friz -mpointers-to-nested-functions
	   -mno-pointers-to-nested-functions -msave-toc-indirect
	   -mno-save-toc-indirect -mpower8-fusion  -mno-mpower8-fusion
	   -mcrypto  -mno-crypto  -mhtm	 -mno-htm -mquad-memory
	   -mno-quad-memory -mquad-memory-atomic  -mno-quad-memory-atomic
	   -mcompat-align-parm	-mno-compat-align-parm -mfloat128
	   -mno-float128  -mfloat128-hardware  -mno-float128-hardware
	   -mgnu-attribute  -mno-gnu-attribute -mstack-protector-guard=guard
	   -mstack-protector-guard-reg=reg
	   -mstack-protector-guard-offset=offset -mprefixed -mno-prefixed
	   -mpcrel -mno-pcrel -mmma -mno-mmma -mrop-protect -mno-rop-protect
	   -mprivileged -mno-privileged

	   RX Options -m64bit-doubles  -m32bit-doubles	-fpu  -nofpu -mcpu=
	   -mbig-endian-data  -mlittle-endian-data -msmall-data -msim
	   -mno-sim -mas100-syntax  -mno-as100-syntax -mrelax
	   -mmax-constant-size= -mint-register= -mpid -mallow-string-insns
	   -mno-allow-string-insns -mjsr -mno-warn-multiple-fast-interrupts
	   -msave-acc-in-interrupts

	   S/390 and zSeries Options -mtune=cpu-type  -march=cpu-type
	   -mhard-float	 -msoft-float  -mhard-dfp  -mno-hard-dfp
	   -mlong-double-64  -mlong-double-128 -mbackchain  -mno-backchain
	   -mpacked-stack  -mno-packed-stack -msmall-exec  -mno-small-exec
	   -mmvcle  -mno-mvcle -m64  -m31  -mdebug  -mno-debug	-mesa  -mzarch
	   -mhtm  -mvx	-mzvector -mtpf-trace  -mno-tpf-trace
	   -mtpf-trace-skip  -mno-tpf-trace-skip -mfused-madd  -mno-fused-madd
	   -mwarn-framesize  -mwarn-dynamicstack  -mstack-size	-mstack-guard
	   -mhotpatch=halfwords,halfwords

	   SH Options -m1  -m2	-m2e -m2a-nofpu	 -m2a-single-only  -m2a-single
	   -m2a -m3  -m3e -m4-nofpu  -m4-single-only  -m4-single  -m4
	   -m4a-nofpu  -m4a-single-only	 -m4a-single  -m4a  -m4al -mb  -ml
	   -mdalign  -mrelax -mbigtable	 -mfmovd  -mrenesas  -mno-renesas
	   -mnomacsave -mieee  -mno-ieee  -mbitops  -misize
	   -minline-ic_invalidate  -mpadstruct -mprefergot  -musermode
	   -multcost=number  -mdiv=strategy -mdivsi3_libfunc=name
	   -mfixed-range=register-range -maccumulate-outgoing-args
	   -matomic-model=atomic-model -mbranch-cost=num  -mzdcbranch
	   -mno-zdcbranch -mcbranch-force-delay-slot -mfused-madd
	   -mno-fused-madd  -mfsca  -mno-fsca  -mfsrra	-mno-fsrra
	   -mpretend-cmove  -mtas

	   Solaris 2 Options -mclear-hwcap  -mno-clear-hwcap  -mimpure-text
	   -mno-impure-text -pthreads

	   SPARC Options -mcpu=cpu-type -mtune=cpu-type -mcmodel=code-model
	   -mmemory-model=mem-model -m32  -m64	-mapp-regs  -mno-app-regs
	   -mfaster-structs  -mno-faster-structs  -mflat  -mno-flat -mfpu
	   -mno-fpu  -mhard-float  -msoft-float -mhard-quad-float
	   -msoft-quad-float -mstack-bias  -mno-stack-bias -mstd-struct-return
	   -mno-std-struct-return -munaligned-doubles  -mno-unaligned-doubles
	   -muser-mode	-mno-user-mode -mv8plus	 -mno-v8plus  -mvis  -mno-vis
	   -mvis2  -mno-vis2  -mvis3  -mno-vis3 -mvis4	-mno-vis4  -mvis4b
	   -mno-vis4b -mcbcond	-mno-cbcond  -mfmaf  -mno-fmaf	-mfsmuld
	   -mno-fsmuld -mpopc  -mno-popc  -msubxc  -mno-subxc -mfix-at697f
	   -mfix-ut699	-mfix-ut700  -mfix-gr712rc -mlra  -mno-lra

	   System V Options -Qy	 -Qn  -YP,paths	 -Ym,dir

	   V850 Options -mlong-calls  -mno-long-calls  -mep  -mno-ep
	   -mprolog-function  -mno-prolog-function  -mspace -mtda=n  -msda=n
	   -mzda=n -mapp-regs  -mno-app-regs -mdisable-callt
	   -mno-disable-callt -mv850e2v3  -mv850e2  -mv850e1  -mv850es -mv850e
	   -mv850  -mv850e3v5 -mloop -mrelax -mlong-jumps -msoft-float
	   -mhard-float -mgcc-abi -mrh850-abi -mbig-switch

	   VAX Options -mg  -mgnu  -munix  -mlra

	   Visium Options -mdebug  -msim  -mfpu	 -mno-fpu  -mhard-float
	   -msoft-float -mcpu=cpu-type	-mtune=cpu-type	 -msv-mode
	   -muser-mode

	   VMS Options -mvms-return-codes  -mdebug-main=prefix	-mmalloc64
	   -mpointer-size=size

	   VxWorks Options -mrtp  -msmp	 -non-static  -Bstatic	-Bdynamic
	   -Xbind-lazy	-Xbind-now

	   x86 Options -mtune=cpu-type	-march=cpu-type -mtune-ctrl=feature-
	   list	 -mdump-tune-features  -mno-default -mfpmath=unit
	   -masm=dialect  -mno-fancy-math-387 -mno-fp-ret-in-387  -m80387
	   -mhard-float	 -msoft-float -mno-wide-multiply  -mrtd
	   -malign-double -mpreferred-stack-boundary=num
	   -mincoming-stack-boundary=num -mcld	-mcx16	-msahf	-mmovbe
	   -mcrc32 -mmwait -mrecip  -mrecip=opt -mvzeroupper  -mprefer-avx128
	   -mprefer-vector-width=opt -mpartial-vector-fp-math -mmove-max=bits
	   -mstore-max=bits -mnoreturn-no-callee-saved-registers -mmmx	-msse
	   -msse2  -msse3  -mssse3  -msse4.1  -msse4.2	-msse4	-mavx -mavx2
	   -mavx512f  -mavx512pf  -mavx512er  -mavx512cd  -mavx512vl
	   -mavx512bw  -mavx512dq  -mavx512ifma	 -mavx512vbmi  -msha  -maes
	   -mpclmul  -mfsgsbase	 -mrdrnd  -mf16c  -mfma	 -mpconfig  -mwbnoinvd
	   -mptwrite  -mprefetchwt1  -mclflushopt  -mclwb  -mxsavec  -mxsaves
	   -msse4a  -m3dnow  -m3dnowa  -mpopcnt	 -mabm	-mbmi  -mtbm  -mfma4
	   -mxop -madx	-mlzcnt	 -mbmi2	 -mfxsr	 -mxsave  -mxsaveopt  -mrtm
	   -mhle  -mlwp -mmwaitx  -mclzero  -mpku  -mthreads  -mgfni  -mvaes
	   -mwaitpkg -mshstk -mmanual-endbr -mcet-switch -mforce-indirect-call
	   -mavx512vbmi2 -mavx512bf16 -menqcmd -mvpclmulqdq  -mavx512bitalg
	   -mmovdiri  -mmovdir64b  -mavx512vpopcntdq -mavx5124fmaps
	   -mavx512vnni	 -mavx5124vnniw	 -mprfchw  -mrdpid -mrdseed  -msgx
	   -mavx512vp2intersect -mserialize -mtsxldtrk -mamx-tile  -mamx-int8
	   -mamx-bf16 -muintr -mhreset -mavxvnni -mavx512fp16 -mavxifma
	   -mavxvnniint8 -mavxneconvert -mcmpccxadd -mamx-fp16 -mprefetchi
	   -mraoint -mamx-complex -mavxvnniint16 -msm3 -msha512 -msm4 -mapxf
	   -musermsr -mavx10.1 -mavx10.1-256 -mavx10.1-512 -mevex512
	   -mcldemote  -mms-bitfields  -mno-align-stringops
	   -minline-all-stringops -minline-stringops-dynamically
	   -mstringop-strategy=alg -mkl -mwidekl -mmemcpy-strategy=strategy
	   -mmemset-strategy=strategy -mpush-args  -maccumulate-outgoing-args
	   -m128bit-long-double -m96bit-long-double  -mlong-double-64
	   -mlong-double-80  -mlong-double-128 -mregparm=num  -msseregparm
	   -mveclibabi=type  -mvect8-ret-in-mem -mpc32	-mpc64	-mpc80
	   -mdaz-ftz -mstackrealign -momit-leaf-frame-pointer  -mno-red-zone
	   -mno-tls-direct-seg-refs -mcmodel=code-model	 -mabi=name
	   -maddress-mode=mode -m32  -m64  -mx32  -m16	-miamcu
	   -mlarge-data-threshold=num -msse2avx	 -mfentry  -mrecord-mcount
	   -mnop-mcount	 -m8bit-idiv -minstrument-return=type
	   -mfentry-name=name -mfentry-section=name
	   -mavx256-split-unaligned-load  -mavx256-split-unaligned-store
	   -malign-data=type  -mstack-protector-guard=guard
	   -mstack-protector-guard-reg=reg
	   -mstack-protector-guard-offset=offset
	   -mstack-protector-guard-symbol=symbol -mgeneral-regs-only
	   -mcall-ms2sysv-xlogues -mrelax-cmpxchg-loop
	   -mindirect-branch=choice  -mfunction-return=choice
	   -mindirect-branch-register -mharden-sls=choice
	   -mindirect-branch-cs-prefix -mneeded -mno-direct-extern-access
	   -munroll-only-small-loops -mlam=choice

	   x86 Windows Options -mconsole  -mcrtdll=library  -mdll
	   -mnop-fun-dllimport	-mthread -municode  -mwin32  -mwindows
	   -fno-set-stack-executable

	   Xstormy16 Options -msim

	   Xtensa Options -mconst16  -mno-const16 -mfused-madd
	   -mno-fused-madd -mforce-no-pic -mserialize-volatile
	   -mno-serialize-volatile -mtext-section-literals
	   -mno-text-section-literals -mauto-litpools  -mno-auto-litpools
	   -mtarget-align  -mno-target-align -mlongcalls  -mno-longcalls
	   -mabi=abi-type -mextra-l32r-costs=cycles -mstrict-align
	   -mno-strict-align

	   zSeries Options See S/390 and zSeries Options.

   Options Controlling the Kind of Output
       Compilation can involve up to four stages: preprocessing, compilation
       proper, assembly and linking, always in that order.  GCC is capable of
       preprocessing and compiling several files either into several assembler
       input files, or into one assembler input file; then each assembler
       input file produces an object file, and linking combines all the object
       files (those newly compiled, and those specified as input) into an
       executable file.

       For any given input file, the file name suffix determines what kind of
       compilation is done:

       file.c
	   C source code that must be preprocessed.

       file.i
	   C source code that should not be preprocessed.

       file.ii
	   C++ source code that should not be preprocessed.

       file.m
	   Objective-C source code.  Note that you must link with the libobjc
	   library to make an Objective-C program work.

       file.mi
	   Objective-C source code that should not be preprocessed.

       file.mm
       file.M
	   Objective-C++ source code.  Note that you must link with the
	   libobjc library to make an Objective-C++ program work.  Note that
	   .M refers to a literal capital M.

       file.mii
	   Objective-C++ source code that should not be preprocessed.

       file.h
	   C, C++, Objective-C or Objective-C++ header file to be turned into
	   a precompiled header (default), or C, C++ header file to be turned
	   into an Ada spec (via the -fdump-ada-spec switch).

       file.cc
       file.cp
       file.cxx
       file.cpp
       file.CPP
       file.c++
       file.C
	   C++ source code that must be preprocessed.  Note that in .cxx, the
	   last two letters must both be literally x.  Likewise, .C refers to
	   a literal capital C.

       file.mm
       file.M
	   Objective-C++ source code that must be preprocessed.

       file.mii
	   Objective-C++ source code that should not be preprocessed.

       file.hh
       file.H
       file.hp
       file.hxx
       file.hpp
       file.HPP
       file.h++
       file.tcc
	   C++ header file to be turned into a precompiled header or Ada spec.

       file.f
       file.for
       file.ftn
       file.fi
	   Fixed form Fortran source code that should not be preprocessed.

       file.F
       file.FOR
       file.fpp
       file.FPP
       file.FTN
	   Fixed form Fortran source code that must be preprocessed (with the
	   traditional preprocessor).

       file.f90
       file.f95
       file.f03
       file.f08
       file.fii
	   Free form Fortran source code that should not be preprocessed.

       file.F90
       file.F95
       file.F03
       file.F08
	   Free form Fortran source code that must be preprocessed (with the
	   traditional preprocessor).

       file.go
	   Go source code.

       file.d
	   D source code.

       file.di
	   D interface file.

       file.dd
	   D documentation code (Ddoc).

       file.ads
	   Ada source code file that contains a library unit declaration (a
	   declaration of a package, subprogram, or generic, or a generic
	   instantiation), or a library unit renaming declaration (a package,
	   generic, or subprogram renaming declaration).  Such files are also
	   called specs.

       file.adb
	   Ada source code file containing a library unit body (a subprogram
	   or package body).  Such files are also called bodies.

       file.s
	   Assembler code.

       file.S
       file.sx
	   Assembler code that must be preprocessed.

       other
	   An object file to be fed straight into linking.  Any file name with
	   no recognized suffix is treated this way.

       You can specify the input language explicitly with the -x option:

       -x language
	   Specify explicitly the language for the following input files
	   (rather than letting the compiler choose a default based on the
	   file name suffix).  This option applies to all following input
	   files until the next -x option.  Possible values for language are:

		   c  c-header	cpp-output
		   c++	c++-header  c++-system-header c++-user-header c++-cpp-output
		   objective-c	objective-c-header  objective-c-cpp-output
		   objective-c++ objective-c++-header objective-c++-cpp-output
		   assembler  assembler-with-cpp
		   ada
		   d
		   f77	f77-cpp-input f95  f95-cpp-input
		   go

       -x none
	   Turn off any specification of a language, so that subsequent files
	   are handled according to their file name suffixes (as they are if
	   -x has not been used at all).

       If you only want some of the stages of compilation, you can use -x (or
       filename suffixes) to tell gcc where to start, and one of the options
       -c, -S, or -E to say where gcc is to stop.  Note that some combinations
       (for example, -x cpp-output -E) instruct gcc to do nothing at all.

       -c  Compile or assemble the source files, but do not link.  The linking
	   stage simply is not done.  The ultimate output is in the form of an
	   object file for each source file.

	   By default, the object file name for a source file is made by
	   replacing the suffix .c, .i, .s, etc., with .o.

	   Unrecognized input files, not requiring compilation or assembly,
	   are ignored.

       -S  Stop after the stage of compilation proper; do not assemble.	 The
	   output is in the form of an assembler code file for each non-
	   assembler input file specified.

	   By default, the assembler file name for a source file is made by
	   replacing the suffix .c, .i, etc., with .s.

	   Input files that don't require compilation are ignored.

       -E  Stop after the preprocessing stage; do not run the compiler proper.
	   The output is in the form of preprocessed source code, which is
	   sent to the standard output.

	   Input files that don't require preprocessing are ignored.

       -o file
	   Place the primary output in file file.  This applies to whatever
	   sort of output is being produced, whether it be an executable file,
	   an object file, an assembler file or preprocessed C code.

	   If -o is not specified, the default is to put an executable file in
	   a.out, the object file for source.suffix in source.o, its assembler
	   file in source.s, a precompiled header file in source.suffix.gch,
	   and all preprocessed C source on standard output.

	   Though -o names only the primary output, it also affects the naming
	   of auxiliary and dump outputs.  See the examples below.  Unless
	   overridden, both auxiliary outputs and dump outputs are placed in
	   the same directory as the primary output.  In auxiliary outputs,
	   the suffix of the input file is replaced with that of the auxiliary
	   output file type; in dump outputs, the suffix of the dump file is
	   appended to the input file suffix.  In compilation commands, the
	   base name of both auxiliary and dump outputs is that of the primary
	   output; in compile and link commands, the primary output name,
	   minus the executable suffix, is combined with the input file name.
	   If both share the same base name, disregarding the suffix, the
	   result of the combination is that base name, otherwise, they are
	   concatenated, separated by a dash.

		   gcc -c foo.c ...

	   will use foo.o as the primary output, and place aux outputs and
	   dumps next to it, e.g., aux file foo.dwo for -gsplit-dwarf, and
	   dump file foo.c.???r.final for -fdump-rtl-final.

	   If a non-linker output file is explicitly specified, aux and dump
	   files by default take the same base name:

		   gcc -c foo.c -o dir/foobar.o ...

	   will name aux outputs dir/foobar.* and dump outputs dir/foobar.c.*.

	   A linker output will instead prefix aux and dump outputs:

		   gcc foo.c bar.c -o dir/foobar ...

	   will generally name aux outputs dir/foobar-foo.* and
	   dir/foobar-bar.*, and dump outputs dir/foobar-foo.c.* and
	   dir/foobar-bar.c.*.

	   The one exception to the above is when the executable shares the
	   base name with the single input:

		   gcc foo.c -o dir/foo ...

	   in which case aux outputs are named dir/foo.* and dump outputs
	   named dir/foo.c.*.

	   The location and the names of auxiliary and dump outputs can be
	   adjusted by the options -dumpbase, -dumpbase-ext, -dumpdir,
	   -save-temps=cwd, and -save-temps=obj.

       -dumpbase dumpbase
	   This option sets the base name for auxiliary and dump output files.
	   It does not affect the name of the primary output file.
	   Intermediate outputs, when preserved, are not regarded as primary
	   outputs, but as auxiliary outputs:

		   gcc -save-temps -S foo.c

	   saves the (no longer) temporary preprocessed file in foo.i, and
	   then compiles to the (implied) output file foo.s, whereas:

		   gcc -save-temps -dumpbase save-foo -c foo.c

	   preprocesses to in save-foo.i, compiles to save-foo.s (now an
	   intermediate, thus auxiliary output), and then assembles to the
	   (implied) output file foo.o.

	   Absent this option, dump and aux files take their names from the
	   input file, or from the (non-linker) output file, if one is
	   explicitly specified: dump output files (e.g. those requested by
	   -fdump-* options) with the input name suffix, and aux output files
	   (those requested by other non-dump options, e.g. "-save-temps",
	   "-gsplit-dwarf", "-fcallgraph-info") without it.

	   Similar suffix differentiation of dump and aux outputs can be
	   attained for explicitly-given -dumpbase basename.suf by also
	   specifying -dumpbase-ext .suf.

	   If dumpbase is explicitly specified with any directory component,
	   any dumppfx specification (e.g. -dumpdir or -save-temps=*) is
	   ignored, and instead of appending to it, dumpbase fully overrides
	   it:

		   gcc foo.c -c -o dir/foo.o -dumpbase alt/foo \
		     -dumpdir pfx- -save-temps=cwd ...

	   creates auxiliary and dump outputs named alt/foo.*, disregarding
	   dir/ in -o, the ./ prefix implied by -save-temps=cwd, and pfx- in
	   -dumpdir.

	   When -dumpbase is specified in a command that compiles multiple
	   inputs, or that compiles and then links, it may be combined with
	   dumppfx, as specified under -dumpdir.  Then, each input file is
	   compiled using the combined dumppfx, and default values for
	   dumpbase and auxdropsuf are computed for each input file:

		   gcc foo.c bar.c -c -dumpbase main ...

	   creates foo.o and bar.o as primary outputs, and avoids overwriting
	   the auxiliary and dump outputs by using the dumpbase as a prefix,
	   creating auxiliary and dump outputs named main-foo.*	 and
	   main-bar.*.

	   An empty string specified as dumpbase avoids the influence of the
	   output basename in the naming of auxiliary and dump outputs during
	   compilation, computing default values :

		   gcc -c foo.c -o dir/foobar.o -dumpbase " ...

	   will name aux outputs dir/foo.* and dump outputs dir/foo.c.*.  Note
	   how their basenames are taken from the input name, but the
	   directory still defaults to that of the output.

	   The empty-string dumpbase does not prevent the use of the output
	   basename for outputs during linking:

		   gcc foo.c bar.c -o dir/foobar -dumpbase " -flto ...

	   The compilation of the source files will name auxiliary outputs
	   dir/foo.* and dir/bar.*, and dump outputs dir/foo.c.* and
	   dir/bar.c.*.	 LTO recompilation during linking will use dir/foobar.
	   as the prefix for dumps and auxiliary files.

       -dumpbase-ext auxdropsuf
	   When forming the name of an auxiliary (but not a dump) output file,
	   drop trailing auxdropsuf from dumpbase before appending any
	   suffixes.  If not specified, this option defaults to the suffix of
	   a default dumpbase, i.e., the suffix of the input file when
	   -dumpbase is not present in the command line, or dumpbase is
	   combined with dumppfx.

		   gcc foo.c -c -o dir/foo.o -dumpbase x-foo.c -dumpbase-ext .c ...

	   creates dir/foo.o as the main output, and generates auxiliary
	   outputs in dir/x-foo.*, taking the location of the primary output,
	   and dropping the .c suffix from the dumpbase.  Dump outputs retain
	   the suffix: dir/x-foo.c.*.

	   This option is disregarded if it does not match the suffix of a
	   specified dumpbase, except as an alternative to the executable
	   suffix when appending the linker output base name to dumppfx, as
	   specified below:

		   gcc foo.c bar.c -o main.out -dumpbase-ext .out ...

	   creates main.out as the primary output, and avoids overwriting the
	   auxiliary and dump outputs by using the executable name minus
	   auxdropsuf as a prefix, creating auxiliary outputs named main-foo.*
	   and main-bar.* and dump outputs named main-foo.c.* and
	   main-bar.c.*.

       -dumpdir dumppfx
	   When forming the name of an auxiliary or dump output file, use
	   dumppfx as a prefix:

		   gcc -dumpdir pfx- -c foo.c ...

	   creates foo.o as the primary output, and auxiliary outputs named
	   pfx-foo.*, combining the given dumppfx with the default dumpbase
	   derived from the default primary output, derived in turn from the
	   input name.	Dump outputs also take the input name suffix:
	   pfx-foo.c.*.

	   If dumppfx is to be used as a directory name, it must end with a
	   directory separator:

		   gcc -dumpdir dir/ -c foo.c -o obj/bar.o ...

	   creates obj/bar.o as the primary output, and auxiliary outputs
	   named dir/bar.*, combining the given dumppfx with the default
	   dumpbase derived from the primary output name.  Dump outputs also
	   take the input name suffix: dir/bar.c.*.

	   It defaults to the location of the output file, unless the output
	   file is a special file like "/dev/null". Options -save-temps=cwd
	   and -save-temps=obj override this default, just like an explicit
	   -dumpdir option.  In case multiple such options are given, the last
	   one prevails:

		   gcc -dumpdir pfx- -c foo.c -save-temps=obj ...

	   outputs foo.o, with auxiliary outputs named foo.* because
	   -save-temps=* overrides the dumppfx given by the earlier -dumpdir
	   option.  It does not matter that =obj is the default for
	   -save-temps, nor that the output directory is implicitly the
	   current directory.  Dump outputs are named foo.c.*.

	   When compiling from multiple input files, if -dumpbase is
	   specified, dumpbase, minus a auxdropsuf suffix, and a dash are
	   appended to (or override, if containing any directory components)
	   an explicit or defaulted dumppfx, so that each of the multiple
	   compilations gets differently-named aux and dump outputs.

		   gcc foo.c bar.c -c -dumpdir dir/pfx- -dumpbase main ...

	   outputs auxiliary dumps to dir/pfx-main-foo.* and
	   dir/pfx-main-bar.*, appending dumpbase- to dumppfx.	Dump outputs
	   retain the input file suffix: dir/pfx-main-foo.c.*  and
	   dir/pfx-main-bar.c.*, respectively.	Contrast with the single-input
	   compilation:

		   gcc foo.c -c -dumpdir dir/pfx- -dumpbase main ...

	   that, applying -dumpbase to a single source, does not compute and
	   append a separate dumpbase per input file.  Its auxiliary and dump
	   outputs go in dir/pfx-main.*.

	   When compiling and then linking from multiple input files, a
	   defaulted or explicitly specified dumppfx also undergoes the
	   dumpbase- transformation above (e.g. the compilation of foo.c and
	   bar.c above, but without -c).  If neither -dumpdir nor -dumpbase
	   are given, the linker output base name, minus auxdropsuf, if
	   specified, or the executable suffix otherwise, plus a dash is
	   appended to the default dumppfx instead.  Note, however, that
	   unlike earlier cases of linking:

		   gcc foo.c bar.c -dumpdir dir/pfx- -o main ...

	   does not append the output name main to dumppfx, because -dumpdir
	   is explicitly specified.  The goal is that the explicitly-specified
	   dumppfx may contain the specified output name as part of the
	   prefix, if desired; only an explicitly-specified -dumpbase would be
	   combined with it, in order to avoid simply discarding a meaningful
	   option.

	   When compiling and then linking from a single input file, the
	   linker output base name will only be appended to the default
	   dumppfx as above if it does not share the base name with the single
	   input file name.  This has been covered in single-input linking
	   cases above, but not with an explicit -dumpdir that inhibits the
	   combination, even if overridden by -save-temps=*:

		   gcc foo.c -dumpdir alt/pfx- -o dir/main.exe -save-temps=cwd ...

	   Auxiliary outputs are named foo.*, and dump outputs foo.c.*, in the
	   current working directory as ultimately requested by
	   -save-temps=cwd.

	   Summing it all up for an intuitive though slightly imprecise data
	   flow: the primary output name is broken into a directory part and a
	   basename part; dumppfx is set to the former, unless overridden by
	   -dumpdir or -save-temps=*, and dumpbase is set to the latter,
	   unless overriden by -dumpbase.  If there are multiple inputs or
	   linking, this dumpbase may be combined with dumppfx and taken from
	   each input file.  Auxiliary output names for each input are formed
	   by combining dumppfx, dumpbase minus suffix, and the auxiliary
	   output suffix; dump output names are only different in that the
	   suffix from dumpbase is retained.

	   When it comes to auxiliary and dump outputs created during LTO
	   recompilation, a combination of dumppfx and dumpbase, as given or
	   as derived from the linker output name but not from inputs, even in
	   cases in which this combination would not otherwise be used as
	   such, is passed down with a trailing period replacing the compiler-
	   added dash, if any, as a -dumpdir option to lto-wrapper; being
	   involved in linking, this program does not normally get any
	   -dumpbase and -dumpbase-ext, and it ignores them.

	   When running sub-compilers, lto-wrapper appends LTO stage names to
	   the received dumppfx, ensures it contains a directory component so
	   that it overrides any -dumpdir, and passes that as -dumpbase to
	   sub-compilers.

       -v  Print (on standard error output) the commands executed to run the
	   stages of compilation.  Also print the version number of the
	   compiler driver program and of the preprocessor and the compiler
	   proper.

       -###
	   Like -v except the commands are not executed and arguments are
	   quoted unless they contain only alphanumeric characters or "./-_".
	   This is useful for shell scripts to capture the driver-generated
	   command lines.

       --help
	   Print (on the standard output) a description of the command-line
	   options understood by gcc.  If the -v option is also specified then
	   --help is also passed on to the various processes invoked by gcc,
	   so that they can display the command-line options they accept.  If
	   the -Wextra option has also been specified (prior to the --help
	   option), then command-line options that have no documentation
	   associated with them are also displayed.

       --target-help
	   Print (on the standard output) a description of target-specific
	   command-line options for each tool.	For some targets extra target-
	   specific information may also be printed.

       --help={class|[^]qualifier}[,...]
	   Print (on the standard output) a description of the command-line
	   options understood by the compiler that fit into all specified
	   classes and qualifiers.  These are the supported classes:

	   optimizers
	       Display all of the optimization options supported by the
	       compiler.

	   warnings
	       Display all of the options controlling warning messages
	       produced by the compiler.

	   target
	       Display target-specific options.	 Unlike the --target-help
	       option however, target-specific options of the linker and
	       assembler are not displayed.  This is because those tools do
	       not currently support the extended --help= syntax.

	   params
	       Display the values recognized by the --param option.

	   language
	       Display the options supported for language, where language is
	       the name of one of the languages supported in this version of
	       GCC.  If an option is supported by all languages, one needs to
	       select common class.

	   common
	       Display the options that are common to all languages.

	   These are the supported qualifiers:

	   undocumented
	       Display only those options that are undocumented.

	   joined
	       Display options taking an argument that appears after an equal
	       sign in the same continuous piece of text, such as:
	       --help=target.

	   separate
	       Display options taking an argument that appears as a separate
	       word following the original option, such as: -o output-file.

	   Thus for example to display all the undocumented target-specific
	   switches supported by the compiler, use:

		   --help=target,undocumented

	   The sense of a qualifier can be inverted by prefixing it with the ^
	   character, so for example to display all binary warning options
	   (i.e., ones that are either on or off and that do not take an
	   argument) that have a description, use:

		   --help=warnings,^joined,^undocumented

	   The argument to --help= should not consist solely of inverted
	   qualifiers.

	   Combining several classes is possible, although this usually
	   restricts the output so much that there is nothing to display.  One
	   case where it does work, however, is when one of the classes is
	   target.  For example, to display all the target-specific
	   optimization options, use:

		   --help=target,optimizers

	   The --help= option can be repeated on the command line.  Each
	   successive use displays its requested class of options, skipping
	   those that have already been displayed.  If --help is also
	   specified anywhere on the command line then this takes precedence
	   over any --help= option.

	   If the -Q option appears on the command line before the --help=
	   option, then the descriptive text displayed by --help= is changed.
	   Instead of describing the displayed options, an indication is given
	   as to whether the option is enabled, disabled or set to a specific
	   value (assuming that the compiler knows this at the point where the
	   --help= option is used).

	   Here is a truncated example from the ARM port of gcc:

		     % gcc -Q -mabi=2 --help=target -c
		     The following options are target specific:
		     -mabi=				   2
		     -mabort-on-noreturn		   [disabled]
		     -mapcs				   [disabled]

	   The output is sensitive to the effects of previous command-line
	   options, so for example it is possible to find out which
	   optimizations are enabled at -O2 by using:

		   -Q -O2 --help=optimizers

	   Alternatively you can discover which binary optimizations are
	   enabled by -O3 by using:

		   gcc -c -Q -O3 --help=optimizers > /tmp/O3-opts
		   gcc -c -Q -O2 --help=optimizers > /tmp/O2-opts
		   diff /tmp/O2-opts /tmp/O3-opts | grep enabled

       --version
	   Display the version number and copyrights of the invoked GCC.

       -pass-exit-codes
	   Normally the gcc program exits with the code of 1 if any phase of
	   the compiler returns a non-success return code.  If you specify
	   -pass-exit-codes, the gcc program instead returns with the
	   numerically highest error produced by any phase returning an error
	   indication.	The C, C++, and Fortran front ends return 4 if an
	   internal compiler error is encountered.

       -pipe
	   Use pipes rather than temporary files for communication between the
	   various stages of compilation.  This fails to work on some systems
	   where the assembler is unable to read from a pipe; but the GNU
	   assembler has no trouble.

       -specs=file
	   Process file after the compiler reads in the standard specs file,
	   in order to override the defaults which the gcc driver program uses
	   when determining what switches to pass to cc1, cc1plus, as, ld,
	   etc.	 More than one -specs=file can be specified on the command
	   line, and they are processed in order, from left to right.

       -wrapper
	   Invoke all subcommands under a wrapper program.  The name of the
	   wrapper program and its parameters are passed as a comma separated
	   list.

		   gcc -c t.c -wrapper gdb,--args

	   This invokes all subprograms of gcc under gdb --args, thus the
	   invocation of cc1 is gdb --args cc1 ....

       -ffile-prefix-map=old=new
	   When compiling files residing in directory old, record any
	   references to them in the result of the compilation as if the files
	   resided in directory new instead.  Specifying this option is
	   equivalent to specifying all the individual -f*-prefix-map options.
	   This can be used to make reproducible builds that are location
	   independent.	 Directories referenced by directives are not affected
	   by these options.  See also -fmacro-prefix-map, -fdebug-prefix-map,
	   -fprofile-prefix-map and -fcanon-prefix-map.

       -fcanon-prefix-map
	   For the -f*-prefix-map options normally comparison of old prefix
	   against the filename that would be normally referenced in the
	   result of the compilation is done using textual comparison of the
	   prefixes, or ignoring character case for case insensitive
	   filesystems and considering slashes and backslashes as equal on DOS
	   based filesystems.  The -fcanon-prefix-map causes such comparisons
	   to be done on canonicalized paths of old and the referenced
	   filename.

       -fplugin=name.so
	   Load the plugin code in file name.so, assumed to be a shared object
	   to be dlopen'd by the compiler.  The base name of the shared object
	   file is used to identify the plugin for the purposes of argument
	   parsing (See -fplugin-arg-name-key=value below).  Each plugin
	   should define the callback functions specified in the Plugins API.

       -fplugin-arg-name-key=value
	   Define an argument called key with a value of value for the plugin
	   called name.

       -fdump-ada-spec[-slim]
	   For C and C++ source and include files, generate corresponding Ada
	   specs.

       -fada-spec-parent=unit
	   In conjunction with -fdump-ada-spec[-slim] above, generate Ada
	   specs as child units of parent unit.

       -fdump-go-spec=file
	   For input files in any language, generate corresponding Go
	   declarations in file.  This generates Go "const", "type", "var",
	   and "func" declarations which may be a useful way to start writing
	   a Go interface to code written in some other language.

       @file
	   Read command-line options from file.	 The options read are inserted
	   in place of the original @file option.  If file does not exist, or
	   cannot be read, then the option will be treated literally, and not
	   removed.

	   Options in file are separated by whitespace.	 A whitespace
	   character may be included in an option by surrounding the entire
	   option in either single or double quotes.  Any character (including
	   a backslash) may be included by prefixing the character to be
	   included with a backslash.  The file may itself contain additional
	   @file options; any such options will be processed recursively.

   Compiling C++ Programs
       C++ source files conventionally use one of the suffixes .C, .cc, .cpp,
       .CPP, .c++, .cp, or .cxx; C++ header files often use .hh, .hpp, .H, or
       (for shared template code) .tcc; and preprocessed C++ files use the
       suffix .ii.  GCC recognizes files with these names and compiles them as
       C++ programs even if you call the compiler the same way as for
       compiling C programs (usually with the name gcc).

       However, the use of gcc does not add the C++ library.  g++ is a program
       that calls GCC and automatically specifies linking against the C++
       library.	 It treats .c, .h and .i files as C++ source files instead of
       C source files unless -x is used.  This program is also useful when
       precompiling a C header file with a .h extension for use in C++
       compilations.  On many systems, g++ is also installed with the name
       c++.

       When you compile C++ programs, you may specify many of the same
       command-line options that you use for compiling programs in any
       language; or command-line options meaningful for C and related
       languages; or options that are meaningful only for C++ programs.

   Options Controlling C Dialect
       The following options control the dialect of C (or languages derived
       from C, such as C++, Objective-C and Objective-C++) that the compiler
       accepts:

       -ansi
	   In C mode, this is equivalent to -std=c90. In C++ mode, it is
	   equivalent to -std=c++98.

	   This turns off certain features of GCC that are incompatible with
	   ISO C90 (when compiling C code), or of standard C++ (when compiling
	   C++ code), such as the "asm" and "typeof" keywords, and predefined
	   macros such as "unix" and "vax" that identify the type of system
	   you are using.  It also enables the undesirable and rarely used ISO
	   trigraph feature.  For the C compiler, it disables recognition of
	   C++ style // comments as well as the "inline" keyword.

	   The alternate keywords "__asm__", "__extension__", "__inline__" and
	   "__typeof__" continue to work despite -ansi.	 You would not want to
	   use them in an ISO C program, of course, but it is useful to put
	   them in header files that might be included in compilations done
	   with -ansi.	Alternate predefined macros such as "__unix__" and
	   "__vax__" are also available, with or without -ansi.

	   The -ansi option does not cause non-ISO programs to be rejected
	   gratuitously.  For that, -Wpedantic is required in addition to
	   -ansi.

	   The macro "__STRICT_ANSI__" is predefined when the -ansi option is
	   used.  Some header files may notice this macro and refrain from
	   declaring certain functions or defining certain macros that the ISO
	   standard doesn't call for; this is to avoid interfering with any
	   programs that might use these names for other things.

	   Functions that are normally built in but do not have semantics
	   defined by ISO C (such as "alloca" and "ffs") are not built-in
	   functions when -ansi is used.

       -std=
	   Determine the language standard.   This option is currently only
	   supported when compiling C or C++.

	   The compiler can accept several base standards, such as c90 or
	   c++98, and GNU dialects of those standards, such as gnu90 or
	   gnu++98.  When a base standard is specified, the compiler accepts
	   all programs following that standard plus those using GNU
	   extensions that do not contradict it.  For example, -std=c90 turns
	   off certain features of GCC that are incompatible with ISO C90,
	   such as the "asm" and "typeof" keywords, but not other GNU
	   extensions that do not have a meaning in ISO C90, such as omitting
	   the middle term of a "?:" expression. On the other hand, when a GNU
	   dialect of a standard is specified, all features supported by the
	   compiler are enabled, even when those features change the meaning
	   of the base standard.  As a result, some strict-conforming programs
	   may be rejected.  The particular standard is used by -Wpedantic to
	   identify which features are GNU extensions given that version of
	   the standard. For example -std=gnu90 -Wpedantic warns about C++
	   style // comments, while -std=gnu99 -Wpedantic does not.

	   A value for this option must be provided; possible values are

	   c90
	   c89
	   iso9899:1990
	       Support all ISO C90 programs (certain GNU extensions that
	       conflict with ISO C90 are disabled). Same as -ansi for C code.

	   iso9899:199409
	       ISO C90 as modified in amendment 1.

	   c99
	   c9x
	   iso9899:1999
	   iso9899:199x
	       ISO C99.	 This standard is substantially completely supported,
	       modulo bugs and floating-point issues (mainly but not entirely
	       relating to optional C99 features from Annexes F and G).	 See
	       <https://gcc.gnu.org/c99status.html> for more information.  The
	       names c9x and iso9899:199x are deprecated.

	   c11
	   c1x
	   iso9899:2011
	       ISO C11, the 2011 revision of the ISO C standard.  This
	       standard is substantially completely supported, modulo bugs,
	       floating-point issues (mainly but not entirely relating to
	       optional C11 features from Annexes F and G) and the optional
	       Annexes K (Bounds-checking interfaces) and L (Analyzability).
	       The name c1x is deprecated.

	   c17
	   c18
	   iso9899:2017
	   iso9899:2018
	       ISO C17, the 2017 revision of the ISO C standard (published in
	       2018).  This standard is same as C11 except for corrections of
	       defects (all of which are also applied with -std=c11) and a new
	       value of "__STDC_VERSION__", and so is supported to the same
	       extent as C11.

	   c23
	   c2x
	   iso9899:2024
	       ISO C23, the 2023 revision of the ISO C standard (expected to
	       be published in 2024).  The support for this version is
	       experimental and incomplete.  The name c2x is deprecated.

	   gnu90
	   gnu89
	       GNU dialect of ISO C90 (including some C99 features).

	   gnu99
	   gnu9x
	       GNU dialect of ISO C99.	The name gnu9x is deprecated.

	   gnu11
	   gnu1x
	       GNU dialect of ISO C11.	The name gnu1x is deprecated.

	   gnu17
	   gnu18
	       GNU dialect of ISO C17.	This is the default for C code.

	   gnu23
	   gnu2x
	       The next version of the ISO C standard, still under
	       development, plus GNU extensions.  The support for this version
	       is experimental and incomplete.	The name gnu2x is deprecated.

	   c++98
	   c++03
	       The 1998 ISO C++ standard plus the 2003 technical corrigendum
	       and some additional defect reports. Same as -ansi for C++ code.

	   gnu++98
	   gnu++03
	       GNU dialect of -std=c++98.

	   c++11
	   c++0x
	       The 2011 ISO C++ standard plus amendments.  The name c++0x is
	       deprecated.

	   gnu++11
	   gnu++0x
	       GNU dialect of -std=c++11.  The name gnu++0x is deprecated.

	   c++14
	   c++1y
	       The 2014 ISO C++ standard plus amendments.  The name c++1y is
	       deprecated.

	   gnu++14
	   gnu++1y
	       GNU dialect of -std=c++14.  The name gnu++1y is deprecated.

	   c++17
	   c++1z
	       The 2017 ISO C++ standard plus amendments.  The name c++1z is
	       deprecated.

	   gnu++17
	   gnu++1z
	       GNU dialect of -std=c++17.  This is the default for C++ code.
	       The name gnu++1z is deprecated.

	   c++20
	   c++2a
	       The 2020 ISO C++ standard plus amendments.  Support is
	       experimental, and could change in incompatible ways in future
	       releases.  The name c++2a is deprecated.

	   gnu++20
	   gnu++2a
	       GNU dialect of -std=c++20.  Support is experimental, and could
	       change in incompatible ways in future releases.	The name
	       gnu++2a is deprecated.

	   c++2b
	   c++23
	       The next revision of the ISO C++ standard, planned for 2023.
	       Support is highly experimental, and will almost certainly
	       change in incompatible ways in future releases.

	   gnu++2b
	   gnu++23
	       GNU dialect of -std=c++2b.  Support is highly experimental, and
	       will almost certainly change in incompatible ways in future
	       releases.

	   c++2c
	   c++26
	       The next revision of the ISO C++ standard, planned for 2026.
	       Support is highly experimental, and will almost certainly
	       change in incompatible ways in future releases.

	   gnu++2c
	   gnu++26
	       GNU dialect of -std=c++2c.  Support is highly experimental, and
	       will almost certainly change in incompatible ways in future
	       releases.

       -aux-info filename
	   Output to the given filename prototyped declarations for all
	   functions declared and/or defined in a translation unit, including
	   those in header files.  This option is silently ignored in any
	   language other than C.

	   Besides declarations, the file indicates, in comments, the origin
	   of each declaration (source file and line), whether the declaration
	   was implicit, prototyped or unprototyped (I, N for new or O for
	   old, respectively, in the first character after the line number and
	   the colon), and whether it came from a declaration or a definition
	   (C or F, respectively, in the following character).	In the case of
	   function definitions, a K&R-style list of arguments followed by
	   their declarations is also provided, inside comments, after the
	   declaration.

       -fno-asm
	   Do not recognize "asm", "inline" or "typeof" as a keyword, so that
	   code can use these words as identifiers.  You can use the keywords
	   "__asm__", "__inline__" and "__typeof__" instead.  In C, -ansi
	   implies -fno-asm.

	   In C++, "inline" is a standard keyword and is not affected by this
	   switch.  You may want to use the -fno-gnu-keywords flag instead,
	   which disables "typeof" but not "asm" and "inline".	In C99 mode
	   (-std=c99 or -std=gnu99), this switch only affects the "asm" and
	   "typeof" keywords, since "inline" is a standard keyword in ISO C99.
	   In C23 mode (-std=c23 or -std=gnu23), this switch only affects the
	   "asm" keyword, since "typeof" is a standard keyword in ISO C23.

       -fno-builtin
       -fno-builtin-function
	   Don't recognize built-in functions that do not begin with
	   __builtin_ as prefix.

	   GCC normally generates special code to handle certain built-in
	   functions more efficiently; for instance, calls to "alloca" may
	   become single instructions which adjust the stack directly, and
	   calls to "memcpy" may become inline copy loops.  The resulting code
	   is often both smaller and faster, but since the function calls no
	   longer appear as such, you cannot set a breakpoint on those calls,
	   nor can you change the behavior of the functions by linking with a
	   different library.  In addition, when a function is recognized as a
	   built-in function, GCC may use information about that function to
	   warn about problems with calls to that function, or to generate
	   more efficient code, even if the resulting code still contains
	   calls to that function.  For example, warnings are given with
	   -Wformat for bad calls to "printf" when "printf" is built in and
	   "strlen" is known not to modify global memory.

	   With the -fno-builtin-function option only the built-in function
	   function is disabled.  function must not begin with __builtin_.  If
	   a function is named that is not built-in in this version of GCC,
	   this option is ignored.  There is no corresponding
	   -fbuiltin-function option; if you wish to enable built-in functions
	   selectively when using -fno-builtin or -ffreestanding, you may
	   define macros such as:

		   #define abs(n)	   __builtin_abs ((n))
		   #define strcpy(d, s)	   __builtin_strcpy ((d), (s))

       -fcond-mismatch
	   Allow conditional expressions with mismatched types in the second
	   and third arguments.	 The value of such an expression is void.
	   This option is not supported for C++.

       -ffreestanding
	   Assert that compilation targets a freestanding environment.	This
	   implies -fno-builtin.  A freestanding environment is one in which
	   the standard library may not exist, and program startup may not
	   necessarily be at "main".  The most obvious example is an OS
	   kernel.  This is equivalent to -fno-hosted.

       -fgimple
	   Enable parsing of function definitions marked with "__GIMPLE".
	   This is an experimental feature that allows unit testing of GIMPLE
	   passes.

       -fgnu-tm
	   When the option -fgnu-tm is specified, the compiler generates code
	   for the Linux variant of Intel's current Transactional Memory ABI
	   specification document (Revision 1.1, May 6 2009).  This is an
	   experimental feature whose interface may change in future versions
	   of GCC, as the official specification changes.  Please note that
	   not all architectures are supported for this feature.

	   For more information on GCC's support for transactional memory,

	   Note that the transactional memory feature is not supported with
	   non-call exceptions (-fnon-call-exceptions).

       -fgnu89-inline
	   The option -fgnu89-inline tells GCC to use the traditional GNU
	   semantics for "inline" functions when in C99 mode.

	   Using this option is roughly equivalent to adding the "gnu_inline"
	   function attribute to all inline functions.

	   The option -fno-gnu89-inline explicitly tells GCC to use the C99
	   semantics for "inline" when in C99 or gnu99 mode (i.e., it
	   specifies the default behavior).  This option is not supported in
	   -std=c90 or -std=gnu90 mode.

	   The preprocessor macros "__GNUC_GNU_INLINE__" and
	   "__GNUC_STDC_INLINE__" may be used to check which semantics are in
	   effect for "inline" functions.

       -fhosted
	   Assert that compilation targets a hosted environment.  This implies
	   -fbuiltin.  A hosted environment is one in which the entire
	   standard library is available, and in which "main" has a return
	   type of "int".  Examples are nearly everything except a kernel.
	   This is equivalent to -fno-freestanding.

       -flax-vector-conversions
	   Allow implicit conversions between vectors with differing numbers
	   of elements and/or incompatible element types.  This option should
	   not be used for new code.

       -fms-extensions
	   Accept some non-standard constructs used in Microsoft header files.

	   In C++ code, this allows member names in structures to be similar
	   to previous types declarations.

		   typedef int UOW;
		   struct ABC {
		     UOW UOW;
		   };

	   Some cases of unnamed fields in structures and unions are only
	   accepted with this option.

	   Note that this option is off for all targets except for x86 targets
	   using ms-abi.

       -foffload=disable
       -foffload=default
       -foffload=target-list
	   Specify for which OpenMP and OpenACC offload targets code should be
	   generated.  The default behavior, equivalent to -foffload=default,
	   is to generate code for all supported offload targets.  The
	   -foffload=disable form generates code only for the host fallback,
	   while -foffload=target-list generates code only for the specified
	   comma-separated list of offload targets.

	   Offload targets are specified in GCC's internal target-triplet
	   format. You can run the compiler with -v to show the list of
	   configured offload targets under "OFFLOAD_TARGET_NAMES".

       -foffload-options=options
       -foffload-options=target-triplet-list=options
	   With -foffload-options=options, GCC passes the specified options to
	   the compilers for all enabled offloading targets.  You can specify
	   options that apply only to a specific target or targets by using
	   the -foffload-options=target-list=options form.  The target-list is
	   a comma-separated list in the same format as for the -foffload=
	   option.

	   Typical command lines are

		   -foffload-options='-fno-math-errno -ffinite-math-only' -foffload-options=nvptx-none=-latomic
		   -foffload-options=amdgcn-amdhsa=-march=gfx906

       -fopenacc
	   Enable handling of OpenACC directives #pragma acc in C/C++ and
	   !$acc in free-form Fortran and !$acc, c$acc and *$acc in fixed-form
	   Fortran.  When -fopenacc is specified, the compiler generates
	   accelerated code according to the OpenACC Application Programming
	   Interface v2.6 <https://www.openacc.org>.  This option implies
	   -pthread, and thus is only supported on targets that have support
	   for -pthread.

       -fopenacc-dim=geom
	   Specify default compute dimensions for parallel offload regions
	   that do not explicitly specify.  The geom value is a triple of
	   ':'-separated sizes, in order 'gang', 'worker' and, 'vector'.  A
	   size can be omitted, to use a target-specific default value.

       -fopenmp
	   Enable handling of OpenMP directives #pragma omp,
	   [[omp::directive(...)]], [[omp::sequence(...)]] and
	   [[omp::decl(...)]] in C/C++ and !$omp in Fortran.  It additionally
	   enables the conditional compilation sentinel !$ in Fortran.	In
	   fixed source form Fortran, the sentinels can also start with c or
	   *.  When -fopenmp is specified, the compiler generates parallel
	   code according to the OpenMP Application Program Interface v4.5
	   <https://www.openmp.org>.  This option implies -pthread, and thus
	   is only supported on targets that have support for -pthread.
	   -fopenmp implies -fopenmp-simd.

       -fopenmp-simd
	   Enable handling of OpenMP's "simd", "declare simd", "declare
	   reduction", "assume", "ordered", "scan" and "loop" directive, and
	   of combined or composite directives with "simd" as constituent with
	   "#pragma omp", "[[omp::directive(...)]]", "[[omp::sequence(...)]]"
	   and "[[omp::decl(...)]]" in C/C++ and "!$omp" in Fortran.  It
	   additionally enables the conditional compilation sentinel !$ in
	   Fortran.  In fixed source form Fortran, the sentinels can also
	   start with c or *.  Other OpenMP directives are ignored.  Unless
	   -fopenmp is additionally specified, the "loop" region binds to the
	   current task region, independent of the specified "bind" clause.

       -fopenmp-target-simd-clone
       -fopenmp-target-simd-clone=device-type
	   In addition to generating SIMD clones for functions marked with the
	   "declare simd" directive, GCC also generates clones for functions
	   marked with the OpenMP "declare target" directive that are suitable
	   for vectorization when this option is in effect.  The device-type
	   may be one of "none", "host", "nohost", and "any", which correspond
	   to keywords for the "device_type" clause of the "declare target"
	   directive; clones are generated for the intersection of devices
	   specified.  -fopenmp-target-simd-clone is equivalent to
	   -fopenmp-target-simd-clone=any and -fno-openmp-target-simd-clone is
	   equivalent to -fopenmp-target-simd-clone=none.

	   At -O2 and higher (but not -Os or -Og) this optimization defaults
	   to -fopenmp-target-simd-clone=nohost; otherwise it is disabled by
	   default.

       -fpermitted-flt-eval-methods=style
	   ISO/IEC TS 18661-3 defines new permissible values for
	   "FLT_EVAL_METHOD" that indicate that operations and constants with
	   a semantic type that is an interchange or extended format should be
	   evaluated to the precision and range of that type.  These new
	   values are a superset of those permitted under C99/C11, which does
	   not specify the meaning of other positive values of
	   "FLT_EVAL_METHOD".  As such, code conforming to C11 may not have
	   been written expecting the possibility of the new values.

	   -fpermitted-flt-eval-methods specifies whether the compiler should
	   allow only the values of "FLT_EVAL_METHOD" specified in C99/C11, or
	   the extended set of values specified in ISO/IEC TS 18661-3.

	   style is either "c11" or "ts-18661-3" as appropriate.

	   The default when in a standards compliant mode (-std=c11 or
	   similar) is -fpermitted-flt-eval-methods=c11.  The default when in
	   a GNU dialect (-std=gnu11 or similar) is
	   -fpermitted-flt-eval-methods=ts-18661-3.

	   The -fdeps-* options are used to extract structured dependency
	   information for a source.  This involves determining what resources
	   provided by other source files will be required to compile the
	   source as well as what resources are provided by the source.	 This
	   information can be used to add required dependencies between
	   compilation rules of dependent sources based on their contents
	   rather than requiring such information be reflected within the
	   build tools as well.

       -fdeps-file=file
	   Where to write structured dependency information.

       -fdeps-format=format
	   The format to use for structured dependency information. p1689r5 is
	   the only supported format right now.	 Note that when this argument
	   is specified, the output of -MF is stripped of some information
	   (namely C++ modules) so that it does not use extended makefile
	   syntax not understood by most tools.

       -fdeps-target=file
	   Analogous to -MT but for structured dependency information.	This
	   indicates the target which will ultimately need any required
	   resources and provide any resources extracted from the source that
	   may be required by other sources.

       -fplan9-extensions
	   Accept some non-standard constructs used in Plan 9 code.

	   This enables -fms-extensions, permits passing pointers to
	   structures with anonymous fields to functions that expect pointers
	   to elements of the type of the field, and permits referring to
	   anonymous fields declared using a typedef.	 This is only
	   supported for C, not C++.

       -fsigned-bitfields
       -funsigned-bitfields
       -fno-signed-bitfields
       -fno-unsigned-bitfields
	   These options control whether a bit-field is signed or unsigned,
	   when the declaration does not use either "signed" or "unsigned".
	   By default, such a bit-field is signed, because this is consistent:
	   the basic integer types such as "int" are signed types.

       -fsigned-char
	   Let the type "char" be signed, like "signed char".

	   Note that this is equivalent to -fno-unsigned-char, which is the
	   negative form of -funsigned-char.  Likewise, the option
	   -fno-signed-char is equivalent to -funsigned-char.

       -funsigned-char
	   Let the type "char" be unsigned, like "unsigned char".

	   Each kind of machine has a default for what "char" should be.  It
	   is either like "unsigned char" by default or like "signed char" by
	   default.

	   Ideally, a portable program should always use "signed char" or
	   "unsigned char" when it depends on the signedness of an object.
	   But many programs have been written to use plain "char" and expect
	   it to be signed, or expect it to be unsigned, depending on the
	   machines they were written for.  This option, and its inverse, let
	   you make such a program work with the opposite default.

	   The type "char" is always a distinct type from each of "signed
	   char" or "unsigned char", even though its behavior is always just
	   like one of those two.

       -fstrict-flex-arrays (C and C++ only)
       -fstrict-flex-arrays=level (C and C++ only)
	   Control when to treat the trailing array of a structure as a
	   flexible array member for the purpose of accessing the elements of
	   such an array.  The value of level controls the level of
	   strictness.

	   -fstrict-flex-arrays is equivalent to -fstrict-flex-arrays=3, which
	   is the strictest; all trailing arrays of structures are treated as
	   flexible array members.

	   The negative form -fno-strict-flex-arrays is equivalent to
	   -fstrict-flex-arrays=0, which is the least strict.  In this case a
	   trailing array is treated as a flexible array member only when it
	   is declared as a flexible array member per C99 standard onwards.

	   The possible values of level are the same as for the
	   "strict_flex_array" attribute.

	   You can control this behavior for a specific trailing array field
	   of a structure by using the variable attribute "strict_flex_array"
	   attribute.

	   The -fstrict_flex_arrays option interacts with the
	   -Wstrict-flex-arrays option.

       -fsso-struct=endianness
	   Set the default scalar storage order of structures and unions to
	   the specified endianness.  The accepted values are big-endian,
	   little-endian and native for the native endianness of the target
	   (the default).  This option is not supported for C++.

	   Warning: the -fsso-struct switch causes GCC to generate code that
	   is not binary compatible with code generated without it if the
	   specified endianness is not the native endianness of the target.

   Options Controlling C++ Dialect
       This section describes the command-line options that are only
       meaningful for C++ programs.  You can also use most of the GNU compiler
       options regardless of what language your program is in.	For example,
       you might compile a file firstClass.C like this:

	       g++ -g -fstrict-enums -O -c firstClass.C

       In this example, only -fstrict-enums is an option meant only for C++
       programs; you can use the other options with any language supported by
       GCC.

       Some options for compiling C programs, such as -std, are also relevant
       for C++ programs.

       Here is a list of options that are only for compiling C++ programs:

       -fabi-version=n
	   Use version n of the C++ ABI.  The default is version 0.

	   Version 0 refers to the version conforming most closely to the C++
	   ABI specification.  Therefore, the ABI obtained using version 0
	   will change in different versions of G++ as ABI bugs are fixed.

	   Version 1 is the version of the C++ ABI that first appeared in G++
	   3.2.

	   Version 2 is the version of the C++ ABI that first appeared in G++
	   3.4, and was the default through G++ 4.9.

	   Version 3 corrects an error in mangling a constant address as a
	   template argument.

	   Version 4, which first appeared in G++ 4.5, implements a standard
	   mangling for vector types.

	   Version 5, which first appeared in G++ 4.6, corrects the mangling
	   of attribute const/volatile on function pointer types, decltype of
	   a plain decl, and use of a function parameter in the declaration of
	   another parameter.

	   Version 6, which first appeared in G++ 4.7, corrects the promotion
	   behavior of C++11 scoped enums and the mangling of template
	   argument packs, const/static_cast, prefix ++ and --, and a class
	   scope function used as a template argument.

	   Version 7, which first appeared in G++ 4.8, that treats nullptr_t
	   as a builtin type and corrects the mangling of lambdas in default
	   argument scope.

	   Version 8, which first appeared in G++ 4.9, corrects the
	   substitution behavior of function types with function-cv-
	   qualifiers.

	   Version 9, which first appeared in G++ 5.2, corrects the alignment
	   of "nullptr_t".

	   Version 10, which first appeared in G++ 6.1, adds mangling of
	   attributes that affect type identity, such as ia32 calling
	   convention attributes (e.g. stdcall).

	   Version 11, which first appeared in G++ 7, corrects the mangling of
	   sizeof... expressions and operator names.  For multiple entities
	   with the same name within a function, that are declared in
	   different scopes, the mangling now changes starting with the
	   twelfth occurrence.	It also implies -fnew-inheriting-ctors.

	   Version 12, which first appeared in G++ 8, corrects the calling
	   conventions for empty classes on the x86_64 target and for classes
	   with only deleted copy/move constructors.  It accidentally changes
	   the calling convention for classes with a deleted copy constructor
	   and a trivial move constructor.

	   Version 13, which first appeared in G++ 8.2, fixes the accidental
	   change in version 12.

	   Version 14, which first appeared in G++ 10, corrects the mangling
	   of the nullptr expression.

	   Version 15, which first appeared in G++ 10.3, corrects G++ 10 ABI
	   tag regression.

	   Version 16, which first appeared in G++ 11, changes the mangling of
	   "__alignof__" to be distinct from that of "alignof", and dependent
	   operator names.

	   Version 17, which first appeared in G++ 12, fixes layout of classes
	   that inherit from aggregate classes with default member
	   initializers in C++14 and up.

	   Version 18, which first appeard in G++ 13, fixes manglings of
	   lambdas that have additional context.

	   Version 19, which first appeard in G++ 14, fixes manglings of
	   structured bindings to include ABI tags.

	   See also -Wabi.

       -fabi-compat-version=n
	   On targets that support strong aliases, G++ works around mangling
	   changes by creating an alias with the correct mangled name when
	   defining a symbol with an incorrect mangled name.  This switch
	   specifies which ABI version to use for the alias.

	   With -fabi-version=0 (the default), this defaults to 13 (GCC 8.2
	   compatibility).  If another ABI version is explicitly selected,
	   this defaults to 0.	For compatibility with GCC versions 3.2
	   through 4.9, use -fabi-compat-version=2.

	   If this option is not provided but -Wabi=n is, that version is used
	   for compatibility aliases.  If this option is provided along with
	   -Wabi (without the version), the version from this option is used
	   for the warning.

       -fno-access-control
	   Turn off all access checking.  This switch is mainly useful for
	   working around bugs in the access control code.

       -faligned-new
	   Enable support for C++17 "new" of types that require more alignment
	   than "void* ::operator new(std::size_t)" provides.  A numeric
	   argument such as "-faligned-new=32" can be used to specify how much
	   alignment (in bytes) is provided by that function, but few users
	   will need to override the default of alignof(std::max_align_t).

	   This flag is enabled by default for -std=c++17.

       -fchar8_t
       -fno-char8_t
	   Enable support for "char8_t" as adopted for C++20.  This includes
	   the addition of a new "char8_t" fundamental type, changes to the
	   types of UTF-8 string and character literals, new signatures for
	   user-defined literals, associated standard library updates, and new
	   "__cpp_char8_t" and "__cpp_lib_char8_t" feature test macros.

	   This option enables functions to be overloaded for ordinary and
	   UTF-8 strings:

		   int f(const char *);	   // #1
		   int f(const char8_t *); // #2
		   int v1 = f("text");	   // Calls #1
		   int v2 = f(u8"text");   // Calls #2

	   and introduces new signatures for user-defined literals:

		   int operator""_udl1(char8_t);
		   int v3 = u8'x'_udl1;
		   int operator""_udl2(const char8_t*, std::size_t);
		   int v4 = u8"text"_udl2;
		   template<typename T, T...> int operator""_udl3();
		   int v5 = u8"text"_udl3;

	   The change to the types of UTF-8 string and character literals
	   introduces incompatibilities with ISO C++11 and later standards.
	   For example, the following code is well-formed under ISO C++11, but
	   is ill-formed when -fchar8_t is specified.

		   const char *cp = u8"xx";// error: invalid conversion from
					   //	     `const char8_t*' to `const char*'
		   int f(const char*);
		   auto v = f(u8"xx");	   // error: invalid conversion from
					   //	     `const char8_t*' to `const char*'
		   std::string s{u8"xx"};  // error: no matching function for call to
					   //	     `std::basic_string<char>::basic_string()'
		   using namespace std::literals;
		   s = u8"xx"s;		   // error: conversion from
					   //	     `basic_string<char8_t>' to non-scalar
					   //	     type `basic_string<char>' requested

       -fcheck-new
	   Check that the pointer returned by "operator new" is non-null
	   before attempting to modify the storage allocated.  This check is
	   normally unnecessary because the C++ standard specifies that
	   "operator new" only returns 0 if it is declared throw(), in which
	   case the compiler always checks the return value even without this
	   option.  In all other cases, when "operator new" has a non-empty
	   exception specification, memory exhaustion is signalled by throwing
	   "std::bad_alloc".  See also new (nothrow).

       -fconcepts
       -fconcepts-ts
	   Enable support for the C++ Concepts feature for constraining
	   template arguments.	With -std=c++20 and above, Concepts are part
	   of the language standard, so -fconcepts defaults to on.

	   Some constructs that were allowed by the earlier C++ Extensions for
	   Concepts Technical Specification, ISO 19217 (2015), but didn't make
	   it into the standard, can additionally be enabled by -fconcepts-ts.
	   The option -fconcepts-ts was deprecated in GCC 14 and may be
	   removed in GCC 15; users are expected to convert their code to
	   C++20 concepts.

       -fconstexpr-depth=n
	   Set the maximum nested evaluation depth for C++11 constexpr
	   functions to n.  A limit is needed to detect endless recursion
	   during constant expression evaluation.  The minimum specified by
	   the standard is 512.

       -fconstexpr-cache-depth=n
	   Set the maximum level of nested evaluation depth for C++11
	   constexpr functions that will be cached to n.  This is a heuristic
	   that trades off compilation speed (when the cache avoids repeated
	   calculations) against memory consumption (when the cache grows very
	   large from highly recursive evaluations).  The default is 8.	 Very
	   few users are likely to want to adjust it, but if your code does
	   heavy constexpr calculations you might want to experiment to find
	   which value works best for you.

       -fconstexpr-fp-except
	   Annex F of the C standard specifies that IEC559 floating point
	   exceptions encountered at compile time should not stop compilation.
	   C++ compilers have historically not followed this guidance, instead
	   treating floating point division by zero as non-constant even
	   though it has a well defined value.	This flag tells the compiler
	   to give Annex F priority over other rules saying that a particular
	   operation is undefined.

		   constexpr float inf = 1./0.; // OK with -fconstexpr-fp-except

       -fconstexpr-loop-limit=n
	   Set the maximum number of iterations for a loop in C++14 constexpr
	   functions to n.  A limit is needed to detect infinite loops during
	   constant expression evaluation.  The default is 262144 (1<<18).

       -fconstexpr-ops-limit=n
	   Set the maximum number of operations during a single constexpr
	   evaluation.	Even when number of iterations of a single loop is
	   limited with the above limit, if there are several nested loops and
	   each of them has many iterations but still smaller than the above
	   limit, or if in a body of some loop or even outside of a loop too
	   many expressions need to be evaluated, the resulting constexpr
	   evaluation might take too long.  The default is 33554432 (1<<25).

       -fcontracts
	   Enable experimental support for the C++ Contracts feature, as
	   briefly added to and then removed from the C++20 working paper
	   (N4820).  The implementation also includes proposed enhancements
	   from papers P1290, P1332, and P1429.	 This functionality is
	   intended mostly for those interested in experimentation towards
	   refining the feature to get it into shape for a future C++
	   standard.

	   On violation of a checked contract, the violation handler is
	   called.  Users can replace the violation handler by defining

		   void
		   handle_contract_violation (const std::experimental::contract_violation&);

	   There are different sets of additional flags that can be used
	   together to specify which contracts will be checked and how, for
	   N4820 contracts, P1332 contracts, or P1429 contracts; these sets
	   cannot be used together.

	   -fcontract-mode=[on|off]
	       Control whether any contracts have any semantics at all.
	       Defaults to on.

	   -fcontract-assumption-mode=[on|off]
	       [N4820] Control whether contracts with level axiom should have
	       the assume semantic.  Defaults to on.

	   -fcontract-build-level=[off|default|audit]
	       [N4820] Specify which level of contracts to generate checks
	       for.  Defaults to default.

	   -fcontract-continuation-mode=[on|off]
	       [N4820] Control whether to allow the program to continue
	       executing after a contract violation.  That is, do checked
	       contracts have the maybe semantic described below rather than
	       the never semantic.  Defaults to off.

	   -fcontract-role=<name>:<default>,<audit>,<axiom>
	       [P1332] Specify the concrete semantics for each contract level
	       of a particular contract role.

	   -fcontract-semantic=[default|audit|axiom]:<semantic>
	       [P1429] Specify the concrete semantic for a particular contract
	       level.

	   -fcontract-strict-declarations=[on|off]
	       Control whether to reject adding contracts to a function after
	       its first declaration.  Defaults to off.

	   The possible concrete semantics for that can be specified with
	   -fcontract-role or -fcontract-semantic are:

	   "ignore"
	       This contract has no effect.

	   "assume"
	       This contract is treated like C++23 "[[assume]]".

	   "check_never_continue"
	   "never"
	   "abort"
	       This contract is checked.  If it fails, the violation handler
	       is called.  If the handler returns, "std::terminate" is called.

	   "check_maybe_continue"
	   "maybe"
	       This contract is checked.  If it fails, the violation handler
	       is called.  If the handler returns, execution continues
	       normally.

       -fcoroutines
	   Enable support for the C++ coroutines extension (experimental).

       -fdiagnostics-all-candidates
	   Permit the C++ front end to note all candidates during overload
	   resolution failure, including when a deleted function is selected.

       -fno-elide-constructors
	   The C++ standard allows an implementation to omit creating a
	   temporary that is only used to initialize another object of the
	   same type.  Specifying this option disables that optimization, and
	   forces G++ to call the copy constructor in all cases.  This option
	   also causes G++ to call trivial member functions which otherwise
	   would be expanded inline.

	   In C++17, the compiler is required to omit these temporaries, but
	   this option still affects trivial member functions.

       -fno-enforce-eh-specs
	   Don't generate code to check for violation of exception
	   specifications at run time.	This option violates the C++ standard,
	   but may be useful for reducing code size in production builds, much
	   like defining "NDEBUG".  This does not give user code permission to
	   throw exceptions in violation of the exception specifications; the
	   compiler still optimizes based on the specifications, so throwing
	   an unexpected exception results in undefined behavior at run time.

       -fextern-tls-init
       -fno-extern-tls-init
	   The C++11 and OpenMP standards allow "thread_local" and
	   "threadprivate" variables to have dynamic (runtime) initialization.
	   To support this, any use of such a variable goes through a wrapper
	   function that performs any necessary initialization.	 When the use
	   and definition of the variable are in the same translation unit,
	   this overhead can be optimized away, but when the use is in a
	   different translation unit there is significant overhead even if
	   the variable doesn't actually need dynamic initialization.  If the
	   programmer can be sure that no use of the variable in a non-
	   defining TU needs to trigger dynamic initialization (either because
	   the variable is statically initialized, or a use of the variable in
	   the defining TU will be executed before any uses in another TU),
	   they can avoid this overhead with the -fno-extern-tls-init option.

	   On targets that support symbol aliases, the default is
	   -fextern-tls-init.  On targets that do not support symbol aliases,
	   the default is -fno-extern-tls-init.

       -ffold-simple-inlines
       -fno-fold-simple-inlines
	   Permit the C++ frontend to fold calls to "std::move",
	   "std::forward", "std::addressof" and "std::as_const".  In contrast
	   to inlining, this means no debug information will be generated for
	   such calls.	Since these functions are rarely interesting to debug,
	   this flag is enabled by default unless -fno-inline is active.

       -fno-gnu-keywords
	   Do not recognize "typeof" as a keyword, so that code can use this
	   word as an identifier.  You can use the keyword "__typeof__"
	   instead.  This option is implied by the strict ISO C++ dialects:
	   -ansi, -std=c++98, -std=c++11, etc.

       -fno-immediate-escalation
	   Do not enable immediate function escalation whereby certain
	   functions can be promoted to consteval, as specified in P2564R3.
	   For example:

		   consteval int id(int i) { return i; }

		   constexpr int f(auto t)
		   {
		     return t + id(t); // id causes f<int> to be promoted to consteval
		   }

		   void g(int i)
		   {
		     f (3);
		   }

	   compiles in C++20: "f" is an immediate-escalating function (due to
	   the "auto" it is a function template and is declared "constexpr")
	   and id(t) is an immediate-escalating expression, so "f" is promoted
	   to "consteval".  Consequently, the call to id(t) is in an immediate
	   context, so doesn't have to produce a constant (that is the
	   mechanism allowing consteval function composition).	However, with
	   -fno-immediate-escalation, "f" is not promoted to "consteval", and
	   since the call to consteval function id(t) is not a constant
	   expression, the compiler rejects the code.

	   This option is turned on by default; it is only effective in C++20
	   mode or later.

       -fimplicit-constexpr
	   Make inline functions implicitly constexpr, if they satisfy the
	   requirements for a constexpr function.  This option can be used in
	   C++14 mode or later.	 This can result in initialization changing
	   from dynamic to static and other optimizations.

       -fno-implicit-templates
	   Never emit code for non-inline templates that are instantiated
	   implicitly (i.e. by use); only emit code for explicit
	   instantiations.  If you use this option, you must take care to
	   structure your code to include all the necessary explicit
	   instantiations to avoid getting undefined symbols at link time.

       -fno-implicit-inline-templates
	   Don't emit code for implicit instantiations of inline templates,
	   either.  The default is to handle inlines differently so that
	   compiles with and without optimization need the same set of
	   explicit instantiations.

       -fno-implement-inlines
	   To save space, do not emit out-of-line copies of inline functions
	   controlled by "#pragma implementation".  This causes linker errors
	   if these functions are not inlined everywhere they are called.

       -fmodules-ts
       -fno-modules-ts
	   Enable support for C++20 modules.  The -fno-modules-ts is usually
	   not needed, as that is the default.	Even though this is a C++20
	   feature, it is not currently implicitly enabled by selecting that
	   standard version.

       -fmodule-header
       -fmodule-header=user
       -fmodule-header=system
	   Compile a header file to create an importable header unit.

       -fmodule-implicit-inline
	   Member functions defined in their class definitions are not
	   implicitly inline for modular code.	This is different to
	   traditional C++ behavior, for good reasons.	However, it may result
	   in a difficulty during code porting.	 This option makes such
	   function definitions implicitly inline.  It does however generate
	   an ABI incompatibility, so you must use it everywhere or nowhere.
	   (Such definitions outside of a named module remain implicitly
	   inline, regardless.)

       -fno-module-lazy
	   Disable lazy module importing and module mapper creation.

       -fmodule-mapper=[hostname]:port[?ident]
       -fmodule-mapper=|program[?ident] args...
       -fmodule-mapper==socket[?ident]
       -fmodule-mapper=<>[inout][?ident]
       -fmodule-mapper=<in>out[?ident]
       -fmodule-mapper=file[?ident]
	   An oracle to query for module name to filename mappings.  If
	   unspecified the CXX_MODULE_MAPPER environment variable is used, and
	   if that is unset, an in-process default is provided.

       -fmodule-only
	   Only emit the Compiled Module Interface, inhibiting any object
	   file.

       -fms-extensions
	   Disable Wpedantic warnings about constructs used in MFC, such as
	   implicit int and getting a pointer to member function via non-
	   standard syntax.

       -fnew-inheriting-ctors
	   Enable the P0136 adjustment to the semantics of C++11 constructor
	   inheritance.	 This is part of C++17 but also considered to be a
	   Defect Report against C++11 and C++14.  This flag is enabled by
	   default unless -fabi-version=10 or lower is specified.

       -fnew-ttp-matching
	   Enable the P0522 resolution to Core issue 150, template template
	   parameters and default arguments: this allows a template with
	   default template arguments as an argument for a template template
	   parameter with fewer template parameters.  This flag is enabled by
	   default for -std=c++17.

       -fno-nonansi-builtins
	   Disable built-in declarations of functions that are not mandated by
	   ANSI/ISO C.	These include "ffs", "alloca", "_exit", "index",
	   "bzero", "conjf", and other related functions.

       -fnothrow-opt
	   Treat a throw() exception specification as if it were a "noexcept"
	   specification to reduce or eliminate the text size overhead
	   relative to a function with no exception specification.  If the
	   function has local variables of types with non-trivial destructors,
	   the exception specification actually makes the function smaller
	   because the EH cleanups for those variables can be optimized away.
	   The semantic effect is that an exception thrown out of a function
	   with such an exception specification results in a call to
	   "terminate" rather than "unexpected".

       -fno-operator-names
	   Do not treat the operator name keywords "and", "bitand", "bitor",
	   "compl", "not", "or" and "xor" as synonyms as keywords.

       -fno-optional-diags
	   Disable diagnostics that the standard says a compiler does not need
	   to issue.  Currently, the only such diagnostic issued by G++ is the
	   one for a name having multiple meanings within a class.

       -fno-pretty-templates
	   When an error message refers to a specialization of a function
	   template, the compiler normally prints the signature of the
	   template followed by the template arguments and any typedefs or
	   typenames in the signature (e.g. "void f(T) [with T = int]" rather
	   than "void f(int)") so that it's clear which template is involved.
	   When an error message refers to a specialization of a class
	   template, the compiler omits any template arguments that match the
	   default template arguments for that template.  If either of these
	   behaviors make it harder to understand the error message rather
	   than easier, you can use -fno-pretty-templates to disable them.

       -fno-rtti
	   Disable generation of information about every class with virtual
	   functions for use by the C++ run-time type identification features
	   ("dynamic_cast" and "typeid").  If you don't use those parts of the
	   language, you can save some space by using this flag.  Note that
	   exception handling uses the same information, but G++ generates it
	   as needed. The "dynamic_cast" operator can still be used for casts
	   that do not require run-time type information, i.e. casts to "void
	   *" or to unambiguous base classes.

	   Mixing code compiled with -frtti with that compiled with -fno-rtti
	   may not work.  For example, programs may fail to link if a class
	   compiled with -fno-rtti is used as a base for a class compiled with
	   -frtti.

       -fsized-deallocation
	   Enable the built-in global declarations

		   void operator delete (void *, std::size_t) noexcept;
		   void operator delete[] (void *, std::size_t) noexcept;

	   as introduced in C++14.  This is useful for user-defined
	   replacement deallocation functions that, for example, use the size
	   of the object to make deallocation faster.  Enabled by default
	   under -std=c++14 and above.	The flag -Wsized-deallocation warns
	   about places that might want to add a definition.

       -fstrict-enums
	   Allow the compiler to optimize using the assumption that a value of
	   enumerated type can only be one of the values of the enumeration
	   (as defined in the C++ standard; basically, a value that can be
	   represented in the minimum number of bits needed to represent all
	   the enumerators).  This assumption may not be valid if the program
	   uses a cast to convert an arbitrary integer value to the enumerated
	   type.  This option has no effect for an enumeration type with a
	   fixed underlying type.

       -fstrong-eval-order
	   Evaluate member access, array subscripting, and shift expressions
	   in left-to-right order, and evaluate assignment in right-to-left
	   order, as adopted for C++17.	 Enabled by default with -std=c++17.
	   -fstrong-eval-order=some enables just the ordering of member access
	   and shift expressions, and is the default without -std=c++17.

       -ftemplate-backtrace-limit=n
	   Set the maximum number of template instantiation notes for a single
	   warning or error to n.  The default value is 10.

       -ftemplate-depth=n
	   Set the maximum instantiation depth for template classes to n.  A
	   limit on the template instantiation depth is needed to detect
	   endless recursions during template class instantiation.  ANSI/ISO
	   C++ conforming programs must not rely on a maximum depth greater
	   than 17 (changed to 1024 in C++11).	The default value is 900, as
	   the compiler can run out of stack space before hitting 1024 in some
	   situations.

       -fno-threadsafe-statics
	   Do not emit the extra code to use the routines specified in the C++
	   ABI for thread-safe initialization of local statics.	 You can use
	   this option to reduce code size slightly in code that doesn't need
	   to be thread-safe.

       -fuse-cxa-atexit
	   Register destructors for objects with static storage duration with
	   the "__cxa_atexit" function rather than the "atexit" function.
	   This option is required for fully standards-compliant handling of
	   static destructors, but only works if your C library supports
	   "__cxa_atexit".

       -fno-use-cxa-get-exception-ptr
	   Don't use the "__cxa_get_exception_ptr" runtime routine.  This
	   causes "std::uncaught_exception" to be incorrect, but is necessary
	   if the runtime routine is not available.

       -fvisibility-inlines-hidden
	   This switch declares that the user does not attempt to compare
	   pointers to inline functions or methods where the addresses of the
	   two functions are taken in different shared objects.

	   The effect of this is that GCC may, effectively, mark inline
	   methods with "__attribute__ ((visibility ("hidden")))" so that they
	   do not appear in the export table of a DSO and do not require a PLT
	   indirection when used within the DSO.  Enabling this option can
	   have a dramatic effect on load and link times of a DSO as it
	   massively reduces the size of the dynamic export table when the
	   library makes heavy use of templates.

	   The behavior of this switch is not quite the same as marking the
	   methods as hidden directly, because it does not affect static
	   variables local to the function or cause the compiler to deduce
	   that the function is defined in only one shared object.

	   You may mark a method as having a visibility explicitly to negate
	   the effect of the switch for that method.  For example, if you do
	   want to compare pointers to a particular inline method, you might
	   mark it as having default visibility.  Marking the enclosing class
	   with explicit visibility has no effect.

	   Explicitly instantiated inline methods are unaffected by this
	   option as their linkage might otherwise cross a shared library
	   boundary.

       -fvisibility-ms-compat
	   This flag attempts to use visibility settings to make GCC's C++
	   linkage model compatible with that of Microsoft Visual Studio.

	   The flag makes these changes to GCC's linkage model:

	   1.  It sets the default visibility to "hidden", like
	       -fvisibility=hidden.

	   2.  Types, but not their members, are not hidden by default.

	   3.  The One Definition Rule is relaxed for types without explicit
	       visibility specifications that are defined in more than one
	       shared object: those declarations are permitted if they are
	       permitted when this option is not used.

	   In new code it is better to use -fvisibility=hidden and export
	   those classes that are intended to be externally visible.
	   Unfortunately it is possible for code to rely, perhaps
	   accidentally, on the Visual Studio behavior.

	   Among the consequences of these changes are that static data
	   members of the same type with the same name but defined in
	   different shared objects are different, so changing one does not
	   change the other; and that pointers to function members defined in
	   different shared objects may not compare equal.  When this flag is
	   given, it is a violation of the ODR to define types with the same
	   name differently.

       -fno-weak
	   Do not use weak symbol support, even if it is provided by the
	   linker.  By default, G++ uses weak symbols if they are available.
	   This option exists only for testing, and should not be used by end-
	   users; it results in inferior code and has no benefits.  This
	   option may be removed in a future release of G++.

       -fext-numeric-literals (C++ and Objective-C++ only)
	   Accept imaginary, fixed-point, or machine-defined literal number
	   suffixes as GNU extensions.	When this option is turned off these
	   suffixes are treated as C++11 user-defined literal numeric
	   suffixes.  This is on by default for all pre-C++11 dialects and all
	   GNU dialects: -std=c++98, -std=gnu++98, -std=gnu++11, -std=gnu++14.
	   This option is off by default for ISO C++11 onwards (-std=c++11,
	   ...).

       -nostdinc++
	   Do not search for header files in the standard directories specific
	   to C++, but do still search the other standard directories.	(This
	   option is used when building the C++ library.)

       -flang-info-include-translate
       -flang-info-include-translate-not
       -flang-info-include-translate=header
	   Inform of include translation events.  The first will note accepted
	   include translations, the second will note declined include
	   translations.  The header form will inform of include translations
	   relating to that specific header.  If header is of the form "user"
	   or "<system>" it will be resolved to a specific user or system
	   header using the include path.

       -flang-info-module-cmi
       -flang-info-module-cmi=module
	   Inform of Compiled Module Interface pathnames.  The first will note
	   all read CMI pathnames.  The module form will not reading a
	   specific module's CMI.  module may be a named module or a header-
	   unit (the latter indicated by either being a pathname containing
	   directory separators or enclosed in "<>" or "").

       -stdlib=libstdc++,libc++
	   When G++ is configured to support this option, it allows
	   specification of alternate C++ runtime libraries.  Two options are
	   available: libstdc++ (the default, native C++ runtime for G++) and
	   libc++ which is the C++ runtime installed on some operating systems
	   (e.g. Darwin versions from Darwin11 onwards).  The option switches
	   G++ to use the headers from the specified library and to emit
	   "-lstdc++" or "-lc++" respectively, when a C++ runtime is required
	   for linking.

       In addition, these warning options have meanings only for C++ programs:

       -Wabi-tag (C++ and Objective-C++ only)
	   Warn when a type with an ABI tag is used in a context that does not
	   have that ABI tag.  See C++ Attributes for more information about
	   ABI tags.

       -Wcomma-subscript (C++ and Objective-C++ only)
	   Warn about uses of a comma expression within a subscripting
	   expression.	This usage was deprecated in C++20 and is going to be
	   removed in C++23.  However, a comma expression wrapped in "( )" is
	   not deprecated.  Example:

		   void f(int *a, int b, int c) {
		       a[b,c];	   // deprecated in C++20, invalid in C++23
		       a[(b,c)];   // OK
		   }

	   In C++23 it is valid to have comma separated expressions in a
	   subscript when an overloaded subscript operator is found and
	   supports the right number and types of arguments.  G++ will accept
	   the formerly valid syntax for code that is not valid in C++23 but
	   used to be valid but deprecated in C++20 with a pedantic warning
	   that can be disabled with -Wno-comma-subscript.

	   Enabled by default with -std=c++20 unless -Wno-deprecated, and with
	   -std=c++23 regardless of -Wno-deprecated.

	   This warning is upgraded to an error by -pedantic-errors in C++23
	   mode or later.

       -Wctad-maybe-unsupported (C++ and Objective-C++ only)
	   Warn when performing class template argument deduction (CTAD) on a
	   type with no explicitly written deduction guides.  This warning
	   will point out cases where CTAD succeeded only because the compiler
	   synthesized the implicit deduction guides, which might not be what
	   the programmer intended.  Certain style guides allow CTAD only on
	   types that specifically "opt-in"; i.e., on types that are designed
	   to support CTAD.  This warning can be suppressed with the following
	   pattern:

		   struct allow_ctad_t; // any name works
		   template <typename T> struct S {
		     S(T) { }
		   };
		   // Guide with incomplete parameter type will never be considered.
		   S(allow_ctad_t) -> S<void>;

       -Wctor-dtor-privacy (C++ and Objective-C++ only)
	   Warn when a class seems unusable because all the constructors or
	   destructors in that class are private, and it has neither friends
	   nor public static member functions.	Also warn if there are no non-
	   private methods, and there's at least one private member function
	   that isn't a constructor or destructor.

       -Wdangling-reference (C++ and Objective-C++ only)
	   Warn when a reference is bound to a temporary whose lifetime has
	   ended.  For example:

		   int n = 1;
		   const int& r = std::max(n - 1, n + 1); // r is dangling

	   In the example above, two temporaries are created, one for each
	   argument, and a reference to one of the temporaries is returned.
	   However, both temporaries are destroyed at the end of the full
	   expression, so the reference "r" is dangling.  This warning also
	   detects dangling references in member initializer lists:

		   const int& f(const int& i) { return i; }
		   struct S {
		     const int &r; // r is dangling
		     S() : r(f(10)) { }
		   };

	   Member functions are checked as well, but only their object
	   argument:

		   struct S {
		      const S& self () { return *this; }
		   };
		   const S& s = S().self(); // s is dangling

	   Certain functions are safe in this respect, for example
	   "std::use_facet": they take and return a reference, but they don't
	   return one of its arguments, which can fool the warning.  Such
	   functions can be excluded from the warning by wrapping them in a
	   "#pragma":

		   #pragma GCC diagnostic push
		   #pragma GCC diagnostic ignored "-Wdangling-reference"
		   const T& foo (const T&) { ... }
		   #pragma GCC diagnostic pop

	   The "#pragma" can also surround the class; in that case, the
	   warning will be disabled for all the member functions.

	   -Wdangling-reference also warns about code like

		   auto p = std::minmax(1, 2);

	   where "std::minmax" returns "std::pair<const int&, const int&>",
	   and both references dangle after the end of the full expression
	   that contains the call to "std::minmax".

	   The warning does not warn for "std::span"-like classes.  We
	   consider classes of the form:

		   template<typename T>
		   struct Span {
		     T* data_;
		     std::size len_;
		   };

	   as "std::span"-like; that is, the class is a non-union class that
	   has a pointer data member and a trivial destructor.

	   The warning can be disabled by using the "gnu::no_dangling"
	   attribute.

	   This warning is enabled by -Wall.

       -Wdelete-non-virtual-dtor (C++ and Objective-C++ only)
	   Warn when "delete" is used to destroy an instance of a class that
	   has virtual functions and non-virtual destructor. It is unsafe to
	   delete an instance of a derived class through a pointer to a base
	   class if the base class does not have a virtual destructor.	This
	   warning is enabled by -Wall.

       -Wdeprecated-copy (C++ and Objective-C++ only)
	   Warn that the implicit declaration of a copy constructor or copy
	   assignment operator is deprecated if the class has a user-provided
	   copy constructor or copy assignment operator, in C++11 and up.
	   This warning is enabled by -Wextra.	With -Wdeprecated-copy-dtor,
	   also deprecate if the class has a user-provided destructor.

       -Wno-deprecated-enum-enum-conversion (C++ and Objective-C++ only)
	   Disable the warning about the case when the usual arithmetic
	   conversions are applied on operands where one is of enumeration
	   type and the other is of a different enumeration type.  This
	   conversion was deprecated in C++20.	For example:

		   enum E1 { e };
		   enum E2 { f };
		   int k = f - e;

	   -Wdeprecated-enum-enum-conversion is enabled by default with
	   -std=c++20.	In pre-C++20 dialects, this warning can be enabled by
	   -Wenum-conversion.

       -Wno-deprecated-enum-float-conversion (C++ and Objective-C++ only)
	   Disable the warning about the case when the usual arithmetic
	   conversions are applied on operands where one is of enumeration
	   type and the other is of a floating-point type.  This conversion
	   was deprecated in C++20.  For example:

		   enum E1 { e };
		   enum E2 { f };
		   bool b = e <= 3.7;

	   -Wdeprecated-enum-float-conversion is enabled by default with
	   -std=c++20.	In pre-C++20 dialects, this warning can be enabled by
	   -Wenum-conversion.

       -Wno-elaborated-enum-base
	   For C++11 and above, warn if an (invalid) additional enum-base is
	   used in an elaborated-type-specifier.  That is, if an enum with
	   given underlying type and no enumerator list is used in a
	   declaration other than just a standalone declaration of the enum.
	   Enabled by default.	This warning is upgraded to an error with
	   -pedantic-errors.

       -Wno-init-list-lifetime (C++ and Objective-C++ only)
	   Do not warn about uses of "std::initializer_list" that are likely
	   to result in dangling pointers.  Since the underlying array for an
	   "initializer_list" is handled like a normal C++ temporary object,
	   it is easy to inadvertently keep a pointer to the array past the
	   end of the array's lifetime.	 For example:

	   *   If a function returns a temporary "initializer_list", or a
	       local "initializer_list" variable, the array's lifetime ends at
	       the end of the return statement, so the value returned has a
	       dangling pointer.

	   *   If a new-expression creates an "initializer_list", the array
	       only lives until the end of the enclosing full-expression, so
	       the "initializer_list" in the heap has a dangling pointer.

	   *   When an "initializer_list" variable is assigned from a brace-
	       enclosed initializer list, the temporary array created for the
	       right side of the assignment only lives until the end of the
	       full-expression, so at the next statement the
	       "initializer_list" variable has a dangling pointer.

		       // li's initial underlying array lives as long as li
		       std::initializer_list<int> li = { 1,2,3 };
		       // assignment changes li to point to a temporary array
		       li = { 4, 5 };
		       // now the temporary is gone and li has a dangling pointer
		       int i = li.begin()[0] // undefined behavior

	   *   When a list constructor stores the "begin" pointer from the
	       "initializer_list" argument, this doesn't extend the lifetime
	       of the array, so if a class variable is constructed from a
	       temporary "initializer_list", the pointer is left dangling by
	       the end of the variable declaration statement.

       -Winvalid-constexpr
	   Warn when a function never produces a constant expression.  In
	   C++20 and earlier, for every "constexpr" function and function
	   template, there must be at least one set of function arguments in
	   at least one instantiation such that an invocation of the function
	   or constructor could be an evaluated subexpression of a core
	   constant expression.	 C++23 removed this restriction, so it's
	   possible to have a function or a function template marked
	   "constexpr" for which no invocation satisfies the requirements of a
	   core constant expression.

	   This warning is enabled as a pedantic warning by default in C++20
	   and earlier.	 In C++23, -Winvalid-constexpr can be turned on, in
	   which case it will be an ordinary warning.  For example:

		   void f (int& i);
		   constexpr void
		   g (int& i)
		   {
		     // Warns by default in C++20, in C++23 only with -Winvalid-constexpr.
		     f(i);
		   }

       -Winvalid-imported-macros
	   Verify all imported macro definitions are valid at the end of
	   compilation.	 This is not enabled by default, as it requires
	   additional processing to determine.	It may be useful when
	   preparing sets of header-units to ensure consistent macros.

       -Wno-literal-suffix (C++ and Objective-C++ only)
	   Do not warn when a string or character literal is followed by a ud-
	   suffix which does not begin with an underscore.  As a conforming
	   extension, GCC treats such suffixes as separate preprocessing
	   tokens in order to maintain backwards compatibility with code that
	   uses formatting macros from "<inttypes.h>".	For example:

		   #define __STDC_FORMAT_MACROS
		   #include <inttypes.h>
		   #include <stdio.h>

		   int main() {
		     int64_t i64 = 123;
		     printf("My int64: %" PRId64"\n", i64);
		   }

	   In this case, "PRId64" is treated as a separate preprocessing
	   token.

	   This option also controls warnings when a user-defined literal
	   operator is declared with a literal suffix identifier that doesn't
	   begin with an underscore. Literal suffix identifiers that don't
	   begin with an underscore are reserved for future standardization.

	   These warnings are enabled by default.

       -Wno-narrowing (C++ and Objective-C++ only)
	   For C++11 and later standards, narrowing conversions are diagnosed
	   by default, as required by the standard.  A narrowing conversion
	   from a constant produces an error, and a narrowing conversion from
	   a non-constant produces a warning, but -Wno-narrowing suppresses
	   the diagnostic.  Note that this does not affect the meaning of
	   well-formed code; narrowing conversions are still considered ill-
	   formed in SFINAE contexts.

	   With -Wnarrowing in C++98, warn when a narrowing conversion
	   prohibited by C++11 occurs within { }, e.g.

		   int i = { 2.2 }; // error: narrowing from double to int

	   This flag is included in -Wall and -Wc++11-compat.

       -Wnoexcept (C++ and Objective-C++ only)
	   Warn when a noexcept-expression evaluates to false because of a
	   call to a function that does not have a non-throwing exception
	   specification (i.e. throw() or "noexcept") but is known by the
	   compiler to never throw an exception.

       -Wnoexcept-type (C++ and Objective-C++ only)
	   Warn if the C++17 feature making "noexcept" part of a function type
	   changes the mangled name of a symbol relative to C++14.  Enabled by
	   -Wabi and -Wc++17-compat.

	   As an example:

		   template <class T> void f(T t) { t(); };
		   void g() noexcept;
		   void h() { f(g); }

	   In C++14, "f" calls "f<void(*)()>", but in C++17 it calls
	   "f<void(*)()noexcept>".

       -Wclass-memaccess (C++ and Objective-C++ only)
	   Warn when the destination of a call to a raw memory function such
	   as "memset" or "memcpy" is an object of class type, and when
	   writing into such an object might bypass the class non-trivial or
	   deleted constructor or copy assignment, violate const-correctness
	   or encapsulation, or corrupt virtual table pointers.	 Modifying the
	   representation of such objects may violate invariants maintained by
	   member functions of the class.  For example, the call to "memset"
	   below is undefined because it modifies a non-trivial class object
	   and is, therefore, diagnosed.  The safe way to either initialize or
	   clear the storage of objects of such types is by using the
	   appropriate constructor or assignment operator, if one is
	   available.

		   std::string str = "abc";
		   memset (&str, 0, sizeof str);

	   The -Wclass-memaccess option is enabled by -Wall.  Explicitly
	   casting the pointer to the class object to "void *" or to a type
	   that can be safely accessed by the raw memory function suppresses
	   the warning.

       -Wnon-virtual-dtor (C++ and Objective-C++ only)
	   Warn when a class has virtual functions and an accessible non-
	   virtual destructor itself or in an accessible polymorphic base
	   class, in which case it is possible but unsafe to delete an
	   instance of a derived class through a pointer to the class itself
	   or base class.  This warning is automatically enabled if -Weffc++
	   is specified.  The -Wdelete-non-virtual-dtor option (enabled by
	   -Wall) should be preferred because it warns about the unsafe cases
	   without false positives.

       -Wregister (C++ and Objective-C++ only)
	   Warn on uses of the "register" storage class specifier, except when
	   it is part of the GNU Explicit Register Variables extension.	 The
	   use of the "register" keyword as storage class specifier has been
	   deprecated in C++11 and removed in C++17.  Enabled by default with
	   -std=c++17.

       -Wreorder (C++ and Objective-C++ only)
	   Warn when the order of member initializers given in the code does
	   not match the order in which they must be executed.	For instance:

		   struct A {
		     int i;
		     int j;
		     A(): j (0), i (1) { }
		   };

	   The compiler rearranges the member initializers for "i" and "j" to
	   match the declaration order of the members, emitting a warning to
	   that effect.	 This warning is enabled by -Wall.

       -Wno-pessimizing-move (C++ and Objective-C++ only)
	   This warning warns when a call to "std::move" prevents copy
	   elision.  A typical scenario when copy elision can occur is when
	   returning in a function with a class return type, when the
	   expression being returned is the name of a non-volatile automatic
	   object, and is not a function parameter, and has the same type as
	   the function return type.

		   struct T {
		   ...
		   };
		   T fn()
		   {
		     T t;
		     ...
		     return std::move (t);
		   }

	   But in this example, the "std::move" call prevents copy elision.

	   This warning is enabled by -Wall.

       -Wno-redundant-move (C++ and Objective-C++ only)
	   This warning warns about redundant calls to "std::move"; that is,
	   when a move operation would have been performed even without the
	   "std::move" call.  This happens because the compiler is forced to
	   treat the object as if it were an rvalue in certain situations such
	   as returning a local variable, where copy elision isn't applicable.
	   Consider:

		   struct T {
		   ...
		   };
		   T fn(T t)
		   {
		     ...
		     return std::move (t);
		   }

	   Here, the "std::move" call is redundant.  Because G++ implements
	   Core Issue 1579, another example is:

		   struct T { // convertible to U
		   ...
		   };
		   struct U {
		   ...
		   };
		   U fn()
		   {
		     T t;
		     ...
		     return std::move (t);
		   }

	   In this example, copy elision isn't applicable because the type of
	   the expression being returned and the function return type differ,
	   yet G++ treats the return value as if it were designated by an
	   rvalue.

	   This warning is enabled by -Wextra.

       -Wrange-loop-construct (C++ and Objective-C++ only)
	   This warning warns when a C++ range-based for-loop is creating an
	   unnecessary copy.  This can happen when the range declaration is
	   not a reference, but probably should be.  For example:

		   struct S { char arr[128]; };
		   void fn () {
		     S arr[5];
		     for (const auto x : arr) { ... }
		   }

	   It does not warn when the type being copied is a trivially-copyable
	   type whose size is less than 64 bytes.

	   This warning also warns when a loop variable in a range-based for-
	   loop is initialized with a value of a different type resulting in a
	   copy.  For example:

		   void fn() {
		     int arr[10];
		     for (const double &x : arr) { ... }
		   }

	   In the example above, in every iteration of the loop a temporary
	   value of type "double" is created and destroyed, to which the
	   reference "const double &" is bound.

	   This warning is enabled by -Wall.

       -Wredundant-tags (C++ and Objective-C++ only)
	   Warn about redundant class-key and enum-key in references to class
	   types and enumerated types in contexts where the key can be
	   eliminated without causing an ambiguity.  For example:

		   struct foo;
		   struct foo *p;   // warn that keyword struct can be eliminated

	   On the other hand, in this example there is no warning:

		   struct foo;
		   void foo ();	  // "hides" struct foo
		   void bar (struct foo&);  // no warning, keyword struct is necessary

       -Wno-subobject-linkage (C++ and Objective-C++ only)
	   Do not warn if a class type has a base or a field whose type uses
	   the anonymous namespace or depends on a type with no linkage.  If a
	   type A depends on a type B with no or internal linkage, defining it
	   in multiple translation units would be an ODR violation because the
	   meaning of B is different in each translation unit.	If A only
	   appears in a single translation unit, the best way to silence the
	   warning is to give it internal linkage by putting it in an
	   anonymous namespace as well.	 The compiler doesn't give this
	   warning for types defined in the main .C file, as those are
	   unlikely to have multiple definitions.  -Wsubobject-linkage is
	   enabled by default.

       -Weffc++ (C++ and Objective-C++ only)
	   Warn about violations of the following style guidelines from Scott
	   Meyers' Effective C++ series of books:

	   *   Define a copy constructor and an assignment operator for
	       classes with dynamically-allocated memory.

	   *   Prefer initialization to assignment in constructors.

	   *   Have "operator=" return a reference to *this.

	   *   Don't try to return a reference when you must return an object.

	   *   Distinguish between prefix and postfix forms of increment and
	       decrement operators.

	   *   Never overload "&&", "||", or ",".

	   This option also enables -Wnon-virtual-dtor, which is also one of
	   the effective C++ recommendations.  However, the check is extended
	   to warn about the lack of virtual destructor in accessible non-
	   polymorphic bases classes too.

	   When selecting this option, be aware that the standard library
	   headers do not obey all of these guidelines; use grep -v to filter
	   out those warnings.

       -Wno-exceptions (C++ and Objective-C++ only)
	   Disable the warning about the case when an exception handler is
	   shadowed by another handler, which can point out a wrong ordering
	   of exception handlers.

       -Wstrict-null-sentinel (C++ and Objective-C++ only)
	   Warn about the use of an uncasted "NULL" as sentinel.  When
	   compiling only with GCC this is a valid sentinel, as "NULL" is
	   defined to "__null".	 Although it is a null pointer constant rather
	   than a null pointer, it is guaranteed to be of the same size as a
	   pointer.  But this use is not portable across different compilers.

       -Wno-non-template-friend (C++ and Objective-C++ only)
	   Disable warnings when non-template friend functions are declared
	   within a template.  In very old versions of GCC that predate
	   implementation of the ISO standard, declarations such as friend int
	   foo(int), where the name of the friend is an unqualified-id, could
	   be interpreted as a particular specialization of a template
	   function; the warning exists to diagnose compatibility problems,
	   and is enabled by default.

       -Wold-style-cast (C++ and Objective-C++ only)
	   Warn if an old-style (C-style) cast to a non-void type is used
	   within a C++ program.  The new-style casts ("dynamic_cast",
	   "static_cast", "reinterpret_cast", and "const_cast") are less
	   vulnerable to unintended effects and much easier to search for.

       -Woverloaded-virtual (C++ and Objective-C++ only)
       -Woverloaded-virtual=n
	   Warn when a function declaration hides virtual functions from a
	   base class.	For example, in:

		   struct A {
		     virtual void f();
		   };

		   struct B: public A {
		     void f(int); // does not override
		   };

	   the "A" class version of "f" is hidden in "B", and code like:

		   B* b;
		   b->f();

	   fails to compile.

	   In cases where the different signatures are not an accident, the
	   simplest solution is to add a using-declaration to the derived
	   class to un-hide the base function, e.g. add "using A::f;" to "B".

	   The optional level suffix controls the behavior when all the
	   declarations in the derived class override virtual functions in the
	   base class, even if not all of the base functions are overridden:

		   struct C {
		     virtual void f();
		     virtual void f(int);
		   };

		   struct D: public C {
		     void f(int); // does override
		   }

	   This pattern is less likely to be a mistake; if D is only used
	   virtually, the user might have decided that the base class
	   semantics for some of the overloads are fine.

	   At level 1, this case does not warn; at level 2, it does.
	   -Woverloaded-virtual by itself selects level 2.  Level 1 is
	   included in -Wall.

       -Wno-pmf-conversions (C++ and Objective-C++ only)
	   Disable the diagnostic for converting a bound pointer to member
	   function to a plain pointer.

       -Wsign-promo (C++ and Objective-C++ only)
	   Warn when overload resolution chooses a promotion from unsigned or
	   enumerated type to a signed type, over a conversion to an unsigned
	   type of the same size.  Previous versions of G++ tried to preserve
	   unsignedness, but the standard mandates the current behavior.

       -Wtemplates (C++ and Objective-C++ only)
	   Warn when a primary template declaration is encountered.  Some
	   coding rules disallow templates, and this may be used to enforce
	   that rule.  The warning is inactive inside a system header file,
	   such as the STL, so one can still use the STL.  One may also
	   instantiate or specialize templates.

       -Wmismatched-new-delete (C++ and Objective-C++ only)
	   Warn for mismatches between calls to "operator new" or "operator
	   delete" and the corresponding call to the allocation or
	   deallocation function.  This includes invocations of C++ "operator
	   delete" with pointers returned from either mismatched forms of
	   "operator new", or from other functions that allocate objects for
	   which the "operator delete" isn't a suitable deallocator, as well
	   as calls to other deallocation functions with pointers returned
	   from "operator new" for which the deallocation function isn't
	   suitable.

	   For example, the "delete" expression in the function below is
	   diagnosed because it doesn't match the array form of the "new"
	   expression the pointer argument was returned from.  Similarly, the
	   call to "free" is also diagnosed.

		   void f ()
		   {
		     int *a = new int[n];
		     delete a;	 // warning: mismatch in array forms of expressions

		     char *p = new char[n];
		     free (p);	 // warning: mismatch between new and free
		   }

	   The related option -Wmismatched-dealloc diagnoses mismatches
	   involving allocation and deallocation functions other than
	   "operator new" and "operator delete".

	   -Wmismatched-new-delete is included in -Wall.

       -Wmismatched-tags (C++ and Objective-C++ only)
	   Warn for declarations of structs, classes, and class templates and
	   their specializations with a class-key that does not match either
	   the definition or the first declaration if no definition is
	   provided.

	   For example, the declaration of "struct Object" in the argument
	   list of "draw" triggers the warning.	 To avoid it, either remove
	   the redundant class-key "struct" or replace it with "class" to
	   match its definition.

		   class Object {
		   public:
		     virtual ~Object () = 0;
		   };
		   void draw (struct Object*);

	   It is not wrong to declare a class with the class-key "struct" as
	   the example above shows.  The -Wmismatched-tags option is intended
	   to help achieve a consistent style of class declarations.  In code
	   that is intended to be portable to Windows-based compilers the
	   warning helps prevent unresolved references due to the difference
	   in the mangling of symbols declared with different class-keys.  The
	   option can be used either on its own or in conjunction with
	   -Wredundant-tags.

       -Wmultiple-inheritance (C++ and Objective-C++ only)
	   Warn when a class is defined with multiple direct base classes.
	   Some coding rules disallow multiple inheritance, and this may be
	   used to enforce that rule.  The warning is inactive inside a system
	   header file, such as the STL, so one can still use the STL.	One
	   may also define classes that indirectly use multiple inheritance.

       -Wvirtual-inheritance
	   Warn when a class is defined with a virtual direct base class.
	   Some coding rules disallow multiple inheritance, and this may be
	   used to enforce that rule.  The warning is inactive inside a system
	   header file, such as the STL, so one can still use the STL.	One
	   may also define classes that indirectly use virtual inheritance.

       -Wno-virtual-move-assign
	   Suppress warnings about inheriting from a virtual base with a non-
	   trivial C++11 move assignment operator.  This is dangerous because
	   if the virtual base is reachable along more than one path, it is
	   moved multiple times, which can mean both objects end up in the
	   moved-from state.  If the move assignment operator is written to
	   avoid moving from a moved-from object, this warning can be
	   disabled.

       -Wnamespaces
	   Warn when a namespace definition is opened.	Some coding rules
	   disallow namespaces, and this may be used to enforce that rule.
	   The warning is inactive inside a system header file, such as the
	   STL, so one can still use the STL.  One may also use using
	   directives and qualified names.

       -Wno-template-id-cdtor (C++ and Objective-C++ only)
	   Disable the warning about the use of simple-template-id as the
	   declarator-id of a constructor or destructor, which became invalid
	   in C++20 via DR 2237.  For example:

		   template<typename T> struct S {
		     S<T>(); // should be S();
		     ~S<T>();  // should be ~S();
		   };

	   -Wtemplate-id-cdtor is enabled by default with -std=c++20; it is
	   also enabled by -Wc++20-compat.

       -Wno-terminate (C++ and Objective-C++ only)
	   Disable the warning about a throw-expression that will immediately
	   result in a call to "terminate".

       -Wno-vexing-parse (C++ and Objective-C++ only)
	   Warn about the most vexing parse syntactic ambiguity.  This warns
	   about the cases when a declaration looks like a variable
	   definition, but the C++ language requires it to be interpreted as a
	   function declaration.  For instance:

		   void f(double a) {
		     int i();	     // extern int i (void);
		     int n(int(a));  // extern int n (int);
		   }

	   Another example:

		   struct S { S(int); };
		   void f(double a) {
		     S x(int(a));   // extern struct S x (int);
		     S y(int());    // extern struct S y (int (*) (void));
		     S z();	    // extern struct S z (void);
		   }

	   The warning will suggest options how to deal with such an
	   ambiguity; e.g., it can suggest removing the parentheses or using
	   braces instead.

	   This warning is enabled by default.

       -Wno-class-conversion (C++ and Objective-C++ only)
	   Do not warn when a conversion function converts an object to the
	   same type, to a base class of that type, or to void; such a
	   conversion function will never be called.

       -Wvolatile (C++ and Objective-C++ only)
	   Warn about deprecated uses of the "volatile" qualifier.  This
	   includes postfix and prefix "++" and "--" expressions of
	   "volatile"-qualified types, using simple assignments where the left
	   operand is a "volatile"-qualified non-class type for their value,
	   compound assignments where the left operand is a
	   "volatile"-qualified non-class type, "volatile"-qualified function
	   return type, "volatile"-qualified parameter type, and structured
	   bindings of a "volatile"-qualified type.  This usage was deprecated
	   in C++20.

	   Enabled by default with -std=c++20.

       -Wzero-as-null-pointer-constant (C++ and Objective-C++ only)
	   Warn when a literal 0 is used as null pointer constant.  This can
	   be useful to facilitate the conversion to "nullptr" in C++11.

       -Waligned-new
	   Warn about a new-expression of a type that requires greater
	   alignment than the alignof(std::max_align_t) but uses an allocation
	   function without an explicit alignment parameter. This option is
	   enabled by -Wall.

	   Normally this only warns about global allocation functions, but
	   -Waligned-new=all also warns about class member allocation
	   functions.

       -Wno-placement-new
       -Wplacement-new=n
	   Warn about placement new expressions with undefined behavior, such
	   as constructing an object in a buffer that is smaller than the type
	   of the object.  For example, the placement new expression below is
	   diagnosed because it attempts to construct an array of 64 integers
	   in a buffer only 64 bytes large.

		   char buf [64];
		   new (buf) int[64];

	   This warning is enabled by default.

	   -Wplacement-new=1
	       This is the default warning level of -Wplacement-new.  At this
	       level the warning is not issued for some strictly undefined
	       constructs that GCC allows as extensions for compatibility with
	       legacy code.  For example, the following "new" expression is
	       not diagnosed at this level even though it has undefined
	       behavior according to the C++ standard because it writes past
	       the end of the one-element array.

		       struct S { int n, a[1]; };
		       S *s = (S *)malloc (sizeof *s + 31 * sizeof s->a[0]);
		       new (s->a)int [32]();

	   -Wplacement-new=2
	       At this level, in addition to diagnosing all the same
	       constructs as at level 1, a diagnostic is also issued for
	       placement new expressions that construct an object in the last
	       member of structure whose type is an array of a single element
	       and whose size is less than the size of the object being
	       constructed.  While the previous example would be diagnosed,
	       the following construct makes use of the flexible member array
	       extension to avoid the warning at level 2.

		       struct S { int n, a[]; };
		       S *s = (S *)malloc (sizeof *s + 32 * sizeof s->a[0]);
		       new (s->a)int [32]();

       -Wcatch-value
       -Wcatch-value=n (C++ and Objective-C++ only)
	   Warn about catch handlers that do not catch via reference.  With
	   -Wcatch-value=1 (or -Wcatch-value for short) warn about polymorphic
	   class types that are caught by value.  With -Wcatch-value=2 warn
	   about all class types that are caught by value. With
	   -Wcatch-value=3 warn about all types that are not caught by
	   reference. -Wcatch-value is enabled by -Wall.

       -Wconditionally-supported (C++ and Objective-C++ only)
	   Warn for conditionally-supported (C++11 [intro.defs]) constructs.

       -Wno-delete-incomplete (C++ and Objective-C++ only)
	   Do not warn when deleting a pointer to incomplete type, which may
	   cause undefined behavior at runtime.	 This warning is enabled by
	   default.

       -Wextra-semi (C++, Objective-C++ only)
	   Warn about redundant semicolons after in-class function
	   definitions.

       -Wno-global-module (C++ and Objective-C++ only)
	   Disable the diagnostic for when the global module fragment of a
	   module unit does not consist only of preprocessor directives.

       -Wno-inaccessible-base (C++, Objective-C++ only)
	   This option controls warnings when a base class is inaccessible in
	   a class derived from it due to ambiguity.  The warning is enabled
	   by default.	Note that the warning for ambiguous virtual bases is
	   enabled by the -Wextra option.

		   struct A { int a; };

		   struct B : A { };

		   struct C : B, A { };

       -Wno-inherited-variadic-ctor
	   Suppress warnings about use of C++11 inheriting constructors when
	   the base class inherited from has a C variadic constructor; the
	   warning is on by default because the ellipsis is not inherited.

       -Wno-invalid-offsetof (C++ and Objective-C++ only)
	   Suppress warnings from applying the "offsetof" macro to a non-POD
	   type.  According to the 2014 ISO C++ standard, applying "offsetof"
	   to a non-standard-layout type is undefined.	In existing C++
	   implementations, however, "offsetof" typically gives meaningful
	   results.  This flag is for users who are aware that they are
	   writing nonportable code and who have deliberately chosen to ignore
	   the warning about it.

	   The restrictions on "offsetof" may be relaxed in a future version
	   of the C++ standard.

       -Wsized-deallocation (C++ and Objective-C++ only)
	   Warn about a definition of an unsized deallocation function

		   void operator delete (void *) noexcept;
		   void operator delete[] (void *) noexcept;

	   without a definition of the corresponding sized deallocation
	   function

		   void operator delete (void *, std::size_t) noexcept;
		   void operator delete[] (void *, std::size_t) noexcept;

	   or vice versa.  Enabled by -Wextra along with -fsized-deallocation.

       -Wsuggest-final-types
	   Warn about types with virtual methods where code quality would be
	   improved if the type were declared with the C++11 "final"
	   specifier, or, if possible, declared in an anonymous namespace.
	   This allows GCC to more aggressively devirtualize the polymorphic
	   calls. This warning is more effective with link-time optimization,
	   where the information about the class hierarchy graph is more
	   complete.

       -Wsuggest-final-methods
	   Warn about virtual methods where code quality would be improved if
	   the method were declared with the C++11 "final" specifier, or, if
	   possible, its type were declared in an anonymous namespace or with
	   the "final" specifier.  This warning is more effective with link-
	   time optimization, where the information about the class hierarchy
	   graph is more complete. It is recommended to first consider
	   suggestions of -Wsuggest-final-types and then rebuild with new
	   annotations.

       -Wsuggest-override
	   Warn about overriding virtual functions that are not marked with
	   the "override" keyword.

       -Wno-conversion-null (C++ and Objective-C++ only)
	   Do not warn for conversions between "NULL" and non-pointer types.
	   -Wconversion-null is enabled by default.

   Options Controlling Objective-C and Objective-C++ Dialects
       (NOTE: This manual does not describe the Objective-C and Objective-C++
       languages themselves.

       This section describes the command-line options that are only
       meaningful for Objective-C and Objective-C++ programs.  You can also
       use most of the language-independent GNU compiler options.  For
       example, you might compile a file some_class.m like this:

	       gcc -g -fgnu-runtime -O -c some_class.m

       In this example, -fgnu-runtime is an option meant only for Objective-C
       and Objective-C++ programs; you can use the other options with any
       language supported by GCC.

       Note that since Objective-C is an extension of the C language,
       Objective-C compilations may also use options specific to the C front-
       end (e.g., -Wtraditional).  Similarly, Objective-C++ compilations may
       use C++-specific options (e.g., -Wabi).

       Here is a list of options that are only for compiling Objective-C and
       Objective-C++ programs:

       -fconstant-string-class=class-name
	   Use class-name as the name of the class to instantiate for each
	   literal string specified with the syntax "@"..."".  The default
	   class name is "NXConstantString" if the GNU runtime is being used,
	   and "NSConstantString" if the NeXT runtime is being used (see
	   below).  On Darwin / macOS platforms, the -fconstant-cfstrings
	   option, if also present, overrides the -fconstant-string-class
	   setting and cause "@"..."" literals to be laid out as constant
	   CoreFoundation strings.  Note that -fconstant-cfstrings is an alias
	   for the target-specific -mconstant-cfstrings equivalent.

       -fgnu-runtime
	   Generate object code compatible with the standard GNU Objective-C
	   runtime.  This is the default for most types of systems.

       -fnext-runtime
	   Generate output compatible with the NeXT runtime.  This is the
	   default for NeXT-based systems, including Darwin / macOS.  The
	   macro "__NEXT_RUNTIME__" is predefined if (and only if) this option
	   is used.

       -fno-nil-receivers
	   Assume that all Objective-C message dispatches ("[receiver
	   message:arg]") in this translation unit ensure that the receiver is
	   not "nil".  This allows for more efficient entry points in the
	   runtime to be used.	This option is only available in conjunction
	   with the NeXT runtime and ABI version 0 or 1.

       -fobjc-abi-version=n
	   Use version n of the Objective-C ABI for the selected runtime.
	   This option is currently supported only for the NeXT runtime.  In
	   that case, Version 0 is the traditional (32-bit) ABI without
	   support for properties and other Objective-C 2.0 additions.
	   Version 1 is the traditional (32-bit) ABI with support for
	   properties and other Objective-C 2.0 additions.  Version 2 is the
	   modern (64-bit) ABI.	 If nothing is specified, the default is
	   Version 0 on 32-bit target machines, and Version 2 on 64-bit target
	   machines.

       -fobjc-call-cxx-cdtors
	   For each Objective-C class, check if any of its instance variables
	   is a C++ object with a non-trivial default constructor.  If so,
	   synthesize a special "- (id) .cxx_construct" instance method which
	   runs non-trivial default constructors on any such instance
	   variables, in order, and then return "self".	 Similarly, check if
	   any instance variable is a C++ object with a non-trivial
	   destructor, and if so, synthesize a special "- (void)
	   .cxx_destruct" method which runs all such default destructors, in
	   reverse order.

	   The "- (id) .cxx_construct" and "- (void) .cxx_destruct" methods
	   thusly generated only operate on instance variables declared in the
	   current Objective-C class, and not those inherited from
	   superclasses.  It is the responsibility of the Objective-C runtime
	   to invoke all such methods in an object's inheritance hierarchy.
	   The "- (id) .cxx_construct" methods are invoked by the runtime
	   immediately after a new object instance is allocated; the "- (void)
	   .cxx_destruct" methods are invoked immediately before the runtime
	   deallocates an object instance.

	   As of this writing, only the NeXT runtime on Mac OS X 10.4 and
	   later has support for invoking the "- (id) .cxx_construct" and "-
	   (void) .cxx_destruct" methods.

       -fobjc-direct-dispatch
	   Allow fast jumps to the message dispatcher.	On Darwin this is
	   accomplished via the comm page.

       -fobjc-exceptions
	   Enable syntactic support for structured exception handling in
	   Objective-C, similar to what is offered by C++.  This option is
	   required to use the Objective-C keywords @try, @throw, @catch,
	   @finally and @synchronized.	This option is available with both the
	   GNU runtime and the NeXT runtime (but not available in conjunction
	   with the NeXT runtime on Mac OS X 10.2 and earlier).

       -fobjc-gc
	   Enable garbage collection (GC) in Objective-C and Objective-C++
	   programs.  This option is only available with the NeXT runtime; the
	   GNU runtime has a different garbage collection implementation that
	   does not require special compiler flags.

       -fobjc-nilcheck
	   For the NeXT runtime with version 2 of the ABI, check for a nil
	   receiver in method invocations before doing the actual method call.
	   This is the default and can be disabled using -fno-objc-nilcheck.
	   Class methods and super calls are never checked for nil in this way
	   no matter what this flag is set to.	Currently this flag does
	   nothing when the GNU runtime, or an older version of the NeXT
	   runtime ABI, is used.

       -fobjc-std=objc1
	   Conform to the language syntax of Objective-C 1.0, the language
	   recognized by GCC 4.0.  This only affects the Objective-C additions
	   to the C/C++ language; it does not affect conformance to C/C++
	   standards, which is controlled by the separate C/C++ dialect option
	   flags.  When this option is used with the Objective-C or
	   Objective-C++ compiler, any Objective-C syntax that is not
	   recognized by GCC 4.0 is rejected.  This is useful if you need to
	   make sure that your Objective-C code can be compiled with older
	   versions of GCC.

       -freplace-objc-classes
	   Emit a special marker instructing ld(1) not to statically link in
	   the resulting object file, and allow dyld(1) to load it in at run
	   time instead.  This is used in conjunction with the Fix-and-
	   Continue debugging mode, where the object file in question may be
	   recompiled and dynamically reloaded in the course of program
	   execution, without the need to restart the program itself.
	   Currently, Fix-and-Continue functionality is only available in
	   conjunction with the NeXT runtime on Mac OS X 10.3 and later.

       -fzero-link
	   When compiling for the NeXT runtime, the compiler ordinarily
	   replaces calls to objc_getClass("...") (when the name of the class
	   is known at compile time) with static class references that get
	   initialized at load time, which improves run-time performance.
	   Specifying the -fzero-link flag suppresses this behavior and causes
	   calls to objc_getClass("...")  to be retained.  This is useful in
	   Zero-Link debugging mode, since it allows for individual class
	   implementations to be modified during program execution.  The GNU
	   runtime currently always retains calls to objc_get_class("...")
	   regardless of command-line options.

       -fno-local-ivars
	   By default instance variables in Objective-C can be accessed as if
	   they were local variables from within the methods of the class
	   they're declared in.	 This can lead to shadowing between instance
	   variables and other variables declared either locally inside a
	   class method or globally with the same name.	 Specifying the
	   -fno-local-ivars flag disables this behavior thus avoiding variable
	   shadowing issues.

       -fivar-visibility=[public|protected|private|package]
	   Set the default instance variable visibility to the specified
	   option so that instance variables declared outside the scope of any
	   access modifier directives default to the specified visibility.

       -gen-decls
	   Dump interface declarations for all classes seen in the source file
	   to a file named sourcename.decl.

       -Wassign-intercept (Objective-C and Objective-C++ only)
	   Warn whenever an Objective-C assignment is being intercepted by the
	   garbage collector.

       -Wno-property-assign-default (Objective-C and Objective-C++ only)
	   Do not warn if a property for an Objective-C object has no assign
	   semantics specified.

       -Wno-protocol (Objective-C and Objective-C++ only)
	   If a class is declared to implement a protocol, a warning is issued
	   for every method in the protocol that is not implemented by the
	   class.  The default behavior is to issue a warning for every method
	   not explicitly implemented in the class, even if a method
	   implementation is inherited from the superclass.  If you use the
	   -Wno-protocol option, then methods inherited from the superclass
	   are considered to be implemented, and no warning is issued for
	   them.

       -Wobjc-root-class (Objective-C and Objective-C++ only)
	   Warn if a class interface lacks a superclass. Most classes will
	   inherit from "NSObject" (or "Object") for example.  When declaring
	   classes intended to be root classes, the warning can be suppressed
	   by marking their interfaces with
	   "__attribute__((objc_root_class))".

       -Wselector (Objective-C and Objective-C++ only)
	   Warn if multiple methods of different types for the same selector
	   are found during compilation.  The check is performed on the list
	   of methods in the final stage of compilation.  Additionally, a
	   check is performed for each selector appearing in a @selector(...)
	   expression, and a corresponding method for that selector has been
	   found during compilation.  Because these checks scan the method
	   table only at the end of compilation, these warnings are not
	   produced if the final stage of compilation is not reached, for
	   example because an error is found during compilation, or because
	   the -fsyntax-only option is being used.

       -Wstrict-selector-match (Objective-C and Objective-C++ only)
	   Warn if multiple methods with differing argument and/or return
	   types are found for a given selector when attempting to send a
	   message using this selector to a receiver of type "id" or "Class".
	   When this flag is off (which is the default behavior), the compiler
	   omits such warnings if any differences found are confined to types
	   that share the same size and alignment.

       -Wundeclared-selector (Objective-C and Objective-C++ only)
	   Warn if a @selector(...) expression referring to an undeclared
	   selector is found.  A selector is considered undeclared if no
	   method with that name has been declared before the @selector(...)
	   expression, either explicitly in an @interface or @protocol
	   declaration, or implicitly in an @implementation section.  This
	   option always performs its checks as soon as a @selector(...)
	   expression is found, while -Wselector only performs its checks in
	   the final stage of compilation.  This also enforces the coding
	   style convention that methods and selectors must be declared before
	   being used.

       -print-objc-runtime-info
	   Generate C header describing the largest structure that is passed
	   by value, if any.

   Options to Control Diagnostic Messages Formatting
       Traditionally, diagnostic messages have been formatted irrespective of
       the output device's aspect (e.g. its width, ...).  You can use the
       options described below to control the formatting algorithm for
       diagnostic messages, e.g. how many characters per line, how often
       source location information should be reported.	Note that some
       language front ends may not honor these options.

       -fmessage-length=n
	   Try to format error messages so that they fit on lines of about n
	   characters.	If n is zero, then no line-wrapping is done; each
	   error message appears on a single line.  This is the default for
	   all front ends.

	   Note - this option also affects the display of the #error and
	   #warning pre-processor directives, and the deprecated
	   function/type/variable attribute.  It does not however affect the
	   pragma GCC warning and pragma GCC error pragmas.

       -fdiagnostics-plain-output
	   This option requests that diagnostic output look as plain as
	   possible, which may be useful when running dejagnu or other
	   utilities that need to parse diagnostics output and prefer that it
	   remain more stable over time.  -fdiagnostics-plain-output is
	   currently equivalent to the following options:
	   -fno-diagnostics-show-caret -fno-diagnostics-show-line-numbers
	   -fdiagnostics-color=never -fdiagnostics-urls=never
	   -fdiagnostics-path-format=separate-events
	   -fdiagnostics-text-art-charset=none In the future, if GCC changes
	   the default appearance of its diagnostics, the corresponding option
	   to disable the new behavior will be added to this list.

       -fdiagnostics-show-location=once
	   Only meaningful in line-wrapping mode.  Instructs the diagnostic
	   messages reporter to emit source location information once; that
	   is, in case the message is too long to fit on a single physical
	   line and has to be wrapped, the source location won't be emitted
	   (as prefix) again, over and over, in subsequent continuation lines.
	   This is the default behavior.

       -fdiagnostics-show-location=every-line
	   Only meaningful in line-wrapping mode.  Instructs the diagnostic
	   messages reporter to emit the same source location information (as
	   prefix) for physical lines that result from the process of breaking
	   a message which is too long to fit on a single line.

       -fdiagnostics-color[=WHEN]
       -fno-diagnostics-color
	   Use color in diagnostics.  WHEN is never, always, or auto.  The
	   default depends on how the compiler has been configured, it can be
	   any of the above WHEN options or also never if GCC_COLORS
	   environment variable isn't present in the environment, and auto
	   otherwise.  auto makes GCC use color only when the standard error
	   is a terminal, and when not executing in an emacs shell.  The forms
	   -fdiagnostics-color and -fno-diagnostics-color are aliases for
	   -fdiagnostics-color=always and -fdiagnostics-color=never,
	   respectively.

	   The colors are defined by the environment variable GCC_COLORS.  Its
	   value is a colon-separated list of capabilities and Select Graphic
	   Rendition (SGR) substrings. SGR commands are interpreted by the
	   terminal or terminal emulator.  (See the section in the
	   documentation of your text terminal for permitted values and their
	   meanings as character attributes.)  These substring values are
	   integers in decimal representation and can be concatenated with
	   semicolons.	Common values to concatenate include 1 for bold, 4 for
	   underline, 5 for blink, 7 for inverse, 39 for default foreground
	   color, 30 to 37 for foreground colors, 90 to 97 for 16-color mode
	   foreground colors, 38;5;0 to 38;5;255 for 88-color and 256-color
	   modes foreground colors, 49 for default background color, 40 to 47
	   for background colors, 100 to 107 for 16-color mode background
	   colors, and 48;5;0 to 48;5;255 for 88-color and 256-color modes
	   background colors.

	   The default GCC_COLORS is

		   error=01;31:warning=01;35:note=01;36:range1=32:range2=34:locus=01:\
		   quote=01:path=01;36:fixit-insert=32:fixit-delete=31:\
		   diff-filename=01:diff-hunk=32:diff-delete=31:diff-insert=32:\
		   type-diff=01;32:fnname=01;32:targs=35:valid=01;31:invalid=01;32

	   where 01;31 is bold red, 01;35 is bold magenta, 01;36 is bold cyan,
	   32 is green, 34 is blue, 01 is bold, and 31 is red.	Setting
	   GCC_COLORS to the empty string disables colors.  Supported
	   capabilities are as follows.

	   "error="
	       SGR substring for error: markers.

	   "warning="
	       SGR substring for warning: markers.

	   "note="
	       SGR substring for note: markers.

	   "path="
	       SGR substring for colorizing paths of control-flow events as
	       printed via -fdiagnostics-path-format=, such as the identifiers
	       of individual events and lines indicating interprocedural calls
	       and returns.

	   "range1="
	       SGR substring for first additional range.

	   "range2="
	       SGR substring for second additional range.

	   "locus="
	       SGR substring for location information, file:line or
	       file:line:column etc.

	   "quote="
	       SGR substring for information printed within quotes.

	   "fnname="
	       SGR substring for names of C++ functions.

	   "targs="
	       SGR substring for C++ function template parameter bindings.

	   "fixit-insert="
	       SGR substring for fix-it hints suggesting text to be inserted
	       or replaced.

	   "fixit-delete="
	       SGR substring for fix-it hints suggesting text to be deleted.

	   "diff-filename="
	       SGR substring for filename headers within generated patches.

	   "diff-hunk="
	       SGR substring for the starts of hunks within generated patches.

	   "diff-delete="
	       SGR substring for deleted lines within generated patches.

	   "diff-insert="
	       SGR substring for inserted lines within generated patches.

	   "type-diff="
	       SGR substring for highlighting mismatching types within
	       template arguments in the C++ frontend.

	   "valid="
	       SGR substring for highlighting valid elements within text art
	       diagrams.

	   "invalid="
	       SGR substring for highlighting invalid elements within text art
	       diagrams.

       -fdiagnostics-urls[=WHEN]
	   Use escape sequences to embed URLs in diagnostics.  For example,
	   when -fdiagnostics-show-option emits text showing the command-line
	   option controlling a diagnostic, embed a URL for documentation of
	   that option.

	   WHEN is never, always, or auto.  auto makes GCC use URL escape
	   sequences only when the standard error is a terminal, and when not
	   executing in an emacs shell or any graphical terminal which is
	   known to be incompatible with this feature, see below.

	   The default depends on how the compiler has been configured.	 It
	   can be any of the above WHEN options.

	   GCC can also be configured (via the
	   --with-diagnostics-urls=auto-if-env configure-time option) so that
	   the default is affected by environment variables.  Under such a
	   configuration, GCC defaults to using auto if either GCC_URLS or
	   TERM_URLS environment variables are present and non-empty in the
	   environment of the compiler, or never if neither are.

	   However, even with -fdiagnostics-urls=always the behavior is
	   dependent on those environment variables: If GCC_URLS is set to
	   empty or no, do not embed URLs in diagnostics.  If set to st, URLs
	   use ST escape sequences.  If set to bel, the default, URLs use BEL
	   escape sequences.  Any other non-empty value enables the feature.
	   If GCC_URLS is not set, use TERM_URLS as a fallback.	 Note: ST is
	   an ANSI escape sequence, string terminator ESC \, BEL is an ASCII
	   character, CTRL-G that usually sounds like a beep.

	   At this time GCC tries to detect also a few terminals that are
	   known to not implement the URL feature, and have bugs or at least
	   had bugs in some versions that are still in use, where the URL
	   escapes are likely to misbehave, i.e. print garbage on the screen.
	   That list is currently xfce4-terminal, certain known to be buggy
	   gnome-terminal versions, the linux console, and mingw.  This check
	   can be skipped with the -fdiagnostics-urls=always.

       -fno-diagnostics-show-option
	   By default, each diagnostic emitted includes text indicating the
	   command-line option that directly controls the diagnostic (if such
	   an option is known to the diagnostic machinery).  Specifying the
	   -fno-diagnostics-show-option flag suppresses that behavior.

       -fno-diagnostics-show-caret
	   By default, each diagnostic emitted includes the original source
	   line and a caret ^ indicating the column.  This option suppresses
	   this information.  The source line is truncated to n characters, if
	   the -fmessage-length=n option is given.  When the output is done to
	   the terminal, the width is limited to the width given by the
	   COLUMNS environment variable or, if not set, to the terminal width.

       -fno-diagnostics-show-labels
	   By default, when printing source code (via
	   -fdiagnostics-show-caret), diagnostics can label ranges of source
	   code with pertinent information, such as the types of expressions:

		       printf ("foo %s bar", long_i + long_j);
				    ~^	     ~~~~~~~~~~~~~~~
				     |		    |
				     char *	    long int

	   This option suppresses the printing of these labels (in the example
	   above, the vertical bars and the "char *" and "long int" text).

       -fno-diagnostics-show-cwe
	   Diagnostic messages can optionally have an associated
	    CWE ("https://cwe.mitre.org/index.html") identifier.  GCC itself
	   only provides such metadata for some of the -fanalyzer diagnostics.
	   GCC plugins may also provide diagnostics with such metadata.	 By
	   default, if this information is present, it will be printed with
	   the diagnostic.  This option suppresses the printing of this
	   metadata.

       -fno-diagnostics-show-rules
	   Diagnostic messages can optionally have rules associated with them,
	   such as from a coding standard, or a specification.	GCC itself
	   does not do this for any of its diagnostics, but plugins may do so.
	   By default, if this information is present, it will be printed with
	   the diagnostic.  This option suppresses the printing of this
	   metadata.

       -fno-diagnostics-show-line-numbers
	   By default, when printing source code (via
	   -fdiagnostics-show-caret), a left margin is printed, showing line
	   numbers.  This option suppresses this left margin.

       -fdiagnostics-minimum-margin-width=width
	   This option controls the minimum width of the left margin printed
	   by -fdiagnostics-show-line-numbers.	It defaults to 6.

       -fdiagnostics-parseable-fixits
	   Emit fix-it hints in a machine-parseable format, suitable for
	   consumption by IDEs.	 For each fix-it, a line will be printed after
	   the relevant diagnostic, starting with the string "fix-it:".	 For
	   example:

		   fix-it:"test.c":{45:3-45:21}:"gtk_widget_show_all"

	   The location is expressed as a half-open range, expressed as a
	   count of bytes, starting at byte 1 for the initial column.  In the
	   above example, bytes 3 through 20 of line 45 of "test.c" are to be
	   replaced with the given string:

		   00000000011111111112222222222
		   12345678901234567890123456789
		     gtk_widget_showall (dlg);
		     ^^^^^^^^^^^^^^^^^^
		     gtk_widget_show_all

	   The filename and replacement string escape backslash as "\\", tab
	   as "\t", newline as "\n", double quotes as "\"", non-printable
	   characters as octal (e.g. vertical tab as "\013").

	   An empty replacement string indicates that the given range is to be
	   removed.  An empty range (e.g. "45:3-45:3") indicates that the
	   string is to be inserted at the given position.

       -fdiagnostics-generate-patch
	   Print fix-it hints to stderr in unified diff format, after any
	   diagnostics are printed.  For example:

		   --- test.c
		   +++ test.c
		   @ -42,5 +42,5 @

		    void show_cb(GtkDialog *dlg)
		    {
		   -  gtk_widget_showall(dlg);
		   +  gtk_widget_show_all(dlg);
		    }

	   The diff may or may not be colorized, following the same rules as
	   for diagnostics (see -fdiagnostics-color).

       -fdiagnostics-show-template-tree
	   In the C++ frontend, when printing diagnostics showing mismatching
	   template types, such as:

		     could not convert 'std::map<int, std::vector<double> >()'
		       from 'map<[...],vector<double>>' to 'map<[...],vector<float>>

	   the -fdiagnostics-show-template-tree flag enables printing a tree-
	   like structure showing the common and differing parts of the types,
	   such as:

		     map<
		       [...],
		       vector<
			 [double != float]>>

	   The parts that differ are highlighted with color ("double" and
	   "float" in this case).

       -fno-elide-type
	   By default when the C++ frontend prints diagnostics showing
	   mismatching template types, common parts of the types are printed
	   as "[...]" to simplify the error message.  For example:

		     could not convert 'std::map<int, std::vector<double> >()'
		       from 'map<[...],vector<double>>' to 'map<[...],vector<float>>

	   Specifying the -fno-elide-type flag suppresses that behavior.  This
	   flag also affects the output of the
	   -fdiagnostics-show-template-tree flag.

       -fdiagnostics-path-format=KIND
	   Specify how to print paths of control-flow events for diagnostics
	   that have such a path associated with them.

	   KIND is none, separate-events, or inline-events, the default.

	   none means to not print diagnostic paths.

	   separate-events means to print a separate "note" diagnostic for
	   each event within the diagnostic.  For example:

		   test.c:29:5: error: passing NULL as argument 1 to 'PyList_Append' which requires a non-NULL parameter
		   test.c:25:10: note: (1) when 'PyList_New' fails, returning NULL
		   test.c:27:3: note: (2) when 'i < count'
		   test.c:29:5: note: (3) when calling 'PyList_Append', passing NULL from (1) as argument 1

	   inline-events means to print the events "inline" within the source
	   code.  This view attempts to consolidate the events into runs of
	   sufficiently-close events, printing them as labelled ranges within
	   the source.

	   For example, the same events as above might be printed as:

		     'test': events 1-3
		       |
		       |   25 |	  list = PyList_New(0);
		       |      |		 ^~~~~~~~~~~~~
		       |      |		 |
		       |      |		 (1) when 'PyList_New' fails, returning NULL
		       |   26 |
		       |   27 |	  for (i = 0; i < count; i++) {
		       |      |	  ~~~
		       |      |	  |
		       |      |	  (2) when 'i < count'
		       |   28 |	    item = PyLong_FromLong(random());
		       |   29 |	    PyList_Append(list, item);
		       |      |	    ~~~~~~~~~~~~~~~~~~~~~~~~~
		       |      |	    |
		       |      |	    (3) when calling 'PyList_Append', passing NULL from (1) as argument 1
		       |

	   Interprocedural control flow is shown by grouping the events by
	   stack frame, and using indentation to show how stack frames are
	   nested, pushed, and popped.

	   For example:

		     'test': events 1-2
		       |
		       |  133 | {
		       |      | ^
		       |      | |
		       |      | (1) entering 'test'
		       |  134 |	  boxed_int *obj = make_boxed_int (i);
		       |      |			   ~~~~~~~~~~~~~~~~~~
		       |      |			   |
		       |      |			   (2) calling 'make_boxed_int'
		       |
		       +--> 'make_boxed_int': events 3-4
			      |
			      |	 120 | {
			      |	     | ^
			      |	     | |
			      |	     | (3) entering 'make_boxed_int'
			      |	 121 |	 boxed_int *result = (boxed_int *)wrapped_malloc (sizeof (boxed_int));
			      |	     |					  ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
			      |	     |					  |
			      |	     |					  (4) calling 'wrapped_malloc'
			      |
			      +--> 'wrapped_malloc': events 5-6
				     |
				     |	  7 | {
				     |	    | ^
				     |	    | |
				     |	    | (5) entering 'wrapped_malloc'
				     |	  8 |	return malloc (size);
				     |	    |	       ~~~~~~~~~~~~~
				     |	    |	       |
				     |	    |	       (6) calling 'malloc'
				     |
		       <-------------+
		       |
		    'test': event 7
		       |
		       |  138 |	  free_boxed_int (obj);
		       |      |	  ^~~~~~~~~~~~~~~~~~~~
		       |      |	  |
		       |      |	  (7) calling 'free_boxed_int'
		       |
		   (etc)

       -fdiagnostics-show-path-depths
	   This option provides additional information when printing control-
	   flow paths associated with a diagnostic.

	   If this is option is provided then the stack depth will be printed
	   for each run of events within
	   -fdiagnostics-path-format=inline-events.  If provided with
	   -fdiagnostics-path-format=separate-events, then the stack depth and
	   function declaration will be appended when printing each event.

	   This is intended for use by GCC developers and plugin developers
	   when debugging diagnostics that report interprocedural control
	   flow.

       -fno-show-column
	   Do not print column numbers in diagnostics.	This may be necessary
	   if diagnostics are being scanned by a program that does not
	   understand the column numbers, such as dejagnu.

       -fdiagnostics-column-unit=UNIT
	   Select the units for the column number.  This affects traditional
	   diagnostics (in the absence of -fno-show-column), as well as JSON
	   format diagnostics if requested.

	   The default UNIT, display, considers the number of display columns
	   occupied by each character.	This may be larger than the number of
	   bytes required to encode the character, in the case of tab
	   characters, or it may be smaller, in the case of multibyte
	   characters.	For example, the character "GREEK SMALL LETTER PI
	   (U+03C0)" occupies one display column, and its UTF-8 encoding
	   requires two bytes; the character "SLIGHTLY SMILING FACE (U+1F642)"
	   occupies two display columns, and its UTF-8 encoding requires four
	   bytes.

	   Setting UNIT to byte changes the column number to the raw byte
	   count in all cases, as was traditionally output by GCC prior to
	   version 11.1.0.

       -fdiagnostics-column-origin=ORIGIN
	   Select the origin for column numbers, i.e. the column number
	   assigned to the first column.  The default value of 1 corresponds
	   to traditional GCC behavior and to the GNU style guide.  Some
	   utilities may perform better with an origin of 0; any non-negative
	   value may be specified.

       -fdiagnostics-escape-format=FORMAT
	   When GCC prints pertinent source lines for a diagnostic it normally
	   attempts to print the source bytes directly.	 However, some
	   diagnostics relate to encoding issues in the source file, such as
	   malformed UTF-8, or issues with Unicode normalization.  These
	   diagnostics are flagged so that GCC will escape bytes that are not
	   printable ASCII when printing their pertinent source lines.

	   This option controls how such bytes should be escaped.

	   The default FORMAT, unicode displays Unicode characters that are
	   not printable ASCII in the form <U+XXXX>, and bytes that do not
	   correspond to a Unicode character validly-encoded in UTF-8-encoded
	   will be displayed as hexadecimal in the form <XX>.

	   For example, a source line containing the string before followed by
	   the Unicode character U+03C0 ("GREEK SMALL LETTER PI", with UTF-8
	   encoding 0xCF 0x80) followed by the byte 0xBF (a stray UTF-8
	   trailing byte), followed by the string after will be printed for
	   such a diagnostic as:

		    before<U+03C0><BF>after

	   Setting FORMAT to bytes will display all non-printable-ASCII bytes
	   in the form <XX>, thus showing the underlying encoding of non-ASCII
	   Unicode characters.	For the example above, the following will be
	   printed:

		    before<CF><80><BF>after

       -fdiagnostics-text-art-charset=CHARSET
	   Some diagnostics can contain "text art" diagrams: visualizations
	   created from text, intended to be viewed in a monospaced font.

	   This option selects which characters should be used for printing
	   such diagrams, if any.  CHARSET is none, ascii, unicode, or emoji.

	   The none value suppresses the printing of such diagrams.  The ascii
	   value will ensure that such diagrams are pure ASCII ("ASCII art").
	   The unicode value will allow for conservative use of unicode
	   drawing characters (such as box-drawing characters).	 The emoji
	   value further adds the possibility of emoji in the output (such as
	   emitting U+26A0 WARNING SIGN followed by U+FE0F VARIATION
	   SELECTOR-16 to select the emoji variant of the character).

	   The default is emoji, except when the environment variable LANG is
	   set to C, in which case the default is ascii.

       -fdiagnostics-format=FORMAT
	   Select a different format for printing diagnostics.	FORMAT is
	   text, sarif-stderr, sarif-file, json, json-stderr, or json-file.

	   The default is text.

	   The sarif-stderr and sarif-file formats both emit diagnostics in
	   SARIF Version 2.1.0 format, either to stderr, or to a file named
	   source.sarif, respectively.

	   The json format is a synonym for json-stderr.  The json-stderr and
	   json-file formats are identical, apart from where the JSON is
	   emitted to - with the former, the JSON is emitted to stderr,
	   whereas with json-file it is written to source.gcc.json.

	   The emitted JSON consists of a top-level JSON array containing JSON
	   objects representing the diagnostics.

	   Diagnostics can have child diagnostics.  For example, this error
	   and note:

		   misleading-indentation.c:15:3: warning: this 'if' clause does not
		     guard... [-Wmisleading-indentation]
		      15 |   if (flag)
			 |   ^~
		   misleading-indentation.c:17:5: note: ...this statement, but the latter
		     is misleadingly indented as if it were guarded by the 'if'
		      17 |     y = 2;
			 |     ^

	   might be printed in JSON form (after formatting) like this:

		   [
		       {
			   "kind": "warning",
			   "locations": [
			       {
				   "caret": {
				       "display-column": 3,
				       "byte-column": 3,
				       "column": 3,
				       "file": "misleading-indentation.c",
				       "line": 15
				   },
				   "finish": {
				       "display-column": 4,
				       "byte-column": 4,
				       "column": 4,
				       "file": "misleading-indentation.c",
				       "line": 15
				   }
			       }
			   ],
			   "message": "this \u2018if\u2019 clause does not guard...",
			   "option": "-Wmisleading-indentation",
			   "option_url": "https://gcc.gnu.org/onlinedocs/gcc/Warning-Options.html#index-Wmisleading-indentation",
			   "children": [
			       {
				   "kind": "note",
				   "locations": [
				       {
					   "caret": {
					       "display-column": 5,
					       "byte-column": 5,
					       "column": 5,
					       "file": "misleading-indentation.c",
					       "line": 17
					   }
				       }
				   ],
				   "escape-source": false,
				   "message": "...this statement, but the latter is ..."
			       }
			   ]
			   "escape-source": false,
			   "column-origin": 1,
		       }
		   ]

	   where the "note" is a child of the "warning".

	   A diagnostic has a "kind".  If this is "warning", then there is an
	   "option" key describing the command-line option controlling the
	   warning.

	   A diagnostic can contain zero or more locations.  Each location has
	   an optional "label" string and up to three positions within it: a
	   "caret" position and optional "start" and "finish" positions.  A
	   position is described by a "file" name, a "line" number, and three
	   numbers indicating a column position:

	   *   "display-column" counts display columns, accounting for tabs
	       and multibyte characters.

	   *   "byte-column" counts raw bytes.

	   *   "column" is equal to one of the previous two, as dictated by
	       the -fdiagnostics-column-unit option.

	   All three columns are relative to the origin specified by
	   -fdiagnostics-column-origin, which is typically equal to 1 but may
	   be set, for instance, to 0 for compatibility with other utilities
	   that number columns from 0.	The column origin is recorded in the
	   JSON output in the "column-origin" tag.  In the remaining examples
	   below, the extra column number outputs have been omitted for
	   brevity.

	   For example, this error:

		   bad-binary-ops.c:64:23: error: invalid operands to binary + (have 'S' {aka
		      'struct s'} and 'T' {aka 'struct t'})
		      64 |   return callee_4a () + callee_4b ();
			 |	    ~~~~~~~~~~~~ ^ ~~~~~~~~~~~~
			 |	    |		   |
			 |	    |		   T {aka struct t}
			 |	    S {aka struct s}

	   has three locations.	 Its primary location is at the "+" token at
	   column 23.  It has two secondary locations, describing the left and
	   right-hand sides of the expression, which have labels.  It might be
	   printed in JSON form as:

		       {
			   "children": [],
			   "kind": "error",
			   "locations": [
			       {
				   "caret": {
				       "column": 23, "file": "bad-binary-ops.c", "line": 64
				   }
			       },
			       {
				   "caret": {
				       "column": 10, "file": "bad-binary-ops.c", "line": 64
				   },
				   "finish": {
				       "column": 21, "file": "bad-binary-ops.c", "line": 64
				   },
				   "label": "S {aka struct s}"
			       },
			       {
				   "caret": {
				       "column": 25, "file": "bad-binary-ops.c", "line": 64
				   },
				   "finish": {
				       "column": 36, "file": "bad-binary-ops.c", "line": 64
				   },
				   "label": "T {aka struct t}"
			       }
			   ],
			   "escape-source": false,
			   "message": "invalid operands to binary + ..."
		       }

	   If a diagnostic contains fix-it hints, it has a "fixits" array,
	   consisting of half-open intervals, similar to the output of
	   -fdiagnostics-parseable-fixits.  For example, this diagnostic with
	   a replacement fix-it hint:

		   demo.c:8:15: error: 'struct s' has no member named 'colour'; did you
		     mean 'color'?
		       8 |   return ptr->colour;
			 |		 ^~~~~~
			 |		 color

	   might be printed in JSON form as:

		       {
			   "children": [],
			   "fixits": [
			       {
				   "next": {
				       "column": 21,
				       "file": "demo.c",
				       "line": 8
				   },
				   "start": {
				       "column": 15,
				       "file": "demo.c",
				       "line": 8
				   },
				   "string": "color"
			       }
			   ],
			   "kind": "error",
			   "locations": [
			       {
				   "caret": {
				       "column": 15,
				       "file": "demo.c",
				       "line": 8
				   },
				   "finish": {
				       "column": 20,
				       "file": "demo.c",
				       "line": 8
				   }
			       }
			   ],
			   "escape-source": false,
			   "message": "\u2018struct s\u2019 has no member named ..."
		       }

	   where the fix-it hint suggests replacing the text from "start" up
	   to but not including "next" with "string"'s value.  Deletions are
	   expressed via an empty value for "string", insertions by having
	   "start" equal "next".

	   If the diagnostic has a path of control-flow events associated with
	   it, it has a "path" array of objects representing the events.  Each
	   event object has a "description" string, a "location" object, along
	   with a "function" string and a "depth" number for representing
	   interprocedural paths.  The "function" represents the current
	   function at that event, and the "depth" represents the stack depth
	   relative to some baseline: the higher, the more frames are within
	   the stack.

	   For example, the intraprocedural example shown for
	   -fdiagnostics-path-format= might have this JSON for its path:

		       "path": [
			   {
			       "depth": 0,
			       "description": "when 'PyList_New' fails, returning NULL",
			       "function": "test",
			       "location": {
				   "column": 10,
				   "file": "test.c",
				   "line": 25
			       }
			   },
			   {
			       "depth": 0,
			       "description": "when 'i < count'",
			       "function": "test",
			       "location": {
				   "column": 3,
				   "file": "test.c",
				   "line": 27
			       }
			   },
			   {
			       "depth": 0,
			       "description": "when calling 'PyList_Append', passing NULL from (1) as argument 1",
			       "function": "test",
			       "location": {
				   "column": 5,
				   "file": "test.c",
				   "line": 29
			       }
			   }
		       ]

	   Diagnostics have a boolean attribute "escape-source", hinting
	   whether non-ASCII bytes should be escaped when printing the
	   pertinent lines of source code ("true" for diagnostics involving
	   source encoding issues).

       -fno-diagnostics-json-formatting
	   By default, when JSON is emitted for diagnostics (via
	   -fdiagnostics-format=sarif-stderr, -fdiagnostics-format=sarif-file,
	   -fdiagnostics-format=json, -fdiagnostics-format=json-stderr,
	   -fdiagnostics-format=json-file), GCC will add newlines and
	   indentation to visually emphasize the hierarchical structure of the
	   JSON.

	   Use -fno-diagnostics-json-formatting to suppress this whitespace.
	   It must be passed before the option it is to affect.

	   This is intended for compatibility with tools that do not expect
	   the output to contain newlines, such as that emitted by older GCC
	   releases.

   Options to Request or Suppress Warnings
       Warnings are diagnostic messages that report constructions that are not
       inherently erroneous but that are risky or suggest there may have been
       an error.

       The following language-independent options do not enable specific
       warnings but control the kinds of diagnostics produced by GCC.

       -fsyntax-only
	   Check the code for syntax errors, but don't do anything beyond
	   that.

       -fmax-errors=n
	   Limits the maximum number of error messages to n, at which point
	   GCC bails out rather than attempting to continue processing the
	   source code.	 If n is 0 (the default), there is no limit on the
	   number of error messages produced.  If -Wfatal-errors is also
	   specified, then -Wfatal-errors takes precedence over this option.

       -w  Inhibit all warning messages.

       -Werror
	   Make all warnings into errors.

       -Werror=
	   Make the specified warning into an error.  The specifier for a
	   warning is appended; for example -Werror=switch turns the warnings
	   controlled by -Wswitch into errors.	This switch takes a negative
	   form, to be used to negate -Werror for specific warnings; for
	   example -Wno-error=switch makes -Wswitch warnings not be errors,
	   even when -Werror is in effect.

	   The warning message for each controllable warning includes the
	   option that controls the warning.  That option can then be used
	   with -Werror= and -Wno-error= as described above.  (Printing of the
	   option in the warning message can be disabled using the
	   -fno-diagnostics-show-option flag.)

	   Note that specifying -Werror=foo automatically implies -Wfoo.
	   However, -Wno-error=foo does not imply anything.

       -Wfatal-errors
	   This option causes the compiler to abort compilation on the first
	   error occurred rather than trying to keep going and printing
	   further error messages.

       You can request many specific warnings with options beginning with -W,
       for example -Wimplicit to request warnings on implicit declarations.
       Each of these specific warning options also has a negative form
       beginning -Wno- to turn off warnings; for example, -Wno-implicit.  This
       manual lists only one of the two forms, whichever is not the default.
       For further language-specific options also refer to C++ Dialect Options
       and Objective-C and Objective-C++ Dialect Options.  Additional warnings
       can be produced by enabling the static analyzer;

       Some options, such as -Wall and -Wextra, turn on other options, such as
       -Wunused, which may turn on further options, such as -Wunused-value.
       The combined effect of positive and negative forms is that more
       specific options have priority over less specific ones, independently
       of their position in the command-line. For options of the same
       specificity, the last one takes effect. Options enabled or disabled via
       pragmas take effect as if they appeared at the end of the command-line.

       When an unrecognized warning option is requested (e.g.,
       -Wunknown-warning), GCC emits a diagnostic stating that the option is
       not recognized.	However, if the -Wno- form is used, the behavior is
       slightly different: no diagnostic is produced for -Wno-unknown-warning
       unless other diagnostics are being produced.  This allows the use of
       new -Wno- options with old compilers, but if something goes wrong, the
       compiler warns that an unrecognized option is present.

       The effectiveness of some warnings depends on optimizations also being
       enabled. For example -Wsuggest-final-types is more effective with link-
       time optimization and some instances of other warnings may not be
       issued at all unless optimization is enabled.  While optimization in
       general improves the efficacy of control and data flow sensitive
       warnings, in some cases it may also cause false positives.

       -Wpedantic
       -pedantic
	   Issue all the warnings demanded by strict ISO C and ISO C++;
	   diagnose all programs that use forbidden extensions, and some other
	   programs that do not follow ISO C and ISO C++.  This follows the
	   version of the ISO C or C++ standard specified by any -std option
	   used.

	   Valid ISO C and ISO C++ programs should compile properly with or
	   without this option (though a rare few require -ansi or a -std
	   option specifying the version of the standard).  However, without
	   this option, certain GNU extensions and traditional C and C++
	   features are supported as well.  With this option, they are
	   diagnosed (or rejected with -pedantic-errors).

	   -Wpedantic does not cause warning messages for use of the alternate
	   keywords whose names begin and end with __.	This alternate format
	   can also be used to disable warnings for non-ISO __intN types, i.e.
	   __intN__.  Pedantic warnings are also disabled in the expression
	   that follows "__extension__".  However, only system header files
	   should use these escape routes; application programs should avoid
	   them.

	   Some warnings about non-conforming programs are controlled by
	   options other than -Wpedantic; in many cases they are implied by
	   -Wpedantic but can be disabled separately by their specific option,
	   e.g. -Wpedantic -Wno-pointer-sign.

	   Where the standard specified with -std represents a GNU extended
	   dialect of C, such as gnu90 or gnu99, there is a corresponding base
	   standard, the version of ISO C on which the GNU extended dialect is
	   based.  Warnings from -Wpedantic are given where they are required
	   by the base standard.  (It does not make sense for such warnings to
	   be given only for features not in the specified GNU C dialect,
	   since by definition the GNU dialects of C include all features the
	   compiler supports with the given option, and there would be nothing
	   to warn about.)

       -pedantic-errors
	   Give an error whenever the base standard (see -Wpedantic) requires
	   a diagnostic, in some cases where there is undefined behavior at
	   compile-time and in some other cases that do not prevent
	   compilation of programs that are valid according to the standard.
	   This is not equivalent to -Werror=pedantic: the latter option is
	   unlikely to be useful, as it only makes errors of the diagnostics
	   that are controlled by -Wpedantic, whereas this option also affects
	   required diagnostics that are always enabled or controlled by
	   options other than -Wpedantic.

	   If you want the required diagnostics that are warnings by default
	   to be errors instead, but don't also want to enable the -Wpedantic
	   diagnostics, you can specify -pedantic-errors -Wno-pedantic (or
	   -pedantic-errors -Wno-error=pedantic to enable them but only as
	   warnings).

	   Some required diagnostics are errors by default, but can be reduced
	   to warnings using -fpermissive or their specific warning option,
	   e.g. -Wno-error=narrowing.

	   Some diagnostics for non-ISO practices are controlled by specific
	   warning options other than -Wpedantic, but are also made errors by
	   -pedantic-errors.  For instance:

	   -Wattributes (for standard attributes) -Wchanges-meaning (C++)
	   -Wcomma-subscript (C++23 or later) -Wdeclaration-after-statement
	   (C90 or earlier) -Welaborated-enum-base (C++11 or later)
	   -Wimplicit-int (C99 or later) -Wimplicit-function-declaration (C99
	   or later) -Wincompatible-pointer-types -Wint-conversion -Wlong-long
	   (C90 or earlier) -Wmain -Wnarrowing (C++11 or later)
	   -Wpointer-arith -Wpointer-sign -Wincompatible-pointer-types
	   -Wregister (C++17 or later) -Wvla (C90 or earlier) -Wwrite-strings
	   (C++11 or later)

       -fpermissive
	   Downgrade some required diagnostics about nonconformant code from
	   errors to warnings.	Thus, using -fpermissive allows some
	   nonconforming code to compile.  Some C++ diagnostics are controlled
	   only by this flag, but it also downgrades some C and C++
	   diagnostics that have their own flag:

	   -Wdeclaration-missing-parameter-type (C and Objective-C only)
	   -Wimplicit-function-declaration (C and Objective-C only)
	   -Wimplicit-int (C and Objective-C only)
	   -Wincompatible-pointer-types (C and Objective-C only)
	   -Wint-conversion (C and Objective-C only) -Wnarrowing (C++ and
	   Objective-C++ only) -Wreturn-mismatch (C and Objective-C only)

	   The -fpermissive option is the default for historic C language
	   modes (-std=c89, -std=gnu89, -std=c90, -std=gnu90).

       -Wall
	   This enables all the warnings about constructions that some users
	   consider questionable, and that are easy to avoid (or modify to
	   prevent the warning), even in conjunction with macros.  This also
	   enables some language-specific warnings described in C++ Dialect
	   Options and Objective-C and Objective-C++ Dialect Options.

	   -Wall turns on the following warning flags:

	   -Waddress -Waligned-new (C++ and Objective-C++ only)
	   -Warray-bounds=1 (only with -O2) -Warray-compare
	   -Warray-parameter=2 -Wbool-compare -Wbool-operation -Wc++11-compat
	   -Wc++14-compat  -Wc++17compat  -Wc++20compat -Wcatch-value (C++ and
	   Objective-C++ only) -Wchar-subscripts -Wclass-memaccess (C++ and
	   Objective-C++ only) -Wcomment -Wdangling-else -Wdangling-pointer=2
	   -Wdelete-non-virtual-dtor (C++ and Objective-C++ only)
	   -Wduplicate-decl-specifier (C and Objective-C only) -Wenum-compare
	   (in C/ObjC; this is on by default in C++) -Wenum-int-mismatch (C
	   and Objective-C only) -Wformat=1 -Wformat-contains-nul
	   -Wformat-diag -Wformat-extra-args -Wformat-overflow=1
	   -Wformat-truncation=1 -Wformat-zero-length -Wframe-address
	   -Wimplicit (C and Objective-C only) -Wimplicit-function-declaration
	   (C and Objective-C only) -Wimplicit-int (C and Objective-C only)
	   -Winfinite-recursion -Winit-self (C++ and Objective-C++ only)
	   -Wint-in-bool-context -Wlogical-not-parentheses -Wmain (only for
	   C/ObjC and unless -ffreestanding) -Wmaybe-uninitialized
	   -Wmemset-elt-size -Wmemset-transposed-args -Wmisleading-indentation
	   (only for C/C++) -Wmismatched-dealloc -Wmismatched-new-delete (C++
	   and Objective-C++ only) -Wmissing-attributes -Wmissing-braces (only
	   for C/ObjC) -Wmultistatement-macros -Wnarrowing  (C++ and
	   Objective-C++ only) -Wnonnull -Wnonnull-compare -Wopenmp-simd (C
	   and C++ only) -Woverloaded-virtual=1 (C++ and Objective-C++ only)
	   -Wpacked-not-aligned -Wparentheses -Wpessimizing-move (C++ and
	   Objective-C++ only) -Wpointer-sign (only for C/ObjC)
	   -Wrange-loop-construct (C++ and Objective-C++ only) -Wreorder (C++
	   and Objective-C++ only) -Wrestrict -Wreturn-type -Wself-move (C++
	   and Objective-C++ only) -Wsequence-point -Wsign-compare (C++ and
	   Objective-C++ only) -Wsizeof-array-div -Wsizeof-pointer-div
	   -Wsizeof-pointer-memaccess -Wstrict-aliasing -Wstrict-overflow=1
	   -Wswitch -Wtautological-compare -Wtrigraphs -Wuninitialized
	   -Wunknown-pragmas -Wunused -Wunused-but-set-variable
	   -Wunused-const-variable=1 (only for C/ObjC) -Wunused-function
	   -Wunused-label -Wunused-local-typedefs -Wunused-value
	   -Wunused-variable -Wuse-after-free=2 -Wvla-parameter
	   -Wvolatile-register-var -Wzero-length-bounds

	   Note that some warning flags are not implied by -Wall.  Some of
	   them warn about constructions that users generally do not consider
	   questionable, but which occasionally you might wish to check for;
	   others warn about constructions that are necessary or hard to avoid
	   in some cases, and there is no simple way to modify the code to
	   suppress the warning. Some of them are enabled by -Wextra but many
	   of them must be enabled individually.

       -Wextra
	   This enables some extra warning flags that are not enabled by
	   -Wall. (This option used to be called -W.  The older name is still
	   supported, but the newer name is more descriptive.)

	   -Wabsolute-value (only for C/ObjC) -Walloc-size
	   -Wcalloc-transposed-args -Wcast-function-type -Wclobbered
	   -Wdeprecated-copy (C++ and Objective-C++ only) -Wempty-body
	   -Wenum-conversion (only for C/ObjC) -Wexpansion-to-defined
	   -Wignored-qualifiers	 (only for C/C++) -Wimplicit-fallthrough=3
	   -Wmaybe-uninitialized -Wmissing-field-initializers
	   -Wmissing-parameter-type (C/ObjC only) -Wold-style-declaration
	   (C/ObjC only) -Woverride-init (C/ObjC only) -Wredundant-move (C++
	   and Objective-C++ only) -Wshift-negative-value (in C++11 to C++17
	   and in C99 and newer) -Wsign-compare (C++ and Objective-C++ only)
	   -Wsized-deallocation (C++ and Objective-C++ only) -Wstring-compare
	   -Wtype-limits -Wuninitialized -Wunused-parameter (only with
	   -Wunused or -Wall) -Wunused-but-set-parameter (only with -Wunused
	   or -Wall)

	   The option -Wextra also prints warning messages for the following
	   cases:

	   *   A pointer is compared against integer zero with "<", "<=", ">",
	       or ">=".

	   *   (C++ only) An enumerator and a non-enumerator both appear in a
	       conditional expression.

	   *   (C++ only) Ambiguous virtual bases.

	   *   (C++ only) Subscripting an array that has been declared
	       "register".

	   *   (C++ only) Taking the address of a variable that has been
	       declared "register".

	   *   (C++ only) A base class is not initialized in the copy
	       constructor of a derived class.

       -Wabi (C, Objective-C, C++ and Objective-C++ only)
	   Warn about code affected by ABI changes.  This includes code that
	   may not be compatible with the vendor-neutral C++ ABI as well as
	   the psABI for the particular target.

	   Since G++ now defaults to updating the ABI with each major release,
	   normally -Wabi warns only about C++ ABI compatibility problems if
	   there is a check added later in a release series for an ABI issue
	   discovered since the initial release.  -Wabi warns about more
	   things if an older ABI version is selected (with -fabi-version=n).

	   -Wabi can also be used with an explicit version number to warn
	   about C++ ABI compatibility with a particular -fabi-version level,
	   e.g. -Wabi=2 to warn about changes relative to -fabi-version=2.

	   If an explicit version number is provided and -fabi-compat-version
	   is not specified, the version number from this option is used for
	   compatibility aliases.  If no explicit version number is provided
	   with this option, but -fabi-compat-version is specified, that
	   version number is used for C++ ABI warnings.

	   Although an effort has been made to warn about all such cases,
	   there are probably some cases that are not warned about, even
	   though G++ is generating incompatible code.	There may also be
	   cases where warnings are emitted even though the code that is
	   generated is compatible.

	   You should rewrite your code to avoid these warnings if you are
	   concerned about the fact that code generated by G++ may not be
	   binary compatible with code generated by other compilers.

	   Known incompatibilities in -fabi-version=2 (which was the default
	   from GCC 3.4 to 4.9) include:

	   *   A template with a non-type template parameter of reference type
	       was mangled incorrectly:

		       extern int N;
		       template <int &> struct S {};
		       void n (S<N>) {2}

	       This was fixed in -fabi-version=3.

	   *   SIMD vector types declared using "__attribute ((vector_size))"
	       were mangled in a non-standard way that does not allow for
	       overloading of functions taking vectors of different sizes.

	       The mangling was changed in -fabi-version=4.

	   *   "__attribute ((const))" and "noreturn" were mangled as type
	       qualifiers, and "decltype" of a plain declaration was folded
	       away.

	       These mangling issues were fixed in -fabi-version=5.

	   *   Scoped enumerators passed as arguments to a variadic function
	       are promoted like unscoped enumerators, causing "va_arg" to
	       complain.  On most targets this does not actually affect the
	       parameter passing ABI, as there is no way to pass an argument
	       smaller than "int".

	       Also, the ABI changed the mangling of template argument packs,
	       "const_cast", "static_cast", prefix increment/decrement, and a
	       class scope function used as a template argument.

	       These issues were corrected in -fabi-version=6.

	   *   Lambdas in default argument scope were mangled incorrectly, and
	       the ABI changed the mangling of "nullptr_t".

	       These issues were corrected in -fabi-version=7.

	   *   When mangling a function type with function-cv-qualifiers, the
	       un-qualified function type was incorrectly treated as a
	       substitution candidate.

	       This was fixed in -fabi-version=8, the default for GCC 5.1.

	   *   decltype(nullptr) incorrectly had an alignment of 1, leading to
	       unaligned accesses.  Note that this did not affect the ABI of a
	       function with a "nullptr_t" parameter, as parameters have a
	       minimum alignment.

	       This was fixed in -fabi-version=9, the default for GCC 5.2.

	   *   Target-specific attributes that affect the identity of a type,
	       such as ia32 calling conventions on a function type (stdcall,
	       regparm, etc.), did not affect the mangled name, leading to
	       name collisions when function pointers were used as template
	       arguments.

	       This was fixed in -fabi-version=10, the default for GCC 6.1.

	   This option also enables warnings about psABI-related changes.  The
	   known psABI changes at this point include:

	   *   For SysV/x86-64, unions with "long double" members are passed
	       in memory as specified in psABI.	 Prior to GCC 4.4, this was
	       not the case.  For example:

		       union U {
			 long double ld;
			 int i;
		       };

	       "union U" is now always passed in memory.

       -Wno-changes-meaning (C++ and Objective-C++ only)
	   C++ requires that unqualified uses of a name within a class have
	   the same meaning in the complete scope of the class, so declaring
	   the name after using it is ill-formed:

		   struct A;
		   struct B1 { A a; typedef A A; }; // warning, 'A' changes meaning
		   struct B2 { A a; struct A { }; }; // error, 'A' changes meaning

	   By default, the B1 case is only a warning because the two
	   declarations have the same type, while the B2 case is an error.
	   Both diagnostics can be disabled with -Wno-changes-meaning.
	   Alternately, the error case can be reduced to a warning with
	   -Wno-error=changes-meaning or -fpermissive.

	   Both diagnostics are also suppressed by -fms-extensions.

       -Wchar-subscripts
	   Warn if an array subscript has type "char".	This is a common cause
	   of error, as programmers often forget that this type is signed on
	   some machines.  This warning is enabled by -Wall.

       -Wno-coverage-mismatch
	   Warn if feedback profiles do not match when using the -fprofile-use
	   option.  If a source file is changed between compiling with
	   -fprofile-generate and with -fprofile-use, the files with the
	   profile feedback can fail to match the source file and GCC cannot
	   use the profile feedback information.  By default, this warning is
	   enabled and is treated as an error.	-Wno-coverage-mismatch can be
	   used to disable the warning or -Wno-error=coverage-mismatch can be
	   used to disable the error.  Disabling the error for this warning
	   can result in poorly optimized code and is useful only in the case
	   of very minor changes such as bug fixes to an existing code-base.
	   Completely disabling the warning is not recommended.

       -Wno-coverage-too-many-conditions
	   Warn if -fcondition-coverage is used and an expression have too
	   many terms and GCC gives up coverage.  Coverage is given up when
	   there are more terms in the conditional than there are bits in a
	   "gcov_type_unsigned".  This warning is enabled by default.

       -Wno-coverage-invalid-line-number
	   Warn in case a function ends earlier than it begins due to an
	   invalid linenum macros.  The warning is emitted only with
	   --coverage enabled.

	   By default, this warning is enabled and is treated as an error.
	   -Wno-coverage-invalid-line-number can be used to disable the
	   warning or -Wno-error=coverage-invalid-line-number can be used to
	   disable the error.

       -Wno-cpp (C, Objective-C, C++, Objective-C++ and Fortran only)
	   Suppress warning messages emitted by "#warning" directives.

       -Wdouble-promotion (C, C++, Objective-C and Objective-C++ only)
	   Give a warning when a value of type "float" is implicitly promoted
	   to "double".	 CPUs with a 32-bit "single-precision" floating-point
	   unit implement "float" in hardware, but emulate "double" in
	   software.  On such a machine, doing computations using "double"
	   values is much more expensive because of the overhead required for
	   software emulation.

	   It is easy to accidentally do computations with "double" because
	   floating-point literals are implicitly of type "double".  For
	   example, in:

		   float area(float radius)
		   {
		      return 3.14159 * radius * radius;
		   }

	   the compiler performs the entire computation with "double" because
	   the floating-point literal is a "double".

       -Wduplicate-decl-specifier (C and Objective-C only)
	   Warn if a declaration has duplicate "const", "volatile", "restrict"
	   or "_Atomic" specifier.  This warning is enabled by -Wall.

       -Wformat
       -Wformat=n
	   Check calls to "printf" and "scanf", etc., to make sure that the
	   arguments supplied have types appropriate to the format string
	   specified, and that the conversions specified in the format string
	   make sense.	This includes standard functions, and others specified
	   by format attributes, in the "printf", "scanf", "strftime" and
	   "strfmon" (an X/Open extension, not in the C standard) families (or
	   other target-specific families).  Which functions are checked
	   without format attributes having been specified depends on the
	   standard version selected, and such checks of functions without the
	   attribute specified are disabled by -ffreestanding or -fno-builtin.

	   The formats are checked against the format features supported by
	   GNU libc version 2.2.  These include all ISO C90 and C99 features,
	   as well as features from the Single Unix Specification and some BSD
	   and GNU extensions.	Other library implementations may not support
	   all these features; GCC does not support warning about features
	   that go beyond a particular library's limitations.  However, if
	   -Wpedantic is used with -Wformat, warnings are given about format
	   features not in the selected standard version (but not for
	   "strfmon" formats, since those are not in any version of the C
	   standard).

	   -Wformat=1
	   -Wformat
	       Option -Wformat is equivalent to -Wformat=1, and -Wno-format is
	       equivalent to -Wformat=0.  Since -Wformat also checks for null
	       format arguments for several functions, -Wformat also implies
	       -Wnonnull.  Some aspects of this level of format checking can
	       be disabled by the options: -Wno-format-contains-nul,
	       -Wno-format-extra-args, and -Wno-format-zero-length.  -Wformat
	       is enabled by -Wall.

	   -Wformat=2
	       Enable -Wformat plus additional format checks.  Currently
	       equivalent to -Wformat -Wformat-nonliteral -Wformat-security
	       -Wformat-y2k.

       -Wno-format-contains-nul
	   If -Wformat is specified, do not warn about format strings that
	   contain NUL bytes.

       -Wno-format-extra-args
	   If -Wformat is specified, do not warn about excess arguments to a
	   "printf" or "scanf" format function.	 The C standard specifies that
	   such arguments are ignored.

	   Where the unused arguments lie between used arguments that are
	   specified with $ operand number specifications, normally warnings
	   are still given, since the implementation could not know what type
	   to pass to "va_arg" to skip the unused arguments.  However, in the
	   case of "scanf" formats, this option suppresses the warning if the
	   unused arguments are all pointers, since the Single Unix
	   Specification says that such unused arguments are allowed.

       -Wformat-overflow
       -Wformat-overflow=level
	   Warn about calls to formatted input/output functions such as
	   "sprintf" and "vsprintf" that might overflow the destination
	   buffer.  When the exact number of bytes written by a format
	   directive cannot be determined at compile-time it is estimated
	   based on heuristics that depend on the level argument and on
	   optimization.  While enabling optimization will in most cases
	   improve the accuracy of the warning, it may also result in false
	   positives.

	   -Wformat-overflow
	   -Wformat-overflow=1
	       Level 1 of -Wformat-overflow enabled by -Wformat employs a
	       conservative approach that warns only about calls that most
	       likely overflow the buffer.  At this level, numeric arguments
	       to format directives with unknown values are assumed to have
	       the value of one, and strings of unknown length to be empty.
	       Numeric arguments that are known to be bounded to a subrange of
	       their type, or string arguments whose output is bounded either
	       by their directive's precision or by a finite set of string
	       literals, are assumed to take on the value within the range
	       that results in the most bytes on output.  For example, the
	       call to "sprintf" below is diagnosed because even with both a
	       and b equal to zero, the terminating NUL character ('\0')
	       appended by the function to the destination buffer will be
	       written past its end.  Increasing the size of the buffer by a
	       single byte is sufficient to avoid the warning, though it may
	       not be sufficient to avoid the overflow.

		       void f (int a, int b)
		       {
			 char buf [13];
			 sprintf (buf, "a = %i, b = %i\n", a, b);
		       }

	   -Wformat-overflow=2
	       Level 2 warns also about calls that might overflow the
	       destination buffer given an argument of sufficient length or
	       magnitude.  At level 2, unknown numeric arguments are assumed
	       to have the minimum representable value for signed types with a
	       precision greater than 1, and the maximum representable value
	       otherwise.  Unknown string arguments whose length cannot be
	       assumed to be bounded either by the directive's precision, or
	       by a finite set of string literals they may evaluate to, or the
	       character array they may point to, are assumed to be 1
	       character long.

	       At level 2, the call in the example above is again diagnosed,
	       but this time because with a equal to a 32-bit "INT_MIN" the
	       first %i directive will write some of its digits beyond the end
	       of the destination buffer.  To make the call safe regardless of
	       the values of the two variables, the size of the destination
	       buffer must be increased to at least 34 bytes.  GCC includes
	       the minimum size of the buffer in an informational note
	       following the warning.

	       An alternative to increasing the size of the destination buffer
	       is to constrain the range of formatted values.  The maximum
	       length of string arguments can be bounded by specifying the
	       precision in the format directive.  When numeric arguments of
	       format directives can be assumed to be bounded by less than the
	       precision of their type, choosing an appropriate length
	       modifier to the format specifier will reduce the required
	       buffer size.  For example, if a and b in the example above can
	       be assumed to be within the precision of the "short int" type
	       then using either the %hi format directive or casting the
	       argument to "short" reduces the maximum required size of the
	       buffer to 24 bytes.

		       void f (int a, int b)
		       {
			 char buf [23];
			 sprintf (buf, "a = %hi, b = %i\n", a, (short)b);
		       }

       -Wno-format-zero-length
	   If -Wformat is specified, do not warn about zero-length formats.
	   The C standard specifies that zero-length formats are allowed.

       -Wformat-nonliteral
	   If -Wformat is specified, also warn if the format string is not a
	   string literal and so cannot be checked, unless the format function
	   takes its format arguments as a "va_list".

       -Wformat-security
	   If -Wformat is specified, also warn about uses of format functions
	   that represent possible security problems.  At present, this warns
	   about calls to "printf" and "scanf" functions where the format
	   string is not a string literal and there are no format arguments,
	   as in "printf (foo);".  This may be a security hole if the format
	   string came from untrusted input and contains %n.  (This is
	   currently a subset of what -Wformat-nonliteral warns about, but in
	   future warnings may be added to -Wformat-security that are not
	   included in -Wformat-nonliteral.)

       -Wformat-signedness
	   If -Wformat is specified, also warn if the format string requires
	   an unsigned argument and the argument is signed and vice versa.

       -Wformat-truncation
       -Wformat-truncation=level
	   Warn about calls to formatted input/output functions such as
	   "snprintf" and "vsnprintf" that might result in output truncation.
	   When the exact number of bytes written by a format directive cannot
	   be determined at compile-time it is estimated based on heuristics
	   that depend on the level argument and on optimization.  While
	   enabling optimization will in most cases improve the accuracy of
	   the warning, it may also result in false positives.	Except as
	   noted otherwise, the option uses the same logic -Wformat-overflow.

	   -Wformat-truncation
	   -Wformat-truncation=1
	       Level 1 of -Wformat-truncation enabled by -Wformat employs a
	       conservative approach that warns only about calls to bounded
	       functions whose return value is unused and that will most
	       likely result in output truncation.

	   -Wformat-truncation=2
	       Level 2 warns also about calls to bounded functions whose
	       return value is used and that might result in truncation given
	       an argument of sufficient length or magnitude.

       -Wformat-y2k
	   If -Wformat is specified, also warn about "strftime" formats that
	   may yield only a two-digit year.

       -Wnonnull
	   Warn about passing a null pointer for arguments marked as requiring
	   a non-null value by the "nonnull" function attribute.

	   -Wnonnull is included in -Wall and -Wformat.	 It can be disabled
	   with the -Wno-nonnull option.

       -Wnonnull-compare
	   Warn when comparing an argument marked with the "nonnull" function
	   attribute against null inside the function.

	   -Wnonnull-compare is included in -Wall.  It can be disabled with
	   the -Wno-nonnull-compare option.

       -Wnull-dereference
	   Warn if the compiler detects paths that trigger erroneous or
	   undefined behavior due to dereferencing a null pointer.  This
	   option is only active when -fdelete-null-pointer-checks is active,
	   which is enabled by optimizations in most targets.  The precision
	   of the warnings depends on the optimization options used.

       -Wnrvo (C++ and Objective-C++ only)
	   Warn if the compiler does not elide the copy from a local variable
	   to the return value of a function in a context where it is allowed
	   by [class.copy.elision].  This elision is commonly known as the
	   Named Return Value Optimization.  For instance, in the example
	   below the compiler cannot elide copies from both v1 and v2, so it
	   elides neither.

		   std::vector<int> f()
		   {
		     std::vector<int> v1, v2;
		     // ...
		     if (cond) return v1;
		     else return v2; // warning: not eliding copy
		   }

       -Winfinite-recursion
	   Warn about infinitely recursive calls.  The warning is effective at
	   all optimization levels but requires optimization in order to
	   detect infinite recursion in calls between two or more functions.
	   -Winfinite-recursion is included in -Wall.

	   Compare with -Wanalyzer-infinite-recursion which provides a similar
	   diagnostic, but is implemented in a different way (as part of
	   -fanalyzer).

       -Winit-self (C, C++, Objective-C and Objective-C++ only)
	   Warn about uninitialized variables that are initialized with
	   themselves.	Note this option can only be used with the
	   -Wuninitialized option.

	   For example, GCC warns about "i" being uninitialized in the
	   following snippet only when -Winit-self has been specified:

		   int f()
		   {
		     int i = i;
		     return i;
		   }

	   This warning is enabled by -Wall in C++.

       -Wno-implicit-int (C and Objective-C only)
	   This option controls warnings when a declaration does not specify a
	   type.  This warning is enabled by default, as an error, in C99 and
	   later dialects of C, and also by -Wall.  The error can be
	   downgraded to a warning using -fpermissive (along with certain
	   other errors), or for this error alone, with
	   -Wno-error=implicit-int.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wno-implicit-function-declaration (C and Objective-C only)
	   This option controls warnings when a function is used before being
	   declared.  This warning is enabled by default, as an error, in C99
	   and later dialects of C, and also by -Wall.	The error can be
	   downgraded to a warning using -fpermissive (along with certain
	   other errors), or for this error alone, with
	   -Wno-error=implicit-function-declaration.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wimplicit (C and Objective-C only)
	   Same as -Wimplicit-int and -Wimplicit-function-declaration.	This
	   warning is enabled by -Wall.

       -Whardened
	   Warn when -fhardened did not enable an option from its set (for
	   which see -fhardened).  For instance, using -fhardened and
	   -fstack-protector at the same time on the command line causes
	   -Whardened to warn because -fstack-protector-strong is not enabled
	   by -fhardened.

	   This warning is enabled by default and has effect only when
	   -fhardened is enabled.

       -Wimplicit-fallthrough
	   -Wimplicit-fallthrough is the same as -Wimplicit-fallthrough=3 and
	   -Wno-implicit-fallthrough is the same as -Wimplicit-fallthrough=0.

       -Wimplicit-fallthrough=n
	   Warn when a switch case falls through.  For example:

		   switch (cond)
		     {
		     case 1:
		       a = 1;
		       break;
		     case 2:
		       a = 2;
		     case 3:
		       a = 3;
		       break;
		     }

	   This warning does not warn when the last statement of a case cannot
	   fall through, e.g. when there is a return statement or a call to
	   function declared with the noreturn attribute.
	   -Wimplicit-fallthrough= also takes into account control flow
	   statements, such as ifs, and only warns when appropriate.  E.g.

		   switch (cond)
		     {
		     case 1:
		       if (i > 3) {
			 bar (5);
			 break;
		       } else if (i < 1) {
			 bar (0);
		       } else
			 return;
		     default:
		       ...
		     }

	   Since there are occasions where a switch case fall through is
	   desirable, GCC provides an attribute, "__attribute__
	   ((fallthrough))", that is to be used along with a null statement to
	   suppress this warning that would normally occur:

		   switch (cond)
		     {
		     case 1:
		       bar (0);
		       __attribute__ ((fallthrough));
		     default:
		       ...
		     }

	   C++17 provides a standard way to suppress the
	   -Wimplicit-fallthrough warning using "[[fallthrough]];" instead of
	   the GNU attribute.  In C++11 or C++14 users can use
	   "[[gnu::fallthrough]];", which is a GNU extension.  Instead of
	   these attributes, it is also possible to add a fallthrough comment
	   to silence the warning.  The whole body of the C or C++ style
	   comment should match the given regular expressions listed below.
	   The option argument n specifies what kind of comments are accepted:

	   *<-Wimplicit-fallthrough=0 disables the warning altogether.>
	   *<-Wimplicit-fallthrough=1 matches ".*" regular>
	       expression, any comment is used as fallthrough comment.

	   *<-Wimplicit-fallthrough=2 case insensitively matches>
	       ".*falls?[ \t-]*thr(ough|u).*" regular expression.

	   *<-Wimplicit-fallthrough=3 case sensitively matches one of the>
	       following regular expressions:

	       *<"-fallthrough">
	       *<"@fallthrough@">
	       *<"lint -fallthrough[ \t]*">
	       *<"[ \t.!]*(ELSE,? |INTENTIONAL(LY)? )?FALL(S |
	       |-)?THR(OUGH|U)[ \t.!]*(-[^\n\r]*)?">
	       *<"[ \t.!]*(Else,? |Intentional(ly)? )?Fall((s |
	       |-)[Tt]|t)hr(ough|u)[ \t.!]*(-[^\n\r]*)?">
	       *<"[ \t.!]*([Ee]lse,? |[Ii]ntentional(ly)? )?fall(s |
	       |-)?thr(ough|u)[ \t.!]*(-[^\n\r]*)?">
	   *<-Wimplicit-fallthrough=4 case sensitively matches one of the>
	       following regular expressions:

	       *<"-fallthrough">
	       *<"@fallthrough@">
	       *<"lint -fallthrough[ \t]*">
	       *<"[ \t]*FALLTHR(OUGH|U)[ \t]*">
	   *<-Wimplicit-fallthrough=5 doesn't recognize any comments as>
	       fallthrough comments, only attributes disable the warning.

	   The comment needs to be followed after optional whitespace and
	   other comments by "case" or "default" keywords or by a user label
	   that precedes some "case" or "default" label.

		   switch (cond)
		     {
		     case 1:
		       bar (0);
		       /* FALLTHRU */
		     default:
		       ...
		     }

	   The -Wimplicit-fallthrough=3 warning is enabled by -Wextra.

       -Wno-if-not-aligned (C, C++, Objective-C and Objective-C++ only)
	   Control if warnings triggered by the "warn_if_not_aligned"
	   attribute should be issued.	These warnings are enabled by default.

       -Wignored-qualifiers (C and C++ only)
	   Warn if the return type of a function has a type qualifier such as
	   "const".  For ISO C such a type qualifier has no effect, since the
	   value returned by a function is not an lvalue.  For C++, the
	   warning is only emitted for scalar types or "void".	ISO C
	   prohibits qualified "void" return types on function definitions, so
	   such return types always receive a warning even without this
	   option.

	   This warning is also enabled by -Wextra.

       -Wno-ignored-attributes (C and C++ only)
	   This option controls warnings when an attribute is ignored.	This
	   is different from the -Wattributes option in that it warns whenever
	   the compiler decides to drop an attribute, not that the attribute
	   is either unknown, used in a wrong place, etc.  This warning is
	   enabled by default.

       -Wmain
	   Warn if the type of "main" is suspicious.  "main" should be a
	   function with external linkage, returning int, taking either zero
	   arguments, two, or three arguments of appropriate types.  This
	   warning is enabled by default in C++ and is enabled by either -Wall
	   or -Wpedantic.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wmisleading-indentation (C and C++ only)
	   Warn when the indentation of the code does not reflect the block
	   structure.  Specifically, a warning is issued for "if", "else",
	   "while", and "for" clauses with a guarded statement that does not
	   use braces, followed by an unguarded statement with the same
	   indentation.

	   In the following example, the call to "bar" is misleadingly
	   indented as if it were guarded by the "if" conditional.

		     if (some_condition ())
		       foo ();
		       bar ();	/* Gotcha: this is not guarded by the "if".  */

	   In the case of mixed tabs and spaces, the warning uses the
	   -ftabstop= option to determine if the statements line up
	   (defaulting to 8).

	   The warning is not issued for code involving multiline preprocessor
	   logic such as the following example.

		     if (flagA)
		       foo (0);
		   #if SOME_CONDITION_THAT_DOES_NOT_HOLD
		     if (flagB)
		   #endif
		       foo (1);

	   The warning is not issued after a "#line" directive, since this
	   typically indicates autogenerated code, and no assumptions can be
	   made about the layout of the file that the directive references.

	   This warning is enabled by -Wall in C and C++.

       -Wmissing-attributes
	   Warn when a declaration of a function is missing one or more
	   attributes that a related function is declared with and whose
	   absence may adversely affect the correctness or efficiency of
	   generated code.  For example, the warning is issued for
	   declarations of aliases that use attributes to specify less
	   restrictive requirements than those of their targets.  This
	   typically represents a potential optimization opportunity.  By
	   contrast, the -Wattribute-alias=2 option controls warnings issued
	   when the alias is more restrictive than the target, which could
	   lead to incorrect code generation.  Attributes considered include
	   "alloc_align", "alloc_size", "cold", "const", "hot", "leaf",
	   "malloc", "nonnull", "noreturn", "nothrow", "pure",
	   "returns_nonnull", and "returns_twice".

	   In C++, the warning is issued when an explicit specialization of a
	   primary template declared with attribute "alloc_align",
	   "alloc_size", "assume_aligned", "format", "format_arg", "malloc",
	   or "nonnull" is declared without it.	 Attributes "deprecated",
	   "error", and "warning" suppress the warning..

	   You can use the "copy" attribute to apply the same set of
	   attributes to a declaration as that on another declaration without
	   explicitly enumerating the attributes. This attribute can be
	   applied to declarations of functions, variables, or types.

	   -Wmissing-attributes is enabled by -Wall.

	   For example, since the declaration of the primary function template
	   below makes use of both attribute "malloc" and "alloc_size" the
	   declaration of the explicit specialization of the template is
	   diagnosed because it is missing one of the attributes.

		   template <class T>
		   T* __attribute__ ((malloc, alloc_size (1)))
		   allocate (size_t);

		   template <>
		   void* __attribute__ ((malloc))   // missing alloc_size
		   allocate<void> (size_t);

       -Wmissing-braces
	   Warn if an aggregate or union initializer is not fully bracketed.
	   In the following example, the initializer for "a" is not fully
	   bracketed, but that for "b" is fully bracketed.

		   int a[2][2] = { 0, 1, 2, 3 };
		   int b[2][2] = { { 0, 1 }, { 2, 3 } };

	   This warning is enabled by -Wall.

       -Wmissing-include-dirs (C, C++, Objective-C, Objective-C++ and Fortran
       only)
	   Warn if a user-supplied include directory does not exist. This
	   option is disabled by default for C, C++, Objective-C and
	   Objective-C++. For Fortran, it is partially enabled by default by
	   warning for -I and -J, only.

       -Wno-missing-profile
	   This option controls warnings if feedback profiles are missing when
	   using the -fprofile-use option.  This option diagnoses those cases
	   where a new function or a new file is added between compiling with
	   -fprofile-generate and with -fprofile-use, without regenerating the
	   profiles.  In these cases, the profile feedback data files do not
	   contain any profile feedback information for the newly added
	   function or file respectively.  Also, in the case when profile
	   count data (.gcda) files are removed, GCC cannot use any profile
	   feedback information.  In all these cases, warnings are issued to
	   inform you that a profile generation step is due.  Ignoring the
	   warning can result in poorly optimized code.	 -Wno-missing-profile
	   can be used to disable the warning, but this is not recommended and
	   should be done only when non-existent profile data is justified.

       -Wmismatched-dealloc
	   Warn for calls to deallocation functions with pointer arguments
	   returned from allocation functions for which the former isn't a
	   suitable deallocator.  A pair of functions can be associated as
	   matching allocators and deallocators by use of attribute "malloc".
	   Unless disabled by the -fno-builtin option the standard functions
	   "calloc", "malloc", "realloc", and "free", as well as the
	   corresponding forms of C++ "operator new" and "operator delete" are
	   implicitly associated as matching allocators and deallocators.  In
	   the following example "mydealloc" is the deallocator for pointers
	   returned from "myalloc".

		   void mydealloc (void*);

		   __attribute__ ((malloc (mydealloc, 1))) void*
		   myalloc (size_t);

		   void f (void)
		   {
		     void *p = myalloc (32);
		     // ...use p...
		     free (p);	 // warning: not a matching deallocator for myalloc
		     mydealloc (p);   // ok
		   }

	   In C++, the related option -Wmismatched-new-delete diagnoses
	   mismatches involving either "operator new" or "operator delete".

	   Option -Wmismatched-dealloc is included in -Wall.

       -Wmultistatement-macros
	   Warn about unsafe multiple statement macros that appear to be
	   guarded by a clause such as "if", "else", "for", "switch", or
	   "while", in which only the first statement is actually guarded
	   after the macro is expanded.

	   For example:

		   #define DOIT x++; y++
		   if (c)
		     DOIT;

	   will increment "y" unconditionally, not just when "c" holds.	 The
	   can usually be fixed by wrapping the macro in a do-while loop:

		   #define DOIT do { x++; y++; } while (0)
		   if (c)
		     DOIT;

	   This warning is enabled by -Wall in C and C++.

       -Wparentheses
	   Warn if parentheses are omitted in certain contexts, such as when
	   there is an assignment in a context where a truth value is
	   expected, or when operators are nested whose precedence people
	   often get confused about.

	   Also warn if a comparison like "x<=y<=z" appears; this is
	   equivalent to "(x<=y ? 1 : 0) <= z", which is a different
	   interpretation from that of ordinary mathematical notation.

	   Also warn for dangerous uses of the GNU extension to "?:" with
	   omitted middle operand. When the condition in the "?": operator is
	   a boolean expression, the omitted value is always 1.	 Often
	   programmers expect it to be a value computed inside the conditional
	   expression instead.

	   For C++ this also warns for some cases of unnecessary parentheses
	   in declarations, which can indicate an attempt at a function call
	   instead of a declaration:

		   {
		     // Declares a local variable called mymutex.
		     std::unique_lock<std::mutex> (mymutex);
		     // User meant std::unique_lock<std::mutex> lock (mymutex);
		   }

	   This warning is enabled by -Wall.

       -Wno-self-move (C++ and Objective-C++ only)
	   This warning warns when a value is moved to itself with
	   "std::move".	 Such a "std::move" typically has no effect.

		   struct T {
		   ...
		   };
		   void fn()
		   {
		     T t;
		     ...
		     t = std::move (t);
		   }

	   This warning is enabled by -Wall.

       -Wsequence-point
	   Warn about code that may have undefined semantics because of
	   violations of sequence point rules in the C and C++ standards.

	   The C and C++ standards define the order in which expressions in a
	   C/C++ program are evaluated in terms of sequence points, which
	   represent a partial ordering between the execution of parts of the
	   program: those executed before the sequence point, and those
	   executed after it.  These occur after the evaluation of a full
	   expression (one which is not part of a larger expression), after
	   the evaluation of the first operand of a "&&", "||", "? :" or ","
	   (comma) operator, before a function is called (but after the
	   evaluation of its arguments and the expression denoting the called
	   function), and in certain other places.  Other than as expressed by
	   the sequence point rules, the order of evaluation of subexpressions
	   of an expression is not specified.  All these rules describe only a
	   partial order rather than a total order, since, for example, if two
	   functions are called within one expression with no sequence point
	   between them, the order in which the functions are called is not
	   specified.  However, the standards committee have ruled that
	   function calls do not overlap.

	   It is not specified when between sequence points modifications to
	   the values of objects take effect.  Programs whose behavior depends
	   on this have undefined behavior; the C and C++ standards specify
	   that "Between the previous and next sequence point an object shall
	   have its stored value modified at most once by the evaluation of an
	   expression.	Furthermore, the prior value shall be read only to
	   determine the value to be stored.".	If a program breaks these
	   rules, the results on any particular implementation are entirely
	   unpredictable.

	   Examples of code with undefined behavior are "a = a++;", "a[n] =
	   b[n++]" and "a[i++] = i;".  Some more complicated cases are not
	   diagnosed by this option, and it may give an occasional false
	   positive result, but in general it has been found fairly effective
	   at detecting this sort of problem in programs.

	   The C++17 standard will define the order of evaluation of operands
	   in more cases: in particular it requires that the right-hand side
	   of an assignment be evaluated before the left-hand side, so the
	   above examples are no longer undefined.  But this option will still
	   warn about them, to help people avoid writing code that is
	   undefined in C and earlier revisions of C++.

	   The standard is worded confusingly, therefore there is some debate
	   over the precise meaning of the sequence point rules in subtle
	   cases.  Links to discussions of the problem, including proposed
	   formal definitions, may be found on the GCC readings page, at
	   <https://gcc.gnu.org/readings.html>.

	   This warning is enabled by -Wall for C and C++.

       -Wno-return-local-addr
	   Do not warn about returning a pointer (or in C++, a reference) to a
	   variable that goes out of scope after the function returns.

       -Wreturn-mismatch
	   Warn about return statements without an expressions in functions
	   which do not return "void".	Also warn about a "return" statement
	   with an expression in a function whose return type is "void",
	   unless the expression type is also "void".  As a GNU extension, the
	   latter case is accepted without a warning unless -Wpedantic is
	   used.

	   Attempting to use the return value of a non-"void" function other
	   than "main" that flows off the end by reaching the closing curly
	   brace that terminates the function is undefined.

	   This warning is specific to C and enabled by default.  In C99 and
	   later language dialects, it is treated as an error.	It can be
	   downgraded to a warning using -fpermissive (along with other
	   warnings), or for just this warning, with
	   -Wno-error=return-mismatch.

       -Wreturn-type
	   Warn whenever a function is defined with a return type that
	   defaults to "int" (unless -Wimplicit-int is active, which takes
	   precedence).	 Also warn if execution may reach the end of the
	   function body, or if the function does not contain any return
	   statement at all.

	   Attempting to use the return value of a non-"void" function other
	   than "main" that flows off the end by reaching the closing curly
	   brace that terminates the function is undefined.

	   Unlike in C, in C++, flowing off the end of a non-"void" function
	   other than "main" results in undefined behavior even when the value
	   of the function is not used.

	   This warning is enabled by default in C++ and by -Wall otherwise.

       -Wno-shift-count-negative
	   Controls warnings if a shift count is negative.  This warning is
	   enabled by default.

       -Wno-shift-count-overflow
	   Controls warnings if a shift count is greater than or equal to the
	   bit width of the type.  This warning is enabled by default.

       -Wshift-negative-value
	   Warn if left shifting a negative value.  This warning is enabled by
	   -Wextra in C99 (and newer) and C++11 to C++17 modes.

       -Wno-shift-overflow
       -Wshift-overflow=n
	   These options control warnings about left shift overflows.

	   -Wshift-overflow=1
	       This is the warning level of -Wshift-overflow and is enabled by
	       default in C99 and C++11 modes (and newer).  This warning level
	       does not warn about left-shifting 1 into the sign bit.
	       (However, in C, such an overflow is still rejected in contexts
	       where an integer constant expression is required.)  No warning
	       is emitted in C++20 mode (and newer), as signed left shifts
	       always wrap.

	   -Wshift-overflow=2
	       This warning level also warns about left-shifting 1 into the
	       sign bit, unless C++14 mode (or newer) is active.

       -Wswitch
	   Warn whenever a "switch" statement has an index of enumerated type
	   and lacks a "case" for one or more of the named codes of that
	   enumeration.	 (The presence of a "default" label prevents this
	   warning.)  "case" labels outside the enumeration range also provoke
	   warnings when this option is used (even if there is a "default"
	   label).  This warning is enabled by -Wall.

       -Wswitch-default
	   Warn whenever a "switch" statement does not have a "default" case.

       -Wswitch-enum
	   Warn whenever a "switch" statement has an index of enumerated type
	   and lacks a "case" for one or more of the named codes of that
	   enumeration.	 "case" labels outside the enumeration range also
	   provoke warnings when this option is used.  The only difference
	   between -Wswitch and this option is that this option gives a
	   warning about an omitted enumeration code even if there is a
	   "default" label.

       -Wno-switch-bool
	   Do not warn when a "switch" statement has an index of boolean type
	   and the case values are outside the range of a boolean type.	 It is
	   possible to suppress this warning by casting the controlling
	   expression to a type other than "bool".  For example:

		   switch ((int) (a == 4))
		     {
		     ...
		     }

	   This warning is enabled by default for C and C++ programs.

       -Wno-switch-outside-range
	   This option controls warnings when a "switch" case has a value that
	   is outside of its respective type range.  This warning is enabled
	   by default for C and C++ programs.

       -Wno-switch-unreachable
	   Do not warn when a "switch" statement contains statements between
	   the controlling expression and the first case label, which will
	   never be executed.  For example:

		   switch (cond)
		     {
		      i = 15;
		     ...
		      case 5:
		     ...
		     }

	   -Wswitch-unreachable does not warn if the statement between the
	   controlling expression and the first case label is just a
	   declaration:

		   switch (cond)
		     {
		      int i;
		     ...
		      case 5:
		      i = 5;
		     ...
		     }

	   This warning is enabled by default for C and C++ programs.

       -Wsync-nand (C and C++ only)
	   Warn when "__sync_fetch_and_nand" and "__sync_nand_and_fetch"
	   built-in functions are used.	 These functions changed semantics in
	   GCC 4.4.

       -Wtrivial-auto-var-init
	   Warn when "-ftrivial-auto-var-init" cannot initialize the automatic
	   variable.  A common situation is an automatic variable that is
	   declared between the controlling expression and the first case
	   label of a "switch" statement.

       -Wunused-but-set-parameter
	   Warn whenever a function parameter is assigned to, but otherwise
	   unused (aside from its declaration).

	   To suppress this warning use the "unused" attribute.

	   This warning is also enabled by -Wunused together with -Wextra.

       -Wunused-but-set-variable
	   Warn whenever a local variable is assigned to, but otherwise unused
	   (aside from its declaration).  This warning is enabled by -Wall.

	   To suppress this warning use the "unused" attribute.

	   This warning is also enabled by -Wunused, which is enabled by
	   -Wall.

       -Wunused-function
	   Warn whenever a static function is declared but not defined or a
	   non-inline static function is unused.  This warning is enabled by
	   -Wall.

       -Wunused-label
	   Warn whenever a label is declared but not used.  This warning is
	   enabled by -Wall.

	   To suppress this warning use the "unused" attribute.

       -Wunused-local-typedefs (C, Objective-C, C++ and Objective-C++ only)
	   Warn when a typedef locally defined in a function is not used.
	   This warning is enabled by -Wall.

       -Wunused-parameter
	   Warn whenever a function parameter is unused aside from its
	   declaration.	 This option is not enabled by "-Wunused" unless
	   "-Wextra" is also specified.

	   To suppress this warning use the "unused" attribute.

       -Wno-unused-result
	   Do not warn if a caller of a function marked with attribute
	   "warn_unused_result" does not use its return value. The default is
	   -Wunused-result.

       -Wunused-variable
	   Warn whenever a local or static variable is unused aside from its
	   declaration. This option implies -Wunused-const-variable=1 for C,
	   but not for C++. This warning is enabled by -Wall.

	   To suppress this warning use the "unused" attribute.

       -Wunused-const-variable
       -Wunused-const-variable=n
	   Warn whenever a constant static variable is unused aside from its
	   declaration.

	   To suppress this warning use the "unused" attribute.

	   -Wunused-const-variable=1
	       Warn about unused static const variables defined in the main
	       compilation unit, but not about static const variables declared
	       in any header included.

	       -Wunused-const-variable=1 is enabled by either
	       -Wunused-variable or -Wunused for C, but not for C++. In C this
	       declares variable storage, but in C++ this is not an error
	       since const variables take the place of "#define"s.

	   -Wunused-const-variable=2
	       This warning level also warns for unused constant static
	       variables in headers (excluding system headers).	 It is
	       equivalent to the short form -Wunused-const-variable.  This
	       level must be explicitly requested in both C and C++ because it
	       might be hard to clean up all headers included.

       -Wunused-value
	   Warn whenever a statement computes a result that is explicitly not
	   used. To suppress this warning cast the unused expression to
	   "void". This includes an expression-statement or the left-hand side
	   of a comma expression that contains no side effects. For example,
	   an expression such as "x[i,j]" causes a warning, while
	   "x[(void)i,j]" does not.

	   This warning is enabled by -Wall.

       -Wunused
	   All the above -Wunused options combined, except those documented as
	   needing to be specified explicitly.

	   In order to get a warning about an unused function parameter, you
	   must either specify -Wextra -Wunused (note that -Wall implies
	   -Wunused), or separately specify -Wunused-parameter and/or
	   -Wunused-but-set-parameter.

	   -Wunused enables only -Wunused-const-variable=1 rather than
	   -Wunused-const-variable, and only for C, not C++.

       -Wuse-after-free (C, Objective-C, C++ and Objective-C++ only)
       -Wuse-after-free=n
	   Warn about uses of pointers to dynamically allocated objects that
	   have been rendered indeterminate by a call to a deallocation
	   function.  The warning is enabled at all optimization levels but
	   may yield different results with optimization than without.

	   -Wuse-after-free=1
	       At level 1 the warning attempts to diagnose only unconditional
	       uses of pointers made indeterminate by a deallocation call or a
	       successful call to "realloc", regardless of whether or not the
	       call resulted in an actual reallocation of memory.  This
	       includes double-"free" calls as well as uses in arithmetic and
	       relational expressions.	Although undefined, uses of
	       indeterminate pointers in equality (or inequality) expressions
	       are not diagnosed at this level.

	   -Wuse-after-free=2
	       At level 2, in addition to unconditional uses, the warning also
	       diagnoses conditional uses of pointers made indeterminate by a
	       deallocation call.  As at level 2, uses in equality (or
	       inequality) expressions are not diagnosed.  For example, the
	       second call to "free" in the following function is diagnosed at
	       this level:

		       struct A { int refcount; void *data; };

		       void release (struct A *p)
		       {
			 int refcount = --p->refcount;
			 free (p);
			 if (refcount == 0)
			   free (p->data);   // warning: p may be used after free
		       }

	   -Wuse-after-free=3
	       At level 3, the warning also diagnoses uses of indeterminate
	       pointers in equality expressions.  All uses of indeterminate
	       pointers are undefined but equality tests sometimes appear
	       after calls to "realloc" as an attempt to determine whether the
	       call resulted in relocating the object to a different address.
	       They are diagnosed at a separate level to aid gradually
	       transitioning legacy code to safe alternatives.	For example,
	       the equality test in the function below is diagnosed at this
	       level:

		       void adjust_pointers (int**, int);

		       void grow (int **p, int n)
		       {
			 int **q = (int**)realloc (p, n *= 2);
			 if (q == p)
			   return;
			 adjust_pointers ((int**)q, n);
		       }

	       To avoid the warning at this level, store offsets into
	       allocated memory instead of pointers.  This approach obviates
	       needing to adjust the stored pointers after reallocation.

	   -Wuse-after-free=2 is included in -Wall.

       -Wuseless-cast (C, Objective-C, C++ and Objective-C++ only)
	   Warn when an expression is cast to its own type.  This warning does
	   not occur when a class object is converted to a non-reference type
	   as that is a way to create a temporary:

		   struct S { };
		   void g (S&&);
		   void f (S&& arg)
		   {
		     g (S(arg)); // make arg prvalue so that it can bind to S&&
		   }

       -Wuninitialized
	   Warn if an object with automatic or allocated storage duration is
	   used without having been initialized.  In C++, also warn if a non-
	   static reference or non-static "const" member appears in a class
	   without constructors.

	   In addition, passing a pointer (or in C++, a reference) to an
	   uninitialized object to a "const"-qualified argument of a built-in
	   function known to read the object is also diagnosed by this
	   warning.  (-Wmaybe-uninitialized is issued for ordinary functions.)

	   If you want to warn about code that uses the uninitialized value of
	   the variable in its own initializer, use the -Winit-self option.

	   These warnings occur for individual uninitialized elements of
	   structure, union or array variables as well as for variables that
	   are uninitialized as a whole.  They do not occur for variables or
	   elements declared "volatile".  Because these warnings depend on
	   optimization, the exact variables or elements for which there are
	   warnings depend on the precise optimization options and version of
	   GCC used.

	   Note that there may be no warning about a variable that is used
	   only to compute a value that itself is never used, because such
	   computations may be deleted by data flow analysis before the
	   warnings are printed.

	   In C++, this warning also warns about using uninitialized objects
	   in member-initializer-lists.	 For example, GCC warns about "b"
	   being uninitialized in the following snippet:

		   struct A {
		     int a;
		     int b;
		     A() : a(b) { }
		   };

       -Wno-invalid-memory-model
	   This option controls warnings for invocations of __atomic Builtins,
	   __sync Builtins, and the C11 atomic generic functions with a memory
	   consistency argument that is either invalid for the operation or
	   outside the range of values of the "memory_order" enumeration.  For
	   example, since the "__atomic_store" and "__atomic_store_n" built-
	   ins are only defined for the relaxed, release, and sequentially
	   consistent memory orders the following code is diagnosed:

		   void store (int *i)
		   {
		     __atomic_store_n (i, 0, memory_order_consume);
		   }

	   -Winvalid-memory-model is enabled by default.

       -Wmaybe-uninitialized
	   For an object with automatic or allocated storage duration, if
	   there exists a path from the function entry to a use of the object
	   that is initialized, but there exist some other paths for which the
	   object is not initialized, the compiler emits a warning if it
	   cannot prove the uninitialized paths are not executed at run time.

	   In addition, passing a pointer (or in C++, a reference) to an
	   uninitialized object to a "const"-qualified function argument is
	   also diagnosed by this warning.  (-Wuninitialized is issued for
	   built-in functions known to read the object.)  Annotating the
	   function with attribute "access (none)" indicates that the argument
	   isn't used to access the object and avoids the warning.

	   These warnings are only possible in optimizing compilation, because
	   otherwise GCC does not keep track of the state of variables.

	   These warnings are made optional because GCC may not be able to
	   determine when the code is correct in spite of appearing to have an
	   error.  Here is one example of how this can happen:

		   {
		     int x;
		     switch (y)
		       {
		       case 1: x = 1;
			 break;
		       case 2: x = 4;
			 break;
		       case 3: x = 5;
		       }
		     foo (x);
		   }

	   If the value of "y" is always 1, 2 or 3, then "x" is always
	   initialized, but GCC doesn't know this. To suppress the warning,
	   you need to provide a default case with assert(0) or similar code.

	   This option also warns when a non-volatile automatic variable might
	   be changed by a call to "longjmp".  The compiler sees only the
	   calls to "setjmp".  It cannot know where "longjmp" will be called;
	   in fact, a signal handler could call it at any point in the code.
	   As a result, you may get a warning even when there is in fact no
	   problem because "longjmp" cannot in fact be called at the place
	   that would cause a problem.

	   Some spurious warnings can be avoided if you declare all the
	   functions you use that never return as "noreturn".

	   This warning is enabled by -Wall or -Wextra.

       -Wunknown-pragmas
	   Warn when a "#pragma" directive is encountered that is not
	   understood by GCC.  If this command-line option is used, warnings
	   are even issued for unknown pragmas in system header files.	This
	   is not the case if the warnings are only enabled by the -Wall
	   command-line option.

       -Wno-pragmas
	   Do not warn about misuses of pragmas, such as incorrect parameters,
	   invalid syntax, or conflicts between pragmas.  See also
	   -Wunknown-pragmas.

       -Wno-prio-ctor-dtor
	   Do not warn if a priority from 0 to 100 is used for constructor or
	   destructor.	The use of constructor and destructor attributes allow
	   you to assign a priority to the constructor/destructor to control
	   its order of execution before "main" is called or after it returns.
	   The priority values must be greater than 100 as the compiler
	   reserves priority values between 0--100 for the implementation.

       -Wstrict-aliasing
	   This option is only active when -fstrict-aliasing is active.	 It
	   warns about code that might break the strict aliasing rules that
	   the compiler is using for optimization.  The warning does not catch
	   all cases, but does attempt to catch the more common pitfalls.  It
	   is included in -Wall.  It is equivalent to -Wstrict-aliasing=3

       -Wstrict-aliasing=n
	   This option is only active when -fstrict-aliasing is active.	 It
	   warns about code that might break the strict aliasing rules that
	   the compiler is using for optimization.  Higher levels correspond
	   to higher accuracy (fewer false positives).	Higher levels also
	   correspond to more effort, similar to the way -O works.
	   -Wstrict-aliasing is equivalent to -Wstrict-aliasing=3.

	   Level 1: Most aggressive, quick, least accurate.  Possibly useful
	   when higher levels do not warn but -fstrict-aliasing still breaks
	   the code, as it has very few false negatives.  However, it has many
	   false positives.  Warns for all pointer conversions between
	   possibly incompatible types, even if never dereferenced.  Runs in
	   the front end only.

	   Level 2: Aggressive, quick, not too precise.	 May still have many
	   false positives (not as many as level 1 though), and few false
	   negatives (but possibly more than level 1).	Unlike level 1, it
	   only warns when an address is taken.	 Warns about incomplete types.
	   Runs in the front end only.

	   Level 3 (default for -Wstrict-aliasing): Should have very few false
	   positives and few false negatives.  Slightly slower than levels 1
	   or 2 when optimization is enabled.  Takes care of the common
	   pun+dereference pattern in the front end: "*(int*)&some_float".  If
	   optimization is enabled, it also runs in the back end, where it
	   deals with multiple statement cases using flow-sensitive points-to
	   information.	 Only warns when the converted pointer is
	   dereferenced.  Does not warn about incomplete types.

       -Wstrict-overflow
       -Wstrict-overflow=n
	   This option is only active when signed overflow is undefined.  It
	   warns about cases where the compiler optimizes based on the
	   assumption that signed overflow does not occur.  Note that it does
	   not warn about all cases where the code might overflow: it only
	   warns about cases where the compiler implements some optimization.
	   Thus this warning depends on the optimization level.

	   An optimization that assumes that signed overflow does not occur is
	   perfectly safe if the values of the variables involved are such
	   that overflow never does, in fact, occur.  Therefore this warning
	   can easily give a false positive: a warning about code that is not
	   actually a problem.	To help focus on important issues, several
	   warning levels are defined.	No warnings are issued for the use of
	   undefined signed overflow when estimating how many iterations a
	   loop requires, in particular when determining whether a loop will
	   be executed at all.

	   -Wstrict-overflow=1
	       Warn about cases that are both questionable and easy to avoid.
	       For example the compiler simplifies "x + 1 > x" to 1.  This
	       level of -Wstrict-overflow is enabled by -Wall; higher levels
	       are not, and must be explicitly requested.

	   -Wstrict-overflow=2
	       Also warn about other cases where a comparison is simplified to
	       a constant.  For example: "abs (x) >= 0".  This can only be
	       simplified when signed integer overflow is undefined, because
	       "abs (INT_MIN)" overflows to "INT_MIN", which is less than
	       zero.  -Wstrict-overflow (with no level) is the same as
	       -Wstrict-overflow=2.

	   -Wstrict-overflow=3
	       Also warn about other cases where a comparison is simplified.
	       For example: "x + 1 > 1" is simplified to "x > 0".

	   -Wstrict-overflow=4
	       Also warn about other simplifications not covered by the above
	       cases.  For example: "(x * 10) / 5" is simplified to "x * 2".

	   -Wstrict-overflow=5
	       Also warn about cases where the compiler reduces the magnitude
	       of a constant involved in a comparison.	For example: "x + 2 >
	       y" is simplified to "x + 1 >= y".  This is reported only at the
	       highest warning level because this simplification applies to
	       many comparisons, so this warning level gives a very large
	       number of false positives.

       -Wstring-compare
	   Warn for calls to "strcmp" and "strncmp" whose result is determined
	   to be either zero or non-zero in tests for such equality owing to
	   the length of one argument being greater than the size of the array
	   the other argument is stored in (or the bound in the case of
	   "strncmp").	Such calls could be mistakes.  For example, the call
	   to "strcmp" below is diagnosed because its result is necessarily
	   non-zero irrespective of the contents of the array "a".

		   extern char a[4];
		   void f (char *d)
		   {
		     strcpy (d, "string");
		     ...
		     if (0 == strcmp (a, d))   // cannot be true
		       puts ("a and d are the same");
		   }

	   -Wstring-compare is enabled by -Wextra.

       -Wno-stringop-overflow
       -Wstringop-overflow
       -Wstringop-overflow=type
	   Warn for calls to string manipulation functions such as "memcpy"
	   and "strcpy" that are determined to overflow the destination
	   buffer.  The optional argument is one greater than the type of
	   Object Size Checking to perform to determine the size of the
	   destination.	 The argument is meaningful only for functions that
	   operate on character arrays but not for raw memory functions like
	   "memcpy" which always make use of Object Size type-0.  The option
	   also warns for calls that specify a size in excess of the largest
	   possible object or at most "SIZE_MAX / 2" bytes.  The option
	   produces the best results with optimization enabled but can detect
	   a small subset of simple buffer overflows even without optimization
	   in calls to the GCC built-in functions like "__builtin_memcpy" that
	   correspond to the standard functions.  In any case, the option
	   warns about just a subset of buffer overflows detected by the
	   corresponding overflow checking built-ins.  For example, the option
	   issues a warning for the "strcpy" call below because it copies at
	   least 5 characters (the string "blue" including the terminating
	   NUL) into the buffer of size 4.

		   enum Color { blue, purple, yellow };
		   const char* f (enum Color clr)
		   {
		     static char buf [4];
		     const char *str;
		     switch (clr)
		       {
			 case blue: str = "blue"; break;
			 case purple: str = "purple"; break;
			 case yellow: str = "yellow"; break;
		       }

		     return strcpy (buf, str);	 // warning here
		   }

	   Option -Wstringop-overflow=2 is enabled by default.

	   -Wstringop-overflow
	   -Wstringop-overflow=1
	       The -Wstringop-overflow=1 option uses type-zero Object Size
	       Checking to determine the sizes of destination objects.	At
	       this setting the option does not warn for writes past the end
	       of subobjects of larger objects accessed by pointers unless the
	       size of the largest surrounding object is known.	 When the
	       destination may be one of several objects it is assumed to be
	       the largest one of them.	 On Linux systems, when optimization
	       is enabled at this setting the option warns for the same code
	       as when the "_FORTIFY_SOURCE" macro is defined to a non-zero
	       value.

	   -Wstringop-overflow=2
	       The -Wstringop-overflow=2 option uses type-one Object Size
	       Checking to determine the sizes of destination objects.	At
	       this setting the option warns about overflows when writing to
	       members of the largest complete objects whose exact size is
	       known.  However, it does not warn for excessive writes to the
	       same members of unknown objects referenced by pointers since
	       they may point to arrays containing unknown numbers of
	       elements.  This is the default setting of the option.

	   -Wstringop-overflow=3
	       The -Wstringop-overflow=3 option uses type-two Object Size
	       Checking to determine the sizes of destination objects.	At
	       this setting the option warns about overflowing the smallest
	       object or data member.  This is the most restrictive setting of
	       the option that may result in warnings for safe code.

	   -Wstringop-overflow=4
	       The -Wstringop-overflow=4 option uses type-three Object Size
	       Checking to determine the sizes of destination objects.	At
	       this setting the option warns about overflowing any data
	       members, and when the destination is one of several objects it
	       uses the size of the largest of them to decide whether to issue
	       a warning.  Similarly to -Wstringop-overflow=3 this setting of
	       the option may result in warnings for benign code.

       -Wno-stringop-overread
	   Warn for calls to string manipulation functions such as "memchr",
	   or "strcpy" that are determined to read past the end of the source
	   sequence.

	   Option -Wstringop-overread is enabled by default.

       -Wno-stringop-truncation
	   Do not warn for calls to bounded string manipulation functions such
	   as "strncat", "strncpy", and "stpncpy" that may either truncate the
	   copied string or leave the destination unchanged.

	   In the following example, the call to "strncat" specifies a bound
	   that is less than the length of the source string.  As a result,
	   the copy of the source will be truncated and so the call is
	   diagnosed.  To avoid the warning use "bufsize - strlen (buf) - 1)"
	   as the bound.

		   void append (char *buf, size_t bufsize)
		   {
		     strncat (buf, ".txt", 3);
		   }

	   As another example, the following call to "strncpy" results in
	   copying to "d" just the characters preceding the terminating NUL,
	   without appending the NUL to the end.  Assuming the result of
	   "strncpy" is necessarily a NUL-terminated string is a common
	   mistake, and so the call is diagnosed.  To avoid the warning when
	   the result is not expected to be NUL-terminated, call "memcpy"
	   instead.

		   void copy (char *d, const char *s)
		   {
		     strncpy (d, s, strlen (s));
		   }

	   In the following example, the call to "strncpy" specifies the size
	   of the destination buffer as the bound.  If the length of the
	   source string is equal to or greater than this size the result of
	   the copy will not be NUL-terminated.	 Therefore, the call is also
	   diagnosed.  To avoid the warning, specify "sizeof buf - 1" as the
	   bound and set the last element of the buffer to "NUL".

		   void copy (const char *s)
		   {
		     char buf[80];
		     strncpy (buf, s, sizeof buf);
		     ...
		   }

	   In situations where a character array is intended to store a
	   sequence of bytes with no terminating "NUL" such an array may be
	   annotated with attribute "nonstring" to avoid this warning.	Such
	   arrays, however, are not suitable arguments to functions that
	   expect "NUL"-terminated strings.  To help detect accidental misuses
	   of such arrays GCC issues warnings unless it can prove that the use
	   is safe.

       -Wstrict-flex-arrays (C and C++ only)
	   Warn about improper usages of flexible array members according to
	   the level of the "strict_flex_array (level)" attribute attached to
	   the trailing array field of a structure if it's available,
	   otherwise according to the level of the option
	   -fstrict-flex-arrays=level.	  "-Wstrict-flex-arrays" is effective
	   only when level is greater than 0.

	   When level=1, warnings are issued for a trailing array reference of
	   a structure that have 2 or more elements if the trailing array is
	   referenced as a flexible array member.

	   When level=2, in addition to level=1, additional warnings are
	   issued for a trailing one-element array reference of a structure if
	   the array is referenced as a flexible array member.

	   When level=3, in addition to level=2, additional warnings are
	   issued for a trailing zero-length array reference of a structure if
	   the array is referenced as a flexible array member.

	   This option is more effective when -ftree-vrp is active (the
	   default for -O2 and above) but some warnings may be diagnosed even
	   without optimization.

       -Wsuggest-attribute=[pure|const|noreturn|format|cold|malloc]returns_nonnull|
	   Warn for cases where adding an attribute may be beneficial. The
	   attributes currently supported are listed below.

	   -Wsuggest-attribute=pure
	   -Wsuggest-attribute=const
	   -Wsuggest-attribute=noreturn
	   -Wmissing-noreturn
	   -Wsuggest-attribute=malloc
	   -Wsuggest-attribute=returns_nonnull
	   -Wno-suggest-attribute=returns_nonnull
	       Warn about functions that might be candidates for attributes
	       "pure", "const", "noreturn", "malloc" or "returns_nonnull". The
	       compiler only warns for functions visible in other compilation
	       units or (in the case of "pure" and "const") if it cannot prove
	       that the function returns normally. A function returns normally
	       if it doesn't contain an infinite loop or return abnormally by
	       throwing, calling "abort" or trapping.  This analysis requires
	       option -fipa-pure-const, which is enabled by default at -O and
	       higher.	Higher optimization levels improve the accuracy of the
	       analysis.

	   -Wsuggest-attribute=format
	   -Wmissing-format-attribute
	       Warn about function pointers that might be candidates for
	       "format" attributes.  Note these are only possible candidates,
	       not absolute ones.  GCC guesses that function pointers with
	       "format" attributes that are used in assignment,
	       initialization, parameter passing or return statements should
	       have a corresponding "format" attribute in the resulting type.
	       I.e. the left-hand side of the assignment or initialization,
	       the type of the parameter variable, or the return type of the
	       containing function respectively should also have a "format"
	       attribute to avoid the warning.

	       GCC also warns about function definitions that might be
	       candidates for "format" attributes.  Again, these are only
	       possible candidates.  GCC guesses that "format" attributes
	       might be appropriate for any function that calls a function
	       like "vprintf" or "vscanf", but this might not always be the
	       case, and some functions for which "format" attributes are
	       appropriate may not be detected.

	   -Wsuggest-attribute=cold
	       Warn about functions that might be candidates for "cold"
	       attribute.  This is based on static detection and generally
	       only warns about functions which always leads to a call to
	       another "cold" function such as wrappers of C++ "throw" or
	       fatal error reporting functions leading to "abort".

       -Walloc-size
	   Warn about calls to allocation functions decorated with attribute
	   "alloc_size" that specify insufficient size for the target type of
	   the pointer the result is assigned to, including those to the
	   built-in forms of the functions "aligned_alloc", "alloca",
	   "calloc", "malloc", and "realloc".

       -Walloc-zero
	   Warn about calls to allocation functions decorated with attribute
	   "alloc_size" that specify zero bytes, including those to the built-
	   in forms of the functions "aligned_alloc", "alloca", "calloc",
	   "malloc", and "realloc".  Because the behavior of these functions
	   when called with a zero size differs among implementations (and in
	   the case of "realloc" has been deprecated) relying on it may result
	   in subtle portability bugs and should be avoided.

       -Wcalloc-transposed-args
	   Warn about calls to allocation functions decorated with attribute
	   "alloc_size" with two arguments, which use "sizeof" operator as the
	   earlier size argument and don't use it as the later size argument.
	   This is a coding style warning.  The first argument to "calloc" is
	   documented to be number of elements in array, while the second
	   argument is size of each element, so "calloc (n, sizeof (int))" is
	   preferred over "calloc (sizeof (int), n)".  If "sizeof" in the
	   earlier argument and not the latter is intentional, the warning can
	   be suppressed by using "calloc (sizeof (struct S) + 0, n)" or
	   "calloc (1 * sizeof (struct S), 4)" or using "sizeof" in the later
	   argument as well.

       -Walloc-size-larger-than=byte-size
	   Warn about calls to functions decorated with attribute "alloc_size"
	   that attempt to allocate objects larger than the specified number
	   of bytes, or where the result of the size computation in an integer
	   type with infinite precision would exceed the value of PTRDIFF_MAX
	   on the target.  -Walloc-size-larger-than=PTRDIFF_MAX is enabled by
	   default.  Warnings controlled by the option can be disabled either
	   by specifying byte-size of SIZE_MAX or more or by
	   -Wno-alloc-size-larger-than.

       -Wno-alloc-size-larger-than
	   Disable -Walloc-size-larger-than= warnings.	The option is
	   equivalent to -Walloc-size-larger-than=SIZE_MAX or larger.

       -Walloca
	   This option warns on all uses of "alloca" in the source.

       -Walloca-larger-than=byte-size
	   This option warns on calls to "alloca" with an integer argument
	   whose value is either zero, or that is not bounded by a controlling
	   predicate that limits its value to at most byte-size.  It also
	   warns for calls to "alloca" where the bound value is unknown.
	   Arguments of non-integer types are considered unbounded even if
	   they appear to be constrained to the expected range.

	   For example, a bounded case of "alloca" could be:

		   void func (size_t n)
		   {
		     void *p;
		     if (n <= 1000)
		       p = alloca (n);
		     else
		       p = malloc (n);
		     f (p);
		   }

	   In the above example, passing "-Walloca-larger-than=1000" would not
	   issue a warning because the call to "alloca" is known to be at most
	   1000 bytes.	However, if "-Walloca-larger-than=500" were passed,
	   the compiler would emit a warning.

	   Unbounded uses, on the other hand, are uses of "alloca" with no
	   controlling predicate constraining its integer argument.  For
	   example:

		   void func ()
		   {
		     void *p = alloca (n);
		     f (p);
		   }

	   If "-Walloca-larger-than=500" were passed, the above would trigger
	   a warning, but this time because of the lack of bounds checking.

	   Note, that even seemingly correct code involving signed integers
	   could cause a warning:

		   void func (signed int n)
		   {
		     if (n < 500)
		       {
			 p = alloca (n);
			 f (p);
		       }
		   }

	   In the above example, n could be negative, causing a larger than
	   expected argument to be implicitly cast into the "alloca" call.

	   This option also warns when "alloca" is used in a loop.

	   -Walloca-larger-than=PTRDIFF_MAX is enabled by default but is
	   usually only effective  when -ftree-vrp is active (default for -O2
	   and above).

	   See also -Wvla-larger-than=byte-size.

       -Wno-alloca-larger-than
	   Disable -Walloca-larger-than= warnings.  The option is equivalent
	   to -Walloca-larger-than=SIZE_MAX or larger.

       -Warith-conversion
	   Do warn about implicit conversions from arithmetic operations even
	   when conversion of the operands to the same type cannot change
	   their values.  This affects warnings from -Wconversion,
	   -Wfloat-conversion, and -Wsign-conversion.

		   void f (char c, int i)
		   {
		     c = c + i; // warns with B<-Wconversion>
		     c = c + 1; // only warns with B<-Warith-conversion>
		   }

       -Warray-bounds
       -Warray-bounds=n
	   Warn about out of bounds subscripts or offsets into arrays.	This
	   warning is enabled by -Wall.	 It is more effective when -ftree-vrp
	   is active (the default for -O2 and above) but a subset of instances
	   are issued even without optimization.

	   By default, the trailing array of a structure will be treated as a
	   flexible array member by -Warray-bounds or -Warray-bounds=n if it
	   is declared as either a flexible array member per C99 standard
	   onwards ([]), a GCC zero-length array extension ([0]), or an one-
	   element array ([1]). As a result, out of bounds subscripts or
	   offsets into zero-length arrays or one-element arrays are not
	   warned by default.

	   You can add the option -fstrict-flex-arrays or
	   -fstrict-flex-arrays=level to control how this option treat
	   trailing array of a structure as a flexible array member:

	   when level<=1, no change to the default behavior.

	   when level=2, additional warnings will be issued for out of bounds
	   subscripts or offsets into one-element arrays;

	   when level=3, in addition to level=2, additional warnings will be
	   issued for out of bounds subscripts or offsets into zero-length
	   arrays.

	   -Warray-bounds=1
	       This is the default warning level of -Warray-bounds and is
	       enabled by -Wall; higher levels are not, and must be explicitly
	       requested.

	   -Warray-bounds=2
	       This warning level also warns about the intermediate results of
	       pointer arithmetic that may yield out of bounds values. This
	       warning level may give a larger number of false positives and
	       is deactivated by default.

       -Warray-compare
	   Warn about equality and relational comparisons between two operands
	   of array type.  This comparison was deprecated in C++20.  For
	   example:

		   int arr1[5];
		   int arr2[5];
		   bool same = arr1 == arr2;

	   -Warray-compare is enabled by -Wall.

       -Warray-parameter
       -Warray-parameter=n
	   Warn about redeclarations of functions involving parameters of
	   array or pointer types of inconsistent kinds or forms, and enable
	   the detection of out-of-bounds accesses to such parameters by
	   warnings such as -Warray-bounds.

	   If the first function declaration uses the array form for a
	   parameter declaration, the bound specified in the array is assumed
	   to be the minimum number of elements expected to be provided in
	   calls to the function and the maximum number of elements accessed
	   by it.  Failing to provide arguments of sufficient size or
	   accessing more than the maximum number of elements may be diagnosed
	   by warnings such as -Warray-bounds or -Wstringop-overflow.  At
	   level 1, the warning diagnoses inconsistencies involving array
	   parameters declared using the "T[static N]" form.

	   For example, the warning triggers for the second declaration of "f"
	   because the first one with the keyword "static" specifies that the
	   array argument must have at least four elements, while the second
	   allows an array of any size to be passed to "f".

		   void f (int[static 4]);
		   void f (int[]);	     // warning (inconsistent array form)

		   void g (void)
		   {
		     int *p = (int *)malloc (1 * sizeof (int));
		     f (p);		     // warning (array too small)
		     ...
		   }

	   At level 2 the warning also triggers for redeclarations involving
	   any other inconsistency in array or pointer argument forms denoting
	   array sizes.	 Pointers and arrays of unspecified bound are
	   considered equivalent and do not trigger a warning.

		   void g (int*);
		   void g (int[]);     // no warning
		   void g (int[8]);    // warning (inconsistent array bound)

	   -Warray-parameter=2 is included in -Wall.  The -Wvla-parameter
	   option triggers warnings for similar inconsistencies involving
	   Variable Length Array arguments.

	   The short form of the option -Warray-parameter is equivalent to
	   -Warray-parameter=2.	 The negative form -Wno-array-parameter is
	   equivalent to -Warray-parameter=0.

       -Wattribute-alias=n
       -Wno-attribute-alias
	   Warn about declarations using the "alias" and similar attributes
	   whose target is incompatible with the type of the alias.

	   -Wattribute-alias=1
	       The default warning level of the -Wattribute-alias option
	       diagnoses incompatibilities between the type of the alias
	       declaration and that of its target.  Such incompatibilities are
	       typically indicative of bugs.

	   -Wattribute-alias=2
	       At this level -Wattribute-alias also diagnoses cases where the
	       attributes of the alias declaration are more restrictive than
	       the attributes applied to its target.  These mismatches can
	       potentially result in incorrect code generation.	 In other
	       cases they may be benign and could be resolved simply by adding
	       the missing attribute to the target.  For comparison, see the
	       -Wmissing-attributes option, which controls diagnostics when
	       the alias declaration is less restrictive than the target,
	       rather than more restrictive.

	       Attributes considered include "alloc_align", "alloc_size",
	       "cold", "const", "hot", "leaf", "malloc", "nonnull",
	       "noreturn", "nothrow", "pure", "returns_nonnull", and
	       "returns_twice".

	   -Wattribute-alias is equivalent to -Wattribute-alias=1.  This is
	   the default.	 You can disable these warnings with either
	   -Wno-attribute-alias or -Wattribute-alias=0.

       -Wbidi-chars=[none|unpaired|any|ucn]
	   Warn about possibly misleading UTF-8 bidirectional control
	   characters in comments, string literals, character constants, and
	   identifiers.	 Such characters can change left-to-right writing
	   direction into right-to-left (and vice versa), which can cause
	   confusion between the logical order and visual order.  This may be
	   dangerous; for instance, it may seem that a piece of code is not
	   commented out, whereas it in fact is.

	   There are three levels of warning supported by GCC.	The default is
	   -Wbidi-chars=unpaired, which warns about improperly terminated bidi
	   contexts.  -Wbidi-chars=none turns the warning off.
	   -Wbidi-chars=any warns about any use of bidirectional control
	   characters.

	   By default, this warning does not warn about UCNs.  It is, however,
	   possible to turn on such checking by using
	   -Wbidi-chars=unpaired,ucn or -Wbidi-chars=any,ucn.  Using
	   -Wbidi-chars=ucn is valid, and is equivalent to
	   -Wbidi-chars=unpaired,ucn, if no previous -Wbidi-chars=any was
	   specified.

       -Wbool-compare
	   Warn about boolean expression compared with an integer value
	   different from "true"/"false".  For instance, the following
	   comparison is always false:

		   int n = 5;
		   ...
		   if ((n > 1) == 2) { ... }

	   This warning is enabled by -Wall.

       -Wbool-operation
	   Warn about suspicious operations on expressions of a boolean type.
	   For instance, bitwise negation of a boolean is very likely a bug in
	   the program.	 For C, this warning also warns about incrementing or
	   decrementing a boolean, which rarely makes sense.  (In C++,
	   decrementing a boolean is always invalid.  Incrementing a boolean
	   is invalid in C++17, and deprecated otherwise.)

	   This warning is enabled by -Wall.

       -Wduplicated-branches
	   Warn when an if-else has identical branches.	 This warning detects
	   cases like

		   if (p != NULL)
		     return 0;
		   else
		     return 0;

	   It doesn't warn when both branches contain just a null statement.
	   This warning also warn for conditional operators:

		     int i = x ? *p : *p;

       -Wduplicated-cond
	   Warn about duplicated conditions in an if-else-if chain.  For
	   instance, warn for the following code:

		   if (p->q != NULL) { ... }
		   else if (p->q != NULL) { ... }

       -Wframe-address
	   Warn when the __builtin_frame_address or __builtin_return_address
	   is called with an argument greater than 0.  Such calls may return
	   indeterminate values or crash the program.  The warning is included
	   in -Wall.

       -Wno-discarded-qualifiers (C and Objective-C only)
	   Do not warn if type qualifiers on pointers are being discarded.
	   Typically, the compiler warns if a "const char *" variable is
	   passed to a function that takes a "char *" parameter.  This option
	   can be used to suppress such a warning.

       -Wno-discarded-array-qualifiers (C and Objective-C only)
	   Do not warn if type qualifiers on arrays which are pointer targets
	   are being discarded.	 Typically, the compiler warns if a "const int
	   (*)[]" variable is passed to a function that takes a "int (*)[]"
	   parameter.  This option can be used to suppress such a warning.

       -Wno-incompatible-pointer-types (C and Objective-C only)
	   Do not warn when there is a conversion between pointers that have
	   incompatible types.	This warning is for cases not covered by
	   -Wno-pointer-sign, which warns for pointer argument passing or
	   assignment with different signedness.

	   By default, in C99 and later dialects of C, GCC treats this issue
	   as an error.	 The error can be downgraded to a warning using
	   -fpermissive (along with certain other errors), or for this error
	   alone, with -Wno-error=incompatible-pointer-types.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wno-int-conversion (C and Objective-C only)
	   Do not warn about incompatible integer to pointer and pointer to
	   integer conversions.	 This warning is about implicit conversions;
	   for explicit conversions the warnings -Wno-int-to-pointer-cast and
	   -Wno-pointer-to-int-cast may be used.

	   By default, in C99 and later dialects of C, GCC treats this issue
	   as an error.	 The error can be downgraded to a warning using
	   -fpermissive (along with certain other errors), or for this error
	   alone, with -Wno-error=int-conversion.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wzero-length-bounds
	   Warn about accesses to elements of zero-length array members that
	   might overlap other members of the same object.  Declaring interior
	   zero-length arrays is discouraged because accesses to them are
	   undefined.

	   For example, the first two stores in function "bad" are diagnosed
	   because the array elements overlap the subsequent members "b" and
	   "c".	 The third store is diagnosed by -Warray-bounds because it is
	   beyond the bounds of the enclosing object.

		   struct X { int a[0]; int b, c; };
		   struct X x;

		   void bad (void)
		   {
		     x.a[0] = 0;   // -Wzero-length-bounds
		     x.a[1] = 1;   // -Wzero-length-bounds
		     x.a[2] = 2;   // -Warray-bounds
		   }

	   Option -Wzero-length-bounds is enabled by -Warray-bounds.

       -Wno-div-by-zero
	   Do not warn about compile-time integer division by zero.  Floating-
	   point division by zero is not warned about, as it can be a
	   legitimate way of obtaining infinities and NaNs.

       -Wsystem-headers
	   Print warning messages for constructs found in system header files.
	   Warnings from system headers are normally suppressed, on the
	   assumption that they usually do not indicate real problems and
	   would only make the compiler output harder to read.	Using this
	   command-line option tells GCC to emit warnings from system headers
	   as if they occurred in user code.  However, note that using -Wall
	   in conjunction with this option does not warn about unknown pragmas
	   in system headers---for that, -Wunknown-pragmas must also be used.

       -Wtautological-compare
	   Warn if a self-comparison always evaluates to true or false.	 This
	   warning detects various mistakes such as:

		   int i = 1;
		   ...
		   if (i > i) { ... }

	   This warning also warns about bitwise comparisons that always
	   evaluate to true or false, for instance:

		   if ((a & 16) == 10) { ... }

	   will always be false.

	   This warning is enabled by -Wall.

       -Wtrampolines
	   Warn about trampolines generated for pointers to nested functions.
	   A trampoline is a small piece of data or code that is created at
	   run time on the stack when the address of a nested function is
	   taken, and is used to call the nested function indirectly.  For
	   some targets, it is made up of data only and thus requires no
	   special treatment.  But, for most targets, it is made up of code
	   and thus requires the stack to be made executable in order for the
	   program to work properly.

       -Wfloat-equal
	   Warn if floating-point values are used in equality comparisons.

	   The idea behind this is that sometimes it is convenient (for the
	   programmer) to consider floating-point values as approximations to
	   infinitely precise real numbers.  If you are doing this, then you
	   need to compute (by analyzing the code, or in some other way) the
	   maximum or likely maximum error that the computation introduces,
	   and allow for it when performing comparisons (and when producing
	   output, but that's a different problem).  In particular, instead of
	   testing for equality, you should check to see whether the two
	   values have ranges that overlap; and this is done with the
	   relational operators, so equality comparisons are probably
	   mistaken.

       -Wtraditional (C and Objective-C only)
	   Warn about certain constructs that behave differently in
	   traditional and ISO C.  Also warn about ISO C constructs that have
	   no traditional C equivalent, and/or problematic constructs that
	   should be avoided.

	   *   Macro parameters that appear within string literals in the
	       macro body.  In traditional C macro replacement takes place
	       within string literals, but in ISO C it does not.

	   *   In traditional C, some preprocessor directives did not exist.
	       Traditional preprocessors only considered a line to be a
	       directive if the # appeared in column 1 on the line.  Therefore
	       -Wtraditional warns about directives that traditional C
	       understands but ignores because the # does not appear as the
	       first character on the line.  It also suggests you hide
	       directives like "#pragma" not understood by traditional C by
	       indenting them.	Some traditional implementations do not
	       recognize "#elif", so this option suggests avoiding it
	       altogether.

	   *   A function-like macro that appears without arguments.

	   *   The unary plus operator.

	   *   The U integer constant suffix, or the F or L floating-point
	       constant suffixes.  (Traditional C does support the L suffix on
	       integer constants.)  Note, these suffixes appear in macros
	       defined in the system headers of most modern systems, e.g. the
	       _MIN/_MAX macros in "<limits.h>".  Use of these macros in user
	       code might normally lead to spurious warnings, however GCC's
	       integrated preprocessor has enough context to avoid warning in
	       these cases.

	   *   A function declared external in one block and then used after
	       the end of the block.

	   *   A "switch" statement has an operand of type "long".

	   *   A non-"static" function declaration follows a "static" one.
	       This construct is not accepted by some traditional C compilers.

	   *   The ISO type of an integer constant has a different width or
	       signedness from its traditional type.  This warning is only
	       issued if the base of the constant is ten.  I.e. hexadecimal or
	       octal values, which typically represent bit patterns, are not
	       warned about.

	   *   Usage of ISO string concatenation is detected.

	   *   Initialization of automatic aggregates.

	   *   Identifier conflicts with labels.  Traditional C lacks a
	       separate namespace for labels.

	   *   Initialization of unions.  If the initializer is zero, the
	       warning is omitted.  This is done under the assumption that the
	       zero initializer in user code appears conditioned on e.g.
	       "__STDC__" to avoid missing initializer warnings and relies on
	       default initialization to zero in the traditional C case.

	   *   Conversions by prototypes between fixed/floating-point values
	       and vice versa.	The absence of these prototypes when compiling
	       with traditional C causes serious problems.  This is a subset
	       of the possible conversion warnings; for the full set use
	       -Wtraditional-conversion.

	   *   Use of ISO C style function definitions.	 This warning
	       intentionally is not issued for prototype declarations or
	       variadic functions because these ISO C features appear in your
	       code when using libiberty's traditional C compatibility macros,
	       "PARAMS" and "VPARAMS".	This warning is also bypassed for
	       nested functions because that feature is already a GCC
	       extension and thus not relevant to traditional C compatibility.

       -Wtraditional-conversion (C and Objective-C only)
	   Warn if a prototype causes a type conversion that is different from
	   what would happen to the same argument in the absence of a
	   prototype.  This includes conversions of fixed point to floating
	   and vice versa, and conversions changing the width or signedness of
	   a fixed-point argument except when the same as the default
	   promotion.

       -Wdeclaration-after-statement (C and Objective-C only)
	   Warn when a declaration is found after a statement in a block.
	   This construct, known from C++, was introduced with ISO C99 and is
	   by default allowed in GCC.  It is not supported by ISO C90.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wshadow
	   Warn whenever a local variable or type declaration shadows another
	   variable, parameter, type, class member (in C++), or instance
	   variable (in Objective-C) or whenever a built-in function is
	   shadowed.  Note that in C++, the compiler warns if a local variable
	   shadows an explicit typedef, but not if it shadows a
	   struct/class/enum.  If this warning is enabled, it includes also
	   all instances of local shadowing.  This means that
	   -Wno-shadow=local and -Wno-shadow=compatible-local are ignored when
	   -Wshadow is used.  Same as -Wshadow=global.

       -Wno-shadow-ivar (Objective-C only)
	   Do not warn whenever a local variable shadows an instance variable
	   in an Objective-C method.

       -Wshadow=global
	   Warn for any shadowing.  Same as -Wshadow.

       -Wshadow=local
	   Warn when a local variable shadows another local variable or
	   parameter.

       -Wshadow=compatible-local
	   Warn when a local variable shadows another local variable or
	   parameter whose type is compatible with that of the shadowing
	   variable.  In C++, type compatibility here means the type of the
	   shadowing variable can be converted to that of the shadowed
	   variable.  The creation of this flag (in addition to
	   -Wshadow=local) is based on the idea that when a local variable
	   shadows another one of incompatible type, it is most likely
	   intentional, not a bug or typo, as shown in the following example:

		   for (SomeIterator i = SomeObj.begin(); i != SomeObj.end(); ++i)
		   {
		     for (int i = 0; i < N; ++i)
		     {
		       ...
		     }
		     ...
		   }

	   Since the two variable "i" in the example above have incompatible
	   types, enabling only -Wshadow=compatible-local does not emit a
	   warning.  Because their types are incompatible, if a programmer
	   accidentally uses one in place of the other, type checking is
	   expected to catch that and emit an error or warning.	 Use of this
	   flag instead of -Wshadow=local can possibly reduce the number of
	   warnings triggered by intentional shadowing.	 Note that this also
	   means that shadowing "const char *i" by "char *i" does not emit a
	   warning.

	   This warning is also enabled by -Wshadow=local.

       -Wlarger-than=byte-size
	   Warn whenever an object is defined whose size exceeds byte-size.
	   -Wlarger-than=PTRDIFF_MAX is enabled by default.  Warnings
	   controlled by the option can be disabled either by specifying byte-
	   size of SIZE_MAX or more or by -Wno-larger-than.

	   Also warn for calls to bounded functions such as "memchr" or
	   "strnlen" that specify a bound greater than the largest possible
	   object, which is PTRDIFF_MAX bytes by default.  These warnings can
	   only be disabled by -Wno-larger-than.

       -Wno-larger-than
	   Disable -Wlarger-than= warnings.  The option is equivalent to
	   -Wlarger-than=SIZE_MAX or larger.

       -Wframe-larger-than=byte-size
	   Warn if the size of a function frame exceeds byte-size.  The
	   computation done to determine the stack frame size is approximate
	   and not conservative.  The actual requirements may be somewhat
	   greater than byte-size even if you do not get a warning.  In
	   addition, any space allocated via "alloca", variable-length arrays,
	   or related constructs is not included by the compiler when
	   determining whether or not to issue a warning.
	   -Wframe-larger-than=PTRDIFF_MAX is enabled by default.  Warnings
	   controlled by the option can be disabled either by specifying byte-
	   size of SIZE_MAX or more or by -Wno-frame-larger-than.

       -Wno-frame-larger-than
	   Disable -Wframe-larger-than= warnings.  The option is equivalent to
	   -Wframe-larger-than=SIZE_MAX or larger.

       -Wfree-nonheap-object
	   Warn when attempting to deallocate an object that was either not
	   allocated on the heap, or by using a pointer that was not returned
	   from a prior call to the corresponding allocation function.	For
	   example, because the call to "stpcpy" returns a pointer to the
	   terminating nul character and not to the beginning of the object,
	   the call to "free" below is diagnosed.

		   void f (char *p)
		   {
		     p = stpcpy (p, "abc");
		     // ...
		     free (p);	 // warning
		   }

	   -Wfree-nonheap-object is included in -Wall.

       -Wstack-usage=byte-size
	   Warn if the stack usage of a function might exceed byte-size.  The
	   computation done to determine the stack usage is conservative.  Any
	   space allocated via "alloca", variable-length arrays, or related
	   constructs is included by the compiler when determining whether or
	   not to issue a warning.

	   The message is in keeping with the output of -fstack-usage.

	   *   If the stack usage is fully static but exceeds the specified
	       amount, it's:

			 warning: stack usage is 1120 bytes

	   *   If the stack usage is (partly) dynamic but bounded, it's:

			 warning: stack usage might be 1648 bytes

	   *   If the stack usage is (partly) dynamic and not bounded, it's:

			 warning: stack usage might be unbounded

	   -Wstack-usage=PTRDIFF_MAX is enabled by default.  Warnings
	   controlled by the option can be disabled either by specifying byte-
	   size of SIZE_MAX or more or by -Wno-stack-usage.

       -Wno-stack-usage
	   Disable -Wstack-usage= warnings.  The option is equivalent to
	   -Wstack-usage=SIZE_MAX or larger.

       -Wunsafe-loop-optimizations
	   Warn if the loop cannot be optimized because the compiler cannot
	   assume anything on the bounds of the loop indices.  With
	   -funsafe-loop-optimizations warn if the compiler makes such
	   assumptions.

       -Wno-pedantic-ms-format (MinGW targets only)
	   When used in combination with -Wformat and -pedantic without GNU
	   extensions, this option disables the warnings about non-ISO
	   "printf" / "scanf" format width specifiers "I32", "I64", and "I"
	   used on Windows targets, which depend on the MS runtime.

       -Wpointer-arith
	   Warn about anything that depends on the "size of" a function type
	   or of "void".  GNU C assigns these types a size of 1, for
	   convenience in calculations with "void *" pointers and pointers to
	   functions.  In C++, warn also when an arithmetic operation involves
	   "NULL".  This warning is also enabled by -Wpedantic.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wno-pointer-compare
	   Do not warn if a pointer is compared with a zero character
	   constant.  This usually means that the pointer was meant to be
	   dereferenced.  For example:

		   const char *p = foo ();
		   if (p == '\0')
		     return 42;

	   Note that the code above is invalid in C++11.

	   This warning is enabled by default.

       -Wno-tsan
	   Disable warnings about unsupported features in ThreadSanitizer.

	   ThreadSanitizer does not support "std::atomic_thread_fence" and can
	   report false positives.

       -Wtype-limits
	   Warn if a comparison is always true or always false due to the
	   limited range of the data type, but do not warn for constant
	   expressions.	 For example, warn if an unsigned variable is compared
	   against zero with "<" or ">=".  This warning is also enabled by
	   -Wextra.

       -Wabsolute-value (C and Objective-C only)
	   Warn for calls to standard functions that compute the absolute
	   value of an argument when a more appropriate standard function is
	   available.  For example, calling abs(3.14) triggers the warning
	   because the appropriate function to call to compute the absolute
	   value of a double argument is "fabs".  The option also triggers
	   warnings when the argument in a call to such a function has an
	   unsigned type.  This warning can be suppressed with an explicit
	   type cast and it is also enabled by -Wextra.

       -Wcomment
       -Wcomments
	   Warn whenever a comment-start sequence /* appears in a /* comment,
	   or whenever a backslash-newline appears in a // comment.  This
	   warning is enabled by -Wall.

       -Wtrigraphs
	   Warn if any trigraphs are encountered that might change the meaning
	   of the program.  Trigraphs within comments are not warned about,
	   except those that would form escaped newlines.

	   This option is implied by -Wall.  If -Wall is not given, this
	   option is still enabled unless trigraphs are enabled.  To get
	   trigraph conversion without warnings, but get the other -Wall
	   warnings, use -trigraphs -Wall -Wno-trigraphs.

       -Wundef
	   Warn if an undefined identifier is evaluated in an "#if" directive.
	   Such identifiers are replaced with zero.

       -Wexpansion-to-defined
	   Warn whenever defined is encountered in the expansion of a macro
	   (including the case where the macro is expanded by an #if
	   directive).	Such usage is not portable.  This warning is also
	   enabled by -Wpedantic and -Wextra.

       -Wunused-macros
	   Warn about macros defined in the main file that are unused.	A
	   macro is used if it is expanded or tested for existence at least
	   once.  The preprocessor also warns if the macro has not been used
	   at the time it is redefined or undefined.

	   Built-in macros, macros defined on the command line, and macros
	   defined in include files are not warned about.

	   Note: If a macro is actually used, but only used in skipped
	   conditional blocks, then the preprocessor reports it as unused.  To
	   avoid the warning in such a case, you might improve the scope of
	   the macro's definition by, for example, moving it into the first
	   skipped block.  Alternatively, you could provide a dummy use with
	   something like:

		   #if defined the_macro_causing_the_warning
		   #endif

       -Wno-endif-labels
	   Do not warn whenever an "#else" or an "#endif" are followed by
	   text.  This sometimes happens in older programs with code of the
	   form

		   #if FOO
		   ...
		   #else FOO
		   ...
		   #endif FOO

	   The second and third "FOO" should be in comments.  This warning is
	   on by default.

       -Wbad-function-cast (C and Objective-C only)
	   Warn when a function call is cast to a non-matching type.  For
	   example, warn if a call to a function returning an integer type is
	   cast to a pointer type.

       -Wc90-c99-compat (C and Objective-C only)
	   Warn about features not present in ISO C90, but present in ISO C99.
	   For instance, warn about use of variable length arrays, "long long"
	   type, "bool" type, compound literals, designated initializers, and
	   so on.  This option is independent of the standards mode.  Warnings
	   are disabled in the expression that follows "__extension__".

       -Wc99-c11-compat (C and Objective-C only)
	   Warn about features not present in ISO C99, but present in ISO C11.
	   For instance, warn about use of anonymous structures and unions,
	   "_Atomic" type qualifier, "_Thread_local" storage-class specifier,
	   "_Alignas" specifier, "Alignof" operator, "_Generic" keyword, and
	   so on.  This option is independent of the standards mode.  Warnings
	   are disabled in the expression that follows "__extension__".

       -Wc11-c23-compat (C and Objective-C only)
       -Wc11-c2x-compat (C and Objective-C only)
	   Warn about features not present in ISO C11, but present in ISO C23.
	   For instance, warn about omitting the string in "_Static_assert",
	   use of [[]] syntax for attributes, use of decimal floating-point
	   types, and so on.  This option is independent of the standards
	   mode.  Warnings are disabled in the expression that follows
	   "__extension__".  The name -Wc11-c2x-compat is deprecated.

	   When not compiling in C23 mode, these warnings are upgraded to
	   errors by -pedantic-errors.

       -Wc++-compat (C and Objective-C only)
	   Warn about ISO C constructs that are outside of the common subset
	   of ISO C and ISO C++, e.g. request for implicit conversion from
	   "void *" to a pointer to non-"void" type.

       -Wc++11-compat (C++ and Objective-C++ only)
	   Warn about C++ constructs whose meaning differs between ISO C++
	   1998 and ISO C++ 2011, e.g., identifiers in ISO C++ 1998 that are
	   keywords in ISO C++ 2011.  This warning turns on -Wnarrowing and is
	   enabled by -Wall.

       -Wc++14-compat (C++ and Objective-C++ only)
	   Warn about C++ constructs whose meaning differs between ISO C++
	   2011 and ISO C++ 2014.  This warning is enabled by -Wall.

       -Wc++17-compat (C++ and Objective-C++ only)
	   Warn about C++ constructs whose meaning differs between ISO C++
	   2014 and ISO C++ 2017.  This warning is enabled by -Wall.

       -Wc++20-compat (C++ and Objective-C++ only)
	   Warn about C++ constructs whose meaning differs between ISO C++
	   2017 and ISO C++ 2020.  This warning is enabled by -Wall.

       -Wno-c++11-extensions (C++ and Objective-C++ only)
	   Do not warn about C++11 constructs in code being compiled using an
	   older C++ standard.	Even without this option, some C++11
	   constructs will only be diagnosed if -Wpedantic is used.

       -Wno-c++14-extensions (C++ and Objective-C++ only)
	   Do not warn about C++14 constructs in code being compiled using an
	   older C++ standard.	Even without this option, some C++14
	   constructs will only be diagnosed if -Wpedantic is used.

       -Wno-c++17-extensions (C++ and Objective-C++ only)
	   Do not warn about C++17 constructs in code being compiled using an
	   older C++ standard.	Even without this option, some C++17
	   constructs will only be diagnosed if -Wpedantic is used.

       -Wno-c++20-extensions (C++ and Objective-C++ only)
	   Do not warn about C++20 constructs in code being compiled using an
	   older C++ standard.	Even without this option, some C++20
	   constructs will only be diagnosed if -Wpedantic is used.

       -Wno-c++23-extensions (C++ and Objective-C++ only)
	   Do not warn about C++23 constructs in code being compiled using an
	   older C++ standard.	Even without this option, some C++23
	   constructs will only be diagnosed if -Wpedantic is used.

       -Wno-c++26-extensions (C++ and Objective-C++ only)
	   Do not warn about C++26 constructs in code being compiled using an
	   older C++ standard.	Even without this option, some C++26
	   constructs will only be diagnosed if -Wpedantic is used.

       -Wcast-qual
	   Warn whenever a pointer is cast so as to remove a type qualifier
	   from the target type.  For example, warn if a "const char *" is
	   cast to an ordinary "char *".

	   Also warn when making a cast that introduces a type qualifier in an
	   unsafe way.	For example, casting "char **" to "const char **" is
	   unsafe, as in this example:

		     /* p is char ** value.  */
		     const char **q = (const char **) p;
		     /* Assignment of readonly string to const char * is OK.  */
		     *q = "string";
		     /* Now char** pointer points to read-only memory.	*/
		     **p = 'b';

       -Wcast-align
	   Warn whenever a pointer is cast such that the required alignment of
	   the target is increased.  For example, warn if a "char *" is cast
	   to an "int *" on machines where integers can only be accessed at
	   two- or four-byte boundaries.

       -Wcast-align=strict
	   Warn whenever a pointer is cast such that the required alignment of
	   the target is increased.  For example, warn if a "char *" is cast
	   to an "int *" regardless of the target machine.

       -Wcast-function-type
	   Warn when a function pointer is cast to an incompatible function
	   pointer.  In a cast involving function types with a variable
	   argument list only the types of initial arguments that are provided
	   are considered.  Any parameter of pointer-type matches any other
	   pointer-type.  Any benign differences in integral types are
	   ignored, like "int" vs. "long" on ILP32 targets.  Likewise type
	   qualifiers are ignored.  The function type "void (*) (void)" is
	   special and matches everything, which can be used to suppress this
	   warning.  In a cast involving pointer to member types this warning
	   warns whenever the type cast is changing the pointer to member
	   type.  This warning is enabled by -Wextra.

       -Wcast-user-defined
	   Warn when a cast to reference type does not involve a user-defined
	   conversion that the programmer might expect to be called.

		   struct A { operator const int&(); } a;
		   auto r = (int&)a; // warning

	   This warning is enabled by default.

       -Wwrite-strings
	   When compiling C, give string constants the type "const
	   char[length]" so that copying the address of one into a non-"const"
	   "char *" pointer produces a warning.	 These warnings help you find
	   at compile time code that can try to write into a string constant,
	   but only if you have been very careful about using "const" in
	   declarations and prototypes.	 Otherwise, it is just a nuisance.
	   This is why we did not make -Wall request these warnings.

	   When compiling C++, warn about the deprecated conversion from
	   string literals to "char *".	 This warning is enabled by default
	   for C++ programs.

	   This warning is upgraded to an error by -pedantic-errors in C++11
	   mode or later.

       -Wclobbered
	   Warn for variables that might be changed by "longjmp" or "vfork".
	   This warning is also enabled by -Wextra.

       -Wno-complain-wrong-lang
	   By default, language front ends complain when a command-line option
	   is valid, but not applicable to that front end.  This may be
	   disabled with -Wno-complain-wrong-lang, which is mostly useful when
	   invoking a single compiler driver for multiple source files written
	   in different languages, for example:

		   $ g++ -fno-rtti a.cc b.f90

	   The driver g++ invokes the C++ front end to compile a.cc and the
	   Fortran front end to compile b.f90.	The latter front end diagnoses
	   f951: Warning: command-line option '-fno-rtti' is valid for
	   C++/D/ObjC++ but not for Fortran, which may be disabled with
	   -Wno-complain-wrong-lang.

       -Wcompare-distinct-pointer-types (C and Objective-C only)
	   Warn if pointers of distinct types are compared without a cast.
	   This warning is enabled by default.

       -Wconversion
	   Warn for implicit conversions that may alter a value. This includes
	   conversions between real and integer, like "abs (x)" when "x" is
	   "double"; conversions between signed and unsigned, like "unsigned
	   ui = -1"; and conversions to smaller types, like "sqrtf (M_PI)". Do
	   not warn for explicit casts like "abs ((int) x)" and "ui =
	   (unsigned) -1", or if the value is not changed by the conversion
	   like in "abs (2.0)".	 Warnings about conversions between signed and
	   unsigned integers can be disabled by using -Wno-sign-conversion.

	   For C++, also warn for confusing overload resolution for user-
	   defined conversions; and conversions that never use a type
	   conversion operator: conversions to "void", the same type, a base
	   class or a reference to them. Warnings about conversions between
	   signed and unsigned integers are disabled by default in C++ unless
	   -Wsign-conversion is explicitly enabled.

	   Warnings about conversion from arithmetic on a small type back to
	   that type are only given with -Warith-conversion.

       -Wdangling-else
	   Warn about constructions where there may be confusion to which "if"
	   statement an "else" branch belongs.	Here is an example of such a
	   case:

		   {
		     if (a)
		       if (b)
			 foo ();
		     else
		       bar ();
		   }

	   In C/C++, every "else" branch belongs to the innermost possible
	   "if" statement, which in this example is "if (b)".  This is often
	   not what the programmer expected, as illustrated in the above
	   example by indentation the programmer chose.	 When there is the
	   potential for this confusion, GCC issues a warning when this flag
	   is specified.  To eliminate the warning, add explicit braces around
	   the innermost "if" statement so there is no way the "else" can
	   belong to the enclosing "if".  The resulting code looks like this:

		   {
		     if (a)
		       {
			 if (b)
			   foo ();
			 else
			   bar ();
		       }
		   }

	   This warning is enabled by -Wparentheses.

       -Wdangling-pointer
       -Wdangling-pointer=n
	   Warn about uses of pointers (or C++ references) to objects with
	   automatic storage duration after their lifetime has ended.  This
	   includes local variables declared in nested blocks, compound
	   literals and other unnamed temporary objects.  In addition, warn
	   about storing the address of such objects in escaped pointers.  The
	   warning is enabled at all optimization levels but may yield
	   different results with optimization than without.

	   -Wdangling-pointer=1
	       At level 1, the warning diagnoses only unconditional uses of
	       dangling pointers.

	   -Wdangling-pointer=2
	       At level 2, in addition to unconditional uses the warning also
	       diagnoses conditional uses of dangling pointers.

	   The short form -Wdangling-pointer is equivalent to
	   -Wdangling-pointer=2, while -Wno-dangling-pointer and
	   -Wdangling-pointer=0 have the same effect of disabling the
	   warnings.  -Wdangling-pointer=2 is included in -Wall.

	   This example triggers the warning at level 1; the address of the
	   unnamed temporary is unconditionally referenced outside of its
	   scope.

		   char f (char c1, char c2, char c3)
		   {
		     char *p;
		     {
		       p = (char[]) { c1, c2, c3 };
		     }
		     // warning: using dangling pointer 'p' to an unnamed temporary
		     return *p;
		   }

	   In the following function the store of the address of the local
	   variable "x" in the escaped pointer *p triggers the warning at
	   level 1.

		   void g (int **p)
		   {
		     int x = 7;
		     // warning: storing the address of local variable 'x' in '*p'
		     *p = &x;
		   }

	   In this example, the array a is out of scope when the pointer s is
	   used.  Since the code that sets "s" is conditional, the warning
	   triggers at level 2.

		   extern void frob (const char *);
		   void h (char *s)
		   {
		     if (!s)
		       {
			 char a[12] = "tmpname";
			 s = a;
		       }
		     // warning: dangling pointer 's' to 'a' may be used
		     frob (s);
		   }

       -Wdate-time
	   Warn when macros "__TIME__", "__DATE__" or "__TIMESTAMP__" are
	   encountered as they might prevent bit-wise-identical reproducible
	   compilations.

       -Wempty-body
	   Warn if an empty body occurs in an "if", "else" or "do while"
	   statement.  This warning is also enabled by -Wextra.

       -Wno-endif-labels
	   Do not warn about stray tokens after "#else" and "#endif".

       -Wenum-compare
	   Warn about a comparison between values of different enumerated
	   types.  In C++ enumerated type mismatches in conditional
	   expressions are also diagnosed and the warning is enabled by
	   default.  In C this warning is enabled by -Wall.

       -Wenum-conversion
	   Warn when a value of enumerated type is implicitly converted to a
	   different enumerated type.  This warning is enabled by -Wextra in
	   C.

       -Wenum-int-mismatch (C and Objective-C only)
	   Warn about mismatches between an enumerated type and an integer
	   type in declarations.  For example:

		   enum E { l = -1, z = 0, g = 1 };
		   int foo(void);
		   enum E foo(void);

	   In C, an enumerated type is compatible with "char", a signed
	   integer type, or an unsigned integer type.  However, since the
	   choice of the underlying type of an enumerated type is
	   implementation-defined, such mismatches may cause portability
	   issues.  In C++, such mismatches are an error.  In C, this warning
	   is enabled by -Wall and -Wc++-compat.

       -Wjump-misses-init (C, Objective-C only)
	   Warn if a "goto" statement or a "switch" statement jumps forward
	   across the initialization of a variable, or jumps backward to a
	   label after the variable has been initialized.  This only warns
	   about variables that are initialized when they are declared.	 This
	   warning is only supported for C and Objective-C; in C++ this sort
	   of branch is an error in any case.

	   -Wjump-misses-init is included in -Wc++-compat.  It can be disabled
	   with the -Wno-jump-misses-init option.

       -Wsign-compare
	   Warn when a comparison between signed and unsigned values could
	   produce an incorrect result when the signed value is converted to
	   unsigned.  In C++, this warning is also enabled by -Wall.  In C, it
	   is also enabled by -Wextra.

       -Wsign-conversion
	   Warn for implicit conversions that may change the sign of an
	   integer value, like assigning a signed integer expression to an
	   unsigned integer variable. An explicit cast silences the warning.
	   In C, this option is enabled also by -Wconversion.

       -Wflex-array-member-not-at-end (C and C++ only)
	   Warn when a structure containing a C99 flexible array member as the
	   last field is not at the end of another structure.  This warning
	   warns e.g. about

		   struct flex	{ int length; char data[]; };
		   struct mid_flex { int m; struct flex flex_data; int n; };

       -Wfloat-conversion
	   Warn for implicit conversions that reduce the precision of a real
	   value.  This includes conversions from real to integer, and from
	   higher precision real to lower precision real values.  This option
	   is also enabled by -Wconversion.

       -Wno-scalar-storage-order
	   Do not warn on suspicious constructs involving reverse scalar
	   storage order.

       -Wsizeof-array-div
	   Warn about divisions of two sizeof operators when the first one is
	   applied to an array and the divisor does not equal the size of the
	   array element.  In such a case, the computation will not yield the
	   number of elements in the array, which is likely what the user
	   intended.  This warning warns e.g. about

		   int fn ()
		   {
		     int arr[10];
		     return sizeof (arr) / sizeof (short);
		   }

	   This warning is enabled by -Wall.

       -Wsizeof-pointer-div
	   Warn for suspicious divisions of two sizeof expressions that divide
	   the pointer size by the element size, which is the usual way to
	   compute the array size but won't work out correctly with pointers.
	   This warning warns e.g. about "sizeof (ptr) / sizeof (ptr[0])" if
	   "ptr" is not an array, but a pointer.  This warning is enabled by
	   -Wall.

       -Wsizeof-pointer-memaccess
	   Warn for suspicious length parameters to certain string and memory
	   built-in functions if the argument uses "sizeof".  This warning
	   triggers for example for "memset (ptr, 0, sizeof (ptr));" if "ptr"
	   is not an array, but a pointer, and suggests a possible fix, or
	   about "memcpy (&foo, ptr, sizeof (&foo));".
	   -Wsizeof-pointer-memaccess also warns about calls to bounded string
	   copy functions like "strncat" or "strncpy" that specify as the
	   bound a "sizeof" expression of the source array.  For example, in
	   the following function the call to "strncat" specifies the size of
	   the source string as the bound.  That is almost certainly a mistake
	   and so the call is diagnosed.

		   void make_file (const char *name)
		   {
		     char path[PATH_MAX];
		     strncpy (path, name, sizeof path - 1);
		     strncat (path, ".text", sizeof ".text");
		     ...
		   }

	   The -Wsizeof-pointer-memaccess option is enabled by -Wall.

       -Wno-sizeof-array-argument
	   Do not warn when the "sizeof" operator is applied to a parameter
	   that is declared as an array in a function definition.  This
	   warning is enabled by default for C and C++ programs.

       -Wmemset-elt-size
	   Warn for suspicious calls to the "memset" built-in function, if the
	   first argument references an array, and the third argument is a
	   number equal to the number of elements, but not equal to the size
	   of the array in memory.  This indicates that the user has omitted a
	   multiplication by the element size.	This warning is enabled by
	   -Wall.

       -Wmemset-transposed-args
	   Warn for suspicious calls to the "memset" built-in function where
	   the second argument is not zero and the third argument is zero.
	   For example, the call "memset (buf, sizeof buf, 0)" is diagnosed
	   because "memset (buf, 0, sizeof buf)" was meant instead.  The
	   diagnostic is only emitted if the third argument is a literal zero.
	   Otherwise, if it is an expression that is folded to zero, or a cast
	   of zero to some type, it is far less likely that the arguments have
	   been mistakenly transposed and no warning is emitted.  This warning
	   is enabled by -Wall.

       -Waddress
	   Warn about suspicious uses of address expressions. These include
	   comparing the address of a function or a declared object to the
	   null pointer constant such as in

		   void f (void);
		   void g (void)
		   {
		     if (!f)   // warning: expression evaluates to false
		       abort ();
		   }

	   comparisons of a pointer to a string literal, such as in

		   void f (const char *x)
		   {
		     if (x == "abc")   // warning: expression evaluates to false
		       puts ("equal");
		   }

	   and tests of the results of pointer addition or subtraction for
	   equality to null, such as in

		   void f (const int *p, int i)
		   {
		     return p + i == NULL;
		   }

	   Such uses typically indicate a programmer error: the address of
	   most functions and objects necessarily evaluates to true (the
	   exception are weak symbols), so their use in a conditional might
	   indicate missing parentheses in a function call or a missing
	   dereference in an array expression.	The subset of the warning for
	   object pointers can be suppressed by casting the pointer operand to
	   an integer type such as "intptr_t" or "uintptr_t".  Comparisons
	   against string literals result in unspecified behavior and are not
	   portable, and suggest the intent was to call "strcmp".  The warning
	   is suppressed if the suspicious expression is the result of macro
	   expansion.  -Waddress warning is enabled by -Wall.

       -Wno-address-of-packed-member
	   Do not warn when the address of packed member of struct or union is
	   taken, which usually results in an unaligned pointer value.	This
	   is enabled by default.

       -Wlogical-op
	   Warn about suspicious uses of logical operators in expressions.
	   This includes using logical operators in contexts where a bit-wise
	   operator is likely to be expected.  Also warns when the operands of
	   a logical operator are the same:

		   extern int a;
		   if (a < 0 && a < 0) { ... }

       -Wlogical-not-parentheses
	   Warn about logical not used on the left hand side operand of a
	   comparison.	This option does not warn if the right operand is
	   considered to be a boolean expression.  Its purpose is to detect
	   suspicious code like the following:

		   int a;
		   ...
		   if (!a > 1) { ... }

	   It is possible to suppress the warning by wrapping the LHS into
	   parentheses:

		   if ((!a) > 1) { ... }

	   This warning is enabled by -Wall.

       -Waggregate-return
	   Warn if any functions that return structures or unions are defined
	   or called.  (In languages where you can return an array, this also
	   elicits a warning.)

       -Wno-aggressive-loop-optimizations
	   Warn if in a loop with constant number of iterations the compiler
	   detects undefined behavior in some statement during one or more of
	   the iterations.

       -Wno-attributes
	   Do not warn if an unexpected "__attribute__" is used, such as
	   unrecognized attributes, function attributes applied to variables,
	   etc.	 This does not stop errors for incorrect use of supported
	   attributes.

	   Warnings about ill-formed uses of standard attributes are upgraded
	   to errors by -pedantic-errors.

	   Additionally, using -Wno-attributes=, it is possible to suppress
	   warnings about unknown scoped attributes (in C++11 and C23).	 For
	   example, -Wno-attributes=vendor::attr disables warning about the
	   following declaration:

		   [[vendor::attr]] void f();

	   It is also possible to disable warning about all attributes in a
	   namespace using -Wno-attributes=vendor:: which prevents warning
	   about both of these declarations:

		   [[vendor::safe]] void f();
		   [[vendor::unsafe]] void f2();

	   Note that -Wno-attributes= does not imply -Wno-attributes.

       -Wno-builtin-declaration-mismatch
	   Warn if a built-in function is declared with an incompatible
	   signature or as a non-function, or when a built-in function
	   declared with a type that does not include a prototype is called
	   with arguments whose promoted types do not match those expected by
	   the function.  When -Wextra is specified, also warn when a built-in
	   function that takes arguments is declared without a prototype.  The
	   -Wbuiltin-declaration-mismatch warning is enabled by default.  To
	   avoid the warning include the appropriate header to bring the
	   prototypes of built-in functions into scope.

	   For example, the call to "memset" below is diagnosed by the warning
	   because the function expects a value of type "size_t" as its
	   argument but the type of 32 is "int".  With -Wextra, the
	   declaration of the function is diagnosed as well.

		   extern void* memset ();
		   void f (void *d)
		   {
		     memset (d, '\0', 32);
		   }

       -Wno-builtin-macro-redefined
	   Do not warn if certain built-in macros are redefined.  This
	   suppresses warnings for redefinition of "__TIMESTAMP__",
	   "__TIME__", "__DATE__", "__FILE__", and "__BASE_FILE__".

       -Wstrict-prototypes (C and Objective-C only)
	   Warn if a function is declared or defined without specifying the
	   argument types.  (An old-style function definition is permitted
	   without a warning if preceded by a declaration that specifies the
	   argument types.)

       -Wold-style-declaration (C and Objective-C only)
	   Warn for obsolescent usages, according to the C Standard, in a
	   declaration. For example, warn if storage-class specifiers like
	   "static" are not the first things in a declaration.	This warning
	   is also enabled by -Wextra.

       -Wold-style-definition (C and Objective-C only)
	   Warn if an old-style function definition is used.  A warning is
	   given even if there is a previous prototype.	 A definition using ()
	   is not considered an old-style definition in C23 mode, because it
	   is equivalent to (void) in that case, but is considered an old-
	   style definition for older standards.

       -Wmissing-parameter-type (C and Objective-C only)
	   A function parameter is declared without a type specifier in
	   K&R-style functions:

		   void foo(bar) { }

	   This warning is also enabled by -Wextra.

       -Wno-declaration-missing-parameter-type (C and Objective-C only)
	   Do not warn if a function declaration contains a parameter name
	   without a type.  Such function declarations do not provide a
	   function prototype and prevent most type checking in function
	   calls.

	   This warning is enabled by default.	In C99 and later dialects of
	   C, it is treated as an error.  The error can be downgraded to a
	   warning using -fpermissive (along with certain other errors), or
	   for this error alone, with
	   -Wno-error=declaration-missing-parameter-type.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wmissing-prototypes (C and Objective-C only)
	   Warn if a global function is defined without a previous prototype
	   declaration.	 This warning is issued even if the definition itself
	   provides a prototype.  Use this option to detect global functions
	   that do not have a matching prototype declaration in a header file.
	   This option is not valid for C++ because all function declarations
	   provide prototypes and a non-matching declaration declares an
	   overload rather than conflict with an earlier declaration.  Use
	   -Wmissing-declarations to detect missing declarations in C++.

       -Wmissing-variable-declarations (C and Objective-C only)
	   Warn if a global variable is defined without a previous
	   declaration.	 Use this option to detect global variables that do
	   not have a matching extern declaration in a header file.

       -Wmissing-declarations
	   Warn if a global function is defined without a previous
	   declaration.	 Do so even if the definition itself provides a
	   prototype.  Use this option to detect global functions that are not
	   declared in header files.  In C, no warnings are issued for
	   functions with previous non-prototype declarations; use
	   -Wmissing-prototypes to detect missing prototypes.  In C++, no
	   warnings are issued for function templates, or for inline
	   functions, or for functions in anonymous namespaces.

       -Wmissing-field-initializers
	   Warn if a structure's initializer has some fields missing.  For
	   example, the following code causes such a warning, because "x.h" is
	   implicitly zero:

		   struct s { int f, g, h; };
		   struct s x = { 3, 4 };

	   In C this option does not warn about designated initializers, so
	   the following modification does not trigger a warning:

		   struct s { int f, g, h; };
		   struct s x = { .f = 3, .g = 4 };

	   In C this option does not warn about the universal zero initializer
	   { 0 }:

		   struct s { int f, g, h; };
		   struct s x = { 0 };

	   Likewise, in C++ this option does not warn about the empty { }
	   initializer, for example:

		   struct s { int f, g, h; };
		   s x = { };

	   This warning is included in -Wextra.	 To get other -Wextra warnings
	   without this one, use -Wextra -Wno-missing-field-initializers.

       -Wno-missing-requires
	   By default, the compiler warns about a concept-id appearing as a
	   C++20 simple-requirement:

		   bool satisfied = requires { C<T> };

	   Here satisfied will be true if C<T> is a valid expression, which it
	   is for all T.  Presumably the user meant to write

		   bool satisfied = requires { requires C<T> };

	   so satisfied is only true if concept C is satisfied for type T.

	   This warning can be disabled with -Wno-missing-requires.

       -Wno-missing-template-keyword
	   The member access tokens ., -> and :: must be followed by the
	   "template" keyword if the parent object is dependent and the member
	   being named is a template.

		   template <class X>
		   void DoStuff (X x)
		   {
		     x.template DoSomeOtherStuff<X>(); // Good.
		     x.DoMoreStuff<X>(); // Warning, x is dependent.
		   }

	   In rare cases it is possible to get false positives. To silence
	   this, wrap the expression in parentheses. For example, the
	   following is treated as a template, even where m and N are
	   integers:

		   void NotATemplate (my_class t)
		   {
		     int N = 5;

		     bool test = t.m < N > (0); // Treated as a template.
		     test = (t.m < N) > (0); // Same meaning, but not treated as a template.
		   }

	   This warning can be disabled with -Wno-missing-template-keyword.

       -Wno-multichar
	   Do not warn if a multicharacter constant ('FOOF') is used.  Usually
	   they indicate a typo in the user's code, as they have
	   implementation-defined values, and should not be used in portable
	   code.

       -Wnormalized=[none|id|nfc|nfkc]
	   In ISO C and ISO C++, two identifiers are different if they are
	   different sequences of characters.  However, sometimes when
	   characters outside the basic ASCII character set are used, you can
	   have two different character sequences that look the same.  To
	   avoid confusion, the ISO 10646 standard sets out some normalization
	   rules which when applied ensure that two sequences that look the
	   same are turned into the same sequence.  GCC can warn you if you
	   are using identifiers that have not been normalized; this option
	   controls that warning.

	   There are four levels of warning supported by GCC.  The default is
	   -Wnormalized=nfc, which warns about any identifier that is not in
	   the ISO 10646 "C" normalized form, NFC.  NFC is the recommended
	   form for most uses.	It is equivalent to -Wnormalized.

	   Unfortunately, there are some characters allowed in identifiers by
	   ISO C and ISO C++ that, when turned into NFC, are not allowed in
	   identifiers.	 That is, there's no way to use these symbols in
	   portable ISO C or C++ and have all your identifiers in NFC.
	   -Wnormalized=id suppresses the warning for these characters.	 It is
	   hoped that future versions of the standards involved will correct
	   this, which is why this option is not the default.

	   You can switch the warning off for all characters by writing
	   -Wnormalized=none or -Wno-normalized.  You should only do this if
	   you are using some other normalization scheme (like "D"), because
	   otherwise you can easily create bugs that are literally impossible
	   to see.

	   Some characters in ISO 10646 have distinct meanings but look
	   identical in some fonts or display methodologies, especially once
	   formatting has been applied.	 For instance "\u207F", "SUPERSCRIPT
	   LATIN SMALL LETTER N", displays just like a regular "n" that has
	   been placed in a superscript.  ISO 10646 defines the NFKC
	   normalization scheme to convert all these into a standard form as
	   well, and GCC warns if your code is not in NFKC if you use
	   -Wnormalized=nfkc.  This warning is comparable to warning about
	   every identifier that contains the letter O because it might be
	   confused with the digit 0, and so is not the default, but may be
	   useful as a local coding convention if the programming environment
	   cannot be fixed to display these characters distinctly.

       -Wno-attribute-warning
	   Do not warn about usage of functions declared with "warning"
	   attribute.  By default, this warning is enabled.
	   -Wno-attribute-warning can be used to disable the warning or
	   -Wno-error=attribute-warning can be used to disable the error when
	   compiled with -Werror flag.

       -Wno-deprecated
	   Do not warn about usage of deprecated features.

       -Wno-deprecated-declarations
	   Do not warn about uses of functions, variables, and types marked as
	   deprecated by using the "deprecated" attribute.

       -Wno-overflow
	   Do not warn about compile-time overflow in constant expressions.

       -Wno-odr
	   Warn about One Definition Rule violations during link-time
	   optimization.  Enabled by default.

       -Wopenacc-parallelism
	   Warn about potentially suboptimal choices related to OpenACC
	   parallelism.

       -Wno-openmp
	   Warn about suspicious OpenMP code.

       -Wopenmp-simd
	   Warn if the vectorizer cost model overrides the OpenMP simd
	   directive set by user.  The -fsimd-cost-model=unlimited option can
	   be used to relax the cost model.

       -Woverride-init (C and Objective-C only)
	   Warn if an initialized field without side effects is overridden
	   when using designated initializers.

	   This warning is included in -Wextra.	 To get other -Wextra warnings
	   without this one, use -Wextra -Wno-override-init.

       -Wno-override-init-side-effects (C and Objective-C only)
	   Do not warn if an initialized field with side effects is overridden
	   when using designated initializers.	This warning is enabled by
	   default.

       -Wpacked
	   Warn if a structure is given the packed attribute, but the packed
	   attribute has no effect on the layout or size of the structure.
	   Such structures may be mis-aligned for little benefit.  For
	   instance, in this code, the variable "f.x" in "struct bar" is
	   misaligned even though "struct bar" does not itself have the packed
	   attribute:

		   struct foo {
		     int x;
		     char a, b, c, d;
		   } __attribute__((packed));
		   struct bar {
		     char z;
		     struct foo f;
		   };

       -Wnopacked-bitfield-compat
	   The 4.1, 4.2 and 4.3 series of GCC ignore the "packed" attribute on
	   bit-fields of type "char".  This was fixed in GCC 4.4 but the
	   change can lead to differences in the structure layout.  GCC
	   informs you when the offset of such a field has changed in GCC 4.4.
	   For example there is no longer a 4-bit padding between field "a"
	   and "b" in this structure:

		   struct foo
		   {
		     char a:4;
		     char b:8;
		   } __attribute__ ((packed));

	   This warning is enabled by default.	Use
	   -Wno-packed-bitfield-compat to disable this warning.

       -Wpacked-not-aligned (C, C++, Objective-C and Objective-C++ only)
	   Warn if a structure field with explicitly specified alignment in a
	   packed struct or union is misaligned.  For example, a warning will
	   be issued on "struct S", like, "warning: alignment 1 of 'struct S'
	   is less than 8", in this code:

		   struct __attribute__ ((aligned (8))) S8 { char a[8]; };
		   struct __attribute__ ((packed)) S {
		     struct S8 s8;
		   };

	   This warning is enabled by -Wall.

       -Wpadded
	   Warn if padding is included in a structure, either to align an
	   element of the structure or to align the whole structure.
	   Sometimes when this happens it is possible to rearrange the fields
	   of the structure to reduce the padding and so make the structure
	   smaller.

       -Wredundant-decls
	   Warn if anything is declared more than once in the same scope, even
	   in cases where multiple declaration is valid and changes nothing.

       -Wrestrict
	   Warn when an object referenced by a "restrict"-qualified parameter
	   (or, in C++, a "__restrict"-qualified parameter) is aliased by
	   another argument, or when copies between such objects overlap.  For
	   example, the call to the "strcpy" function below attempts to
	   truncate the string by replacing its initial characters with the
	   last four.  However, because the call writes the terminating NUL
	   into "a[4]", the copies overlap and the call is diagnosed.

		   void foo (void)
		   {
		     char a[] = "abcd1234";
		     strcpy (a, a + 4);
		     ...
		   }

	   The -Wrestrict option detects some instances of simple overlap even
	   without optimization but works best at -O2 and above.  It is
	   included in -Wall.

       -Wnested-externs (C and Objective-C only)
	   Warn if an "extern" declaration is encountered within a function.

       -Winline
	   Warn if a function that is declared as inline cannot be inlined.
	   Even with this option, the compiler does not warn about failures to
	   inline functions declared in system headers.

	   The compiler uses a variety of heuristics to determine whether or
	   not to inline a function.  For example, the compiler takes into
	   account the size of the function being inlined and the amount of
	   inlining that has already been done in the current function.
	   Therefore, seemingly insignificant changes in the source program
	   can cause the warnings produced by -Winline to appear or disappear.

       -Winterference-size
	   Warn about use of C++17
	   "std::hardware_destructive_interference_size" without specifying
	   its value with --param destructive-interference-size.  Also warn
	   about questionable values for that option.

	   This variable is intended to be used for controlling class layout,
	   to avoid false sharing in concurrent code:

		   struct independent_fields {
		     alignas(std::hardware_destructive_interference_size)
		       std::atomic<int> one;
		     alignas(std::hardware_destructive_interference_size)
		       std::atomic<int> two;
		   };

	   Here one and two are intended to be far enough apart that stores to
	   one won't require accesses to the other to reload the cache line.

	   By default, --param destructive-interference-size and --param
	   constructive-interference-size are set based on the current -mtune
	   option, typically to the L1 cache line size for the particular
	   target CPU, sometimes to a range if tuning for a generic target.
	   So all translation units that depend on ABI compatibility for the
	   use of these variables must be compiled with the same -mtune (or
	   -mcpu).

	   If ABI stability is important, such as if the use is in a header
	   for a library, you should probably not use the hardware
	   interference size variables at all.	Alternatively, you can force a
	   particular value with --param.

	   If you are confident that your use of the variable does not affect
	   ABI outside a single build of your project, you can turn off the
	   warning with -Wno-interference-size.

       -Wint-in-bool-context
	   Warn for suspicious use of integer values where boolean values are
	   expected, such as conditional expressions (?:) using non-boolean
	   integer constants in boolean context, like "if (a <= b ? 2 : 3)".
	   Or left shifting of signed integers in boolean context, like "for
	   (a = 0; 1 << a; a++);".  Likewise for all kinds of multiplications
	   regardless of the data type.	 This warning is enabled by -Wall.

       -Wno-int-to-pointer-cast
	   Suppress warnings from casts to pointer type of an integer of a
	   different size. In C++, casting to a pointer type of smaller size
	   is an error. Wint-to-pointer-cast is enabled by default.

       -Wno-pointer-to-int-cast (C and Objective-C only)
	   Suppress warnings from casts from a pointer to an integer type of a
	   different size.

       -Winvalid-pch
	   Warn if a precompiled header is found in the search path but cannot
	   be used.

       -Winvalid-utf8
	   Warn if an invalid UTF-8 character is found.	 This warning is on by
	   default for C++23 if -finput-charset=UTF-8 is used and turned into
	   error with -pedantic-errors.

       -Wno-unicode
	   Don't diagnose invalid forms of delimited or named escape sequences
	   which are treated as separate tokens.  Wunicode is enabled by
	   default.

       -Wlong-long
	   Warn if "long long" type is used.  This is enabled by either
	   -Wpedantic or -Wtraditional in ISO C90 and C++98 modes.  To inhibit
	   the warning messages, use -Wno-long-long.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wvariadic-macros
	   Warn if variadic macros are used in ISO C90 mode, or if the GNU
	   alternate syntax is used in ISO C99 mode.  This is enabled by
	   either -Wpedantic or -Wtraditional.	To inhibit the warning
	   messages, use -Wno-variadic-macros.

       -Wno-varargs
	   Do not warn upon questionable usage of the macros used to handle
	   variable arguments like "va_start".	These warnings are enabled by
	   default.

       -Wvector-operation-performance
	   Warn if vector operation is not implemented via SIMD capabilities
	   of the architecture.	 Mainly useful for the performance tuning.
	   Vector operation can be implemented "piecewise", which means that
	   the scalar operation is performed on every vector element; "in
	   parallel", which means that the vector operation is implemented
	   using scalars of wider type, which normally is more performance
	   efficient; and "as a single scalar", which means that vector fits
	   into a scalar type.

       -Wvla
	   Warn if a variable-length array is used in the code.	 -Wno-vla
	   prevents the -Wpedantic warning of the variable-length array.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wvla-larger-than=byte-size
	   If this option is used, the compiler warns for declarations of
	   variable-length arrays whose size is either unbounded, or bounded
	   by an argument that allows the array size to exceed byte-size
	   bytes.  This is similar to how -Walloca-larger-than=byte-size
	   works, but with variable-length arrays.

	   Note that GCC may optimize small variable-length arrays of a known
	   value into plain arrays, so this warning may not get triggered for
	   such arrays.

	   -Wvla-larger-than=PTRDIFF_MAX is enabled by default but is
	   typically only effective when -ftree-vrp is active (default for -O2
	   and above).

	   See also -Walloca-larger-than=byte-size.

       -Wno-vla-larger-than
	   Disable -Wvla-larger-than= warnings.	 The option is equivalent to
	   -Wvla-larger-than=SIZE_MAX or larger.

       -Wvla-parameter
	   Warn about redeclarations of functions involving arguments of
	   Variable Length Array types of inconsistent kinds or forms, and
	   enable the detection of out-of-bounds accesses to such parameters
	   by warnings such as -Warray-bounds.

	   If the first function declaration uses the VLA form the bound
	   specified in the array is assumed to be the minimum number of
	   elements expected to be provided in calls to the function and the
	   maximum number of elements accessed by it.  Failing to provide
	   arguments of sufficient size or accessing more than the maximum
	   number of elements may be diagnosed.

	   For example, the warning triggers for the following redeclarations
	   because the first one allows an array of any size to be passed to
	   "f" while the second one specifies that the array argument must
	   have at least "n" elements.	In addition, calling "f" with the
	   associated VLA bound parameter in excess of the actual VLA bound
	   triggers a warning as well.

		   void f (int n, int[n]);
		   // warning: argument 2 previously declared as a VLA
		   void f (int, int[]);

		   void g (int n)
		   {
		       if (n > 4)
			 return;
		       int a[n];
		       // warning: access to a by f may be out of bounds
		       f (sizeof a, a);
		     ...
		   }

	   -Wvla-parameter is included in -Wall.  The -Warray-parameter option
	   triggers warnings for similar problems involving ordinary array
	   arguments.

       -Wvolatile-register-var
	   Warn if a register variable is declared volatile.  The volatile
	   modifier does not inhibit all optimizations that may eliminate
	   reads and/or writes to register variables.  This warning is enabled
	   by -Wall.

       -Wno-xor-used-as-pow (C, C++, Objective-C and Objective-C++ only)
	   Disable warnings about uses of "^", the exclusive or operator,
	   where it appears the code meant exponentiation.  Specifically, the
	   warning occurs when the left-hand side is the decimal constant 2 or
	   10 and the right-hand side is also a decimal constant.

	   In C and C++, "^" means exclusive or, whereas in some other
	   languages (e.g. TeX and some versions of BASIC) it means
	   exponentiation.

	   This warning can be silenced by converting one of the operands to
	   hexadecimal as well as by compiling with -Wno-xor-used-as-pow.

       -Wdisabled-optimization
	   Warn if a requested optimization pass is disabled.  This warning
	   does not generally indicate that there is anything wrong with your
	   code; it merely indicates that GCC's optimizers are unable to
	   handle the code effectively.	 Often, the problem is that your code
	   is too big or too complex; GCC refuses to optimize programs when
	   the optimization itself is likely to take inordinate amounts of
	   time.

       -Wpointer-sign (C and Objective-C only)
	   Warn for pointer argument passing or assignment with different
	   signedness.	This option is only supported for C and Objective-C.
	   It is implied by -Wall and by -Wpedantic, which can be disabled
	   with -Wno-pointer-sign.

	   This warning is upgraded to an error by -pedantic-errors.

       -Wstack-protector
	   This option is only active when -fstack-protector is active.	 It
	   warns about functions that are not protected against stack
	   smashing.

       -Woverlength-strings
	   Warn about string constants that are longer than the "minimum
	   maximum" length specified in the C standard.	 Modern compilers
	   generally allow string constants that are much longer than the
	   standard's minimum limit, but very portable programs should avoid
	   using longer strings.

	   The limit applies after string constant concatenation, and does not
	   count the trailing NUL.  In C90, the limit was 509 characters; in
	   C99, it was raised to 4095.	C++98 does not specify a normative
	   minimum maximum, so we do not diagnose overlength strings in C++.

	   This option is implied by -Wpedantic, and can be disabled with
	   -Wno-overlength-strings.

       -Wunsuffixed-float-constants (C and Objective-C only)
	   Issue a warning for any floating constant that does not have a
	   suffix.  When used together with -Wsystem-headers it warns about
	   such constants in system header files.  This can be useful when
	   preparing code to use with the "FLOAT_CONST_DECIMAL64" pragma from
	   the decimal floating-point extension to C99.

       -Wno-lto-type-mismatch
	   During the link-time optimization, do not warn about type
	   mismatches in global declarations from different compilation units.
	   Requires -flto to be enabled.  Enabled by default.

       -Wno-designated-init (C and Objective-C only)
	   Suppress warnings when a positional initializer is used to
	   initialize a structure that has been marked with the
	   "designated_init" attribute.

   Options That Control Static Analysis
       -fanalyzer
	   This option enables an static analysis of program flow which looks
	   for "interesting" interprocedural paths through the code, and
	   issues warnings for problems found on them.

	   This analysis is much more expensive than other GCC warnings.

	   In technical terms, it performs coverage-guided symbolic execution
	   of the code being compiled.	It is neither sound nor complete: it
	   can have false positives and false negatives.  It is a bug-finding
	   tool, rather than a tool for proving program correctness.

	   The analyzer is only suitable for use on C code in this release.

	   Enabling this option effectively enables the following warnings:

	   -Wanalyzer-allocation-size -Wanalyzer-deref-before-check
	   -Wanalyzer-double-fclose -Wanalyzer-double-free
	   -Wanalyzer-exposure-through-output-file
	   -Wanalyzer-exposure-through-uninit-copy
	   -Wanalyzer-fd-access-mode-mismatch -Wanalyzer-fd-double-close
	   -Wanalyzer-fd-leak -Wanalyzer-fd-phase-mismatch
	   -Wanalyzer-fd-type-mismatch -Wanalyzer-fd-use-after-close
	   -Wanalyzer-fd-use-without-check -Wanalyzer-file-leak
	   -Wanalyzer-free-of-non-heap -Wanalyzer-imprecise-fp-arithmetic
	   -Wanalyzer-infinite-loop -Wanalyzer-infinite-recursion
	   -Wanalyzer-jump-through-null -Wanalyzer-malloc-leak
	   -Wanalyzer-mismatching-deallocation -Wanalyzer-null-argument
	   -Wanalyzer-null-dereference -Wanalyzer-out-of-bounds
	   -Wanalyzer-overlapping-buffers -Wanalyzer-possible-null-argument
	   -Wanalyzer-possible-null-dereference -Wanalyzer-putenv-of-auto-var
	   -Wanalyzer-shift-count-negative -Wanalyzer-shift-count-overflow
	   -Wanalyzer-stale-setjmp-buffer -Wanalyzer-tainted-allocation-size
	   -Wanalyzer-tainted-array-index -Wanalyzer-tainted-assertion
	   -Wanalyzer-tainted-divisor -Wanalyzer-tainted-offset
	   -Wanalyzer-tainted-size -Wanalyzer-undefined-behavior-strtok
	   -Wanalyzer-unsafe-call-within-signal-handler
	   -Wanalyzer-use-after-free
	   -Wanalyzer-use-of-pointer-in-stale-stack-frame
	   -Wanalyzer-use-of-uninitialized-value
	   -Wanalyzer-va-arg-type-mismatch -Wanalyzer-va-list-exhausted
	   -Wanalyzer-va-list-leak -Wanalyzer-va-list-use-after-va-end
	   -Wanalyzer-write-to-const -Wanalyzer-write-to-string-literal

	   This option is only available if GCC was configured with analyzer
	   support enabled.

       -Wanalyzer-symbol-too-complex
	   If -fanalyzer is enabled, the analyzer uses various heuristics to
	   attempt to track the state of memory, but these can be defeated by
	   sufficiently complicated code.

	   By default, the analysis silently stops tracking values of
	   expressions if they exceed the threshold defined by --param
	   analyzer-max-svalue-depth=value, and falls back to an imprecise
	   representation for such expressions.	 The
	   -Wanalyzer-symbol-too-complex option warns if this occurs.

       -Wanalyzer-too-complex
	   If -fanalyzer is enabled, the analyzer uses various heuristics to
	   attempt to explore the control flow and data flow in the program,
	   but these can be defeated by sufficiently complicated code.

	   By default, the analysis silently stops if the code is too
	   complicated for the analyzer to fully explore and it reaches an
	   internal limit.  The -Wanalyzer-too-complex option warns if this
	   occurs.

       -Wno-analyzer-allocation-size
	   This warning requires -fanalyzer, which enables it; to disable it,
	   use -Wno-analyzer-allocation-size.

	   This diagnostic warns for paths through the code in which a pointer
	   to a buffer is assigned to point at a buffer with a size that is
	   not a multiple of "sizeof (*pointer)".

	   See	CWE-131: Incorrect Calculation of Buffer Size
	   ("https://cwe.mitre.org/data/definitions/131.html").

       -Wno-analyzer-deref-before-check
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-deref-before-check to disable it.

	   This diagnostic warns for paths through the code in which a pointer
	   is checked for "NULL" *after* it has already been dereferenced,
	   suggesting that the pointer could have been NULL.  Such cases
	   suggest that the check for NULL is either redundant, or that it
	   needs to be moved to before the pointer is dereferenced.

	   This diagnostic also considers values passed to a function argument
	   marked with "__attribute__((nonnull))" as requiring a non-NULL
	   value, and thus will complain if such values are checked for "NULL"
	   after returning from such a function call.

	   This diagnostic is unlikely to be reported when any level of
	   optimization is enabled, as GCC's optimization logic will typically
	   consider such checks for NULL as being redundant, and optimize them
	   away before the analyzer "sees" them.  Hence optimization should be
	   disabled when attempting to trigger this diagnostic.

       -Wno-analyzer-double-fclose
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-double-fclose to disable it.

	   This diagnostic warns for paths through the code in which a "FILE
	   *" can have "fclose" called on it more than once.

	   See	CWE-1341: Multiple Releases of Same Resource or Handle
	   ("https://cwe.mitre.org/data/definitions/1341.html").

       -Wno-analyzer-double-free
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-double-free to disable it.

	   This diagnostic warns for paths through the code in which a pointer
	   can have a deallocator called on it more than once, either "free",
	   or a deallocator referenced by attribute "malloc".

	   See	CWE-415: Double Free
	   ("https://cwe.mitre.org/data/definitions/415.html").

       -Wno-analyzer-exposure-through-output-file
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-exposure-through-output-file to disable it.

	   This diagnostic warns for paths through the code in which a
	   security-sensitive value is written to an output file (such as
	   writing a password to a log file).

	   See	CWE-532: Information Exposure Through Log Files
	   ("https://cwe.mitre.org/data/definitions/532.html").

       -Wanalyzer-exposure-through-uninit-copy
	   This warning requires both -fanalyzer and the use of a plugin to
	   specify a function that copies across a "trust boundary".  Use
	   -Wno-analyzer-exposure-through-uninit-copy to disable it.

	   This diagnostic warns for "infoleaks" - paths through the code in
	   which uninitialized values are copied across a security boundary
	   (such as code within an OS kernel that copies a partially-
	   initialized struct on the stack to user space).

	   See	CWE-200: Exposure of Sensitive Information to an Unauthorized
	   Actor ("https://cwe.mitre.org/data/definitions/200.html").

       -Wno-analyzer-fd-access-mode-mismatch
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-fd-access-mode-mismatch to disable it.

	   This diagnostic warns for paths through code in which a "read" on a
	   write-only file descriptor is attempted, or vice versa.

	   This diagnostic also warns for code paths in a which a function
	   with attribute "fd_arg_read (N)" is called with a file descriptor
	   opened with "O_WRONLY" at referenced argument "N" or a function
	   with attribute "fd_arg_write (N)" is called with a file descriptor
	   opened with "O_RDONLY" at referenced argument N.

       -Wno-analyzer-fd-double-close
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-fd-double-close to disable it.

	   This diagnostic warns for paths through code in which a file
	   descriptor can be closed more than once.

	   See	CWE-1341: Multiple Releases of Same Resource or Handle
	   ("https://cwe.mitre.org/data/definitions/1341.html").

       -Wno-analyzer-fd-leak
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-fd-leak to disable it.

	   This diagnostic warns for paths through code in which an open file
	   descriptor is leaked.

	   See	CWE-775: Missing Release of File Descriptor or Handle after
	   Effective Lifetime
	   ("https://cwe.mitre.org/data/definitions/775.html").

       -Wno-analyzer-fd-phase-mismatch
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-fd-phase-mismatch to disable it.

	   This diagnostic warns for paths through code in which an operation
	   is attempted in the wrong phase of a file descriptor's lifetime.
	   For example, it will warn on attempts to call "accept" on a stream
	   socket that has not yet had "listen" successfully called on it.

	   See	CWE-666: Operation on Resource in Wrong Phase of Lifetime
	   ("https://cwe.mitre.org/data/definitions/666.html").

       -Wno-analyzer-fd-type-mismatch
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-fd-type-mismatch to disable it.

	   This diagnostic warns for paths through code in which an operation
	   is attempted on the wrong type of file descriptor.  For example, it
	   will warn on attempts to use socket operations on a file descriptor
	   obtained via "open", or when attempting to use a stream socket
	   operation on a datagram socket.

       -Wno-analyzer-fd-use-after-close
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-fd-use-after-close to disable it.

	   This diagnostic warns for paths through code in which a read or
	   write is called on a closed file descriptor.

	   This diagnostic also warns for paths through code in which a
	   function with attribute "fd_arg (N)" or "fd_arg_read (N)" or
	   "fd_arg_write (N)" is called with a closed file descriptor at
	   referenced argument "N".

       -Wno-analyzer-fd-use-without-check
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-fd-use-without-check to disable it.

	   This diagnostic warns for paths through code in which a file
	   descriptor is used without being checked for validity.

	   This diagnostic also warns for paths through code in which a
	   function with attribute "fd_arg (N)" or "fd_arg_read (N)" or
	   "fd_arg_write (N)" is called with a file descriptor, at referenced
	   argument "N", without being checked for validity.

       -Wno-analyzer-file-leak
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-file-leak to disable it.

	   This diagnostic warns for paths through the code in which a
	   "<stdio.h>" "FILE *" stream object is leaked.

	   See	CWE-775: Missing Release of File Descriptor or Handle after
	   Effective Lifetime
	   ("https://cwe.mitre.org/data/definitions/775.html").

       -Wno-analyzer-free-of-non-heap
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-free-of-non-heap to disable it.

	   This diagnostic warns for paths through the code in which "free" is
	   called on a non-heap pointer (e.g. an on-stack buffer, or a
	   global).

	   See	CWE-590: Free of Memory not on the Heap
	   ("https://cwe.mitre.org/data/definitions/590.html").

       -Wno-analyzer-imprecise-fp-arithmetic
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-imprecise-fp-arithmetic to disable it.

	   This diagnostic warns for paths through the code in which floating-
	   point arithmetic is used in locations where precise computation is
	   needed.  This diagnostic only warns on use of floating-point
	   operands inside the calculation of an allocation size at the
	   moment.

       -Wno-analyzer-infinite-loop
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-infinite-loop to disable it.

	   This diagnostics warns for paths through the code which appear to
	   lead to an infinite loop.

	   Specifically, the analyzer will issue this warning when it "sees" a
	   loop in which:

	   *   no externally-visible work could be being done within the loop

	   *   there is no way to escape from the loop

	   *   the analyzer is sufficiently confident about the program state
	       throughout the loop to know that the above are true

	   One way for this warning to be emitted is when there is an
	   execution path through a loop for which taking the path on one
	   iteration implies that the same path will be taken on all
	   subsequent iterations.

	   For example, consider:

		     while (1)
		       {
			 char opcode = *cpu_state.pc;
			 switch (opcode)
			  {
			  case OPCODE_FOO:
			    handle_opcode_foo (&cpu_state);
			    break;
			  case OPCODE_BAR:
			    handle_opcode_bar (&cpu_state);
			    break;
			  }
		       }

	   The analyzer will complain for the above case because if "opcode"
	   ever matches none of the cases, the "switch" will follow the
	   implicit "default" case, making the body of the loop be a "no-op"
	   with "cpu_state.pc" unchanged, and thus using the same value of
	   "opcode" on all subseqent iterations, leading to an infinite loop.

	   See	CWE-835: Loop with Unreachable Exit Condition ('Infinite
	   Loop') ("https://cwe.mitre.org/data/definitions/835.html").

       -Wno-analyzer-infinite-recursion
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-infinite-recursion to disable it.

	   This diagnostics warns for paths through the code which appear to
	   lead to infinite recursion.

	   Specifically, when the analyzer "sees" a recursive call, it will
	   compare the state of memory at the entry to the new frame with that
	   at the entry to the previous frame of that function on the stack.
	   The warning is issued if nothing in memory appears to be changing;
	   any changes observed to parameters or globals are assumed to lead
	   to termination of the recursion and thus suppress the warning.

	   This diagnostic is likely to miss cases of infinite recursion that
	   are convered to iteration by the optimizer before the analyzer
	   "sees" them.	 Hence optimization should be disabled when attempting
	   to trigger this diagnostic.

	   Compare with -Winfinite-recursion, which provides a similar
	   diagnostic, but is implemented in a different way.

	   See	CWE-674: Uncontrolled Recursion
	   ("https://cwe.mitre.org/data/definitions/674.html").

       -Wno-analyzer-jump-through-null
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-jump-through-null to disable it.

	   This diagnostic warns for paths through the code in which a "NULL"
	   function pointer is called.

       -Wno-analyzer-malloc-leak
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-malloc-leak to disable it.

	   This diagnostic warns for paths through the code in which a pointer
	   allocated via an allocator is leaked: either "malloc", or a
	   function marked with attribute "malloc".

	   See	CWE-401: Missing Release of Memory after Effective Lifetime
	   ("https://cwe.mitre.org/data/definitions/401.html").

       -Wno-analyzer-mismatching-deallocation
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-mismatching-deallocation to disable it.

	   This diagnostic warns for paths through the code in which the wrong
	   deallocation function is called on a pointer value, based on which
	   function was used to allocate the pointer value.  The diagnostic
	   will warn about mismatches between "free", scalar "delete" and
	   vector "delete[]", and those marked as allocator/deallocator pairs
	   using attribute "malloc".

	   See	CWE-762: Mismatched Memory Management Routines
	   ("https://cwe.mitre.org/data/definitions/762.html").

       -Wno-analyzer-out-of-bounds
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-out-of-bounds to disable it.

	   This diagnostic warns for paths through the code in which a buffer
	   is definitely read or written out-of-bounds.	 The diagnostic
	   applies for cases where the analyzer is able to determine a
	   constant offset and for accesses past the end of a buffer, also a
	   constant capacity.  Further, the diagnostic does limited checking
	   for accesses past the end when the offset as well as the capacity
	   is symbolic.

	   See	CWE-119: Improper Restriction of Operations within the Bounds
	   of a Memory Buffer
	   ("https://cwe.mitre.org/data/definitions/119.html").

	   For cases where the analyzer is able, it will emit a text art
	   diagram visualizing the spatial relationship between the memory
	   region that the analyzer predicts would be accessed, versus the
	   range of memory that is valid to access: whether they overlap, are
	   touching, are close or far apart; which one is before or after in
	   memory, the relative sizes involved, the direction of the access
	   (read vs write), and, in some cases, the values of data involved.
	   This diagram can be suppressed using
	   -fdiagnostics-text-art-charset=none.

       -Wno-analyzer-overlapping-buffers
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-overlapping-buffers to disable it.

	   This diagnostic warns for paths through the code in which
	   overlapping buffers are passed to an API for which the behavior on
	   such buffers is undefined.

	   Specifically, the diagnostic occurs on calls to the following
	   functions

	   *<"memcpy">
	   *<"strcat">
	   *<"strcpy">

	   for cases where the buffers are known to overlap.

       -Wno-analyzer-possible-null-argument
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-possible-null-argument to disable it.

	   This diagnostic warns for paths through the code in which a
	   possibly-NULL value is passed to a function argument marked with
	   "__attribute__((nonnull))" as requiring a non-NULL value.

	   See	CWE-690: Unchecked Return Value to NULL Pointer Dereference
	   ("https://cwe.mitre.org/data/definitions/690.html").

       -Wno-analyzer-possible-null-dereference
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-possible-null-dereference to disable it.

	   This diagnostic warns for paths through the code in which a
	   possibly-NULL value is dereferenced.

	   See	CWE-690: Unchecked Return Value to NULL Pointer Dereference
	   ("https://cwe.mitre.org/data/definitions/690.html").

       -Wno-analyzer-null-argument
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-null-argument to disable it.

	   This diagnostic warns for paths through the code in which a value
	   known to be NULL is passed to a function argument marked with
	   "__attribute__((nonnull))" as requiring a non-NULL value.

	   See	CWE-476: NULL Pointer Dereference
	   ("https://cwe.mitre.org/data/definitions/476.html").

       -Wno-analyzer-null-dereference
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-null-dereference to disable it.

	   This diagnostic warns for paths through the code in which a value
	   known to be NULL is dereferenced.

	   See	CWE-476: NULL Pointer Dereference
	   ("https://cwe.mitre.org/data/definitions/476.html").

       -Wno-analyzer-putenv-of-auto-var
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-putenv-of-auto-var to disable it.

	   This diagnostic warns for paths through the code in which a call to
	   "putenv" is passed a pointer to an automatic variable or an on-
	   stack buffer.

	   See	POS34-C. Do not call putenv() with a pointer to an automatic
	   variable as the argument
	   ("https://wiki.sei.cmu.edu/confluence/x/6NYxBQ").

       -Wno-analyzer-shift-count-negative
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-shift-count-negative to disable it.

	   This diagnostic warns for paths through the code in which a shift
	   is attempted with a negative count.	It is analogous to the
	   -Wshift-count-negative diagnostic implemented in the C/C++ front
	   ends, but is implemented based on analyzing interprocedural paths,
	   rather than merely parsing the syntax tree.	However, the analyzer
	   does not prioritize detection of such paths, so false negatives are
	   more likely relative to other warnings.

       -Wno-analyzer-shift-count-overflow
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-shift-count-overflow to disable it.

	   This diagnostic warns for paths through the code in which a shift
	   is attempted with a count greater than or equal to the precision of
	   the operand's type.	It is analogous to the -Wshift-count-overflow
	   diagnostic implemented in the C/C++ front ends, but is implemented
	   based on analyzing interprocedural paths, rather than merely
	   parsing the syntax tree.  However, the analyzer does not prioritize
	   detection of such paths, so false negatives are more likely
	   relative to other warnings.

       -Wno-analyzer-stale-setjmp-buffer
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-stale-setjmp-buffer to disable it.

	   This diagnostic warns for paths through the code in which "longjmp"
	   is called to rewind to a "jmp_buf" relating to a "setjmp" call in a
	   function that has returned.

	   When "setjmp" is called on a "jmp_buf" to record a rewind location,
	   it records the stack frame.	The stack frame becomes invalid when
	   the function containing the "setjmp" call returns.  Attempting to
	   rewind to it via "longjmp" would reference a stack frame that no
	   longer exists, and likely lead to a crash (or worse).

       -Wno-analyzer-tainted-allocation-size
	   This warning requires -fanalyzer which enables it; use
	   -Wno-analyzer-tainted-allocation-size to disable it.

	   This diagnostic warns for paths through the code in which a value
	   that could be under an attacker's control is used as the size of an
	   allocation without being sanitized, so that an attacker could
	   inject an excessively large allocation and potentially cause a
	   denial of service attack.

	   See	CWE-789: Memory Allocation with Excessive Size Value
	   ("https://cwe.mitre.org/data/definitions/789.html").

       -Wno-analyzer-tainted-assertion
	   This warning requires -fanalyzer which enables it; use
	   -Wno-analyzer-tainted-assertion to disable it.

	   This diagnostic warns for paths through the code in which a value
	   that could be under an attacker's control is used as part of a
	   condition without being first sanitized, and that condition guards
	   a call to a function marked with attribute "noreturn" (such as the
	   function "__builtin_unreachable").  Such functions typically
	   indicate abnormal termination of the program, such as for assertion
	   failure handlers.  For example:

		   assert (some_tainted_value < SOME_LIMIT);

	   In such cases:

	   *   when assertion-checking is enabled: an attacker could trigger a
	       denial of service by injecting an assertion failure

	   *   when assertion-checking is disabled, such as by defining
	       "NDEBUG", an attacker could inject data that subverts the
	       process, since it presumably violates a precondition that is
	       being assumed by the code.

	   Note that when assertion-checking is disabled, the assertions are
	   typically removed by the preprocessor before the analyzer has a
	   chance to "see" them, so this diagnostic can only generate warnings
	   on builds in which assertion-checking is enabled.

	   For the purpose of this warning, any function marked with attribute
	   "noreturn" is considered as a possible assertion failure handler,
	   including "__builtin_unreachable".  Note that these functions are
	   sometimes removed by the optimizer before the analyzer "sees" them.
	   Hence optimization should be disabled when attempting to trigger
	   this diagnostic.

	   See	CWE-617: Reachable Assertion
	   ("https://cwe.mitre.org/data/definitions/617.html").

	   The warning can also report problematic constructions such as

		   switch (some_tainted_value) {
		   case 0:
		     /* [...etc; various valid cases omitted...] */
		     break;

		   default:
		     __builtin_unreachable (); /* BUG: attacker can trigger this  */
		   }

	   despite the above not being an assertion failure, strictly
	   speaking.

       -Wno-analyzer-tainted-array-index
	   This warning requires -fanalyzer which enables it; use
	   -Wno-analyzer-tainted-array-index to disable it.

	   This diagnostic warns for paths through the code in which a value
	   that could be under an attacker's control is used as the index of
	   an array access without being sanitized, so that an attacker could
	   inject an out-of-bounds access.

	   See	CWE-129: Improper Validation of Array Index
	   ("https://cwe.mitre.org/data/definitions/129.html").

       -Wno-analyzer-tainted-divisor
	   This warning requires -fanalyzer which enables it; use
	   -Wno-analyzer-tainted-divisor to disable it.

	   This diagnostic warns for paths through the code in which a value
	   that could be under an attacker's control is used as the divisor in
	   a division or modulus operation without being sanitized, so that an
	   attacker could inject a division-by-zero.

	   See	CWE-369: Divide By Zero
	   ("https://cwe.mitre.org/data/definitions/369.html").

       -Wno-analyzer-tainted-offset
	   This warning requires -fanalyzer which enables it; use
	   -Wno-analyzer-tainted-offset to disable it.

	   This diagnostic warns for paths through the code in which a value
	   that could be under an attacker's control is used as a pointer
	   offset without being sanitized, so that an attacker could inject an
	   out-of-bounds access.

	   See	CWE-823: Use of Out-of-range Pointer Offset
	   ("https://cwe.mitre.org/data/definitions/823.html").

       -Wno-analyzer-tainted-size
	   This warning requires -fanalyzer which enables it; use
	   -Wno-analyzer-tainted-size to disable it.

	   This diagnostic warns for paths through the code in which a value
	   that could be under an attacker's control is used as the size of an
	   operation such as "memset" without being sanitized, so that an
	   attacker could inject an out-of-bounds access.

	   See	CWE-129: Improper Validation of Array Index
	   ("https://cwe.mitre.org/data/definitions/129.html").

       -Wno-analyzer-undefined-behavior-strtok
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-undefined-behavior-strtok to disable it.

	   This diagnostic warns for paths through the code in which a call is
	   made to "strtok" with undefined behavior.

	   Specifically, passing NULL as the first parameter for the initial
	   call to "strtok" within a process has undefined behavior.

       -Wno-analyzer-unsafe-call-within-signal-handler
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-unsafe-call-within-signal-handler to disable it.

	   This diagnostic warns for paths through the code in which a
	   function known to be async-signal-unsafe (such as "fprintf") is
	   called from a signal handler.

	   See	CWE-479: Signal Handler Use of a Non-reentrant Function
	   ("https://cwe.mitre.org/data/definitions/479.html").

       -Wno-analyzer-use-after-free
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-use-after-free to disable it.

	   This diagnostic warns for paths through the code in which a pointer
	   is used after a deallocator is called on it: either "free", or a
	   deallocator referenced by attribute "malloc".

	   See	CWE-416: Use After Free
	   ("https://cwe.mitre.org/data/definitions/416.html").

       -Wno-analyzer-use-of-pointer-in-stale-stack-frame
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-use-of-pointer-in-stale-stack-frame to disable it.

	   This diagnostic warns for paths through the code in which a pointer
	   is dereferenced that points to a variable in a stale stack frame.

       -Wno-analyzer-va-arg-type-mismatch
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-va-arg-type-mismatch to disable it.

	   This diagnostic warns for interprocedural paths through the code
	   for which the analyzer detects an attempt to use "va_arg" to
	   extract a value passed to a variadic call, but uses a type that
	   does not match that of the expression passed to the call.

	   See	CWE-686: Function Call With Incorrect Argument Type
	   ("https://cwe.mitre.org/data/definitions/686.html").

       -Wno-analyzer-va-list-exhausted
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-va-list-exhausted to disable it.

	   This diagnostic warns for interprocedural paths through the code
	   for which the analyzer detects an attempt to use "va_arg" to access
	   the next value passed to a variadic call, but all of the values in
	   the "va_list" have already been consumed.

	   See	CWE-685: Function Call With Incorrect Number of Arguments
	   ("https://cwe.mitre.org/data/definitions/685.html").

       -Wno-analyzer-va-list-leak
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-va-list-leak to disable it.

	   This diagnostic warns for interprocedural paths through the code
	   for which the analyzer detects that "va_start" or "va_copy" has
	   been called on a "va_list" without a corresponding call to
	   "va_end".

       -Wno-analyzer-va-list-use-after-va-end
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-va-list-use-after-va-end to disable it.

	   This diagnostic warns for interprocedural paths through the code
	   for which the analyzer detects an attempt to use a "va_list"	 after
	   "va_end" has been called on it.  "va_list".

       -Wno-analyzer-write-to-const
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-write-to-const to disable it.

	   This diagnostic warns for paths through the code in which the
	   analyzer detects an attempt to write through a pointer to a "const"
	   object.  However, the analyzer does not prioritize detection of
	   such paths, so false negatives are more likely relative to other
	   warnings.

       -Wno-analyzer-write-to-string-literal
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-write-to-string-literal to disable it.

	   This diagnostic warns for paths through the code in which the
	   analyzer detects an attempt to write through a pointer to a string
	   literal.  However, the analyzer does not prioritize detection of
	   such paths, so false negatives are more likely relative to other
	   warnings.

       -Wno-analyzer-use-of-uninitialized-value
	   This warning requires -fanalyzer, which enables it; use
	   -Wno-analyzer-use-of-uninitialized-value to disable it.

	   This diagnostic warns for paths through the code in which an
	   uninitialized value is used.

	   See	CWE-457: Use of Uninitialized Variable
	   ("https://cwe.mitre.org/data/definitions/457.html").

       The analyzer has hardcoded knowledge about the behavior of the
       following memory-management functions:

       *<"alloca">
       *<The built-in functions "__builtin_alloc",>
	   "__builtin_alloc_with_align", @item "__builtin_calloc",
	   "__builtin_free", "__builtin_malloc", "__builtin_memcpy",
	   "__builtin_memcpy_chk", "__builtin_memset", "__builtin_memset_chk",
	   "__builtin_realloc", "__builtin_stack_restore", and
	   "__builtin_stack_save"

       *<"calloc">
       *<"free">
       *<"malloc">
       *<"memset">
       *<"operator delete">
       *<"operator delete []">
       *<"operator new">
       *<"operator new []">
       *<"realloc">
       *<"strdup">
       *<"strndup">

       of the following functions for working with file descriptors:

       *<"open">
       *<"close">
       *<"creat">
       *<"dup", "dup2" and "dup3">
       *<"isatty">
       *<"pipe", and "pipe2">
       *<"read">
       *<"write">
       *<"socket", "bind", "listen", "accept", and "connect">

       of the following functions for working with "<stdio.h>" streams:

       *<The built-in functions "__builtin_fprintf",>
	   "__builtin_fprintf_unlocked", "__builtin_fputc",
	   "__builtin_fputc_unlocked", "__builtin_fputs",
	   "__builtin_fputs_unlocked", "__builtin_fwrite",
	   "__builtin_fwrite_unlocked", "__builtin_printf",
	   "__builtin_printf_unlocked", "__builtin_putc", "__builtin_putchar",
	   "__builtin_putchar_unlocked", "__builtin_putc_unlocked",
	   "__builtin_puts", "__builtin_puts_unlocked", "__builtin_vfprintf",
	   and "__builtin_vprintf"

       *<"fopen">
       *<"fclose">
       *<"ferror">
       *<"fgets">
       *<"fgets_unlocked">
       *<"fileno">
       *<"fread">
       *<"getc">
       *<"getchar">
       *<"fprintf">
       *<"printf">
       *<"fwrite">

       and of the following functions:

       *<The built-in functions "__builtin_expect",>
	   "__builtin_expect_with_probability", "__builtin_strchr",
	   "__builtin_strcpy", "__builtin_strcpy_chk", "__builtin_strlen",
	   "__builtin_va_copy", and "__builtin_va_start"

       *<The GNU extensions "error" and "error_at_line">
       *<"getpass">
       *<"longjmp">
       *<"putenv">
       *<"setjmp">
       *<"siglongjmp">
       *<"signal">
       *<"sigsetjmp">
       *<"strcat">
       *<"strchr">
       *<"strlen">

       In addition, various functions with an "__analyzer_" prefix have
       special meaning to the analyzer, described in the GCC Internals manual.

       Pertinent parameters for controlling the exploration are:

       *<--param analyzer-bb-explosion-factor=value>
       *<--param analyzer-max-enodes-per-program-point=value>
       *<--param analyzer-max-recursion-depth=value>
       *<--param analyzer-min-snodes-for-call-summary=value>

       The following options control the analyzer.

       -fanalyzer-call-summaries
	   Simplify interprocedural analysis by computing the effect of
	   certain calls, rather than exploring all paths through the function
	   from callsite to each possible return.

	   If enabled, call summaries are only used for functions with more
	   than one call site, and that are sufficiently complicated (as per
	   --param analyzer-min-snodes-for-call-summary=value).

       -fanalyzer-checker=name
	   Restrict the analyzer to run just the named checker, and enable it.

       -fanalyzer-debug-text-art-headings
	   This option is intended for analyzer developers.  If enabled, the
	   analyzer will add extra annotations to any diagrams it generates.

       -fno-analyzer-feasibility
	   This option is intended for analyzer developers.

	   By default the analyzer verifies that there is a feasible control
	   flow path for each diagnostic it emits: that the conditions that
	   hold are not mutually exclusive.  Diagnostics for which no feasible
	   path can be found are rejected.  This filtering can be suppressed
	   with -fno-analyzer-feasibility, for debugging issues in this code.

       -fanalyzer-fine-grained
	   This option is intended for analyzer developers.

	   Internally the analyzer builds an "exploded graph" that combines
	   control flow graphs with data flow information.

	   By default, an edge in this graph can contain the effects of a run
	   of multiple statements within a basic block.	 With
	   -fanalyzer-fine-grained, each statement gets its own edge.

       -fanalyzer-show-duplicate-count
	   This option is intended for analyzer developers: if multiple
	   diagnostics have been detected as being duplicates of each other,
	   it emits a note when reporting the best diagnostic, giving the
	   number of additional diagnostics that were suppressed by the
	   deduplication logic.

       -fanalyzer-show-events-in-system-headers
	   By default the analyzer emits simplified diagnostics paths by
	   hiding events fully located within a system header.	With
	   -fanalyzer-show-events-in-system-headers such events are no longer
	   suppressed.

       -fno-analyzer-state-merge
	   This option is intended for analyzer developers.

	   By default the analyzer attempts to simplify analysis by merging
	   sufficiently similar states at each program point as it builds its
	   "exploded graph".  With -fno-analyzer-state-merge this merging can
	   be suppressed, for debugging state-handling issues.

       -fno-analyzer-state-purge
	   This option is intended for analyzer developers.

	   By default the analyzer attempts to simplify analysis by purging
	   aspects of state at a program point that appear to no longer be
	   relevant e.g. the values of locals that aren't accessed later in
	   the function and which aren't relevant to leak analysis.

	   With -fno-analyzer-state-purge this purging of state can be
	   suppressed, for debugging state-handling issues.

       -fno-analyzer-suppress-followups
	   This option is intended for analyzer developers.

	   By default the analyzer will stop exploring an execution path after
	   encountering certain diagnostics, in order to avoid potentially
	   issuing a cascade of follow-up diagnostics.

	   The diagnostics that terminate analysis along a path are:

	   *<-Wanalyzer-null-argument>
	   *<-Wanalyzer-null-dereference>
	   *<-Wanalyzer-use-after-free>
	   *<-Wanalyzer-use-of-pointer-in-stale-stack-frame>
	   *<-Wanalyzer-use-of-uninitialized-value>

	   With -fno-analyzer-suppress-followups the analyzer will continue to
	   explore such paths even after such diagnostics, which may be
	   helpful for debugging issues in the analyzer, or for
	   microbenchmarks for detecting undefined behavior.

       -fanalyzer-transitivity
	   This option enables transitivity of constraints within the
	   analyzer.

       -fno-analyzer-undo-inlining
	   This option is intended for analyzer developers.

	   -fanalyzer runs relatively late compared to other code analysis
	   tools, and some optimizations have already been applied to the
	   code.  In particular function inlining may have occurred, leading
	   to the interprocedural execution paths emitted by the analyzer
	   containing function frames that don't correspond to those in the
	   original source code.

	   By default the analyzer attempts to reconstruct the original
	   function frames, and to emit events showing the inlined calls.

	   With -fno-analyzer-undo-inlining this attempt to reconstruct the
	   original frame information can be disabled, which may be of help
	   when debugging issues in the analyzer.

       -fanalyzer-verbose-edges
	   This option is intended for analyzer developers.  It enables more
	   verbose, lower-level detail in the descriptions of control flow
	   within diagnostic paths.

       -fanalyzer-verbose-state-changes
	   This option is intended for analyzer developers.  It enables more
	   verbose, lower-level detail in the descriptions of events relating
	   to state machines within diagnostic paths.

       -fanalyzer-verbosity=level
	   This option controls the complexity of the control flow paths that
	   are emitted for analyzer diagnostics.

	   The level can be one of:

	   0   At this level, interprocedural call and return events are
	       displayed, along with the most pertinent state-change events
	       relating to a diagnostic.  For example, for a double-"free"
	       diagnostic, both calls to "free" will be shown.

	   1   As per the previous level, but also show events for the entry
	       to each function.

	   2   As per the previous level, but also show events relating to
	       control flow that are significant to triggering the issue (e.g.
	       "true path taken" at a conditional).

	       This level is the default.

	   3   As per the previous level, but show all control flow events,
	       not just significant ones.

	   4   This level is intended for analyzer developers; it adds various
	       other events intended for debugging the analyzer.

       -fdump-analyzer
	   Dump internal details about what the analyzer is doing to
	   file.analyzer.txt.  -fdump-analyzer-stderr overrides this option.

       -fdump-analyzer-stderr
	   Dump internal details about what the analyzer is doing to stderr.
	   This option overrides -fdump-analyzer.

       -fdump-analyzer-callgraph
	   Dump a representation of the call graph suitable for viewing with
	   GraphViz to file.callgraph.dot.

       -fdump-analyzer-exploded-graph
	   Dump a representation of the "exploded graph" suitable for viewing
	   with GraphViz to file.eg.dot.  Nodes are color-coded based on
	   state-machine states to emphasize state changes.

       -fdump-analyzer-exploded-nodes
	   Emit diagnostics showing where nodes in the "exploded graph" are in
	   relation to the program source.

       -fdump-analyzer-exploded-nodes-2
	   Dump a textual representation of the "exploded graph" to
	   file.eg.txt.

       -fdump-analyzer-exploded-nodes-3
	   Dump a textual representation of the "exploded graph" to one dump
	   file per node, to file.eg-id.txt.  This is typically a large number
	   of dump files.

       -fdump-analyzer-exploded-paths
	   Dump a textual representation of the "exploded path" for each
	   diagnostic to file.idx.kind.epath.txt.

       -fdump-analyzer-feasibility
	   Dump internal details about the analyzer's search for feasible
	   paths.  The details are written in a form suitable for viewing with
	   GraphViz to filenames of the form file.*.fg.dot, file.*.tg.dot, and
	   file.*.fpath.txt.

       -fdump-analyzer-infinite-loop
	   Dump internal details about the analyzer's search for infinite
	   loops.  The details are written in a form suitable for viewing with
	   GraphViz to filenames of the form file.*.infinite-loop.dot.

       -fdump-analyzer-json
	   Dump a compressed JSON representation of analyzer internals to
	   file.analyzer.json.gz.  The precise format is subject to change.

       -fdump-analyzer-state-purge
	   As per -fdump-analyzer-supergraph, dump a representation of the
	   "supergraph" suitable for viewing with GraphViz, but annotate the
	   graph with information on what state will be purged at each node.
	   The graph is written to file.state-purge.dot.

       -fdump-analyzer-supergraph
	   Dump representations of the "supergraph" suitable for viewing with
	   GraphViz to file.supergraph.dot and to file.supergraph-eg.dot.
	   These show all of the control flow graphs in the program, with
	   interprocedural edges for calls and returns.	 The second dump
	   contains annotations showing nodes in the "exploded graph" and
	   diagnostics associated with them.

       -fdump-analyzer-untracked
	   Emit custom warnings with internal details intended for analyzer
	   developers.

   Options for Debugging Your Program
       To tell GCC to emit extra information for use by a debugger, in almost
       all cases you need only to add -g to your other options.	 Some debug
       formats can co-exist (like DWARF with CTF) when each of them is enabled
       explicitly by adding the respective command line option to your other
       options.

       GCC allows you to use -g with -O.  The shortcuts taken by optimized
       code may occasionally be surprising: some variables you declared may
       not exist at all; flow of control may briefly move where you did not
       expect it; some statements may not be executed because they compute
       constant results or their values are already at hand; some statements
       may execute in different places because they have been moved out of
       loops.  Nevertheless it is possible to debug optimized output.  This
       makes it reasonable to use the optimizer for programs that might have
       bugs.

       If you are not using some other optimization option, consider using -Og
       with -g.	 With no -O option at all, some compiler passes that collect
       information useful for debugging do not run at all, so that -Og may
       result in a better debugging experience.

       -g  Produce debugging information in the operating system's native
	   format (stabs, COFF, XCOFF, or DWARF).  GDB can work with this
	   debugging information.

	   On most systems that use stabs format, -g enables use of extra
	   debugging information that only GDB can use; this extra information
	   makes debugging work better in GDB but probably makes other
	   debuggers crash or refuse to read the program.  If you want to
	   control for certain whether to generate the extra information, use
	   -gvms (see below).

       -ggdb
	   Produce debugging information for use by GDB.  This means to use
	   the most expressive format available (DWARF, stabs, or the native
	   format if neither of those are supported), including GDB extensions
	   if at all possible.

       -gdwarf
       -gdwarf-version
	   Produce debugging information in DWARF format (if that is
	   supported).	The value of version may be either 2, 3, 4 or 5; the
	   default version for most targets is 5 (with the exception of
	   VxWorks, TPF and Darwin / macOS, which default to version 2, and
	   AIX, which defaults to version 4).

	   Note that with DWARF Version 2, some ports require and always use
	   some non-conflicting DWARF 3 extensions in the unwind tables.

	   Version 4 may require GDB 7.0 and -fvar-tracking-assignments for
	   maximum benefit. Version 5 requires GDB 8.0 or higher.

	   GCC no longer supports DWARF Version 1, which is substantially
	   different than Version 2 and later.	For historical reasons, some
	   other DWARF-related options such as -fno-dwarf2-cfi-asm) retain a
	   reference to DWARF Version 2 in their names, but apply to all
	   currently-supported versions of DWARF.

       -gbtf
	   Request BTF debug information.  BTF is the default debugging format
	   for the eBPF target.	 On other targets, like x86, BTF debug
	   information can be generated along with DWARF debug information
	   when both of the debug formats are enabled explicitly via their
	   respective command line options.

       -gctf
       -gctflevel
	   Request CTF debug information and use level to specify how much CTF
	   debug information should be produced.  If -gctf is specified
	   without a value for level, the default level of CTF debug
	   information is 2.

	   CTF debug information can be generated along with DWARF debug
	   information when both of the debug formats are enabled explicitly
	   via their respective command line options.

	   Level 0 produces no CTF debug information at all.  Thus, -gctf0
	   negates -gctf.

	   Level 1 produces CTF information for tracebacks only.  This
	   includes callsite information, but does not include type
	   information.

	   Level 2 produces type information for entities (functions, data
	   objects etc.)  at file-scope or global-scope only.

       -gvms
	   Produce debugging information in Alpha/VMS debug format (if that is
	   supported).	This is the format used by DEBUG on Alpha/VMS systems.

       -gcodeview
	   Produce debugging information in CodeView debug format (if that is
	   supported).	This is the format used by Microsoft Visual C++ on
	   Windows.

       -glevel
       -ggdblevel
       -gvmslevel
	   Request debugging information and also use level to specify how
	   much information.  The default level is 2.

	   Level 0 produces no debug information at all.  Thus, -g0 negates
	   -g.

	   Level 1 produces minimal information, enough for making backtraces
	   in parts of the program that you don't plan to debug.  This
	   includes descriptions of functions and external variables, and line
	   number tables, but no information about local variables.

	   Level 3 includes extra information, such as all the macro
	   definitions present in the program.	Some debuggers support macro
	   expansion when you use -g3.

	   If you use multiple -g options, with or without level numbers, the
	   last such option is the one that is effective.

	   -gdwarf does not accept a concatenated debug level, to avoid
	   confusion with -gdwarf-level.  Instead use an additional -glevel
	   option to change the debug level for DWARF.

       -fno-eliminate-unused-debug-symbols
	   By default, no debug information is produced for symbols that are
	   not actually used. Use this option if you want debug information
	   for all symbols.

       -femit-class-debug-always
	   Instead of emitting debugging information for a C++ class in only
	   one object file, emit it in all object files using the class.  This
	   option should be used only with debuggers that are unable to handle
	   the way GCC normally emits debugging information for classes
	   because using this option increases the size of debugging
	   information by as much as a factor of two.

       -fno-merge-debug-strings
	   Direct the linker to not merge together strings in the debugging
	   information that are identical in different object files.  Merging
	   is not supported by all assemblers or linkers.  Merging decreases
	   the size of the debug information in the output file at the cost of
	   increasing link processing time.  Merging is enabled by default.

       -fdebug-prefix-map=old=new
	   When compiling files residing in directory old, record debugging
	   information describing them as if the files resided in directory
	   new instead.	 This can be used to replace a build-time path with an
	   install-time path in the debug info.	 It can also be used to change
	   an absolute path to a relative path by using . for new.  This can
	   give more reproducible builds, which are location independent, but
	   may require an extra command to tell GDB where to find the source
	   files. See also -ffile-prefix-map and -fcanon-prefix-map.

       -fvar-tracking
	   Run variable tracking pass.	It computes where variables are stored
	   at each position in code.  Better debugging information is then
	   generated (if the debugging information format supports this
	   information).

	   It is enabled by default when compiling with optimization (-Os, -O,
	   -O2, ...), debugging information (-g) and the debug info format
	   supports it.

       -fvar-tracking-assignments
	   Annotate assignments to user variables early in the compilation and
	   attempt to carry the annotations over throughout the compilation
	   all the way to the end, in an attempt to improve debug information
	   while optimizing.  Use of -gdwarf-4 is recommended along with it.

	   It can be enabled even if var-tracking is disabled, in which case
	   annotations are created and maintained, but discarded at the end.
	   By default, this flag is enabled together with -fvar-tracking,
	   except when selective scheduling is enabled.

       -gsplit-dwarf
	   If DWARF debugging information is enabled, separate as much
	   debugging information as possible into a separate output file with
	   the extension .dwo.	This option allows the build system to avoid
	   linking files with debug information.  To be useful, this option
	   requires a debugger capable of reading .dwo files.

       -gdwarf32
       -gdwarf64
	   If DWARF debugging information is enabled, the -gdwarf32 selects
	   the 32-bit DWARF format and the -gdwarf64 selects the 64-bit DWARF
	   format.  The default is target specific, on most targets it is
	   -gdwarf32 though.  The 32-bit DWARF format is smaller, but can't
	   support more than 2GiB of debug information in any of the DWARF
	   debug information sections.	The 64-bit DWARF format allows larger
	   debug information and might not be well supported by all consumers
	   yet.

       -gdescribe-dies
	   Add description attributes to some DWARF DIEs that have no name
	   attribute, such as artificial variables, external references and
	   call site parameter DIEs.

       -gpubnames
	   Generate DWARF ".debug_pubnames" and ".debug_pubtypes" sections.

       -ggnu-pubnames
	   Generate ".debug_pubnames" and ".debug_pubtypes" sections in a
	   format suitable for conversion into a GDB index.  This option is
	   only useful with a linker that can produce GDB index version 7.

       -fdebug-types-section
	   When using DWARF Version 4 or higher, type DIEs can be put into
	   their own ".debug_types" section instead of making them part of the
	   ".debug_info" section.  It is more efficient to put them in a
	   separate comdat section since the linker can then remove
	   duplicates.	But not all DWARF consumers support ".debug_types"
	   sections yet and on some objects ".debug_types" produces larger
	   instead of smaller debugging information.

       -grecord-gcc-switches
       -gno-record-gcc-switches
	   This switch causes the command-line options used to invoke the
	   compiler that may affect code generation to be appended to the
	   DW_AT_producer attribute in DWARF debugging information.  The
	   options are concatenated with spaces separating them from each
	   other and from the compiler version.	 It is enabled by default.
	   See also -frecord-gcc-switches for another way of storing compiler
	   options into the object file.

       -gstrict-dwarf
	   Disallow using extensions of later DWARF standard version than
	   selected with -gdwarf-version.  On most targets using non-
	   conflicting DWARF extensions from later standard versions is
	   allowed.

       -gno-strict-dwarf
	   Allow using extensions of later DWARF standard version than
	   selected with -gdwarf-version.

       -gas-loc-support
	   Inform the compiler that the assembler supports ".loc" directives.
	   It may then use them for the assembler to generate DWARF2+ line
	   number tables.

	   This is generally desirable, because assembler-generated line-
	   number tables are a lot more compact than those the compiler can
	   generate itself.

	   This option will be enabled by default if, at GCC configure time,
	   the assembler was found to support such directives.

       -gno-as-loc-support
	   Force GCC to generate DWARF2+ line number tables internally, if
	   DWARF2+ line number tables are to be generated.

       -gas-locview-support
	   Inform the compiler that the assembler supports "view" assignment
	   and reset assertion checking in ".loc" directives.

	   This option will be enabled by default if, at GCC configure time,
	   the assembler was found to support them.

       -gno-as-locview-support
	   Force GCC to assign view numbers internally, if
	   -gvariable-location-views are explicitly requested.

       -gcolumn-info
       -gno-column-info
	   Emit location column information into DWARF debugging information,
	   rather than just file and line.  This option is enabled by default.

       -gstatement-frontiers
       -gno-statement-frontiers
	   This option causes GCC to create markers in the internal
	   representation at the beginning of statements, and to keep them
	   roughly in place throughout compilation, using them to guide the
	   output of "is_stmt" markers in the line number table.  This is
	   enabled by default when compiling with optimization (-Os, -O1, -O2,
	   ...), and outputting DWARF 2 debug information at the normal level.

       -gvariable-location-views
       -gvariable-location-views=incompat5
       -gno-variable-location-views
	   Augment variable location lists with progressive view numbers
	   implied from the line number table.	This enables debug information
	   consumers to inspect state at certain points of the program, even
	   if no instructions associated with the corresponding source
	   locations are present at that point.	 If the assembler lacks
	   support for view numbers in line number tables, this will cause the
	   compiler to emit the line number table, which generally makes them
	   somewhat less compact.  The augmented line number tables and
	   location lists are fully backward-compatible, so they can be
	   consumed by debug information consumers that are not aware of these
	   augmentations, but they won't derive any benefit from them either.

	   This is enabled by default when outputting DWARF 2 debug
	   information at the normal level, as long as there is assembler
	   support, -fvar-tracking-assignments is enabled and -gstrict-dwarf
	   is not.  When assembler support is not available, this may still be
	   enabled, but it will force GCC to output internal line number
	   tables, and if -ginternal-reset-location-views is not enabled, that
	   will most certainly lead to silently mismatching location views.

	   There is a proposed representation for view numbers that is not
	   backward compatible with the location list format introduced in
	   DWARF 5, that can be enabled with
	   -gvariable-location-views=incompat5.	 This option may be removed in
	   the future, is only provided as a reference implementation of the
	   proposed representation.  Debug information consumers are not
	   expected to support this extended format, and they would be
	   rendered unable to decode location lists using it.

       -ginternal-reset-location-views
       -gno-internal-reset-location-views
	   Attempt to determine location views that can be omitted from
	   location view lists.	 This requires the compiler to have very
	   accurate insn length estimates, which isn't always the case, and it
	   may cause incorrect view lists to be generated silently when using
	   an assembler that does not support location view lists.  The GNU
	   assembler will flag any such error as a "view number mismatch".
	   This is only enabled on ports that define a reliable estimation
	   function.

       -ginline-points
       -gno-inline-points
	   Generate extended debug information for inlined functions.
	   Location view tracking markers are inserted at inlined entry
	   points, so that address and view numbers can be computed and output
	   in debug information.  This can be enabled independently of
	   location views, in which case the view numbers won't be output, but
	   it can only be enabled along with statement frontiers, and it is
	   only enabled by default if location views are enabled.

       -gz[=type]
	   Produce compressed debug sections in DWARF format, if that is
	   supported.  If type is not given, the default type depends on the
	   capabilities of the assembler and linker used.  type may be one of
	   none (don't compress debug sections), or zlib (use zlib compression
	   in ELF gABI format).	 If the linker doesn't support writing
	   compressed debug sections, the option is rejected.  Otherwise, if
	   the assembler does not support them, -gz is silently ignored when
	   producing object files.

       -femit-struct-debug-baseonly
	   Emit debug information for struct-like types only when the base
	   name of the compilation source file matches the base name of file
	   in which the struct is defined.

	   This option substantially reduces the size of debugging
	   information, but at significant potential loss in type information
	   to the debugger.  See -femit-struct-debug-reduced for a less
	   aggressive option.  See -femit-struct-debug-detailed for more
	   detailed control.

	   This option works only with DWARF debug output.

       -femit-struct-debug-reduced
	   Emit debug information for struct-like types only when the base
	   name of the compilation source file matches the base name of file
	   in which the type is defined, unless the struct is a template or
	   defined in a system header.

	   This option significantly reduces the size of debugging
	   information, with some potential loss in type information to the
	   debugger.  See -femit-struct-debug-baseonly for a more aggressive
	   option.  See -femit-struct-debug-detailed for more detailed
	   control.

	   This option works only with DWARF debug output.

       -femit-struct-debug-detailed[=spec-list]
	   Specify the struct-like types for which the compiler generates
	   debug information.  The intent is to reduce duplicate struct debug
	   information between different object files within the same program.

	   This option is a detailed version of -femit-struct-debug-reduced
	   and -femit-struct-debug-baseonly, which serves for most needs.

	   A specification has the
	   syntax[dir:|ind:][ord:|gen:](any|sys|base|none)

	   The optional first word limits the specification to structs that
	   are used directly (dir:) or used indirectly (ind:).	A struct type
	   is used directly when it is the type of a variable, member.
	   Indirect uses arise through pointers to structs.  That is, when use
	   of an incomplete struct is valid, the use is indirect.  An example
	   is struct one direct; struct two * indirect;.

	   The optional second word limits the specification to ordinary
	   structs (ord:) or generic structs (gen:).  Generic structs are a
	   bit complicated to explain.	For C++, these are non-explicit
	   specializations of template classes, or non-template classes within
	   the above.  Other programming languages have generics, but
	   -femit-struct-debug-detailed does not yet implement them.

	   The third word specifies the source files for those structs for
	   which the compiler should emit debug information.  The values none
	   and any have the normal meaning.  The value base means that the
	   base of name of the file in which the type declaration appears must
	   match the base of the name of the main compilation file.  In
	   practice, this means that when compiling foo.c, debug information
	   is generated for types declared in that file and foo.h, but not
	   other header files.	The value sys means those types satisfying
	   base or declared in system or compiler headers.

	   You may need to experiment to determine the best settings for your
	   application.

	   The default is -femit-struct-debug-detailed=all.

	   This option works only with DWARF debug output.

       -fno-dwarf2-cfi-asm
	   Emit DWARF unwind info as compiler generated ".eh_frame" section
	   instead of using GAS ".cfi_*" directives.

       -fno-eliminate-unused-debug-types
	   Normally, when producing DWARF output, GCC avoids producing debug
	   symbol output for types that are nowhere used in the source file
	   being compiled.  Sometimes it is useful to have GCC emit debugging
	   information for all types declared in a compilation unit,
	   regardless of whether or not they are actually used in that
	   compilation unit, for example if, in the debugger, you want to cast
	   a value to a type that is not actually used in your program (but is
	   declared).  More often, however, this results in a significant
	   amount of wasted space.

   Options That Control Optimization
       These options control various sorts of optimizations.

       Without any optimization option, the compiler's goal is to reduce the
       cost of compilation and to make debugging produce the expected results.
       Statements are independent: if you stop the program with a breakpoint
       between statements, you can then assign a new value to any variable or
       change the program counter to any other statement in the function and
       get exactly the results you expect from the source code.

       Turning on optimization flags makes the compiler attempt to improve the
       performance and/or code size at the expense of compilation time and
       possibly the ability to debug the program.

       The compiler performs optimization based on the knowledge it has of the
       program.	 Compiling multiple files at once to a single output file mode
       allows the compiler to use information gained from all of the files
       when compiling each of them.

       Not all optimizations are controlled directly by a flag.	 Only
       optimizations that have a flag are listed in this section.

       Most optimizations are completely disabled at -O0 or if an -O level is
       not set on the command line, even if individual optimization flags are
       specified.  Similarly, -Og suppresses many optimization passes.

       Depending on the target and how GCC was configured, a slightly
       different set of optimizations may be enabled at each -O level than
       those listed here.  You can invoke GCC with -Q --help=optimizers to
       find out the exact set of optimizations that are enabled at each level.

       -O
       -O1 Optimize.  Optimizing compilation takes somewhat more time, and a
	   lot more memory for a large function.

	   With -O, the compiler tries to reduce code size and execution time,
	   without performing any optimizations that take a great deal of
	   compilation time.

	   -O turns on the following optimization flags:

	   -fauto-inc-dec -fbranch-count-reg -fcombine-stack-adjustments
	   -fcompare-elim -fcprop-registers -fdce -fdefer-pop -fdelayed-branch
	   -fdse -fforward-propagate -fguess-branch-probability
	   -fif-conversion -fif-conversion2 -finline-functions-called-once
	   -fipa-modref -fipa-profile -fipa-pure-const -fipa-reference
	   -fipa-reference-addressable -fmerge-constants
	   -fmove-loop-invariants -fmove-loop-stores -fomit-frame-pointer
	   -freorder-blocks -fshrink-wrap -fshrink-wrap-separate
	   -fsplit-wide-types -fssa-backprop -fssa-phiopt -ftree-bit-ccp
	   -ftree-ccp -ftree-ch -ftree-coalesce-vars -ftree-copy-prop
	   -ftree-dce -ftree-dominator-opts -ftree-dse -ftree-forwprop
	   -ftree-fre -ftree-phiprop -ftree-pta -ftree-scev-cprop -ftree-sink
	   -ftree-slsr -ftree-sra -ftree-ter -funit-at-a-time

       -O2 Optimize even more.	GCC performs nearly all supported
	   optimizations that do not involve a space-speed tradeoff.  As
	   compared to -O, this option increases both compilation time and the
	   performance of the generated code.

	   -O2 turns on all optimization flags specified by -O1.  It also
	   turns on the following optimization flags:

	   -falign-functions  -falign-jumps -falign-labels  -falign-loops
	   -fcaller-saves -fcode-hoisting -fcrossjumping -fcse-follow-jumps
	   -fcse-skip-blocks -fdelete-null-pointer-checks -fdevirtualize
	   -fdevirtualize-speculatively -fexpensive-optimizations
	   -ffinite-loops -fgcse  -fgcse-lm -fhoist-adjacent-loads
	   -finline-functions -finline-small-functions -findirect-inlining
	   -fipa-bit-cp	 -fipa-cp  -fipa-icf -fipa-ra  -fipa-sra  -fipa-vrp
	   -fisolate-erroneous-paths-dereference -flra-remat
	   -foptimize-sibling-calls -foptimize-strlen -fpartial-inlining
	   -fpeephole2 -freorder-blocks-algorithm=stc
	   -freorder-blocks-and-partition  -freorder-functions
	   -frerun-cse-after-loop -fschedule-insns  -fschedule-insns2
	   -fsched-interblock  -fsched-spec -fstore-merging -fstrict-aliasing
	   -fthread-jumps -ftree-builtin-call-dce -ftree-loop-vectorize
	   -ftree-pre -ftree-slp-vectorize -ftree-switch-conversion
	   -ftree-tail-merge -ftree-vrp -fvect-cost-model=very-cheap

	   Please note the warning under -fgcse about invoking -O2 on programs
	   that use computed gotos.

       -O3 Optimize yet more.  -O3 turns on all optimizations specified by -O2
	   and also turns on the following optimization flags:

	   -fgcse-after-reload -fipa-cp-clone -floop-interchange
	   -floop-unroll-and-jam -fpeel-loops -fpredictive-commoning
	   -fsplit-loops -fsplit-paths -ftree-loop-distribution
	   -ftree-partial-pre -funswitch-loops -fvect-cost-model=dynamic
	   -fversion-loops-for-strides

       -O0 Reduce compilation time and make debugging produce the expected
	   results.  This is the default.

       -Os Optimize for size.  -Os enables all -O2 optimizations except those
	   that often increase code size:

	   -falign-functions  -falign-jumps -falign-labels  -falign-loops
	   -fprefetch-loop-arrays  -freorder-blocks-algorithm=stc

	   It also enables -finline-functions, causes the compiler to tune for
	   code size rather than execution speed, and performs further
	   optimizations designed to reduce code size.

       -Ofast
	   Disregard strict standards compliance.  -Ofast enables all -O3
	   optimizations.  It also enables optimizations that are not valid
	   for all standard-compliant programs.	 It turns on -ffast-math,
	   -fallow-store-data-races and the Fortran-specific -fstack-arrays,
	   unless -fmax-stack-var-size is specified, and -fno-protect-parens.
	   It turns off -fsemantic-interposition.

       -Og Optimize debugging experience.  -Og should be the optimization
	   level of choice for the standard edit-compile-debug cycle, offering
	   a reasonable level of optimization while maintaining fast
	   compilation and a good debugging experience.	 It is a better choice
	   than -O0 for producing debuggable code because some compiler passes
	   that collect debug information are disabled at -O0.

	   Like -O0, -Og completely disables a number of optimization passes
	   so that individual options controlling them have no effect.
	   Otherwise -Og enables all -O1 optimization flags except for those
	   that may interfere with debugging:

	   -fbranch-count-reg  -fdelayed-branch -fdse  -fif-conversion
	   -fif-conversion2 -finline-functions-called-once
	   -fmove-loop-invariants  -fmove-loop-stores  -fssa-phiopt
	   -ftree-bit-ccp  -ftree-dse  -ftree-pta  -ftree-sra

       -Oz Optimize aggressively for size rather than speed.  This may
	   increase the number of instructions executed if those instructions
	   require fewer bytes to encode.  -Oz behaves similarly to -Os
	   including enabling most -O2 optimizations.

       If you use multiple -O options, with or without level numbers, the last
       such option is the one that is effective.

       Options of the form -fflag specify machine-independent flags.  Most
       flags have both positive and negative forms; the negative form of -ffoo
       is -fno-foo.  In the table below, only one of the forms is listed---the
       one you typically use.  You can figure out the other form by either
       removing no- or adding it.

       The following options control specific optimizations.  They are either
       activated by -O options or are related to ones that are.	 You can use
       the following flags in the rare cases when "fine-tuning" of
       optimizations to be performed is desired.

       -fno-defer-pop
	   For machines that must pop arguments after a function call, always
	   pop the arguments as soon as each function returns.	At levels -O1
	   and higher, -fdefer-pop is the default; this allows the compiler to
	   let arguments accumulate on the stack for several function calls
	   and pop them all at once.

       -fforward-propagate
	   Perform a forward propagation pass on RTL.  The pass tries to
	   combine two instructions and checks if the result can be
	   simplified.	If loop unrolling is active, two passes are performed
	   and the second is scheduled after loop unrolling.

	   This option is enabled by default at optimization levels -O1, -O2,
	   -O3, -Os.

       -ffp-contract=style
	   -ffp-contract=off disables floating-point expression contraction.
	   -ffp-contract=fast enables floating-point expression contraction
	   such as forming of fused multiply-add operations if the target has
	   native support for them.  -ffp-contract=on enables floating-point
	   expression contraction if allowed by the language standard.	This
	   is implemented for C and C++, where it enables contraction within
	   one expression, but not across different statements.

	   The default is -ffp-contract=off for C in a standards compliant
	   mode (-std=c11 or similar), -ffp-contract=fast otherwise.

       -fomit-frame-pointer
	   Omit the frame pointer in functions that don't need one.  This
	   avoids the instructions to save, set up and restore the frame
	   pointer; on many targets it also makes an extra register available.

	   On some targets this flag has no effect because the standard
	   calling sequence always uses a frame pointer, so it cannot be
	   omitted.

	   Note that -fno-omit-frame-pointer doesn't guarantee the frame
	   pointer is used in all functions.  Several targets always omit the
	   frame pointer in leaf functions.

	   Enabled by default at -O1 and higher.

       -foptimize-sibling-calls
	   Optimize sibling and tail recursive calls.

	   Enabled at levels -O2, -O3, -Os.

       -foptimize-strlen
	   Optimize various standard C string functions (e.g. "strlen",
	   "strchr" or "strcpy") and their "_FORTIFY_SOURCE" counterparts into
	   faster alternatives.

	   Enabled at levels -O2, -O3.

       -finline-stringops[=fn]
	   Expand memory and string operations (for now, only "memset")
	   inline, even when the length is variable or big enough as to
	   require looping.  This is most useful along with -ffreestanding and
	   -fno-builtin.

	   In some circumstances, it enables the compiler to generate code
	   that takes advantage of known alignment and length multipliers, but
	   even then it may be less efficient than optimized runtime
	   implementations, and grow code size so much that even a less
	   performant but shared implementation runs faster due to better use
	   of code caches.  This option is disabled by default.

       -fno-inline
	   Do not expand any functions inline apart from those marked with the
	   "always_inline" attribute.  This is the default when not
	   optimizing.

	   Single functions can be exempted from inlining by marking them with
	   the "noinline" attribute.

       -finline-small-functions
	   Integrate functions into their callers when their body is smaller
	   than expected function call code (so overall size of program gets
	   smaller).  The compiler heuristically decides which functions are
	   simple enough to be worth integrating in this way.  This inlining
	   applies to all functions, even those not declared inline.

	   Enabled at levels -O2, -O3, -Os.

       -findirect-inlining
	   Inline also indirect calls that are discovered to be known at
	   compile time thanks to previous inlining.  This option has any
	   effect only when inlining itself is turned on by the
	   -finline-functions or -finline-small-functions options.

	   Enabled at levels -O2, -O3, -Os.

       -finline-functions
	   Consider all functions for inlining, even if they are not declared
	   inline.  The compiler heuristically decides which functions are
	   worth integrating in this way.

	   If all calls to a given function are integrated, and the function
	   is declared "static", then the function is normally not output as
	   assembler code in its own right.

	   Enabled at levels -O2, -O3, -Os.  Also enabled by -fprofile-use and
	   -fauto-profile.

       -finline-functions-called-once
	   Consider all "static" functions called once for inlining into their
	   caller even if they are not marked "inline".	 If a call to a given
	   function is integrated, then the function is not output as
	   assembler code in its own right.

	   Enabled at levels -O1, -O2, -O3 and -Os, but not -Og.

       -fearly-inlining
	   Inline functions marked by "always_inline" and functions whose body
	   seems smaller than the function call overhead early before doing
	   -fprofile-generate instrumentation and real inlining pass.  Doing
	   so makes profiling significantly cheaper and usually inlining
	   faster on programs having large chains of nested wrapper functions.

	   Enabled by default.

       -fipa-sra
	   Perform interprocedural scalar replacement of aggregates, removal
	   of unused parameters and replacement of parameters passed by
	   reference by parameters passed by value.

	   Enabled at levels -O2, -O3 and -Os.

       -finline-limit=n
	   By default, GCC limits the size of functions that can be inlined.
	   This flag allows coarse control of this limit.  n is the size of
	   functions that can be inlined in number of pseudo instructions.

	   Inlining is actually controlled by a number of parameters, which
	   may be specified individually by using --param name=value.  The
	   -finline-limit=n option sets some of these parameters as follows:

	   max-inline-insns-single
	       is set to n/2.

	   max-inline-insns-auto
	       is set to n/2.

	   See below for a documentation of the individual parameters
	   controlling inlining and for the defaults of these parameters.

	   Note: there may be no value to -finline-limit that results in
	   default behavior.

	   Note: pseudo instruction represents, in this particular context, an
	   abstract measurement of function's size.  In no way does it
	   represent a count of assembly instructions and as such its exact
	   meaning might change from one release to an another.

       -fno-keep-inline-dllexport
	   This is a more fine-grained version of -fkeep-inline-functions,
	   which applies only to functions that are declared using the
	   "dllexport" attribute or declspec.

       -fkeep-inline-functions
	   In C, emit "static" functions that are declared "inline" into the
	   object file, even if the function has been inlined into all of its
	   callers.  This switch does not affect functions using the "extern
	   inline" extension in GNU C90.  In C++, emit any and all inline
	   functions into the object file.

       -fkeep-static-functions
	   Emit "static" functions into the object file, even if the function
	   is never used.

       -fkeep-static-consts
	   Emit variables declared "static const" when optimization isn't
	   turned on, even if the variables aren't referenced.

	   GCC enables this option by default.	If you want to force the
	   compiler to check if a variable is referenced, regardless of
	   whether or not optimization is turned on, use the
	   -fno-keep-static-consts option.

       -fmerge-constants
	   Attempt to merge identical constants (string constants and
	   floating-point constants) across compilation units.

	   This option is the default for optimized compilation if the
	   assembler and linker support it.  Use -fno-merge-constants to
	   inhibit this behavior.

	   Enabled at levels -O1, -O2, -O3, -Os.

       -fmerge-all-constants
	   Attempt to merge identical constants and identical variables.

	   This option implies -fmerge-constants.  In addition to
	   -fmerge-constants this considers e.g. even constant initialized
	   arrays or initialized constant variables with integral or floating-
	   point types.	 Languages like C or C++ require each variable,
	   including multiple instances of the same variable in recursive
	   calls, to have distinct locations, so using this option results in
	   non-conforming behavior.

       -fmodulo-sched
	   Perform swing modulo scheduling immediately before the first
	   scheduling pass.  This pass looks at innermost loops and reorders
	   their instructions by overlapping different iterations.

       -fmodulo-sched-allow-regmoves
	   Perform more aggressive SMS-based modulo scheduling with register
	   moves allowed.  By setting this flag certain anti-dependences edges
	   are deleted, which triggers the generation of reg-moves based on
	   the life-range analysis.  This option is effective only with
	   -fmodulo-sched enabled.

       -fno-branch-count-reg
	   Disable the optimization pass that scans for opportunities to use
	   "decrement and branch" instructions on a count register instead of
	   instruction sequences that decrement a register, compare it against
	   zero, and then branch based upon the result.	 This option is only
	   meaningful on architectures that support such instructions, which
	   include x86, PowerPC, IA-64 and S/390.  Note that the
	   -fno-branch-count-reg option doesn't remove the decrement and
	   branch instructions from the generated instruction stream
	   introduced by other optimization passes.

	   The default is -fbranch-count-reg at -O1 and higher, except for
	   -Og.

       -fno-function-cse
	   Do not put function addresses in registers; make each instruction
	   that calls a constant function contain the function's address
	   explicitly.

	   This option results in less efficient code, but some strange hacks
	   that alter the assembler output may be confused by the
	   optimizations performed when this option is not used.

	   The default is -ffunction-cse

       -fno-zero-initialized-in-bss
	   If the target supports a BSS section, GCC by default puts variables
	   that are initialized to zero into BSS.  This can save space in the
	   resulting code.

	   This option turns off this behavior because some programs
	   explicitly rely on variables going to the data section---e.g., so
	   that the resulting executable can find the beginning of that
	   section and/or make assumptions based on that.

	   The default is -fzero-initialized-in-bss.

       -fthread-jumps
	   Perform optimizations that check to see if a jump branches to a
	   location where another comparison subsumed by the first is found.
	   If so, the first branch is redirected to either the destination of
	   the second branch or a point immediately following it, depending on
	   whether the condition is known to be true or false.

	   Enabled at levels -O1, -O2, -O3, -Os.

       -fsplit-wide-types
	   When using a type that occupies multiple registers, such as "long
	   long" on a 32-bit system, split the registers apart and allocate
	   them independently.	This normally generates better code for those
	   types, but may make debugging more difficult.

	   Enabled at levels -O1, -O2, -O3, -Os.

       -fsplit-wide-types-early
	   Fully split wide types early, instead of very late.	This option
	   has no effect unless -fsplit-wide-types is turned on.

	   This is the default on some targets.

       -fcse-follow-jumps
	   In common subexpression elimination (CSE), scan through jump
	   instructions when the target of the jump is not reached by any
	   other path.	For example, when CSE encounters an "if" statement
	   with an "else" clause, CSE follows the jump when the condition
	   tested is false.

	   Enabled at levels -O2, -O3, -Os.

       -fcse-skip-blocks
	   This is similar to -fcse-follow-jumps, but causes CSE to follow
	   jumps that conditionally skip over blocks.  When CSE encounters a
	   simple "if" statement with no else clause, -fcse-skip-blocks causes
	   CSE to follow the jump around the body of the "if".

	   Enabled at levels -O2, -O3, -Os.

       -frerun-cse-after-loop
	   Re-run common subexpression elimination after loop optimizations
	   are performed.

	   Enabled at levels -O2, -O3, -Os.

       -fgcse
	   Perform a global common subexpression elimination pass.  This pass
	   also performs global constant and copy propagation.

	   Note: When compiling a program using computed gotos, a GCC
	   extension, you may get better run-time performance if you disable
	   the global common subexpression elimination pass by adding
	   -fno-gcse to the command line.

	   Enabled at levels -O2, -O3, -Os.

       -fgcse-lm
	   When -fgcse-lm is enabled, global common subexpression elimination
	   attempts to move loads that are only killed by stores into
	   themselves.	This allows a loop containing a load/store sequence to
	   be changed to a load outside the loop, and a copy/store within the
	   loop.

	   Enabled by default when -fgcse is enabled.

       -fgcse-sm
	   When -fgcse-sm is enabled, a store motion pass is run after global
	   common subexpression elimination.  This pass attempts to move
	   stores out of loops.	 When used in conjunction with -fgcse-lm,
	   loops containing a load/store sequence can be changed to a load
	   before the loop and a store after the loop.

	   Not enabled at any optimization level.

       -fgcse-las
	   When -fgcse-las is enabled, the global common subexpression
	   elimination pass eliminates redundant loads that come after stores
	   to the same memory location (both partial and full redundancies).

	   Not enabled at any optimization level.

       -fgcse-after-reload
	   When -fgcse-after-reload is enabled, a redundant load elimination
	   pass is performed after reload.  The purpose of this pass is to
	   clean up redundant spilling.

	   Enabled by -O3, -fprofile-use and -fauto-profile.

       -faggressive-loop-optimizations
	   This option tells the loop optimizer to use language constraints to
	   derive bounds for the number of iterations of a loop.  This assumes
	   that loop code does not invoke undefined behavior by for example
	   causing signed integer overflows or out-of-bound array accesses.
	   The bounds for the number of iterations of a loop are used to guide
	   loop unrolling and peeling and loop exit test optimizations.	 This
	   option is enabled by default.

       -funconstrained-commons
	   This option tells the compiler that variables declared in common
	   blocks (e.g. Fortran) may later be overridden with longer trailing
	   arrays. This prevents certain optimizations that depend on knowing
	   the array bounds.

       -fcrossjumping
	   Perform cross-jumping transformation.  This transformation unifies
	   equivalent code and saves code size.	 The resulting code may or may
	   not perform better than without cross-jumping.

	   Enabled at levels -O2, -O3, -Os.

       -fauto-inc-dec
	   Combine increments or decrements of addresses with memory accesses.
	   This pass is always skipped on architectures that do not have
	   instructions to support this.  Enabled by default at -O1 and higher
	   on architectures that support this.

       -fdce
	   Perform dead code elimination (DCE) on RTL.	Enabled by default at
	   -O1 and higher.

       -fdse
	   Perform dead store elimination (DSE) on RTL.	 Enabled by default at
	   -O1 and higher.

       -fif-conversion
	   Attempt to transform conditional jumps into branch-less
	   equivalents.	 This includes use of conditional moves, min, max, set
	   flags and abs instructions, and some tricks doable by standard
	   arithmetics.	 The use of conditional execution on chips where it is
	   available is controlled by -fif-conversion2.

	   Enabled at levels -O1, -O2, -O3, -Os, but not with -Og.

       -fif-conversion2
	   Use conditional execution (where available) to transform
	   conditional jumps into branch-less equivalents.

	   Enabled at levels -O1, -O2, -O3, -Os, but not with -Og.

       -fdeclone-ctor-dtor
	   The C++ ABI requires multiple entry points for constructors and
	   destructors: one for a base subobject, one for a complete object,
	   and one for a virtual destructor that calls operator delete
	   afterwards.	For a hierarchy with virtual bases, the base and
	   complete variants are clones, which means two copies of the
	   function.  With this option, the base and complete variants are
	   changed to be thunks that call a common implementation.

	   Enabled by -Os.

       -fdelete-null-pointer-checks
	   Assume that programs cannot safely dereference null pointers, and
	   that no code or data element resides at address zero.  This option
	   enables simple constant folding optimizations at all optimization
	   levels.  In addition, other optimization passes in GCC use this
	   flag to control global dataflow analyses that eliminate useless
	   checks for null pointers; these assume that a memory access to
	   address zero always results in a trap, so that if a pointer is
	   checked after it has already been dereferenced, it cannot be null.

	   Note however that in some environments this assumption is not true.
	   Use -fno-delete-null-pointer-checks to disable this optimization
	   for programs that depend on that behavior.

	   This option is enabled by default on most targets.  On Nios II ELF,
	   it defaults to off.	On AVR and MSP430, this option is completely
	   disabled.

	   Passes that use the dataflow information are enabled independently
	   at different optimization levels.

       -fdevirtualize
	   Attempt to convert calls to virtual functions to direct calls.
	   This is done both within a procedure and interprocedurally as part
	   of indirect inlining (-findirect-inlining) and interprocedural
	   constant propagation (-fipa-cp).  Enabled at levels -O2, -O3, -Os.

       -fdevirtualize-speculatively
	   Attempt to convert calls to virtual functions to speculative direct
	   calls.  Based on the analysis of the type inheritance graph,
	   determine for a given call the set of likely targets. If the set is
	   small, preferably of size 1, change the call into a conditional
	   deciding between direct and indirect calls.	The speculative calls
	   enable more optimizations, such as inlining.	 When they seem
	   useless after further optimization, they are converted back into
	   original form.

       -fdevirtualize-at-ltrans
	   Stream extra information needed for aggressive devirtualization
	   when running the link-time optimizer in local transformation mode.
	   This option enables more devirtualization but significantly
	   increases the size of streamed data. For this reason it is disabled
	   by default.

       -fexpensive-optimizations
	   Perform a number of minor optimizations that are relatively
	   expensive.

	   Enabled at levels -O2, -O3, -Os.

       -free
	   Attempt to remove redundant extension instructions.	This is
	   especially helpful for the x86-64 architecture, which implicitly
	   zero-extends in 64-bit registers after writing to their lower
	   32-bit half.

	   Enabled for Alpha, AArch64, LoongArch, PowerPC, RISC-V, SPARC,
	   h83000 and x86 at levels -O2, -O3, -Os.

       -fno-lifetime-dse
	   In C++ the value of an object is only affected by changes within
	   its lifetime: when the constructor begins, the object has an
	   indeterminate value, and any changes during the lifetime of the
	   object are dead when the object is destroyed.  Normally dead store
	   elimination will take advantage of this; if your code relies on the
	   value of the object storage persisting beyond the lifetime of the
	   object, you can use this flag to disable this optimization.	To
	   preserve stores before the constructor starts (e.g. because your
	   operator new clears the object storage) but still treat the object
	   as dead after the destructor, you can use -flifetime-dse=1.	The
	   default behavior can be explicitly selected with -flifetime-dse=2.
	   -flifetime-dse=0 is equivalent to -fno-lifetime-dse.

       -flive-range-shrinkage
	   Attempt to decrease register pressure through register live range
	   shrinkage.  This is helpful for fast processors with small or
	   moderate size register sets.

       -fira-algorithm=algorithm
	   Use the specified coloring algorithm for the integrated register
	   allocator.  The algorithm argument can be priority, which specifies
	   Chow's priority coloring, or CB, which specifies Chaitin-Briggs
	   coloring.  Chaitin-Briggs coloring is not implemented for all
	   architectures, but for those targets that do support it, it is the
	   default because it generates better code.

       -fira-region=region
	   Use specified regions for the integrated register allocator.	 The
	   region argument should be one of the following:

	   all Use all loops as register allocation regions.  This can give
	       the best results for machines with a small and/or irregular
	       register set.

	   mixed
	       Use all loops except for loops with small register pressure as
	       the regions.  This value usually gives the best results in most
	       cases and for most architectures, and is enabled by default
	       when compiling with optimization for speed (-O, -O2, ...).

	   one Use all functions as a single region.  This typically results
	       in the smallest code size, and is enabled by default for -Os or
	       -O0.

       -fira-hoist-pressure
	   Use IRA to evaluate register pressure in the code hoisting pass for
	   decisions to hoist expressions.  This option usually results in
	   smaller code, but it can slow the compiler down.

	   This option is enabled at level -Os for all targets.

       -fira-loop-pressure
	   Use IRA to evaluate register pressure in loops for decisions to
	   move loop invariants.  This option usually results in generation of
	   faster and smaller code on machines with large register files (>=
	   32 registers), but it can slow the compiler down.

	   This option is enabled at level -O3 for some targets.

       -fno-ira-share-save-slots
	   Disable sharing of stack slots used for saving call-used hard
	   registers living through a call.  Each hard register gets a
	   separate stack slot, and as a result function stack frames are
	   larger.

       -fno-ira-share-spill-slots
	   Disable sharing of stack slots allocated for pseudo-registers.
	   Each pseudo-register that does not get a hard register gets a
	   separate stack slot, and as a result function stack frames are
	   larger.

       -flra-remat
	   Enable CFG-sensitive rematerialization in LRA.  Instead of loading
	   values of spilled pseudos, LRA tries to rematerialize (recalculate)
	   values if it is profitable.

	   Enabled at levels -O2, -O3, -Os.

       -fdelayed-branch
	   If supported for the target machine, attempt to reorder
	   instructions to exploit instruction slots available after delayed
	   branch instructions.

	   Enabled at levels -O1, -O2, -O3, -Os, but not at -Og.

       -fschedule-insns
	   If supported for the target machine, attempt to reorder
	   instructions to eliminate execution stalls due to required data
	   being unavailable.  This helps machines that have slow floating
	   point or memory load instructions by allowing other instructions to
	   be issued until the result of the load or floating-point
	   instruction is required.

	   Enabled at levels -O2, -O3.

       -fschedule-insns2
	   Similar to -fschedule-insns, but requests an additional pass of
	   instruction scheduling after register allocation has been done.
	   This is especially useful on machines with a relatively small
	   number of registers and where memory load instructions take more
	   than one cycle.

	   Enabled at levels -O2, -O3, -Os.

       -fno-sched-interblock
	   Disable instruction scheduling across basic blocks, which is
	   normally enabled when scheduling before register allocation, i.e.
	   with -fschedule-insns or at -O2 or higher.

       -fno-sched-spec
	   Disable speculative motion of non-load instructions, which is
	   normally enabled when scheduling before register allocation, i.e.
	   with -fschedule-insns or at -O2 or higher.

       -fsched-pressure
	   Enable register pressure sensitive insn scheduling before register
	   allocation.	This only makes sense when scheduling before register
	   allocation is enabled, i.e. with -fschedule-insns or at -O2 or
	   higher.  Usage of this option can improve the generated code and
	   decrease its size by preventing register pressure increase above
	   the number of available hard registers and subsequent spills in
	   register allocation.

       -fsched-spec-load
	   Allow speculative motion of some load instructions.	This only
	   makes sense when scheduling before register allocation, i.e. with
	   -fschedule-insns or at -O2 or higher.

       -fsched-spec-load-dangerous
	   Allow speculative motion of more load instructions.	This only
	   makes sense when scheduling before register allocation, i.e. with
	   -fschedule-insns or at -O2 or higher.

       -fsched-stalled-insns
       -fsched-stalled-insns=n
	   Define how many insns (if any) can be moved prematurely from the
	   queue of stalled insns into the ready list during the second
	   scheduling pass.  -fno-sched-stalled-insns means that no insns are
	   moved prematurely, -fsched-stalled-insns=0 means there is no limit
	   on how many queued insns can be moved prematurely.
	   -fsched-stalled-insns without a value is equivalent to
	   -fsched-stalled-insns=1.

       -fsched-stalled-insns-dep
       -fsched-stalled-insns-dep=n
	   Define how many insn groups (cycles) are examined for a dependency
	   on a stalled insn that is a candidate for premature removal from
	   the queue of stalled insns.	This has an effect only during the
	   second scheduling pass, and only if -fsched-stalled-insns is used.
	   -fno-sched-stalled-insns-dep is equivalent to
	   -fsched-stalled-insns-dep=0.	 -fsched-stalled-insns-dep without a
	   value is equivalent to -fsched-stalled-insns-dep=1.

       -fsched2-use-superblocks
	   When scheduling after register allocation, use superblock
	   scheduling.	This allows motion across basic block boundaries,
	   resulting in faster schedules.  This option is experimental, as not
	   all machine descriptions used by GCC model the CPU closely enough
	   to avoid unreliable results from the algorithm.

	   This only makes sense when scheduling after register allocation,
	   i.e. with -fschedule-insns2 or at -O2 or higher.

       -fsched-group-heuristic
	   Enable the group heuristic in the scheduler.	 This heuristic favors
	   the instruction that belongs to a schedule group.  This is enabled
	   by default when scheduling is enabled, i.e. with -fschedule-insns
	   or -fschedule-insns2 or at -O2 or higher.

       -fsched-critical-path-heuristic
	   Enable the critical-path heuristic in the scheduler.	 This
	   heuristic favors instructions on the critical path.	This is
	   enabled by default when scheduling is enabled, i.e. with
	   -fschedule-insns or -fschedule-insns2 or at -O2 or higher.

       -fsched-spec-insn-heuristic
	   Enable the speculative instruction heuristic in the scheduler.
	   This heuristic favors speculative instructions with greater
	   dependency weakness.	 This is enabled by default when scheduling is
	   enabled, i.e.  with -fschedule-insns or -fschedule-insns2 or at -O2
	   or higher.

       -fsched-rank-heuristic
	   Enable the rank heuristic in the scheduler.	This heuristic favors
	   the instruction belonging to a basic block with greater size or
	   frequency.  This is enabled by default when scheduling is enabled,
	   i.e.	 with -fschedule-insns or -fschedule-insns2 or at -O2 or
	   higher.

       -fsched-last-insn-heuristic
	   Enable the last-instruction heuristic in the scheduler.  This
	   heuristic favors the instruction that is less dependent on the last
	   instruction scheduled.  This is enabled by default when scheduling
	   is enabled, i.e. with -fschedule-insns or -fschedule-insns2 or at
	   -O2 or higher.

       -fsched-dep-count-heuristic
	   Enable the dependent-count heuristic in the scheduler.  This
	   heuristic favors the instruction that has more instructions
	   depending on it.  This is enabled by default when scheduling is
	   enabled, i.e.  with -fschedule-insns or -fschedule-insns2 or at -O2
	   or higher.

       -freschedule-modulo-scheduled-loops
	   Modulo scheduling is performed before traditional scheduling.  If a
	   loop is modulo scheduled, later scheduling passes may change its
	   schedule.  Use this option to control that behavior.

       -fselective-scheduling
	   Schedule instructions using selective scheduling algorithm.
	   Selective scheduling runs instead of the first scheduler pass.

       -fselective-scheduling2
	   Schedule instructions using selective scheduling algorithm.
	   Selective scheduling runs instead of the second scheduler pass.

       -fsel-sched-pipelining
	   Enable software pipelining of innermost loops during selective
	   scheduling.	This option has no effect unless one of
	   -fselective-scheduling or -fselective-scheduling2 is turned on.

       -fsel-sched-pipelining-outer-loops
	   When pipelining loops during selective scheduling, also pipeline
	   outer loops.	 This option has no effect unless
	   -fsel-sched-pipelining is turned on.

       -fsemantic-interposition
	   Some object formats, like ELF, allow interposing of symbols by the
	   dynamic linker.  This means that for symbols exported from the DSO,
	   the compiler cannot perform interprocedural propagation, inlining
	   and other optimizations in anticipation that the function or
	   variable in question may change. While this feature is useful, for
	   example, to rewrite memory allocation functions by a debugging
	   implementation, it is expensive in the terms of code quality.  With
	   -fno-semantic-interposition the compiler assumes that if
	   interposition happens for functions the overwriting function will
	   have precisely the same semantics (and side effects).  Similarly if
	   interposition happens for variables, the constructor of the
	   variable will be the same. The flag has no effect for functions
	   explicitly declared inline (where it is never allowed for
	   interposition to change semantics) and for symbols explicitly
	   declared weak.

       -fshrink-wrap
	   Emit function prologues only before parts of the function that need
	   it, rather than at the top of the function.	This flag is enabled
	   by default at -O and higher.

       -fshrink-wrap-separate
	   Shrink-wrap separate parts of the prologue and epilogue separately,
	   so that those parts are only executed when needed.  This option is
	   on by default, but has no effect unless -fshrink-wrap is also
	   turned on and the target supports this.

       -fcaller-saves
	   Enable allocation of values to registers that are clobbered by
	   function calls, by emitting extra instructions to save and restore
	   the registers around such calls.  Such allocation is done only when
	   it seems to result in better code.

	   This option is always enabled by default on certain machines,
	   usually those which have no call-preserved registers to use
	   instead.

	   Enabled at levels -O2, -O3, -Os.

       -fcombine-stack-adjustments
	   Tracks stack adjustments (pushes and pops) and stack memory
	   references and then tries to find ways to combine them.

	   Enabled by default at -O1 and higher.

       -fipa-ra
	   Use caller save registers for allocation if those registers are not
	   used by any called function.	 In that case it is not necessary to
	   save and restore them around calls.	This is only possible if
	   called functions are part of same compilation unit as current
	   function and they are compiled before it.

	   Enabled at levels -O2, -O3, -Os, however the option is disabled if
	   generated code will be instrumented for profiling (-p, or -pg) or
	   if callee's register usage cannot be known exactly (this happens on
	   targets that do not expose prologues and epilogues in RTL).

       -fconserve-stack
	   Attempt to minimize stack usage.  The compiler attempts to use less
	   stack space, even if that makes the program slower.	This option
	   implies setting the large-stack-frame parameter to 100 and the
	   large-stack-frame-growth parameter to 400.

       -ftree-reassoc
	   Perform reassociation on trees.  This flag is enabled by default at
	   -O1 and higher.

       -fcode-hoisting
	   Perform code hoisting.  Code hoisting tries to move the evaluation
	   of expressions executed on all paths to the function exit as early
	   as possible.	 This is especially useful as a code size
	   optimization, but it often helps for code speed as well.  This flag
	   is enabled by default at -O2 and higher.

       -ftree-pre
	   Perform partial redundancy elimination (PRE) on trees.  This flag
	   is enabled by default at -O2 and -O3.

       -ftree-partial-pre
	   Make partial redundancy elimination (PRE) more aggressive.  This
	   flag is enabled by default at -O3.

       -ftree-forwprop
	   Perform forward propagation on trees.  This flag is enabled by
	   default at -O1 and higher.

       -ftree-fre
	   Perform full redundancy elimination (FRE) on trees.	The difference
	   between FRE and PRE is that FRE only considers expressions that are
	   computed on all paths leading to the redundant computation.	This
	   analysis is faster than PRE, though it exposes fewer redundancies.
	   This flag is enabled by default at -O1 and higher.

       -ftree-phiprop
	   Perform hoisting of loads from conditional pointers on trees.  This
	   pass is enabled by default at -O1 and higher.

       -fhoist-adjacent-loads
	   Speculatively hoist loads from both branches of an if-then-else if
	   the loads are from adjacent locations in the same structure and the
	   target architecture has a conditional move instruction.  This flag
	   is enabled by default at -O2 and higher.

       -ftree-copy-prop
	   Perform copy propagation on trees.  This pass eliminates
	   unnecessary copy operations.	 This flag is enabled by default at
	   -O1 and higher.

       -fipa-pure-const
	   Discover which functions are pure or constant.  Enabled by default
	   at -O1 and higher.

       -fipa-reference
	   Discover which static variables do not escape the compilation unit.
	   Enabled by default at -O1 and higher.

       -fipa-reference-addressable
	   Discover read-only, write-only and non-addressable static
	   variables.  Enabled by default at -O1 and higher.

       -fipa-stack-alignment
	   Reduce stack alignment on call sites if possible.  Enabled by
	   default.

       -fipa-pta
	   Perform interprocedural pointer analysis and interprocedural
	   modification and reference analysis.	 This option can cause
	   excessive memory and compile-time usage on large compilation units.
	   It is not enabled by default at any optimization level.

       -fipa-profile
	   Perform interprocedural profile propagation.	 The functions called
	   only from cold functions are marked as cold. Also functions
	   executed once (such as "cold", "noreturn", static constructors or
	   destructors) are identified. Cold functions and loop less parts of
	   functions executed once are then optimized for size.	 Enabled by
	   default at -O1 and higher.

       -fipa-modref
	   Perform interprocedural mod/ref analysis.  This optimization
	   analyzes the side effects of functions (memory locations that are
	   modified or referenced) and enables better optimization across the
	   function call boundary.  This flag is enabled by default at -O1 and
	   higher.

       -fipa-cp
	   Perform interprocedural constant propagation.  This optimization
	   analyzes the program to determine when values passed to functions
	   are constants and then optimizes accordingly.  This optimization
	   can substantially increase performance if the application has
	   constants passed to functions.  This flag is enabled by default at
	   -O2, -Os and -O3.  It is also enabled by -fprofile-use and
	   -fauto-profile.

       -fipa-cp-clone
	   Perform function cloning to make interprocedural constant
	   propagation stronger.  When enabled, interprocedural constant
	   propagation performs function cloning when externally visible
	   function can be called with constant arguments.  Because this
	   optimization can create multiple copies of functions, it may
	   significantly increase code size (see --param
	   ipa-cp-unit-growth=value).  This flag is enabled by default at -O3.
	   It is also enabled by -fprofile-use and -fauto-profile.

       -fipa-bit-cp
	   When enabled, perform interprocedural bitwise constant propagation.
	   This flag is enabled by default at -O2 and by -fprofile-use and
	   -fauto-profile.  It requires that -fipa-cp is enabled.

       -fipa-vrp
	   When enabled, perform interprocedural propagation of value ranges.
	   This flag is enabled by default at -O2. It requires that -fipa-cp
	   is enabled.

       -fipa-icf
	   Perform Identical Code Folding for functions and read-only
	   variables.  The optimization reduces code size and may disturb
	   unwind stacks by replacing a function by equivalent one with a
	   different name. The optimization works more effectively with link-
	   time optimization enabled.

	   Although the behavior is similar to the Gold Linker's ICF
	   optimization, GCC ICF works on different levels and thus the
	   optimizations are not same - there are equivalences that are found
	   only by GCC and equivalences found only by Gold.

	   This flag is enabled by default at -O2 and -Os.

       -flive-patching=level
	   Control GCC's optimizations to produce output suitable for live-
	   patching.

	   If the compiler's optimization uses a function's body or
	   information extracted from its body to optimize/change another
	   function, the latter is called an impacted function of the former.
	   If a function is patched, its impacted functions should be patched
	   too.

	   The impacted functions are determined by the compiler's
	   interprocedural optimizations.  For example, a caller is impacted
	   when inlining a function into its caller, cloning a function and
	   changing its caller to call this new clone, or extracting a
	   function's pureness/constness information to optimize its direct or
	   indirect callers, etc.

	   Usually, the more IPA optimizations enabled, the larger the number
	   of impacted functions for each function.  In order to control the
	   number of impacted functions and more easily compute the list of
	   impacted function, IPA optimizations can be partially enabled at
	   two different levels.

	   The level argument should be one of the following:

	   inline-clone
	       Only enable inlining and cloning optimizations, which includes
	       inlining, cloning, interprocedural scalar replacement of
	       aggregates and partial inlining.	 As a result, when patching a
	       function, all its callers and its clones' callers are impacted,
	       therefore need to be patched as well.

	       -flive-patching=inline-clone disables the following
	       optimization flags: -fwhole-program  -fipa-pta  -fipa-reference
	       -fipa-ra -fipa-icf  -fipa-icf-functions	-fipa-icf-variables
	       -fipa-bit-cp  -fipa-vrp	-fipa-pure-const
	       -fipa-reference-addressable -fipa-stack-alignment -fipa-modref

	   inline-only-static
	       Only enable inlining of static functions.  As a result, when
	       patching a static function, all its callers are impacted and so
	       need to be patched as well.

	       In addition to all the flags that -flive-patching=inline-clone
	       disables, -flive-patching=inline-only-static disables the
	       following additional optimization flags: -fipa-cp-clone
	       -fipa-sra  -fpartial-inlining  -fipa-cp

	   When -flive-patching is specified without any value, the default
	   value is inline-clone.

	   This flag is disabled by default.

	   Note that -flive-patching is not supported with link-time
	   optimization (-flto).

       -fisolate-erroneous-paths-dereference
	   Detect paths that trigger erroneous or undefined behavior due to
	   dereferencing a null pointer.  Isolate those paths from the main
	   control flow and turn the statement with erroneous or undefined
	   behavior into a trap.  This flag is enabled by default at -O2 and
	   higher and depends on -fdelete-null-pointer-checks also being
	   enabled.

       -fisolate-erroneous-paths-attribute
	   Detect paths that trigger erroneous or undefined behavior due to a
	   null value being used in a way forbidden by a "returns_nonnull" or
	   "nonnull" attribute.	 Isolate those paths from the main control
	   flow and turn the statement with erroneous or undefined behavior
	   into a trap.	 This is not currently enabled, but may be enabled by
	   -O2 in the future.

       -ftree-sink
	   Perform forward store motion on trees.  This flag is enabled by
	   default at -O1 and higher.

       -ftree-bit-ccp
	   Perform sparse conditional bit constant propagation on trees and
	   propagate pointer alignment information.  This pass only operates
	   on local scalar variables and is enabled by default at -O1 and
	   higher, except for -Og.  It requires that -ftree-ccp is enabled.

       -ftree-ccp
	   Perform sparse conditional constant propagation (CCP) on trees.
	   This pass only operates on local scalar variables and is enabled by
	   default at -O1 and higher.

       -fssa-backprop
	   Propagate information about uses of a value up the definition chain
	   in order to simplify the definitions.  For example, this pass
	   strips sign operations if the sign of a value never matters.	 The
	   flag is enabled by default at -O1 and higher.

       -fssa-phiopt
	   Perform pattern matching on SSA PHI nodes to optimize conditional
	   code.  This pass is enabled by default at -O1 and higher, except
	   for -Og.

       -ftree-switch-conversion
	   Perform conversion of simple initializations in a switch to
	   initializations from a scalar array.	 This flag is enabled by
	   default at -O2 and higher.

       -ftree-tail-merge
	   Look for identical code sequences.  When found, replace one with a
	   jump to the other.  This optimization is known as tail merging or
	   cross jumping.  This flag is enabled by default at -O2 and higher.
	   The compilation time in this pass can be limited using max-tail-
	   merge-comparisons parameter and max-tail-merge-iterations
	   parameter.

       -ftree-dce
	   Perform dead code elimination (DCE) on trees.  This flag is enabled
	   by default at -O1 and higher.

       -ftree-builtin-call-dce
	   Perform conditional dead code elimination (DCE) for calls to built-
	   in functions that may set "errno" but are otherwise free of side
	   effects.  This flag is enabled by default at -O2 and higher if -Os
	   is not also specified.

       -ffinite-loops
	   Assume that a loop with an exit will eventually take the exit and
	   not loop indefinitely.  This allows the compiler to remove loops
	   that otherwise have no side-effects, not considering eventual
	   endless looping as such.

	   This option is enabled by default at -O2 for C++ with -std=c++11 or
	   higher.

       -ftree-dominator-opts
	   Perform a variety of simple scalar cleanups (constant/copy
	   propagation, redundancy elimination, range propagation and
	   expression simplification) based on a dominator tree traversal.
	   This also performs jump threading (to reduce jumps to jumps). This
	   flag is enabled by default at -O1 and higher.

       -ftree-dse
	   Perform dead store elimination (DSE) on trees.  A dead store is a
	   store into a memory location that is later overwritten by another
	   store without any intervening loads.	 In this case the earlier
	   store can be deleted.  This flag is enabled by default at -O1 and
	   higher.

       -ftree-ch
	   Perform loop header copying on trees.  This is beneficial since it
	   increases effectiveness of code motion optimizations.  It also
	   saves one jump.  This flag is enabled by default at -O1 and higher.
	   It is not enabled for -Os, since it usually increases code size.

       -ftree-loop-optimize
	   Perform loop optimizations on trees.	 This flag is enabled by
	   default at -O1 and higher.

       -ftree-loop-linear
       -floop-strip-mine
       -floop-block
	   Perform loop nest optimizations.  Same as -floop-nest-optimize.  To
	   use this code transformation, GCC has to be configured with
	   --with-isl to enable the Graphite loop transformation
	   infrastructure.

       -fgraphite-identity
	   Enable the identity transformation for graphite.  For every SCoP we
	   generate the polyhedral representation and transform it back to
	   gimple.  Using -fgraphite-identity we can check the costs or
	   benefits of the GIMPLE -> GRAPHITE -> GIMPLE transformation.	 Some
	   minimal optimizations are also performed by the code generator isl,
	   like index splitting and dead code elimination in loops.

       -floop-nest-optimize
	   Enable the isl based loop nest optimizer.  This is a generic loop
	   nest optimizer based on the Pluto optimization algorithms.  It
	   calculates a loop structure optimized for data-locality and
	   parallelism.	 This option is experimental.

       -floop-parallelize-all
	   Use the Graphite data dependence analysis to identify loops that
	   can be parallelized.	 Parallelize all the loops that can be
	   analyzed to not contain loop carried dependences without checking
	   that it is profitable to parallelize the loops.

       -ftree-coalesce-vars
	   While transforming the program out of the SSA representation,
	   attempt to reduce copying by coalescing versions of different user-
	   defined variables, instead of just compiler temporaries.  This may
	   severely limit the ability to debug an optimized program compiled
	   with -fno-var-tracking-assignments.	In the negated form, this flag
	   prevents SSA coalescing of user variables.  This option is enabled
	   by default if optimization is enabled, and it does very little
	   otherwise.

       -ftree-loop-if-convert
	   Attempt to transform conditional jumps in the innermost loops to
	   branch-less equivalents.  The intent is to remove control-flow from
	   the innermost loops in order to improve the ability of the
	   vectorization pass to handle these loops.  This is enabled by
	   default if vectorization is enabled.

       -ftree-loop-distribution
	   Perform loop distribution.  This flag can improve cache performance
	   on big loop bodies and allow further loop optimizations, like
	   parallelization or vectorization, to take place.  For example, the
	   loop

		   DO I = 1, N
		     A(I) = B(I) + C
		     D(I) = E(I) * F
		   ENDDO

	   is transformed to

		   DO I = 1, N
		      A(I) = B(I) + C
		   ENDDO
		   DO I = 1, N
		      D(I) = E(I) * F
		   ENDDO

	   This flag is enabled by default at -O3.  It is also enabled by
	   -fprofile-use and -fauto-profile.

       -ftree-loop-distribute-patterns
	   Perform loop distribution of patterns that can be code generated
	   with calls to a library.  This flag is enabled by default at -O2
	   and higher, and by -fprofile-use and -fauto-profile.

	   This pass distributes the initialization loops and generates a call
	   to memset zero.  For example, the loop

		   DO I = 1, N
		     A(I) = 0
		     B(I) = A(I) + I
		   ENDDO

	   is transformed to

		   DO I = 1, N
		      A(I) = 0
		   ENDDO
		   DO I = 1, N
		      B(I) = A(I) + I
		   ENDDO

	   and the initialization loop is transformed into a call to memset
	   zero.

       -floop-interchange
	   Perform loop interchange outside of graphite.  This flag can
	   improve cache performance on loop nest and allow further loop
	   optimizations, like vectorization, to take place.  For example, the
	   loop

		   for (int i = 0; i < N; i++)
		     for (int j = 0; j < N; j++)
		       for (int k = 0; k < N; k++)
			 c[i][j] = c[i][j] + a[i][k]*b[k][j];

	   is transformed to

		   for (int i = 0; i < N; i++)
		     for (int k = 0; k < N; k++)
		       for (int j = 0; j < N; j++)
			 c[i][j] = c[i][j] + a[i][k]*b[k][j];

	   This flag is enabled by default at -O3.  It is also enabled by
	   -fprofile-use and -fauto-profile.

       -floop-unroll-and-jam
	   Apply unroll and jam transformations on feasible loops.  In a loop
	   nest this unrolls the outer loop by some factor and fuses the
	   resulting multiple inner loops.  This flag is enabled by default at
	   -O3.	 It is also enabled by -fprofile-use and -fauto-profile.

       -ftree-loop-im
	   Perform loop invariant motion on trees.  This pass moves only
	   invariants that are hard to handle at RTL level (function calls,
	   operations that expand to nontrivial sequences of insns).  With
	   -funswitch-loops it also moves operands of conditions that are
	   invariant out of the loop, so that we can use just trivial
	   invariantness analysis in loop unswitching.	The pass also includes
	   store motion.

       -ftree-loop-ivcanon
	   Create a canonical counter for number of iterations in loops for
	   which determining number of iterations requires complicated
	   analysis.  Later optimizations then may determine the number
	   easily.  Useful especially in connection with unrolling.

       -ftree-scev-cprop
	   Perform final value replacement.  If a variable is modified in a
	   loop in such a way that its value when exiting the loop can be
	   determined using only its initial value and the number of loop
	   iterations, replace uses of the final value by such a computation,
	   provided it is sufficiently cheap.  This reduces data dependencies
	   and may allow further simplifications.  Enabled by default at -O1
	   and higher.

       -fivopts
	   Perform induction variable optimizations (strength reduction,
	   induction variable merging and induction variable elimination) on
	   trees.

       -ftree-parallelize-loops=n
	   Parallelize loops, i.e., split their iteration space to run in n
	   threads.  This is only possible for loops whose iterations are
	   independent and can be arbitrarily reordered.  The optimization is
	   only profitable on multiprocessor machines, for loops that are CPU-
	   intensive, rather than constrained e.g. by memory bandwidth.	 This
	   option implies -pthread, and thus is only supported on targets that
	   have support for -pthread.

       -ftree-pta
	   Perform function-local points-to analysis on trees.	This flag is
	   enabled by default at -O1 and higher, except for -Og.

       -ftree-sra
	   Perform scalar replacement of aggregates.  This pass replaces
	   structure references with scalars to prevent committing structures
	   to memory too early.	 This flag is enabled by default at -O1 and
	   higher, except for -Og.

       -fstore-merging
	   Perform merging of narrow stores to consecutive memory addresses.
	   This pass merges contiguous stores of immediate values narrower
	   than a word into fewer wider stores to reduce the number of
	   instructions.  This is enabled by default at -O2 and higher as well
	   as -Os.

       -ftree-ter
	   Perform temporary expression replacement during the SSA->normal
	   phase.  Single use/single def temporaries are replaced at their use
	   location with their defining expression.  This results in non-
	   GIMPLE code, but gives the expanders much more complex trees to
	   work on resulting in better RTL generation.	This is enabled by
	   default at -O1 and higher.

       -ftree-slsr
	   Perform straight-line strength reduction on trees.  This recognizes
	   related expressions involving multiplications and replaces them by
	   less expensive calculations when possible.  This is enabled by
	   default at -O1 and higher.

       -ftree-vectorize
	   Perform vectorization on trees. This flag enables
	   -ftree-loop-vectorize and -ftree-slp-vectorize if not explicitly
	   specified.

       -ftree-loop-vectorize
	   Perform loop vectorization on trees. This flag is enabled by
	   default at -O2 and by -ftree-vectorize, -fprofile-use, and
	   -fauto-profile.

       -ftree-slp-vectorize
	   Perform basic block vectorization on trees. This flag is enabled by
	   default at -O2 and by -ftree-vectorize, -fprofile-use, and
	   -fauto-profile.

       -ftrivial-auto-var-init=choice
	   Initialize automatic variables with either a pattern or with zeroes
	   to increase the security and predictability of a program by
	   preventing uninitialized memory disclosure and use.	GCC still
	   considers an automatic variable that doesn't have an explicit
	   initializer as uninitialized, -Wuninitialized and
	   -Wanalyzer-use-of-uninitialized-value will still report warning
	   messages on such automatic variables and the compiler will perform
	   optimization as if the variable were uninitialized.	With this
	   option, GCC will also initialize any padding of automatic variables
	   that have structure or union types to zeroes.  However, the current
	   implementation cannot initialize automatic variables that are
	   declared between the controlling expression and the first case of a
	   "switch" statement.	Using -Wtrivial-auto-var-init to report all
	   such cases.

	   The three values of choice are:

	   *   uninitialized doesn't initialize any automatic variables.  This
	       is C and C++'s default.

	   *   pattern Initialize automatic variables with values which will
	       likely transform logic bugs into crashes down the line, are
	       easily recognized in a crash dump and without being values that
	       programmers can rely on for useful program semantics.  The
	       current value is byte-repeatable pattern with byte "0xFE".  The
	       values used for pattern initialization might be changed in the
	       future.

	   *   zero Initialize automatic variables with zeroes.

	   The default is uninitialized.

	   Note that the initializer values, whether zero or pattern, refer to
	   data representation (in memory or machine registers), rather than
	   to their interpretation as numerical values.	 This distinction may
	   be important in languages that support types with biases or
	   implicit multipliers, and with such extensions as hardbool.	For
	   example, a variable that uses 8 bits to represent (biased)
	   quantities in the "range 160..400" will be initialized with the bit
	   patterns 0x00 or 0xFE, depending on choice, whether or not these
	   representations stand for values in that range, and even if they
	   do, the interpretation of the value held by the variable will
	   depend on the bias.	A hardbool variable that uses say "0X5A" and
	   0xA5 for "false" and "true", respectively, will trap with either
	   choice of trivial initializer, i.e., zero initialization will not
	   convert to the representation for "false", even if it would for a
	   "static" variable of the same type.	This means the initializer
	   pattern doesn't generally depend on the type of the initialized
	   variable.  One notable exception is that (non-hardened) boolean
	   variables that fit in registers are initialized with "false"
	   (zero), even when pattern is requested.

	   You can control this behavior for a specific variable by using the
	   variable attribute "uninitialized".

       -fvect-cost-model=model
	   Alter the cost model used for vectorization.	 The model argument
	   should be one of unlimited, dynamic, cheap or very-cheap.  With the
	   unlimited model the vectorized code-path is assumed to be
	   profitable while with the dynamic model a runtime check guards the
	   vectorized code-path to enable it only for iteration counts that
	   will likely execute faster than when executing the original scalar
	   loop.  The cheap model disables vectorization of loops where doing
	   so would be cost prohibitive for example due to required runtime
	   checks for data dependence or alignment but otherwise is equal to
	   the dynamic model.  The very-cheap model only allows vectorization
	   if the vector code would entirely replace the scalar code that is
	   being vectorized.  For example, if each iteration of a vectorized
	   loop would only be able to handle exactly four iterations of the
	   scalar loop, the very-cheap model would only allow vectorization if
	   the scalar iteration count is known to be a multiple of four.

	   The default cost model depends on other optimization flags and is
	   either dynamic or cheap.

       -fsimd-cost-model=model
	   Alter the cost model used for vectorization of loops marked with
	   the OpenMP simd directive.  The model argument should be one of
	   unlimited, dynamic, cheap.  All values of model have the same
	   meaning as described in -fvect-cost-model and by default a cost
	   model defined with -fvect-cost-model is used.

       -ftree-vrp
	   Perform Value Range Propagation on trees.  This is similar to the
	   constant propagation pass, but instead of values, ranges of values
	   are propagated.  This allows the optimizers to remove unnecessary
	   range checks like array bound checks and null pointer checks.  This
	   is enabled by default at -O2 and higher.  Null pointer check
	   elimination is only done if -fdelete-null-pointer-checks is
	   enabled.

       -fsplit-paths
	   Split paths leading to loop backedges.  This can improve dead code
	   elimination and common subexpression elimination.  This is enabled
	   by default at -O3 and above.

       -fsplit-ivs-in-unroller
	   Enables expression of values of induction variables in later
	   iterations of the unrolled loop using the value in the first
	   iteration.  This breaks long dependency chains, thus improving
	   efficiency of the scheduling passes.

	   A combination of -fweb and CSE is often sufficient to obtain the
	   same effect.	 However, that is not reliable in cases where the loop
	   body is more complicated than a single basic block.	It also does
	   not work at all on some architectures due to restrictions in the
	   CSE pass.

	   This optimization is enabled by default.

       -fvariable-expansion-in-unroller
	   With this option, the compiler creates multiple copies of some
	   local variables when unrolling a loop, which can result in superior
	   code.

	   This optimization is enabled by default for PowerPC targets, but
	   disabled by default otherwise.

       -fpartial-inlining
	   Inline parts of functions.  This option has any effect only when
	   inlining itself is turned on by the -finline-functions or
	   -finline-small-functions options.

	   Enabled at levels -O2, -O3, -Os.

       -fpredictive-commoning
	   Perform predictive commoning optimization, i.e., reusing
	   computations (especially memory loads and stores) performed in
	   previous iterations of loops.

	   This option is enabled at level -O3.	 It is also enabled by
	   -fprofile-use and -fauto-profile.

       -fprefetch-loop-arrays
	   If supported by the target machine, generate instructions to
	   prefetch memory to improve the performance of loops that access
	   large arrays.

	   This option may generate better or worse code; results are highly
	   dependent on the structure of loops within the source code.

	   Disabled at level -Os.

       -fno-printf-return-value
	   Do not substitute constants for known return value of formatted
	   output functions such as "sprintf", "snprintf", "vsprintf", and
	   "vsnprintf" (but not "printf" of "fprintf").	 This transformation
	   allows GCC to optimize or even eliminate branches based on the
	   known return value of these functions called with arguments that
	   are either constant, or whose values are known to be in a range
	   that makes determining the exact return value possible.  For
	   example, when -fprintf-return-value is in effect, both the branch
	   and the body of the "if" statement (but not the call to "snprint")
	   can be optimized away when "i" is a 32-bit or smaller integer
	   because the return value is guaranteed to be at most 8.

		   char buf[9];
		   if (snprintf (buf, "%08x", i) >= sizeof buf)
		     ...

	   The -fprintf-return-value option relies on other optimizations and
	   yields best results with -O2 and above.  It works in tandem with
	   the -Wformat-overflow and -Wformat-truncation options.  The
	   -fprintf-return-value option is enabled by default.

       -fno-peephole
       -fno-peephole2
	   Disable any machine-specific peephole optimizations.	 The
	   difference between -fno-peephole and -fno-peephole2 is in how they
	   are implemented in the compiler; some targets use one, some use the
	   other, a few use both.

	   -fpeephole is enabled by default.  -fpeephole2 enabled at levels
	   -O2, -O3, -Os.

       -fno-guess-branch-probability
	   Do not guess branch probabilities using heuristics.

	   GCC uses heuristics to guess branch probabilities if they are not
	   provided by profiling feedback (-fprofile-arcs).  These heuristics
	   are based on the control flow graph.	 If some branch probabilities
	   are specified by "__builtin_expect", then the heuristics are used
	   to guess branch probabilities for the rest of the control flow
	   graph, taking the "__builtin_expect" info into account.  The
	   interactions between the heuristics and "__builtin_expect" can be
	   complex, and in some cases, it may be useful to disable the
	   heuristics so that the effects of "__builtin_expect" are easier to
	   understand.

	   It is also possible to specify expected probability of the
	   expression with "__builtin_expect_with_probability" built-in
	   function.

	   The default is -fguess-branch-probability at levels -O, -O2, -O3,
	   -Os.

       -freorder-blocks
	   Reorder basic blocks in the compiled function in order to reduce
	   number of taken branches and improve code locality.

	   Enabled at levels -O1, -O2, -O3, -Os.

       -freorder-blocks-algorithm=algorithm
	   Use the specified algorithm for basic block reordering.  The
	   algorithm argument can be simple, which does not increase code size
	   (except sometimes due to secondary effects like alignment), or stc,
	   the "software trace cache" algorithm, which tries to put all often
	   executed code together, minimizing the number of branches executed
	   by making extra copies of code.

	   The default is simple at levels -O1, -Os, and stc at levels -O2,
	   -O3.

       -freorder-blocks-and-partition
	   In addition to reordering basic blocks in the compiled function, in
	   order to reduce number of taken branches, partitions hot and cold
	   basic blocks into separate sections of the assembly and .o files,
	   to improve paging and cache locality performance.

	   This optimization is automatically turned off in the presence of
	   exception handling or unwind tables (on targets using
	   setjump/longjump or target specific scheme), for linkonce sections,
	   for functions with a user-defined section attribute and on any
	   architecture that does not support named sections.  When
	   -fsplit-stack is used this option is not enabled by default (to
	   avoid linker errors), but may be enabled explicitly (if using a
	   working linker).

	   Enabled for x86 at levels -O2, -O3, -Os.

       -freorder-functions
	   Reorder functions in the object file in order to improve code
	   locality.  This is implemented by using special subsections
	   ".text.hot" for most frequently executed functions and
	   ".text.unlikely" for unlikely executed functions.  Reordering is
	   done by the linker so object file format must support named
	   sections and linker must place them in a reasonable way.

	   This option isn't effective unless you either provide profile
	   feedback (see -fprofile-arcs for details) or manually annotate
	   functions with "hot" or "cold" attributes.

	   Enabled at levels -O2, -O3, -Os.

       -fstrict-aliasing
	   Allow the compiler to assume the strictest aliasing rules
	   applicable to the language being compiled.  For C (and C++), this
	   activates optimizations based on the type of expressions.  In
	   particular, an object of one type is assumed never to reside at the
	   same address as an object of a different type, unless the types are
	   almost the same.  For example, an "unsigned int" can alias an
	   "int", but not a "void*" or a "double".  A character type may alias
	   any other type.

	   Pay special attention to code like this:

		   union a_union {
		     int i;
		     double d;
		   };

		   int f() {
		     union a_union t;
		     t.d = 3.0;
		     return t.i;
		   }

	   The practice of reading from a different union member than the one
	   most recently written to (called "type-punning") is common.	Even
	   with -fstrict-aliasing, type-punning is allowed, provided the
	   memory is accessed through the union type.  So, the code above
	   works as expected.	 However, this code might not:

		   int f() {
		     union a_union t;
		     int* ip;
		     t.d = 3.0;
		     ip = &t.i;
		     return *ip;
		   }

	   Similarly, access by taking the address, casting the resulting
	   pointer and dereferencing the result has undefined behavior, even
	   if the cast uses a union type, e.g.:

		   int f() {
		     double d = 3.0;
		     return ((union a_union *) &d)->i;
		   }

	   The -fstrict-aliasing option is enabled at levels -O2, -O3, -Os.

       -fipa-strict-aliasing
	   Controls whether rules of -fstrict-aliasing are applied across
	   function boundaries.	 Note that if multiple functions gets inlined
	   into a single function the memory accesses are no longer considered
	   to be crossing a function boundary.

	   The -fipa-strict-aliasing option is enabled by default and is
	   effective only in combination with -fstrict-aliasing.

       -falign-functions
       -falign-functions=n
       -falign-functions=n:m
       -falign-functions=n:m:n2
       -falign-functions=n:m:n2:m2
	   Align the start of functions to the next power-of-two greater than
	   or equal to n, skipping up to m-1 bytes.  This ensures that at
	   least the first m bytes of the function can be fetched by the CPU
	   without crossing an n-byte alignment boundary.  This is an
	   optimization of code performance and alignment is ignored for
	   functions considered cold.  If alignment is required for all
	   functions, use -fmin-function-alignment.

	   If m is not specified, it defaults to n.

	   Examples: -falign-functions=32 aligns functions to the next 32-byte
	   boundary, -falign-functions=24 aligns to the next 32-byte boundary
	   only if this can be done by skipping 23 bytes or less,
	   -falign-functions=32:7 aligns to the next 32-byte boundary only if
	   this can be done by skipping 6 bytes or less.

	   The second pair of n2:m2 values allows you to specify a secondary
	   alignment: -falign-functions=64:7:32:3 aligns to the next 64-byte
	   boundary if this can be done by skipping 6 bytes or less, otherwise
	   aligns to the next 32-byte boundary if this can be done by skipping
	   2 bytes or less.  If m2 is not specified, it defaults to n2.

	   Some assemblers only support this flag when n is a power of two; in
	   that case, it is rounded up.

	   -fno-align-functions and -falign-functions=1 are equivalent and
	   mean that functions are not aligned.

	   If n is not specified or is zero, use a machine-dependent default.
	   The maximum allowed n option value is 65536.

	   Enabled at levels -O2, -O3.

       -flimit-function-alignment
	   If this option is enabled, the compiler tries to avoid
	   unnecessarily overaligning functions. It attempts to instruct the
	   assembler to align by the amount specified by -falign-functions,
	   but not to skip more bytes than the size of the function.

       -falign-labels
       -falign-labels=n
       -falign-labels=n:m
       -falign-labels=n:m:n2
       -falign-labels=n:m:n2:m2
	   Align all branch targets to a power-of-two boundary.

	   Parameters of this option are analogous to the -falign-functions
	   option.  -fno-align-labels and -falign-labels=1 are equivalent and
	   mean that labels are not aligned.

	   If -falign-loops or -falign-jumps are applicable and are greater
	   than this value, then their values are used instead.

	   If n is not specified or is zero, use a machine-dependent default
	   which is very likely to be 1, meaning no alignment.	The maximum
	   allowed n option value is 65536.

	   Enabled at levels -O2, -O3.

       -falign-loops
       -falign-loops=n
       -falign-loops=n:m
       -falign-loops=n:m:n2
       -falign-loops=n:m:n2:m2
	   Align loops to a power-of-two boundary.  If the loops are executed
	   many times, this makes up for any execution of the dummy padding
	   instructions.  This is an optimization of code performance and
	   alignment is ignored for loops considered cold.

	   If -falign-labels is greater than this value, then its value is
	   used instead.

	   Parameters of this option are analogous to the -falign-functions
	   option.  -fno-align-loops and -falign-loops=1 are equivalent and
	   mean that loops are not aligned.  The maximum allowed n option
	   value is 65536.

	   If n is not specified or is zero, use a machine-dependent default.

	   Enabled at levels -O2, -O3.

       -falign-jumps
       -falign-jumps=n
       -falign-jumps=n:m
       -falign-jumps=n:m:n2
       -falign-jumps=n:m:n2:m2
	   Align branch targets to a power-of-two boundary, for branch targets
	   where the targets can only be reached by jumping.  In this case, no
	   dummy operations need be executed.  This is an optimization of code
	   performance and alignment is ignored for jumps considered cold.

	   If -falign-labels is greater than this value, then its value is
	   used instead.

	   Parameters of this option are analogous to the -falign-functions
	   option.  -fno-align-jumps and -falign-jumps=1 are equivalent and
	   mean that loops are not aligned.

	   If n is not specified or is zero, use a machine-dependent default.
	   The maximum allowed n option value is 65536.

	   Enabled at levels -O2, -O3.

       -fmin-function-alignment
	   Specify minimal alignment of functions to the next power-of-two
	   greater than or equal to n. Unlike -falign-functions this alignment
	   is applied also to all functions (even those considered cold).  The
	   alignment is also not affected by -flimit-function-alignment

       -fno-allocation-dce
	   Do not remove unused C++ allocations in dead code elimination.

       -fallow-store-data-races
	   Allow the compiler to perform optimizations that may introduce new
	   data races on stores, without proving that the variable cannot be
	   concurrently accessed by other threads.  Does not affect
	   optimization of local data.	It is safe to use this option if it is
	   known that global data will not be accessed by multiple threads.

	   Examples of optimizations enabled by -fallow-store-data-races
	   include hoisting or if-conversions that may cause a value that was
	   already in memory to be re-written with that same value.  Such re-
	   writing is safe in a single threaded context but may be unsafe in a
	   multi-threaded context.  Note that on some processors, if-
	   conversions may be required in order to enable vectorization.

	   Enabled at level -Ofast.

       -funit-at-a-time
	   This option is left for compatibility reasons. -funit-at-a-time has
	   no effect, while -fno-unit-at-a-time implies -fno-toplevel-reorder
	   and -fno-section-anchors.

	   Enabled by default.

       -fno-toplevel-reorder
	   Do not reorder top-level functions, variables, and "asm"
	   statements.	Output them in the same order that they appear in the
	   input file.	When this option is used, unreferenced static
	   variables are not removed.  This option is intended to support
	   existing code that relies on a particular ordering.	For new code,
	   it is better to use attributes when possible.

	   -ftoplevel-reorder is the default at -O1 and higher, and also at
	   -O0 if -fsection-anchors is explicitly requested.  Additionally
	   -fno-toplevel-reorder implies -fno-section-anchors.

       -funreachable-traps
	   With this option, the compiler turns calls to
	   "__builtin_unreachable" into traps, instead of using them for
	   optimization.  This also affects any such calls implicitly
	   generated by the compiler.

	   This option has the same effect as -fsanitize=unreachable
	   -fsanitize-trap=unreachable, but does not affect the values of
	   those options.  If -fsanitize=unreachable is enabled, that option
	   takes priority over this one.

	   This option is enabled by default at -O0 and -Og.

       -fweb
	   Constructs webs as commonly used for register allocation purposes
	   and assign each web individual pseudo register.  This allows the
	   register allocation pass to operate on pseudos directly, but also
	   strengthens several other optimization passes, such as CSE, loop
	   optimizer and trivial dead code remover.  It can, however, make
	   debugging impossible, since variables no longer stay in a "home
	   register".

	   Enabled by default with -funroll-loops.

       -fwhole-program
	   Assume that the current compilation unit represents the whole
	   program being compiled.  All public functions and variables with
	   the exception of "main" and those merged by attribute
	   "externally_visible" become static functions and in effect are
	   optimized more aggressively by interprocedural optimizers.

	   With -flto this option has a limited use.  In most cases the
	   precise list of symbols used or exported from the binary is known
	   the resolution info passed to the link-time optimizer by the linker
	   plugin.  It is still useful if no linker plugin is used or during
	   incremental link step when final code is produced (with -flto
	   -flinker-output=nolto-rel).

       -flto[=n]
	   This option runs the standard link-time optimizer.  When invoked
	   with source code, it generates GIMPLE (one of GCC's internal
	   representations) and writes it to special ELF sections in the
	   object file.	 When the object files are linked together, all the
	   function bodies are read from these ELF sections and instantiated
	   as if they had been part of the same translation unit.

	   To use the link-time optimizer, -flto and optimization options
	   should be specified at compile time and during the final link.  It
	   is recommended that you compile all the files participating in the
	   same link with the same options and also specify those options at
	   link time.  For example:

		   gcc -c -O2 -flto foo.c
		   gcc -c -O2 -flto bar.c
		   gcc -o myprog -flto -O2 foo.o bar.o

	   The first two invocations to GCC save a bytecode representation of
	   GIMPLE into special ELF sections inside foo.o and bar.o.  The final
	   invocation reads the GIMPLE bytecode from foo.o and bar.o, merges
	   the two files into a single internal image, and compiles the result
	   as usual.  Since both foo.o and bar.o are merged into a single
	   image, this causes all the interprocedural analyses and
	   optimizations in GCC to work across the two files as if they were a
	   single one.	This means, for example, that the inliner is able to
	   inline functions in bar.o into functions in foo.o and vice-versa.

	   Another (simpler) way to enable link-time optimization is:

		   gcc -o myprog -flto -O2 foo.c bar.c

	   The above generates bytecode for foo.c and bar.c, merges them
	   together into a single GIMPLE representation and optimizes them as
	   usual to produce myprog.

	   The important thing to keep in mind is that to enable link-time
	   optimizations you need to use the GCC driver to perform the link
	   step.  GCC automatically performs link-time optimization if any of
	   the objects involved were compiled with the -flto command-line
	   option.  You can always override the automatic decision to do link-
	   time optimization by passing -fno-lto to the link command.

	   To make whole program optimization effective, it is necessary to
	   make certain whole program assumptions.  The compiler needs to know
	   what functions and variables can be accessed by libraries and
	   runtime outside of the link-time optimized unit.  When supported by
	   the linker, the linker plugin (see -fuse-linker-plugin) passes
	   information to the compiler about used and externally visible
	   symbols.  When the linker plugin is not available, -fwhole-program
	   should be used to allow the compiler to make these assumptions,
	   which leads to more aggressive optimization decisions.

	   When a file is compiled with -flto without -fuse-linker-plugin, the
	   generated object file is larger than a regular object file because
	   it contains GIMPLE bytecodes and the usual final code (see
	   -ffat-lto-objects).	This means that object files with LTO
	   information can be linked as normal object files; if -fno-lto is
	   passed to the linker, no interprocedural optimizations are applied.
	   Note that when -fno-fat-lto-objects is enabled the compile stage is
	   faster but you cannot perform a regular, non-LTO link on them.

	   When producing the final binary, GCC only applies link-time
	   optimizations to those files that contain bytecode.	Therefore, you
	   can mix and match object files and libraries with GIMPLE bytecodes
	   and final object code.  GCC automatically selects which files to
	   optimize in LTO mode and which files to link without further
	   processing.

	   Generally, options specified at link time override those specified
	   at compile time, although in some cases GCC attempts to infer link-
	   time options from the settings used to compile the input files.

	   If you do not specify an optimization level option -O at link time,
	   then GCC uses the highest optimization level used when compiling
	   the object files.  Note that it is generally ineffective to specify
	   an optimization level option only at link time and not at compile
	   time, for two reasons.  First, compiling without optimization
	   suppresses compiler passes that gather information needed for
	   effective optimization at link time.	 Second, some early
	   optimization passes can be performed only at compile time and not
	   at link time.

	   There are some code generation flags preserved by GCC when
	   generating bytecodes, as they need to be used during the final
	   link.  Currently, the following options and their settings are
	   taken from the first object file that explicitly specifies them:
	   -fcommon, -fexceptions, -fnon-call-exceptions, -fgnu-tm and all the
	   -m target flags.

	   The following options -fPIC, -fpic, -fpie and -fPIE are combined
	   based on the following scheme:

		   B<-fPIC> + B<-fpic> = B<-fpic>
		   B<-fPIC> + B<-fno-pic> = B<-fno-pic>
		   B<-fpic/-fPIC> + (no option) = (no option)
		   B<-fPIC> + B<-fPIE> = B<-fPIE>
		   B<-fpic> + B<-fPIE> = B<-fpie>
		   B<-fPIC/-fpic> + B<-fpie> = B<-fpie>

	   Certain ABI-changing flags are required to match in all compilation
	   units, and trying to override this at link time with a conflicting
	   value is ignored.  This includes options such as
	   -freg-struct-return and -fpcc-struct-return.

	   Other options such as -ffp-contract, -fno-strict-overflow, -fwrapv,
	   -fno-trapv or -fno-strict-aliasing are passed through to the link
	   stage and merged conservatively for conflicting translation units.
	   Specifically -fno-strict-overflow, -fwrapv and -fno-trapv take
	   precedence; and for example -ffp-contract=off takes precedence over
	   -ffp-contract=fast.	You can override them at link time.

	   Diagnostic options such as -Wstringop-overflow are passed through
	   to the link stage and their setting matches that of the compile-
	   step at function granularity.  Note that this matters only for
	   diagnostics emitted during optimization.  Note that code transforms
	   such as inlining can lead to warnings being enabled or disabled for
	   regions if code not consistent with the setting at compile time.

	   When you need to pass options to the assembler via -Wa or
	   -Xassembler make sure to either compile such translation units with
	   -fno-lto or consistently use the same assembler options on all
	   translation units.  You can alternatively also specify assembler
	   options at LTO link time.

	   To enable debug info generation you need to supply -g at compile
	   time.  If any of the input files at link time were built with debug
	   info generation enabled the link will enable debug info generation
	   as well.  Any elaborate debug info settings like the dwarf level
	   -gdwarf-5 need to be explicitly repeated at the linker command line
	   and mixing different settings in different translation units is
	   discouraged.

	   If LTO encounters objects with C linkage declared with incompatible
	   types in separate translation units to be linked together
	   (undefined behavior according to ISO C99 6.2.7), a non-fatal
	   diagnostic may be issued.  The behavior is still undefined at run
	   time.  Similar diagnostics may be raised for other languages.

	   Another feature of LTO is that it is possible to apply
	   interprocedural optimizations on files written in different
	   languages:

		   gcc -c -flto foo.c
		   g++ -c -flto bar.cc
		   gfortran -c -flto baz.f90
		   g++ -o myprog -flto -O3 foo.o bar.o baz.o -lgfortran

	   Notice that the final link is done with g++ to get the C++ runtime
	   libraries and -lgfortran is added to get the Fortran runtime
	   libraries.  In general, when mixing languages in LTO mode, you
	   should use the same link command options as when mixing languages
	   in a regular (non-LTO) compilation.

	   If object files containing GIMPLE bytecode are stored in a library
	   archive, say libfoo.a, it is possible to extract and use them in an
	   LTO link if you are using a linker with plugin support.  To create
	   static libraries suitable for LTO, use gcc-ar and gcc-ranlib
	   instead of ar and ranlib; to show the symbols of object files with
	   GIMPLE bytecode, use gcc-nm.	 Those commands require that ar,
	   ranlib and nm have been compiled with plugin support.  At link
	   time, use the flag -fuse-linker-plugin to ensure that the library
	   participates in the LTO optimization process:

		   gcc -o myprog -O2 -flto -fuse-linker-plugin a.o b.o -lfoo

	   With the linker plugin enabled, the linker extracts the needed
	   GIMPLE files from libfoo.a and passes them on to the running GCC to
	   make them part of the aggregated GIMPLE image to be optimized.

	   If you are not using a linker with plugin support and/or do not
	   enable the linker plugin, then the objects inside libfoo.a are
	   extracted and linked as usual, but they do not participate in the
	   LTO optimization process.  In order to make a static library
	   suitable for both LTO optimization and usual linkage, compile its
	   object files with -flto -ffat-lto-objects.

	   Link-time optimizations do not require the presence of the whole
	   program to operate.	If the program does not require any symbols to
	   be exported, it is possible to combine -flto and -fwhole-program to
	   allow the interprocedural optimizers to use more aggressive
	   assumptions which may lead to improved optimization opportunities.
	   Use of -fwhole-program is not needed when linker plugin is active
	   (see -fuse-linker-plugin).

	   The current implementation of LTO makes no attempt to generate
	   bytecode that is portable between different types of hosts.	The
	   bytecode files are versioned and there is a strict version check,
	   so bytecode files generated in one version of GCC do not work with
	   an older or newer version of GCC.

	   Link-time optimization does not work well with generation of
	   debugging information on systems other than those using a
	   combination of ELF and DWARF.

	   If you specify the optional n, the optimization and code generation
	   done at link time is executed in parallel using n parallel jobs by
	   utilizing an installed make program.	 The environment variable MAKE
	   may be used to override the program used.

	   You can also specify -flto=jobserver to use GNU make's job server
	   mode to determine the number of parallel jobs. This is useful when
	   the Makefile calling GCC is already executing in parallel.  You
	   must prepend a + to the command recipe in the parent Makefile for
	   this to work.  This option likely only works if MAKE is GNU make.
	   Even without the option value, GCC tries to automatically detect a
	   running GNU make's job server.

	   Use -flto=auto to use GNU make's job server, if available, or
	   otherwise fall back to autodetection of the number of CPU threads
	   present in your system.

       -flto-partition=alg
	   Specify the partitioning algorithm used by the link-time optimizer.
	   The value is either 1to1 to specify a partitioning mirroring the
	   original source files or balanced to specify partitioning into
	   equally sized chunks (whenever possible) or max to create new
	   partition for every symbol where possible.  Specifying none as an
	   algorithm disables partitioning and streaming completely.  The
	   default value is balanced. While 1to1 can be used as an workaround
	   for various code ordering issues, the max partitioning is intended
	   for internal testing only.  The value one specifies that exactly
	   one partition should be used while the value none bypasses
	   partitioning and executes the link-time optimization step directly
	   from the WPA phase.

       -flto-compression-level=n
	   This option specifies the level of compression used for
	   intermediate language written to LTO object files, and is only
	   meaningful in conjunction with LTO mode (-flto).  GCC currently
	   supports two LTO compression algorithms. For zstd, valid values are
	   0 (no compression) to 19 (maximum compression), while zlib supports
	   values from 0 to 9.	Values outside this range are clamped to
	   either minimum or maximum of the supported values.  If the option
	   is not given, a default balanced compression setting is used.

       -fuse-linker-plugin
	   Enables the use of a linker plugin during link-time optimization.
	   This option relies on plugin support in the linker, which is
	   available in gold or in GNU ld 2.21 or newer.

	   This option enables the extraction of object files with GIMPLE
	   bytecode out of library archives. This improves the quality of
	   optimization by exposing more code to the link-time optimizer.
	   This information specifies what symbols can be accessed externally
	   (by non-LTO object or during dynamic linking).  Resulting code
	   quality improvements on binaries (and shared libraries that use
	   hidden visibility) are similar to -fwhole-program.  See -flto for a
	   description of the effect of this flag and how to use it.

	   This option is enabled by default when LTO support in GCC is
	   enabled and GCC was configured for use with a linker supporting
	   plugins (GNU ld 2.21 or newer or gold).

       -ffat-lto-objects
	   Fat LTO objects are object files that contain both the intermediate
	   language and the object code. This makes them usable for both LTO
	   linking and normal linking. This option is effective only when
	   compiling with -flto and is ignored at link time.

	   -fno-fat-lto-objects improves compilation time over plain LTO, but
	   requires the complete toolchain to be aware of LTO. It requires a
	   linker with linker plugin support for basic functionality.
	   Additionally, nm, ar and ranlib need to support linker plugins to
	   allow a full-featured build environment (capable of building static
	   libraries etc).  GCC provides the gcc-ar, gcc-nm, gcc-ranlib
	   wrappers to pass the right options to these tools. With non fat LTO
	   makefiles need to be modified to use them.

	   Note that modern binutils provide plugin auto-load mechanism.
	   Installing the linker plugin into $libdir/bfd-plugins has the same
	   effect as usage of the command wrappers (gcc-ar, gcc-nm and gcc-
	   ranlib).

	   The default is -fno-fat-lto-objects on targets with linker plugin
	   support.

       -fcompare-elim
	   After register allocation and post-register allocation instruction
	   splitting, identify arithmetic instructions that compute processor
	   flags similar to a comparison operation based on that arithmetic.
	   If possible, eliminate the explicit comparison operation.

	   This pass only applies to certain targets that cannot explicitly
	   represent the comparison operation before register allocation is
	   complete.

	   Enabled at levels -O1, -O2, -O3, -Os.

       -ffold-mem-offsets
       -fno-fold-mem-offsets
	   Try to eliminate add instructions by folding them in memory
	   loads/stores.

	   Enabled at levels -O2, -O3.

       -fcprop-registers
	   After register allocation and post-register allocation instruction
	   splitting, perform a copy-propagation pass to try to reduce
	   scheduling dependencies and occasionally eliminate the copy.

	   Enabled at levels -O1, -O2, -O3, -Os.

       -fprofile-correction
	   Profiles collected using an instrumented binary for multi-threaded
	   programs may be inconsistent due to missed counter updates. When
	   this option is specified, GCC uses heuristics to correct or smooth
	   out such inconsistencies. By default, GCC emits an error message
	   when an inconsistent profile is detected.

	   This option is enabled by -fauto-profile.

       -fprofile-partial-training
	   With "-fprofile-use" all portions of programs not executed during
	   train run are optimized agressively for size rather than speed.  In
	   some cases it is not practical to train all possible hot paths in
	   the program. (For example, program may contain functions specific
	   for a given hardware and trianing may not cover all hardware
	   configurations program is run on.)  With
	   "-fprofile-partial-training" profile feedback will be ignored for
	   all functions not executed during the train run leading them to be
	   optimized as if they were compiled without profile feedback. This
	   leads to better performance when train run is not representative
	   but also leads to significantly bigger code.

       -fprofile-use
       -fprofile-use=path
	   Enable profile feedback-directed optimizations, and the following
	   optimizations, many of which are generally profitable only with
	   profile feedback available:

	   -fbranch-probabilities  -fprofile-values -funroll-loops
	   -fpeel-loops	 -ftracer  -fvpt -finline-functions  -fipa-cp
	   -fipa-cp-clone  -fipa-bit-cp -fpredictive-commoning	-fsplit-loops
	   -funswitch-loops -fgcse-after-reload	 -ftree-loop-vectorize
	   -ftree-slp-vectorize -fvect-cost-model=dynamic
	   -ftree-loop-distribute-patterns -fprofile-reorder-functions

	   Before you can use this option, you must first generate profiling
	   information.

	   By default, GCC emits an error message if the feedback profiles do
	   not match the source code.  This error can be turned into a warning
	   by using -Wno-error=coverage-mismatch.  Note this may result in
	   poorly optimized code.  Additionally, by default, GCC also emits a
	   warning message if the feedback profiles do not exist (see
	   -Wmissing-profile).

	   If path is specified, GCC looks at the path to find the profile
	   feedback data files. See -fprofile-dir.

       -fauto-profile
       -fauto-profile=path
	   Enable sampling-based feedback-directed optimizations, and the
	   following optimizations, many of which are generally profitable
	   only with profile feedback available:

	   -fbranch-probabilities  -fprofile-values -funroll-loops
	   -fpeel-loops	 -ftracer  -fvpt -finline-functions  -fipa-cp
	   -fipa-cp-clone  -fipa-bit-cp -fpredictive-commoning	-fsplit-loops
	   -funswitch-loops -fgcse-after-reload	 -ftree-loop-vectorize
	   -ftree-slp-vectorize -fvect-cost-model=dynamic
	   -ftree-loop-distribute-patterns -fprofile-correction

	   path is the name of a file containing AutoFDO profile information.
	   If omitted, it defaults to fbdata.afdo in the current directory.

	   Producing an AutoFDO profile data file requires running your
	   program with the perf utility on a supported GNU/Linux target
	   system.  For more information, see <https://perf.wiki.kernel.org/>.

	   E.g.

		   perf record -e br_inst_retired:near_taken -b -o perf.data \
		       -- your_program

	   Then use the create_gcov tool to convert the raw profile data to a
	   format that can be used by GCC.  You must also supply the
	   unstripped binary for your program to this tool.  See
	   <https://github.com/google/autofdo>.

	   E.g.

		   create_gcov --binary=your_program.unstripped --profile=perf.data \
		       --gcov=profile.afdo

       The following options control compiler behavior regarding floating-
       point arithmetic.  These options trade off between speed and
       correctness.  All must be specifically enabled.

       -ffloat-store
	   Do not store floating-point variables in registers, and inhibit
	   other options that might change whether a floating-point value is
	   taken from a register or memory.

	   This option prevents undesirable excess precision on machines such
	   as the 68000 where the floating registers (of the 68881) keep more
	   precision than a "double" is supposed to have.  Similarly for the
	   x86 architecture.  For most programs, the excess precision does
	   only good, but a few programs rely on the precise definition of
	   IEEE floating point.	 Use -ffloat-store for such programs, after
	   modifying them to store all pertinent intermediate computations
	   into variables.

       -fexcess-precision=style
	   This option allows further control over excess precision on
	   machines where floating-point operations occur in a format with
	   more precision or range than the IEEE standard and interchange
	   floating-point types.  By default, -fexcess-precision=fast is in
	   effect; this means that operations may be carried out in a wider
	   precision than the types specified in the source if that would
	   result in faster code, and it is unpredictable when rounding to the
	   types specified in the source code takes place.  When compiling C
	   or C++, if -fexcess-precision=standard is specified then excess
	   precision follows the rules specified in ISO C99 or C++; in
	   particular, both casts and assignments cause values to be rounded
	   to their semantic types (whereas -ffloat-store only affects
	   assignments).  This option is enabled by default for C or C++ if a
	   strict conformance option such as -std=c99 or -std=c++17 is used.
	   -ffast-math enables -fexcess-precision=fast by default regardless
	   of whether a strict conformance option is used.  If
	   -fexcess-precision=16 is specified, constants and the results of
	   expressions with types "_Float16" and "__bf16" are computed without
	   excess precision.

	   -fexcess-precision=standard is not implemented for languages other
	   than C or C++.  On the x86, it has no effect if -mfpmath=sse or
	   -mfpmath=sse+387 is specified; in the former case, IEEE semantics
	   apply without excess precision, and in the latter, rounding is
	   unpredictable.

       -ffast-math
	   Sets the options -fno-math-errno, -funsafe-math-optimizations,
	   -ffinite-math-only, -fno-rounding-math, -fno-signaling-nans,
	   -fcx-limited-range and -fexcess-precision=fast.

	   This option causes the preprocessor macro "__FAST_MATH__" to be
	   defined.

	   This option is not turned on by any -O option besides -Ofast since
	   it can result in incorrect output for programs that depend on an
	   exact implementation of IEEE or ISO rules/specifications for math
	   functions. It may, however, yield faster code for programs that do
	   not require the guarantees of these specifications.

       -fno-math-errno
	   Do not set "errno" after calling math functions that are executed
	   with a single instruction, e.g., "sqrt".  A program that relies on
	   IEEE exceptions for math error handling may want to use this flag
	   for speed while maintaining IEEE arithmetic compatibility.

	   This option is not turned on by any -O option since it can result
	   in incorrect output for programs that depend on an exact
	   implementation of IEEE or ISO rules/specifications for math
	   functions. It may, however, yield faster code for programs that do
	   not require the guarantees of these specifications.

	   The default is -fmath-errno.

	   On Darwin systems, the math library never sets "errno".  There is
	   therefore no reason for the compiler to consider the possibility
	   that it might, and -fno-math-errno is the default.

       -funsafe-math-optimizations
	   Allow optimizations for floating-point arithmetic that (a) assume
	   that arguments and results are valid and (b) may violate IEEE or
	   ANSI standards.  When used at link time, it may include libraries
	   or startup files that change the default FPU control word or other
	   similar optimizations.

	   This option is not turned on by any -O option since it can result
	   in incorrect output for programs that depend on an exact
	   implementation of IEEE or ISO rules/specifications for math
	   functions. It may, however, yield faster code for programs that do
	   not require the guarantees of these specifications.	Enables
	   -fno-signed-zeros, -fno-trapping-math, -fassociative-math and
	   -freciprocal-math.

	   The default is -fno-unsafe-math-optimizations.

       -fassociative-math
	   Allow re-association of operands in series of floating-point
	   operations.	This violates the ISO C and C++ language standard by
	   possibly changing computation result.  NOTE: re-ordering may change
	   the sign of zero as well as ignore NaNs and inhibit or create
	   underflow or overflow (and thus cannot be used on code that relies
	   on rounding behavior like "(x + 2**52) - 2**52".  May also reorder
	   floating-point comparisons and thus may not be used when ordered
	   comparisons are required.  This option requires that both
	   -fno-signed-zeros and -fno-trapping-math be in effect.  Moreover,
	   it doesn't make much sense with -frounding-math. For Fortran the
	   option is automatically enabled when both -fno-signed-zeros and
	   -fno-trapping-math are in effect.

	   The default is -fno-associative-math.

       -freciprocal-math
	   Allow the reciprocal of a value to be used instead of dividing by
	   the value if this enables optimizations.  For example "x / y" can
	   be replaced with "x * (1/y)", which is useful if "(1/y)" is subject
	   to common subexpression elimination.	 Note that this loses
	   precision and increases the number of flops operating on the value.

	   The default is -fno-reciprocal-math.

       -ffinite-math-only
	   Allow optimizations for floating-point arithmetic that assume that
	   arguments and results are not NaNs or +-Infs.

	   This option is not turned on by any -O option since it can result
	   in incorrect output for programs that depend on an exact
	   implementation of IEEE or ISO rules/specifications for math
	   functions. It may, however, yield faster code for programs that do
	   not require the guarantees of these specifications.

	   The default is -fno-finite-math-only.

       -fno-signed-zeros
	   Allow optimizations for floating-point arithmetic that ignore the
	   signedness of zero.	IEEE arithmetic specifies the behavior of
	   distinct +0.0 and -0.0 values, which then prohibits simplification
	   of expressions such as x+0.0 or 0.0*x (even with
	   -ffinite-math-only).	 This option implies that the sign of a zero
	   result isn't significant.

	   The default is -fsigned-zeros.

       -fno-trapping-math
	   Compile code assuming that floating-point operations cannot
	   generate user-visible traps.	 These traps include division by zero,
	   overflow, underflow, inexact result and invalid operation.  This
	   option requires that -fno-signaling-nans be in effect.  Setting
	   this option may allow faster code if one relies on "non-stop" IEEE
	   arithmetic, for example.

	   This option should never be turned on by any -O option since it can
	   result in incorrect output for programs that depend on an exact
	   implementation of IEEE or ISO rules/specifications for math
	   functions.

	   The default is -ftrapping-math.

	   Future versions of GCC may provide finer control of this setting
	   using C99's "FENV_ACCESS" pragma.  This command-line option will be
	   used along with -frounding-math to specify the default state for
	   "FENV_ACCESS".

       -frounding-math
	   Disable transformations and optimizations that assume default
	   floating-point rounding behavior.  This is round-to-zero for all
	   floating point to integer conversions, and round-to-nearest for all
	   other arithmetic truncations.  This option should be specified for
	   programs that change the FP rounding mode dynamically, or that may
	   be executed with a non-default rounding mode.  This option disables
	   constant folding of floating-point expressions at compile time
	   (which may be affected by rounding mode) and arithmetic
	   transformations that are unsafe in the presence of sign-dependent
	   rounding modes.

	   The default is -fno-rounding-math.

	   This option is experimental and does not currently guarantee to
	   disable all GCC optimizations that are affected by rounding mode.
	   Future versions of GCC may provide finer control of this setting
	   using C99's "FENV_ACCESS" pragma.  This command-line option will be
	   used along with -ftrapping-math to specify the default state for
	   "FENV_ACCESS".

       -fsignaling-nans
	   Compile code assuming that IEEE signaling NaNs may generate user-
	   visible traps during floating-point operations.  Setting this
	   option disables optimizations that may change the number of
	   exceptions visible with signaling NaNs.  This option implies
	   -ftrapping-math.

	   This option causes the preprocessor macro "__SUPPORT_SNAN__" to be
	   defined.

	   The default is -fno-signaling-nans.

	   This option is experimental and does not currently guarantee to
	   disable all GCC optimizations that affect signaling NaN behavior.

       -fno-fp-int-builtin-inexact
	   Do not allow the built-in functions "ceil", "floor", "round" and
	   "trunc", and their "float" and "long double" variants, to generate
	   code that raises the "inexact" floating-point exception for
	   noninteger arguments.  ISO C99 and C11 allow these functions to
	   raise the "inexact" exception, but ISO/IEC TS 18661-1:2014, the C
	   bindings to IEEE 754-2008, as integrated into ISO C23, does not
	   allow these functions to do so.

	   The default is -ffp-int-builtin-inexact, allowing the exception to
	   be raised, unless C23 or a later C standard is selected.  This
	   option does nothing unless -ftrapping-math is in effect.

	   Even if -fno-fp-int-builtin-inexact is used, if the functions
	   generate a call to a library function then the "inexact" exception
	   may be raised if the library implementation does not follow TS
	   18661.

       -fsingle-precision-constant
	   Treat floating-point constants as single precision instead of
	   implicitly converting them to double-precision constants.

       -fcx-limited-range
	   When enabled, this option states that a range reduction step is not
	   needed when performing complex division.  Also, there is no
	   checking whether the result of a complex multiplication or division
	   is "NaN + I*NaN", with an attempt to rescue the situation in that
	   case.  The default is -fno-cx-limited-range, but is enabled by
	   -ffast-math.

	   This option controls the default setting of the ISO C99
	   "CX_LIMITED_RANGE" pragma.  Nevertheless, the option applies to all
	   languages.

       -fcx-fortran-rules
	   Complex multiplication and division follow Fortran rules.  Range
	   reduction is done as part of complex division, but there is no
	   checking whether the result of a complex multiplication or division
	   is "NaN + I*NaN", with an attempt to rescue the situation in that
	   case.

	   The default is -fno-cx-fortran-rules.

       The following options control optimizations that may improve
       performance, but are not enabled by any -O options.  This section
       includes experimental options that may produce broken code.

       -fbranch-probabilities
	   After running a program compiled with -fprofile-arcs, you can
	   compile it a second time using -fbranch-probabilities, to improve
	   optimizations based on the number of times each branch was taken.
	   When a program compiled with -fprofile-arcs exits, it saves arc
	   execution counts to a file called sourcename.gcda for each source
	   file.  The information in this data file is very dependent on the
	   structure of the generated code, so you must use the same source
	   code and the same optimization options for both compilations.  See
	   details about the file naming in -fprofile-arcs.

	   With -fbranch-probabilities, GCC puts a REG_BR_PROB note on each
	   JUMP_INSN and CALL_INSN.  These can be used to improve
	   optimization.  Currently, they are only used in one place: in
	   reorg.cc, instead of guessing which path a branch is most likely to
	   take, the REG_BR_PROB values are used to exactly determine which
	   path is taken more often.

	   Enabled by -fprofile-use and -fauto-profile.

       -fprofile-values
	   If combined with -fprofile-arcs, it adds code so that some data
	   about values of expressions in the program is gathered.

	   With -fbranch-probabilities, it reads back the data gathered from
	   profiling values of expressions for usage in optimizations.

	   Enabled by -fprofile-generate, -fprofile-use, and -fauto-profile.

       -fprofile-reorder-functions
	   Function reordering based on profile instrumentation collects first
	   time of execution of a function and orders these functions in
	   ascending order.

	   Enabled with -fprofile-use.

       -fvpt
	   If combined with -fprofile-arcs, this option instructs the compiler
	   to add code to gather information about values of expressions.

	   With -fbranch-probabilities, it reads back the data gathered and
	   actually performs the optimizations based on them.  Currently the
	   optimizations include specialization of division operations using
	   the knowledge about the value of the denominator.

	   Enabled with -fprofile-use and -fauto-profile.

       -frename-registers
	   Attempt to avoid false dependencies in scheduled code by making use
	   of registers left over after register allocation.  This
	   optimization most benefits processors with lots of registers.
	   Depending on the debug information format adopted by the target,
	   however, it can make debugging impossible, since variables no
	   longer stay in a "home register".

	   Enabled by default with -funroll-loops.

       -fschedule-fusion
	   Performs a target dependent pass over the instruction stream to
	   schedule instructions of same type together because target machine
	   can execute them more efficiently if they are adjacent to each
	   other in the instruction flow.

	   Enabled at levels -O2, -O3, -Os.

       -ftracer
	   Perform tail duplication to enlarge superblock size.	 This
	   transformation simplifies the control flow of the function allowing
	   other optimizations to do a better job.

	   Enabled by -fprofile-use and -fauto-profile.

       -funroll-loops
	   Unroll loops whose number of iterations can be determined at
	   compile time or upon entry to the loop.  -funroll-loops implies
	   -frerun-cse-after-loop, -fweb and -frename-registers.  It also
	   turns on complete loop peeling (i.e. complete removal of loops with
	   a small constant number of iterations).  This option makes code
	   larger, and may or may not make it run faster.

	   Enabled by -fprofile-use and -fauto-profile.

       -funroll-all-loops
	   Unroll all loops, even if their number of iterations is uncertain
	   when the loop is entered.  This usually makes programs run more
	   slowly.  -funroll-all-loops implies the same options as
	   -funroll-loops.

       -fpeel-loops
	   Peels loops for which there is enough information that they do not
	   roll much (from profile feedback or static analysis).  It also
	   turns on complete loop peeling (i.e. complete removal of loops with
	   small constant number of iterations).

	   Enabled by -O3, -fprofile-use, and -fauto-profile.

       -fmove-loop-invariants
	   Enables the loop invariant motion pass in the RTL loop optimizer.
	   Enabled at level -O1 and higher, except for -Og.

       -fmove-loop-stores
	   Enables the loop store motion pass in the GIMPLE loop optimizer.
	   This moves invariant stores to after the end of the loop in
	   exchange for carrying the stored value in a register across the
	   iteration.  Note for this option to have an effect -ftree-loop-im
	   has to be enabled as well.  Enabled at level -O1 and higher, except
	   for -Og.

       -fsplit-loops
	   Split a loop into two if it contains a condition that's always true
	   for one side of the iteration space and false for the other.

	   Enabled by -fprofile-use and -fauto-profile.

       -funswitch-loops
	   Move branches with loop invariant conditions out of the loop, with
	   duplicates of the loop on both branches (modified according to
	   result of the condition).

	   Enabled by -fprofile-use and -fauto-profile.

       -fversion-loops-for-strides
	   If a loop iterates over an array with a variable stride, create
	   another version of the loop that assumes the stride is always one.
	   For example:

		   for (int i = 0; i < n; ++i)
		     x[i * stride] = ...;

	   becomes:

		   if (stride == 1)
		     for (int i = 0; i < n; ++i)
		       x[i] = ...;
		   else
		     for (int i = 0; i < n; ++i)
		       x[i * stride] = ...;

	   This is particularly useful for assumed-shape arrays in Fortran
	   where (for example) it allows better vectorization assuming
	   contiguous accesses.	 This flag is enabled by default at -O3.  It
	   is also enabled by -fprofile-use and -fauto-profile.

       -ffunction-sections
       -fdata-sections
	   Place each function or data item into its own section in the output
	   file if the target supports arbitrary sections.  The name of the
	   function or the name of the data item determines the section's name
	   in the output file.

	   Use these options on systems where the linker can perform
	   optimizations to improve locality of reference in the instruction
	   space.  Most systems using the ELF object format have linkers with
	   such optimizations.	On AIX, the linker rearranges sections
	   (CSECTs) based on the call graph.  The performance impact varies.

	   Together with a linker garbage collection (linker --gc-sections
	   option) these options may lead to smaller statically-linked
	   executables (after stripping).

	   On ELF/DWARF systems these options do not degenerate the quality of
	   the debug information.  There could be issues with other object
	   files/debug info formats.

	   Only use these options when there are significant benefits from
	   doing so.  When you specify these options, the assembler and linker
	   create larger object and executable files and are also slower.
	   These options affect code generation.  They prevent optimizations
	   by the compiler and assembler using relative locations inside a
	   translation unit since the locations are unknown until link time.
	   An example of such an optimization is relaxing calls to short call
	   instructions.

       -fstdarg-opt
	   Optimize the prologue of variadic argument functions with respect
	   to usage of those arguments.

       -fsection-anchors
	   Try to reduce the number of symbolic address calculations by using
	   shared "anchor" symbols to address nearby objects.  This
	   transformation can help to reduce the number of GOT entries and GOT
	   accesses on some targets.

	   For example, the implementation of the following function "foo":

		   static int a, b, c;
		   int foo (void) { return a + b + c; }

	   usually calculates the addresses of all three variables, but if you
	   compile it with -fsection-anchors, it accesses the variables from a
	   common anchor point instead.	 The effect is similar to the
	   following pseudocode (which isn't valid C):

		   int foo (void)
		   {
		     register int *xr = &x;
		     return xr[&a - &x] + xr[&b - &x] + xr[&c - &x];
		   }

	   Not all targets support this option.

       -fzero-call-used-regs=choice
	   Zero call-used registers at function return to increase program
	   security by either mitigating Return-Oriented Programming (ROP)
	   attacks or preventing information leakage through registers.

	   The possible values of choice are the same as for the
	   "zero_call_used_regs" attribute.  The default is skip.

	   You can control this behavior for a specific function by using the
	   function attribute "zero_call_used_regs".

       --param name=value
	   In some places, GCC uses various constants to control the amount of
	   optimization that is done.  For example, GCC does not inline
	   functions that contain more than a certain number of instructions.
	   You can control some of these constants on the command line using
	   the --param option.

	   The names of specific parameters, and the meaning of the values,
	   are tied to the internals of the compiler, and are subject to
	   change without notice in future releases.

	   In order to get the minimal, maximal and default values of a
	   parameter, use the --help=param -Q options.

	   In each case, the value is an integer.  The following choices of
	   name are recognized for all targets:

	   predictable-branch-outcome
	       When branch is predicted to be taken with probability lower
	       than this threshold (in percent), then it is considered well
	       predictable.

	   max-rtl-if-conversion-insns
	       RTL if-conversion tries to remove conditional branches around a
	       block and replace them with conditionally executed
	       instructions.  This parameter gives the maximum number of
	       instructions in a block which should be considered for if-
	       conversion.  The compiler will also use other heuristics to
	       decide whether if-conversion is likely to be profitable.

	   max-rtl-if-conversion-predictable-cost
	       RTL if-conversion will try to remove conditional branches
	       around a block and replace them with conditionally executed
	       instructions.  These parameters give the maximum permissible
	       cost for the sequence that would be generated by if-conversion
	       depending on whether the branch is statically determined to be
	       predictable or not.  The units for this parameter are the same
	       as those for the GCC internal seq_cost metric.  The compiler
	       will try to provide a reasonable default for this parameter
	       using the BRANCH_COST target macro.

	   max-crossjump-edges
	       The maximum number of incoming edges to consider for cross-
	       jumping.	 The algorithm used by -fcrossjumping is O(N^2) in the
	       number of edges incoming to each block.	Increasing values mean
	       more aggressive optimization, making the compilation time
	       increase with probably small improvement in executable size.

	   min-crossjump-insns
	       The minimum number of instructions that must be matched at the
	       end of two blocks before cross-jumping is performed on them.
	       This value is ignored in the case where all instructions in the
	       block being cross-jumped from are matched.

	   max-grow-copy-bb-insns
	       The maximum code size expansion factor when copying basic
	       blocks instead of jumping.  The expansion is relative to a jump
	       instruction.

	   max-goto-duplication-insns
	       The maximum number of instructions to duplicate to a block that
	       jumps to a computed goto.  To avoid O(N^2) behavior in a number
	       of passes, GCC factors computed gotos early in the compilation
	       process, and unfactors them as late as possible.	 Only computed
	       jumps at the end of a basic blocks with no more than max-goto-
	       duplication-insns are unfactored.

	   max-delay-slot-insn-search
	       The maximum number of instructions to consider when looking for
	       an instruction to fill a delay slot.  If more than this
	       arbitrary number of instructions are searched, the time savings
	       from filling the delay slot are minimal, so stop searching.
	       Increasing values mean more aggressive optimization, making the
	       compilation time increase with probably small improvement in
	       execution time.

	   max-delay-slot-live-search
	       When trying to fill delay slots, the maximum number of
	       instructions to consider when searching for a block with valid
	       live register information.  Increasing this arbitrarily chosen
	       value means more aggressive optimization, increasing the
	       compilation time.  This parameter should be removed when the
	       delay slot code is rewritten to maintain the control-flow
	       graph.

	   max-gcse-memory
	       The approximate maximum amount of memory in "kB" that can be
	       allocated in order to perform the global common subexpression
	       elimination optimization.  If more memory than specified is
	       required, the optimization is not done.

	   max-gcse-insertion-ratio
	       If the ratio of expression insertions to deletions is larger
	       than this value for any expression, then RTL PRE inserts or
	       removes the expression and thus leaves partially redundant
	       computations in the instruction stream.

	   max-pending-list-length
	       The maximum number of pending dependencies scheduling allows
	       before flushing the current state and starting over.  Large
	       functions with few branches or calls can create excessively
	       large lists which needlessly consume memory and resources.

	   max-modulo-backtrack-attempts
	       The maximum number of backtrack attempts the scheduler should
	       make when modulo scheduling a loop.  Larger values can
	       exponentially increase compilation time.

	   max-inline-functions-called-once-loop-depth
	       Maximal loop depth of a call considered by inline heuristics
	       that tries to inline all functions called once.

	   max-inline-functions-called-once-insns
	       Maximal estimated size of functions produced while inlining
	       functions called once.

	   max-inline-insns-single
	       Several parameters control the tree inliner used in GCC.	 This
	       number sets the maximum number of instructions (counted in
	       GCC's internal representation) in a single function that the
	       tree inliner considers for inlining.  This only affects
	       functions declared inline and methods implemented in a class
	       declaration (C++).

	   max-inline-insns-auto
	       When you use -finline-functions (included in -O3), a lot of
	       functions that would otherwise not be considered for inlining
	       by the compiler are investigated.  To those functions, a
	       different (more restrictive) limit compared to functions
	       declared inline can be applied (--param max-inline-insns-auto).

	   max-inline-insns-small
	       This is bound applied to calls which are considered relevant
	       with -finline-small-functions.

	   max-inline-insns-size
	       This is bound applied to calls which are optimized for size.
	       Small growth may be desirable to anticipate optimization
	       oppurtunities exposed by inlining.

	   uninlined-function-insns
	       Number of instructions accounted by inliner for function
	       overhead such as function prologue and epilogue.

	   uninlined-function-time
	       Extra time accounted by inliner for function overhead such as
	       time needed to execute function prologue and epilogue.

	   inline-heuristics-hint-percent
	       The scale (in percents) applied to inline-insns-single,
	       inline-insns-single-O2, inline-insns-auto when inline
	       heuristics hints that inlining is very profitable (will enable
	       later optimizations).

	   uninlined-thunk-insns
	   uninlined-thunk-time
	       Same as --param uninlined-function-insns and --param uninlined-
	       function-time but applied to function thunks.

	   inline-min-speedup
	       When estimated performance improvement of caller + callee
	       runtime exceeds this threshold (in percent), the function can
	       be inlined regardless of the limit on --param max-inline-insns-
	       single and --param max-inline-insns-auto.

	   large-function-insns
	       The limit specifying really large functions.  For functions
	       larger than this limit after inlining, inlining is constrained
	       by --param large-function-growth.  This parameter is useful
	       primarily to avoid extreme compilation time caused by non-
	       linear algorithms used by the back end.

	   large-function-growth
	       Specifies maximal growth of large function caused by inlining
	       in percents.  For example, parameter value 100 limits large
	       function growth to 2.0 times the original size.

	   large-unit-insns
	       The limit specifying large translation unit.  Growth caused by
	       inlining of units larger than this limit is limited by --param
	       inline-unit-growth.  For small units this might be too tight.
	       For example, consider a unit consisting of function A that is
	       inline and B that just calls A three times.  If B is small
	       relative to A, the growth of unit is 300\% and yet such
	       inlining is very sane.  For very large units consisting of
	       small inlineable functions, however, the overall unit growth
	       limit is needed to avoid exponential explosion of code size.
	       Thus for smaller units, the size is increased to --param large-
	       unit-insns before applying --param inline-unit-growth.

	   lazy-modules
	       Maximum number of concurrently open C++ module files when lazy
	       loading.

	   inline-unit-growth
	       Specifies maximal overall growth of the compilation unit caused
	       by inlining.  For example, parameter value 20 limits unit
	       growth to 1.2 times the original size. Cold functions (either
	       marked cold via an attribute or by profile feedback) are not
	       accounted into the unit size.

	   ipa-cp-unit-growth
	       Specifies maximal overall growth of the compilation unit caused
	       by interprocedural constant propagation.	 For example,
	       parameter value 10 limits unit growth to 1.1 times the original
	       size.

	   ipa-cp-large-unit-insns
	       The size of translation unit that IPA-CP pass considers large.

	   large-stack-frame
	       The limit specifying large stack frames.	 While inlining the
	       algorithm is trying to not grow past this limit too much.

	   large-stack-frame-growth
	       Specifies maximal growth of large stack frames caused by
	       inlining in percents.  For example, parameter value 1000 limits
	       large stack frame growth to 11 times the original size.

	   max-inline-insns-recursive
	   max-inline-insns-recursive-auto
	       Specifies the maximum number of instructions an out-of-line
	       copy of a self-recursive inline function can grow into by
	       performing recursive inlining.

	       --param max-inline-insns-recursive applies to functions
	       declared inline.	 For functions not declared inline, recursive
	       inlining happens only when -finline-functions (included in -O3)
	       is enabled; --param max-inline-insns-recursive-auto applies
	       instead.

	   max-inline-recursive-depth
	   max-inline-recursive-depth-auto
	       Specifies the maximum recursion depth used for recursive
	       inlining.

	       --param max-inline-recursive-depth applies to functions
	       declared inline.	 For functions not declared inline, recursive
	       inlining happens only when -finline-functions (included in -O3)
	       is enabled; --param max-inline-recursive-depth-auto applies
	       instead.

	   min-inline-recursive-probability
	       Recursive inlining is profitable only for function having deep
	       recursion in average and can hurt for function having little
	       recursion depth by increasing the prologue size or complexity
	       of function body to other optimizers.

	       When profile feedback is available (see -fprofile-generate) the
	       actual recursion depth can be guessed from the probability that
	       function recurses via a given call expression.  This parameter
	       limits inlining only to call expressions whose probability
	       exceeds the given threshold (in percents).

	   early-inlining-insns
	       Specify growth that the early inliner can make.	In effect it
	       increases the amount of inlining for code having a large
	       abstraction penalty.

	   max-early-inliner-iterations
	       Limit of iterations of the early inliner.  This basically
	       bounds the number of nested indirect calls the early inliner
	       can resolve.  Deeper chains are still handled by late inlining.

	   comdat-sharing-probability
	       Probability (in percent) that C++ inline function with comdat
	       visibility are shared across multiple compilation units.

	   modref-max-bases
	   modref-max-refs
	   modref-max-accesses
	       Specifies the maximal number of base pointers, references and
	       accesses stored for a single function by mod/ref analysis.

	   modref-max-tests
	       Specifies the maxmal number of tests alias oracle can perform
	       to disambiguate memory locations using the mod/ref information.
	       This parameter ought to be bigger than --param modref-max-bases
	       and --param modref-max-refs.

	   modref-max-depth
	       Specifies the maximum depth of DFS walk used by modref escape
	       analysis.  Setting to 0 disables the analysis completely.

	   modref-max-escape-points
	       Specifies the maximum number of escape points tracked by modref
	       per SSA-name.

	   modref-max-adjustments
	       Specifies the maximum number the access range is enlarged
	       during modref dataflow analysis.

	   profile-func-internal-id
	       A parameter to control whether to use function internal id in
	       profile database lookup. If the value is 0, the compiler uses
	       an id that is based on function assembler name and filename,
	       which makes old profile data more tolerant to source changes
	       such as function reordering etc.

	   min-vect-loop-bound
	       The minimum number of iterations under which loops are not
	       vectorized when -ftree-vectorize is used.  The number of
	       iterations after vectorization needs to be greater than the
	       value specified by this option to allow vectorization.

	   gcse-cost-distance-ratio
	       Scaling factor in calculation of maximum distance an expression
	       can be moved by GCSE optimizations.  This is currently
	       supported only in the code hoisting pass.  The bigger the
	       ratio, the more aggressive code hoisting is with simple
	       expressions, i.e., the expressions that have cost less than
	       gcse-unrestricted-cost.	Specifying 0 disables hoisting of
	       simple expressions.

	   gcse-unrestricted-cost
	       Cost, roughly measured as the cost of a single typical machine
	       instruction, at which GCSE optimizations do not constrain the
	       distance an expression can travel.  This is currently supported
	       only in the code hoisting pass.	The lesser the cost, the more
	       aggressive code hoisting is.  Specifying 0 allows all
	       expressions to travel unrestricted distances.

	   max-hoist-depth
	       The depth of search in the dominator tree for expressions to
	       hoist.  This is used to avoid quadratic behavior in hoisting
	       algorithm.  The value of 0 does not limit on the search, but
	       may slow down compilation of huge functions.

	   max-tail-merge-comparisons
	       The maximum amount of similar bbs to compare a bb with.	This
	       is used to avoid quadratic behavior in tree tail merging.

	   max-tail-merge-iterations
	       The maximum amount of iterations of the pass over the function.
	       This is used to limit compilation time in tree tail merging.

	   store-merging-allow-unaligned
	       Allow the store merging pass to introduce unaligned stores if
	       it is legal to do so.

	   max-stores-to-merge
	       The maximum number of stores to attempt to merge into wider
	       stores in the store merging pass.

	   max-store-chains-to-track
	       The maximum number of store chains to track at the same time in
	       the attempt to merge them into wider stores in the store
	       merging pass.

	   max-stores-to-track
	       The maximum number of stores to track at the same time in the
	       attemt to to merge them into wider stores in the store merging
	       pass.

	   max-unrolled-insns
	       The maximum number of instructions that a loop may have to be
	       unrolled.  If a loop is unrolled, this parameter also
	       determines how many times the loop code is unrolled.

	   max-average-unrolled-insns
	       The maximum number of instructions biased by probabilities of
	       their execution that a loop may have to be unrolled.  If a loop
	       is unrolled, this parameter also determines how many times the
	       loop code is unrolled.

	   max-unroll-times
	       The maximum number of unrollings of a single loop.

	   max-peeled-insns
	       The maximum number of instructions that a loop may have to be
	       peeled.	If a loop is peeled, this parameter also determines
	       how many times the loop code is peeled.

	   max-peel-times
	       The maximum number of peelings of a single loop.

	   max-peel-branches
	       The maximum number of branches on the hot path through the
	       peeled sequence.

	   max-completely-peeled-insns
	       The maximum number of insns of a completely peeled loop.

	   max-completely-peel-times
	       The maximum number of iterations of a loop to be suitable for
	       complete peeling.

	   max-completely-peel-loop-nest-depth
	       The maximum depth of a loop nest suitable for complete peeling.

	   max-unswitch-insns
	       The maximum number of insns of an unswitched loop.

	   max-unswitch-depth
	       The maximum depth of a loop nest to be unswitched.

	   lim-expensive
	       The minimum cost of an expensive expression in the loop
	       invariant motion.

	   min-loop-cond-split-prob
	       When FDO profile information is available, min-loop-cond-split-
	       prob specifies minimum threshold for probability of semi-
	       invariant condition statement to trigger loop split.

	   iv-consider-all-candidates-bound
	       Bound on number of candidates for induction variables, below
	       which all candidates are considered for each use in induction
	       variable optimizations.	If there are more candidates than
	       this, only the most relevant ones are considered to avoid
	       quadratic time complexity.

	   iv-max-considered-uses
	       The induction variable optimizations give up on loops that
	       contain more induction variable uses.

	   iv-always-prune-cand-set-bound
	       If the number of candidates in the set is smaller than this
	       value, always try to remove unnecessary ivs from the set when
	       adding a new one.

	   avg-loop-niter
	       Average number of iterations of a loop.

	   dse-max-object-size
	       Maximum size (in bytes) of objects tracked bytewise by dead
	       store elimination.  Larger values may result in larger
	       compilation times.

	   dse-max-alias-queries-per-store
	       Maximum number of queries into the alias oracle per store.
	       Larger values result in larger compilation times and may result
	       in more removed dead stores.

	   scev-max-expr-size
	       Bound on size of expressions used in the scalar evolutions
	       analyzer.  Large expressions slow the analyzer.

	   scev-max-expr-complexity
	       Bound on the complexity of the expressions in the scalar
	       evolutions analyzer.  Complex expressions slow the analyzer.

	   max-tree-if-conversion-phi-args
	       Maximum number of arguments in a PHI supported by TREE if
	       conversion unless the loop is marked with simd pragma.

	   vect-max-layout-candidates
	       The maximum number of possible vector layouts (such as
	       permutations) to consider when optimizing to-be-vectorized
	       code.

	   vect-max-version-for-alignment-checks
	       The maximum number of run-time checks that can be performed
	       when doing loop versioning for alignment in the vectorizer.

	   vect-max-version-for-alias-checks
	       The maximum number of run-time checks that can be performed
	       when doing loop versioning for alias in the vectorizer.

	   vect-max-peeling-for-alignment
	       The maximum number of loop peels to enhance access alignment
	       for vectorizer. Value -1 means no limit.

	   max-iterations-to-track
	       The maximum number of iterations of a loop the brute-force
	       algorithm for analysis of the number of iterations of the loop
	       tries to evaluate.

	   hot-bb-count-fraction
	       The denominator n of fraction 1/n of the maximal execution
	       count of a basic block in the entire program that a basic block
	       needs to at least have in order to be considered hot.  The
	       default is 10000, which means that a basic block is considered
	       hot if its execution count is greater than 1/10000 of the
	       maximal execution count.	 0 means that it is never considered
	       hot.  Used in non-LTO mode.

	   hot-bb-count-ws-permille
	       The number of most executed permilles, ranging from 0 to 1000,
	       of the profiled execution of the entire program to which the
	       execution count of a basic block must be part of in order to be
	       considered hot.	The default is 990, which means that a basic
	       block is considered hot if its execution count contributes to
	       the upper 990 permilles, or 99.0%, of the profiled execution of
	       the entire program.  0 means that it is never considered hot.
	       Used in LTO mode.

	   hot-bb-frequency-fraction
	       The denominator n of fraction 1/n of the execution frequency of
	       the entry block of a function that a basic block of this
	       function needs to at least have in order to be considered hot.
	       The default is 1000, which means that a basic block is
	       considered hot in a function if it is executed more frequently
	       than 1/1000 of the frequency of the entry block of the
	       function.  0 means that it is never considered hot.

	   unlikely-bb-count-fraction
	       The denominator n of fraction 1/n of the number of profiled
	       runs of the entire program below which the execution count of a
	       basic block must be in order for the basic block to be
	       considered unlikely executed.  The default is 20, which means
	       that a basic block is considered unlikely executed if it is
	       executed in fewer than 1/20, or 5%, of the runs of the program.
	       0 means that it is always considered unlikely executed.

	   max-predicted-iterations
	       The maximum number of loop iterations we predict statically.
	       This is useful in cases where a function contains a single loop
	       with known bound and another loop with unknown bound.  The
	       known number of iterations is predicted correctly, while the
	       unknown number of iterations average to roughly 10.  This means
	       that the loop without bounds appears artificially cold relative
	       to the other one.

	   builtin-expect-probability
	       Control the probability of the expression having the specified
	       value. This parameter takes a percentage (i.e. 0 ... 100) as
	       input.

	   builtin-string-cmp-inline-length
	       The maximum length of a constant string for a builtin string
	       cmp call eligible for inlining.

	   align-threshold
	       Select fraction of the maximal frequency of executions of a
	       basic block in a function to align the basic block.

	   align-loop-iterations
	       A loop expected to iterate at least the selected number of
	       iterations is aligned.

	   tracer-dynamic-coverage
	   tracer-dynamic-coverage-feedback
	       This value is used to limit superblock formation once the given
	       percentage of executed instructions is covered.	This limits
	       unnecessary code size expansion.

	       The tracer-dynamic-coverage-feedback parameter is used only
	       when profile feedback is available.  The real profiles (as
	       opposed to statically estimated ones) are much less balanced
	       allowing the threshold to be larger value.

	   tracer-max-code-growth
	       Stop tail duplication once code growth has reached given
	       percentage.  This is a rather artificial limit, as most of the
	       duplicates are eliminated later in cross jumping, so it may be
	       set to much higher values than is the desired code growth.

	   tracer-min-branch-ratio
	       Stop reverse growth when the reverse probability of best edge
	       is less than this threshold (in percent).

	   tracer-min-branch-probability
	   tracer-min-branch-probability-feedback
	       Stop forward growth if the best edge has probability lower than
	       this threshold.

	       Similarly to tracer-dynamic-coverage two parameters are
	       provided.  tracer-min-branch-probability-feedback is used for
	       compilation with profile feedback and tracer-min-branch-
	       probability compilation without.	 The value for compilation
	       with profile feedback needs to be more conservative (higher) in
	       order to make tracer effective.

	   stack-clash-protection-guard-size
	       Specify the size of the operating system provided stack guard
	       as 2 raised to num bytes.  Higher values may reduce the number
	       of explicit probes, but a value larger than the operating
	       system provided guard will leave code vulnerable to stack clash
	       style attacks.

	   stack-clash-protection-probe-interval
	       Stack clash protection involves probing stack space as it is
	       allocated.  This param controls the maximum distance between
	       probes into the stack as 2 raised to num bytes.	Higher values
	       may reduce the number of explicit probes, but a value larger
	       than the operating system provided guard will leave code
	       vulnerable to stack clash style attacks.

	   max-cse-path-length
	       The maximum number of basic blocks on path that CSE considers.

	   max-cse-insns
	       The maximum number of instructions CSE processes before
	       flushing.

	   ggc-min-expand
	       GCC uses a garbage collector to manage its own memory
	       allocation.  This parameter specifies the minimum percentage by
	       which the garbage collector's heap should be allowed to expand
	       between collections.  Tuning this may improve compilation
	       speed; it has no effect on code generation.

	       The default is 30% + 70% * (RAM/1GB) with an upper bound of
	       100% when RAM >= 1GB.  If "getrlimit" is available, the notion
	       of "RAM" is the smallest of actual RAM and "RLIMIT_DATA" or
	       "RLIMIT_AS".  If GCC is not able to calculate RAM on a
	       particular platform, the lower bound of 30% is used.  Setting
	       this parameter and ggc-min-heapsize to zero causes a full
	       collection to occur at every opportunity.  This is extremely
	       slow, but can be useful for debugging.

	   ggc-min-heapsize
	       Minimum size of the garbage collector's heap before it begins
	       bothering to collect garbage.  The first collection occurs
	       after the heap expands by ggc-min-expand% beyond ggc-min-
	       heapsize.  Again, tuning this may improve compilation speed,
	       and has no effect on code generation.

	       The default is the smaller of RAM/8, RLIMIT_RSS, or a limit
	       that tries to ensure that RLIMIT_DATA or RLIMIT_AS are not
	       exceeded, but with a lower bound of 4096 (four megabytes) and
	       an upper bound of 131072 (128 megabytes).  If GCC is not able
	       to calculate RAM on a particular platform, the lower bound is
	       used.  Setting this parameter very large effectively disables
	       garbage collection.  Setting this parameter and ggc-min-expand
	       to zero causes a full collection to occur at every opportunity.

	   max-reload-search-insns
	       The maximum number of instruction reload should look backward
	       for equivalent register.	 Increasing values mean more
	       aggressive optimization, making the compilation time increase
	       with probably slightly better performance.

	   max-cselib-memory-locations
	       The maximum number of memory locations cselib should take into
	       account.	 Increasing values mean more aggressive optimization,
	       making the compilation time increase with probably slightly
	       better performance.

	   max-sched-ready-insns
	       The maximum number of instructions ready to be issued the
	       scheduler should consider at any given time during the first
	       scheduling pass.	 Increasing values mean more thorough
	       searches, making the compilation time increase with probably
	       little benefit.

	   max-sched-region-blocks
	       The maximum number of blocks in a region to be considered for
	       interblock scheduling.

	   max-pipeline-region-blocks
	       The maximum number of blocks in a region to be considered for
	       pipelining in the selective scheduler.

	   max-sched-region-insns
	       The maximum number of insns in a region to be considered for
	       interblock scheduling.

	   max-pipeline-region-insns
	       The maximum number of insns in a region to be considered for
	       pipelining in the selective scheduler.

	   min-spec-prob
	       The minimum probability (in percents) of reaching a source
	       block for interblock speculative scheduling.

	   max-sched-extend-regions-iters
	       The maximum number of iterations through CFG to extend regions.
	       A value of 0 disables region extensions.

	   max-sched-insn-conflict-delay
	       The maximum conflict delay for an insn to be considered for
	       speculative motion.

	   sched-spec-prob-cutoff
	       The minimal probability of speculation success (in percents),
	       so that speculative insns are scheduled.

	   sched-state-edge-prob-cutoff
	       The minimum probability an edge must have for the scheduler to
	       save its state across it.

	   sched-mem-true-dep-cost
	       Minimal distance (in CPU cycles) between store and load
	       targeting same memory locations.

	   selsched-max-lookahead
	       The maximum size of the lookahead window of selective
	       scheduling.  It is a depth of search for available
	       instructions.

	   selsched-max-sched-times
	       The maximum number of times that an instruction is scheduled
	       during selective scheduling.  This is the limit on the number
	       of iterations through which the instruction may be pipelined.

	   selsched-insns-to-rename
	       The maximum number of best instructions in the ready list that
	       are considered for renaming in the selective scheduler.

	   sms-min-sc
	       The minimum value of stage count that swing modulo scheduler
	       generates.

	   max-last-value-rtl
	       The maximum size measured as number of RTLs that can be
	       recorded in an expression in combiner for a pseudo register as
	       last known value of that register.

	   max-combine-insns
	       The maximum number of instructions the RTL combiner tries to
	       combine.

	   integer-share-limit
	       Small integer constants can use a shared data structure,
	       reducing the compiler's memory usage and increasing its speed.
	       This sets the maximum value of a shared integer constant.

	   ssp-buffer-size
	       The minimum size of buffers (i.e. arrays) that receive stack
	       smashing protection when -fstack-protector is used.

	   min-size-for-stack-sharing
	       The minimum size of variables taking part in stack slot sharing
	       when not optimizing.

	   max-jump-thread-duplication-stmts
	       Maximum number of statements allowed in a block that needs to
	       be duplicated when threading jumps.

	   max-jump-thread-paths
	       The maximum number of paths to consider when searching for jump
	       threading opportunities.	 When arriving at a block, incoming
	       edges are only considered if the number of paths to be searched
	       so far multiplied by the number of incoming edges does not
	       exhaust the specified maximum number of paths to consider.

	   max-fields-for-field-sensitive
	       Maximum number of fields in a structure treated in a field
	       sensitive manner during pointer analysis.

	   prefetch-latency
	       Estimate on average number of instructions that are executed
	       before prefetch finishes.  The distance prefetched ahead is
	       proportional to this constant.  Increasing this number may also
	       lead to less streams being prefetched (see simultaneous-
	       prefetches).

	   simultaneous-prefetches
	       Maximum number of prefetches that can run at the same time.

	   l1-cache-line-size
	       The size of cache line in L1 data cache, in bytes.

	   l1-cache-size
	       The size of L1 data cache, in kilobytes.

	   l2-cache-size
	       The size of L2 data cache, in kilobytes.

	   prefetch-dynamic-strides
	       Whether the loop array prefetch pass should issue software
	       prefetch hints for strides that are non-constant.  In some
	       cases this may be beneficial, though the fact the stride is
	       non-constant may make it hard to predict when there is clear
	       benefit to issuing these hints.

	       Set to 1 if the prefetch hints should be issued for non-
	       constant strides.  Set to 0 if prefetch hints should be issued
	       only for strides that are known to be constant and below
	       prefetch-minimum-stride.

	   prefetch-minimum-stride
	       Minimum constant stride, in bytes, to start using prefetch
	       hints for.  If the stride is less than this threshold, prefetch
	       hints will not be issued.

	       This setting is useful for processors that have hardware
	       prefetchers, in which case there may be conflicts between the
	       hardware prefetchers and the software prefetchers.  If the
	       hardware prefetchers have a maximum stride they can handle, it
	       should be used here to improve the use of software prefetchers.

	       A value of -1 means we don't have a threshold and therefore
	       prefetch hints can be issued for any constant stride.

	       This setting is only useful for strides that are known and
	       constant.

	   destructive-interference-size
	   constructive-interference-size
	       The values for the C++17 variables
	       "std::hardware_destructive_interference_size" and
	       "std::hardware_constructive_interference_size".	The
	       destructive interference size is the minimum recommended offset
	       between two independent concurrently-accessed objects; the
	       constructive interference size is the maximum recommended size
	       of contiguous memory accessed together.	Typically both will be
	       the size of an L1 cache line for the target, in bytes.  For a
	       generic target covering a range of L1 cache line sizes,
	       typically the constructive interference size will be the small
	       end of the range and the destructive size will be the large
	       end.

	       The destructive interference size is intended to be used for
	       layout, and thus has ABI impact.	 The default value is not
	       expected to be stable, and on some targets varies with -mtune,
	       so use of this variable in a context where ABI stability is
	       important, such as the public interface of a library, is
	       strongly discouraged; if it is used in that context, users can
	       stabilize the value using this option.

	       The constructive interference size is less sensitive, as it is
	       typically only used in a static_assert to make sure that a type
	       fits within a cache line.

	       See also -Winterference-size.

	   loop-interchange-max-num-stmts
	       The maximum number of stmts in a loop to be interchanged.

	   loop-interchange-stride-ratio
	       The minimum ratio between stride of two loops for interchange
	       to be profitable.

	   min-insn-to-prefetch-ratio
	       The minimum ratio between the number of instructions and the
	       number of prefetches to enable prefetching in a loop.

	   prefetch-min-insn-to-mem-ratio
	       The minimum ratio between the number of instructions and the
	       number of memory references to enable prefetching in a loop.

	   use-canonical-types
	       Whether the compiler should use the "canonical" type system.
	       Should always be 1, which uses a more efficient internal
	       mechanism for comparing types in C++ and Objective-C++.
	       However, if bugs in the canonical type system are causing
	       compilation failures, set this value to 0 to disable canonical
	       types.

	   switch-conversion-max-branch-ratio
	       Switch initialization conversion refuses to create arrays that
	       are bigger than switch-conversion-max-branch-ratio times the
	       number of branches in the switch.

	   max-partial-antic-length
	       Maximum length of the partial antic set computed during the
	       tree partial redundancy elimination optimization (-ftree-pre)
	       when optimizing at -O3 and above.  For some sorts of source
	       code the enhanced partial redundancy elimination optimization
	       can run away, consuming all of the memory available on the host
	       machine.	 This parameter sets a limit on the length of the sets
	       that are computed, which prevents the runaway behavior.
	       Setting a value of 0 for this parameter allows an unlimited set
	       length.

	   rpo-vn-max-loop-depth
	       Maximum loop depth that is value-numbered optimistically.  When
	       the limit hits the innermost rpo-vn-max-loop-depth loops and
	       the outermost loop in the loop nest are value-numbered
	       optimistically and the remaining ones not.

	   sccvn-max-alias-queries-per-access
	       Maximum number of alias-oracle queries we perform when looking
	       for redundancies for loads and stores.  If this limit is hit
	       the search is aborted and the load or store is not considered
	       redundant.  The number of queries is algorithmically limited to
	       the number of stores on all paths from the load to the function
	       entry.

	   ira-max-loops-num
	       IRA uses regional register allocation by default.  If a
	       function contains more loops than the number given by this
	       parameter, only at most the given number of the most
	       frequently-executed loops form regions for regional register
	       allocation.

	   ira-max-conflict-table-size
	       Although IRA uses a sophisticated algorithm to compress the
	       conflict table, the table can still require excessive amounts
	       of memory for huge functions.  If the conflict table for a
	       function could be more than the size in MB given by this
	       parameter, the register allocator instead uses a faster,
	       simpler, and lower-quality algorithm that does not require
	       building a pseudo-register conflict table.

	   ira-loop-reserved-regs
	       IRA can be used to evaluate more accurate register pressure in
	       loops for decisions to move loop invariants (see -O3).  The
	       number of available registers reserved for some other purposes
	       is given by this parameter.  Default of the parameter is the
	       best found from numerous experiments.

	   ira-consider-dup-in-all-alts
	       Make IRA to consider matching constraint (duplicated operand
	       number) heavily in all available alternatives for preferred
	       register class.	If it is set as zero, it means IRA only
	       respects the matching constraint when it's in the only
	       available alternative with an appropriate register class.
	       Otherwise, it means IRA will check all available alternatives
	       for preferred register class even if it has found some choice
	       with an appropriate register class and respect the found
	       qualified matching constraint.

	   ira-simple-lra-insn-threshold
	       Approximate function insn number in 1K units triggering simple
	       local RA.

	   lra-inheritance-ebb-probability-cutoff
	       LRA tries to reuse values reloaded in registers in subsequent
	       insns.  This optimization is called inheritance.	 EBB is used
	       as a region to do this optimization.  The parameter defines a
	       minimal fall-through edge probability in percentage used to add
	       BB to inheritance EBB in LRA.  The default value was chosen
	       from numerous runs of SPEC2000 on x86-64.

	   loop-invariant-max-bbs-in-loop
	       Loop invariant motion can be very expensive, both in
	       compilation time and in amount of needed compile-time memory,
	       with very large loops.  Loops with more basic blocks than this
	       parameter won't have loop invariant motion optimization
	       performed on them.

	   loop-max-datarefs-for-datadeps
	       Building data dependencies is expensive for very large loops.
	       This parameter limits the number of data references in loops
	       that are considered for data dependence analysis.  These large
	       loops are no handled by the optimizations using loop data
	       dependencies.

	   max-vartrack-size
	       Sets a maximum number of hash table slots to use during
	       variable tracking dataflow analysis of any function.  If this
	       limit is exceeded with variable tracking at assignments
	       enabled, analysis for that function is retried without it,
	       after removing all debug insns from the function.  If the limit
	       is exceeded even without debug insns, var tracking analysis is
	       completely disabled for the function.  Setting the parameter to
	       zero makes it unlimited.

	   max-vartrack-expr-depth
	       Sets a maximum number of recursion levels when attempting to
	       map variable names or debug temporaries to value expressions.
	       This trades compilation time for more complete debug
	       information.  If this is set too low, value expressions that
	       are available and could be represented in debug information may
	       end up not being used; setting this higher may enable the
	       compiler to find more complex debug expressions, but compile
	       time and memory use may grow.

	   max-debug-marker-count
	       Sets a threshold on the number of debug markers (e.g. begin
	       stmt markers) to avoid complexity explosion at inlining or
	       expanding to RTL.  If a function has more such gimple stmts
	       than the set limit, such stmts will be dropped from the inlined
	       copy of a function, and from its RTL expansion.

	   min-nondebug-insn-uid
	       Use uids starting at this parameter for nondebug insns.	The
	       range below the parameter is reserved exclusively for debug
	       insns created by -fvar-tracking-assignments, but debug insns
	       may get (non-overlapping) uids above it if the reserved range
	       is exhausted.

	   ipa-sra-deref-prob-threshold
	       IPA-SRA replaces a pointer which is known not be NULL with one
	       or more new parameters only when the probability (in percent,
	       relative to function entry) of it being dereferenced is higher
	       than this parameter.

	   ipa-sra-ptr-growth-factor
	       IPA-SRA replaces a pointer to an aggregate with one or more new
	       parameters only when their cumulative size is less or equal to
	       ipa-sra-ptr-growth-factor times the size of the original
	       pointer parameter.

	   ipa-sra-ptrwrap-growth-factor
	       Additional maximum allowed growth of total size of new
	       parameters that ipa-sra replaces a pointer to an aggregate
	       with, if it points to a local variable that the caller only
	       writes to and passes it as an argument to other functions.

	   ipa-sra-max-replacements
	       Maximum pieces of an aggregate that IPA-SRA tracks.  As a
	       consequence, it is also the maximum number of replacements of a
	       formal parameter.

	   sra-max-scalarization-size-Ospeed
	   sra-max-scalarization-size-Osize
	       The two Scalar Reduction of Aggregates passes (SRA and IPA-SRA)
	       aim to replace scalar parts of aggregates with uses of
	       independent scalar variables.  These parameters control the
	       maximum size, in storage units, of aggregate which is
	       considered for replacement when compiling for speed (sra-max-
	       scalarization-size-Ospeed) or size (sra-max-scalarization-size-
	       Osize) respectively.

	   sra-max-propagations
	       The maximum number of artificial accesses that Scalar
	       Replacement of Aggregates (SRA) will track, per one local
	       variable, in order to facilitate copy propagation.

	   tm-max-aggregate-size
	       When making copies of thread-local variables in a transaction,
	       this parameter specifies the size in bytes after which
	       variables are saved with the logging functions as opposed to
	       save/restore code sequence pairs.  This option only applies
	       when using -fgnu-tm.

	   graphite-max-nb-scop-params
	       To avoid exponential effects in the Graphite loop transforms,
	       the number of parameters in a Static Control Part (SCoP) is
	       bounded.	 A value of zero can be used to lift the bound.	 A
	       variable whose value is unknown at compilation time and defined
	       outside a SCoP is a parameter of the SCoP.

	   hardcfr-max-blocks
	       Disable -fharden-control-flow-redundancy for functions with a
	       larger number of blocks than the specified value.  Zero removes
	       any limit.

	   hardcfr-max-inline-blocks
	       Force -fharden-control-flow-redundancy to use out-of-line
	       checking for functions with a larger number of basic blocks
	       than the specified value.

	   loop-block-tile-size
	       Loop blocking or strip mining transforms, enabled with
	       -floop-block or -floop-strip-mine, strip mine each loop in the
	       loop nest by a given number of iterations.  The strip length
	       can be changed using the loop-block-tile-size parameter.

	   ipa-jump-function-lookups
	       Specifies number of statements visited during jump function
	       offset discovery.

	   ipa-cp-value-list-size
	       IPA-CP attempts to track all possible values and types passed
	       to a function's parameter in order to propagate them and
	       perform devirtualization.  ipa-cp-value-list-size is the
	       maximum number of values and types it stores per one formal
	       parameter of a function.

	   ipa-cp-eval-threshold
	       IPA-CP calculates its own score of cloning profitability
	       heuristics and performs those cloning opportunities with scores
	       that exceed ipa-cp-eval-threshold.

	   ipa-cp-max-recursive-depth
	       Maximum depth of recursive cloning for self-recursive function.

	   ipa-cp-min-recursive-probability
	       Recursive cloning only when the probability of call being
	       executed exceeds the parameter.

	   ipa-cp-profile-count-base
	       When using -fprofile-use option, IPA-CP will consider the
	       measured execution count of a call graph edge at this
	       percentage position in their histogram as the basis for its
	       heuristics calculation.

	   ipa-cp-recursive-freq-factor
	       The number of times interprocedural copy propagation expects
	       recursive functions to call themselves.

	   ipa-cp-recursion-penalty
	       Percentage penalty the recursive functions will receive when
	       they are evaluated for cloning.

	   ipa-cp-single-call-penalty
	       Percentage penalty functions containing a single call to
	       another function will receive when they are evaluated for
	       cloning.

	   ipa-max-agg-items
	       IPA-CP is also capable to propagate a number of scalar values
	       passed in an aggregate. ipa-max-agg-items controls the maximum
	       number of such values per one parameter.

	   ipa-cp-loop-hint-bonus
	       When IPA-CP determines that a cloning candidate would make the
	       number of iterations of a loop known, it adds a bonus of ipa-
	       cp-loop-hint-bonus to the profitability score of the candidate.

	   ipa-max-loop-predicates
	       The maximum number of different predicates IPA will use to
	       describe when loops in a function have known properties.

	   ipa-max-aa-steps
	       During its analysis of function bodies, IPA-CP employs alias
	       analysis in order to track values pointed to by function
	       parameters.  In order not spend too much time analyzing huge
	       functions, it gives up and consider all memory clobbered after
	       examining ipa-max-aa-steps statements modifying memory.

	   ipa-max-switch-predicate-bounds
	       Maximal number of boundary endpoints of case ranges of switch
	       statement.  For switch exceeding this limit, IPA-CP will not
	       construct cloning cost predicate, which is used to estimate
	       cloning benefit, for default case of the switch statement.

	   ipa-max-param-expr-ops
	       IPA-CP will analyze conditional statement that references some
	       function parameter to estimate benefit for cloning upon certain
	       constant value.	But if number of operations in a parameter
	       expression exceeds ipa-max-param-expr-ops, the expression is
	       treated as complicated one, and is not handled by IPA analysis.

	   lto-partitions
	       Specify desired number of partitions produced during WHOPR
	       compilation.  The number of partitions should exceed the number
	       of CPUs used for compilation.

	   lto-min-partition
	       Size of minimal partition for WHOPR (in estimated
	       instructions).  This prevents expenses of splitting very small
	       programs into too many partitions.

	   lto-max-partition
	       Size of max partition for WHOPR (in estimated instructions).
	       to provide an upper bound for individual size of partition.
	       Meant to be used only with balanced partitioning.

	   lto-max-streaming-parallelism
	       Maximal number of parallel processes used for LTO streaming.

	   cxx-max-namespaces-for-diagnostic-help
	       The maximum number of namespaces to consult for suggestions
	       when C++ name lookup fails for an identifier.

	   sink-frequency-threshold
	       The maximum relative execution frequency (in percents) of the
	       target block relative to a statement's original block to allow
	       statement sinking of a statement.  Larger numbers result in
	       more aggressive statement sinking.  A small positive adjustment
	       is applied for statements with memory operands as those are
	       even more profitable so sink.

	   max-stores-to-sink
	       The maximum number of conditional store pairs that can be sunk.
	       Set to 0 if either vectorization (-ftree-vectorize) or if-
	       conversion (-ftree-loop-if-convert) is disabled.

	   case-values-threshold
	       The smallest number of different values for which it is best to
	       use a jump-table instead of a tree of conditional branches.  If
	       the value is 0, use the default for the machine.

	   jump-table-max-growth-ratio-for-size
	       The maximum code size growth ratio when expanding into a jump
	       table (in percent).  The parameter is used when optimizing for
	       size.

	   jump-table-max-growth-ratio-for-speed
	       The maximum code size growth ratio when expanding into a jump
	       table (in percent).  The parameter is used when optimizing for
	       speed.

	   tree-reassoc-width
	       Set the maximum number of instructions executed in parallel in
	       reassociated tree. This parameter overrides target dependent
	       heuristics used by default if has non zero value.

	   sched-pressure-algorithm
	       Choose between the two available implementations of
	       -fsched-pressure.  Algorithm 1 is the original implementation
	       and is the more likely to prevent instructions from being
	       reordered.  Algorithm 2 was designed to be a compromise between
	       the relatively conservative approach taken by algorithm 1 and
	       the rather aggressive approach taken by the default scheduler.
	       It relies more heavily on having a regular register file and
	       accurate register pressure classes.  See haifa-sched.cc in the
	       GCC sources for more details.

	       The default choice depends on the target.

	   max-slsr-cand-scan
	       Set the maximum number of existing candidates that are
	       considered when seeking a basis for a new straight-line
	       strength reduction candidate.

	   asan-globals
	       Enable buffer overflow detection for global objects.  This kind
	       of protection is enabled by default if you are using
	       -fsanitize=address option.  To disable global objects
	       protection use --param asan-globals=0.

	   asan-stack
	       Enable buffer overflow detection for stack objects.  This kind
	       of protection is enabled by default when using
	       -fsanitize=address.  To disable stack protection use --param
	       asan-stack=0 option.

	   asan-instrument-reads
	       Enable buffer overflow detection for memory reads.  This kind
	       of protection is enabled by default when using
	       -fsanitize=address.  To disable memory reads protection use
	       --param asan-instrument-reads=0.

	   asan-instrument-writes
	       Enable buffer overflow detection for memory writes.  This kind
	       of protection is enabled by default when using
	       -fsanitize=address.  To disable memory writes protection use
	       --param asan-instrument-writes=0 option.

	   asan-memintrin
	       Enable detection for built-in functions.	 This kind of
	       protection is enabled by default when using -fsanitize=address.
	       To disable built-in functions protection use --param
	       asan-memintrin=0.

	   asan-use-after-return
	       Enable detection of use-after-return.  This kind of protection
	       is enabled by default when using the -fsanitize=address option.
	       To disable it use --param asan-use-after-return=0.

	       Note: By default the check is disabled at run time.  To enable
	       it, add "detect_stack_use_after_return=1" to the environment
	       variable ASAN_OPTIONS.

	   asan-instrumentation-with-call-threshold
	       If number of memory accesses in function being instrumented is
	       greater or equal to this number, use callbacks instead of
	       inline checks.  E.g. to disable inline code use --param
	       asan-instrumentation-with-call-threshold=0.

	   asan-kernel-mem-intrinsic-prefix
	       If nonzero, prefix calls to "memcpy", "memset" and "memmove"
	       with __asan_ or __hwasan_ for -fsanitize=kernel-address or
	       -fsanitize=kernel-hwaddress, respectively.

	   hwasan-instrument-stack
	       Enable hwasan instrumentation of statically sized stack-
	       allocated variables.  This kind of instrumentation is enabled
	       by default when using -fsanitize=hwaddress and disabled by
	       default when using -fsanitize=kernel-hwaddress.	To disable
	       stack instrumentation use --param hwasan-instrument-stack=0,
	       and to enable it use --param hwasan-instrument-stack=1.

	   hwasan-random-frame-tag
	       When using stack instrumentation, decide tags for stack
	       variables using a deterministic sequence beginning at a random
	       tag for each frame.  With this parameter unset tags are chosen
	       using the same sequence but beginning from 1.  This is enabled
	       by default for -fsanitize=hwaddress and unavailable for
	       -fsanitize=kernel-hwaddress.  To disable it use --param
	       hwasan-random-frame-tag=0.

	   hwasan-instrument-allocas
	       Enable hwasan instrumentation of dynamically sized stack-
	       allocated variables.  This kind of instrumentation is enabled
	       by default when using -fsanitize=hwaddress and disabled by
	       default when using -fsanitize=kernel-hwaddress.	To disable
	       instrumentation of such variables use --param
	       hwasan-instrument-allocas=0, and to enable it use --param
	       hwasan-instrument-allocas=1.

	   hwasan-instrument-reads
	       Enable hwasan checks on memory reads.  Instrumentation of reads
	       is enabled by default for both -fsanitize=hwaddress and
	       -fsanitize=kernel-hwaddress.  To disable checking memory reads
	       use --param hwasan-instrument-reads=0.

	   hwasan-instrument-writes
	       Enable hwasan checks on memory writes.  Instrumentation of
	       writes is enabled by default for both -fsanitize=hwaddress and
	       -fsanitize=kernel-hwaddress.  To disable checking memory writes
	       use --param hwasan-instrument-writes=0.

	   hwasan-instrument-mem-intrinsics
	       Enable hwasan instrumentation of builtin functions.
	       Instrumentation of these builtin functions is enabled by
	       default for both -fsanitize=hwaddress and
	       -fsanitize=kernel-hwaddress.  To disable instrumentation of
	       builtin functions use --param
	       hwasan-instrument-mem-intrinsics=0.

	   use-after-scope-direct-emission-threshold
	       If the size of a local variable in bytes is smaller or equal to
	       this number, directly poison (or unpoison) shadow memory
	       instead of using run-time callbacks.

	   tsan-distinguish-volatile
	       Emit special instrumentation for accesses to volatiles.

	   tsan-instrument-func-entry-exit
	       Emit instrumentation calls to __tsan_func_entry() and
	       __tsan_func_exit().

	   max-fsm-thread-path-insns
	       Maximum number of instructions to copy when duplicating blocks
	       on a finite state automaton jump thread path.

	   threader-debug
	       threader-debug=[none|all] Enables verbose dumping of the
	       threader solver.

	   parloops-chunk-size
	       Chunk size of omp schedule for loops parallelized by parloops.

	   parloops-schedule
	       Schedule type of omp schedule for loops parallelized by
	       parloops (static, dynamic, guided, auto, runtime).

	   parloops-min-per-thread
	       The minimum number of iterations per thread of an innermost
	       parallelized loop for which the parallelized variant is
	       preferred over the single threaded one.	Note that for a
	       parallelized loop nest the minimum number of iterations of the
	       outermost loop per thread is two.

	   max-ssa-name-query-depth
	       Maximum depth of recursion when querying properties of SSA
	       names in things like fold routines.  One level of recursion
	       corresponds to following a use-def chain.

	   max-speculative-devirt-maydefs
	       The maximum number of may-defs we analyze when looking for a
	       must-def specifying the dynamic type of an object that invokes
	       a virtual call we may be able to devirtualize speculatively.

	   ranger-debug
	       Specifies the type of debug output to be issued for ranges.

	   unroll-jam-min-percent
	       The minimum percentage of memory references that must be
	       optimized away for the unroll-and-jam transformation to be
	       considered profitable.

	   unroll-jam-max-unroll
	       The maximum number of times the outer loop should be unrolled
	       by the unroll-and-jam transformation.

	   max-rtl-if-conversion-unpredictable-cost
	       Maximum permissible cost for the sequence that would be
	       generated by the RTL if-conversion pass for a branch that is
	       considered unpredictable.

	   max-variable-expansions-in-unroller
	       If -fvariable-expansion-in-unroller is used, the maximum number
	       of times that an individual variable will be expanded during
	       loop unrolling.

	   partial-inlining-entry-probability
	       Maximum probability of the entry BB of split region (in percent
	       relative to entry BB of the function) to make partial inlining
	       happen.

	   max-tracked-strlens
	       Maximum number of strings for which strlen optimization pass
	       will track string lengths.

	   gcse-after-reload-partial-fraction
	       The threshold ratio for performing partial redundancy
	       elimination after reload.

	   gcse-after-reload-critical-fraction
	       The threshold ratio of critical edges execution count that
	       permit performing redundancy elimination after reload.

	   max-loop-header-insns
	       The maximum number of insns in loop header duplicated by the
	       copy loop headers pass.

	   vect-epilogues-nomask
	       Enable loop epilogue vectorization using smaller vector size.

	   vect-partial-vector-usage
	       Controls when the loop vectorizer considers using partial
	       vector loads and stores as an alternative to falling back to
	       scalar code.  0 stops the vectorizer from ever using partial
	       vector loads and stores.	 1 allows partial vector loads and
	       stores if vectorization removes the need for the code to
	       iterate.	 2 allows partial vector loads and stores in all
	       loops.  The parameter only has an effect on targets that
	       support partial vector loads and stores.

	   vect-inner-loop-cost-factor
	       The maximum factor which the loop vectorizer applies to the
	       cost of statements in an inner loop relative to the loop being
	       vectorized.  The factor applied is the maximum of the estimated
	       number of iterations of the inner loop and this parameter.  The
	       default value of this parameter is 50.

	   vect-induction-float
	       Enable loop vectorization of floating point inductions.

	   vrp-sparse-threshold
	       Maximum number of basic blocks before VRP uses a sparse bitmap
	       cache.

	   vrp-switch-limit
	       Maximum number of outgoing edges in a switch before VRP will
	       not process it.

	   vrp-vector-threshold
	       Maximum number of basic blocks for VRP to use a basic cache
	       vector.

	   avoid-fma-max-bits
	       Maximum number of bits for which we avoid creating FMAs.

	   fully-pipelined-fma
	       Whether the target fully pipelines FMA instructions.  If non-
	       zero, reassociation considers the benefit of parallelizing
	       FMA's multiplication part and addition part, assuming FMUL and
	       FMA use the same units that can also do FADD.

	   sms-loop-average-count-threshold
	       A threshold on the average loop count considered by the swing
	       modulo scheduler.

	   sms-dfa-history
	       The number of cycles the swing modulo scheduler considers when
	       checking conflicts using DFA.

	   graphite-allow-codegen-errors
	       Whether codegen errors should be ICEs when -fchecking.

	   sms-max-ii-factor
	       A factor for tuning the upper bound that swing modulo scheduler
	       uses for scheduling a loop.

	   lra-max-considered-reload-pseudos
	       The max number of reload pseudos which are considered during
	       spilling a non-reload pseudo.

	   max-pow-sqrt-depth
	       Maximum depth of sqrt chains to use when synthesizing
	       exponentiation by a real constant.

	   max-dse-active-local-stores
	       Maximum number of active local stores in RTL dead store
	       elimination.

	   asan-instrument-allocas
	       Enable asan allocas/VLAs protection.

	   max-iterations-computation-cost
	       Bound on the cost of an expression to compute the number of
	       iterations.

	   max-isl-operations
	       Maximum number of isl operations, 0 means unlimited.

	   graphite-max-arrays-per-scop
	       Maximum number of arrays per scop.

	   max-vartrack-reverse-op-size
	       Max. size of loc list for which reverse ops should be added.

	   fsm-scale-path-stmts
	       Scale factor to apply to the number of statements in a
	       threading path crossing a loop backedge when comparing to
	       --param=max-jump-thread-duplication-stmts.

	   uninit-control-dep-attempts
	       Maximum number of nested calls to search for control
	       dependencies during uninitialized variable analysis.

	   uninit-max-chain-len
	       Maximum number of predicates anded for each predicate ored in
	       the normalized predicate chain.

	   uninit-max-num-chains
	       Maximum number of predicates ored in the normalized predicate
	       chain.

	   sched-autopref-queue-depth
	       Hardware autoprefetcher scheduler model control flag.  Number
	       of lookahead cycles the model looks into; at ' ' only enable
	       instruction sorting heuristic.

	   loop-versioning-max-inner-insns
	       The maximum number of instructions that an inner loop can have
	       before the loop versioning pass considers it too big to copy.

	   loop-versioning-max-outer-insns
	       The maximum number of instructions that an outer loop can have
	       before the loop versioning pass considers it too big to copy,
	       discounting any instructions in inner loops that directly
	       benefit from versioning.

	   ssa-name-def-chain-limit
	       The maximum number of SSA_NAME assignments to follow in
	       determining a property of a variable such as its value.	This
	       limits the number of iterations or recursive calls GCC performs
	       when optimizing certain statements or when determining their
	       validity prior to issuing diagnostics.

	   store-merging-max-size
	       Maximum size of a single store merging region in bytes.

	   hash-table-verification-limit
	       The number of elements for which hash table verification is
	       done for each searched element.

	   max-find-base-term-values
	       Maximum number of VALUEs handled during a single find_base_term
	       call.

	   analyzer-max-enodes-per-program-point
	       The maximum number of exploded nodes per program point within
	       the analyzer, before terminating analysis of that point.

	   analyzer-max-constraints
	       The maximum number of constraints per state.

	   analyzer-min-snodes-for-call-summary
	       The minimum number of supernodes within a function for the
	       analyzer to consider summarizing its effects at call sites.

	   analyzer-max-enodes-for-full-dump
	       The maximum depth of exploded nodes that should appear in a dot
	       dump before switching to a less verbose format.

	   analyzer-max-recursion-depth
	       The maximum number of times a callsite can appear in a call
	       stack within the analyzer, before terminating analysis of a
	       call that would recurse deeper.

	   analyzer-max-svalue-depth
	       The maximum depth of a symbolic value, before approximating the
	       value as unknown.

	   analyzer-max-infeasible-edges
	       The maximum number of infeasible edges to reject before
	       declaring a diagnostic as infeasible.

	   gimple-fe-computed-hot-bb-threshold
	       The number of executions of a basic block which is considered
	       hot.  The parameter is used only in GIMPLE FE.

	   analyzer-bb-explosion-factor
	       The maximum number of 'after supernode' exploded nodes within
	       the analyzer per supernode, before terminating analysis.

	   analyzer-text-art-string-ellipsis-threshold
	       The number of bytes at which to ellipsize string literals in
	       analyzer text art diagrams.

	   analyzer-text-art-ideal-canvas-width
	       The ideal width in characters of text art diagrams generated by
	       the analyzer.

	   analyzer-text-art-string-ellipsis-head-len
	       The number of literal bytes to show at the head of a string
	       literal in text art when ellipsizing it.

	   analyzer-text-art-string-ellipsis-tail-len
	       The number of literal bytes to show at the tail of a string
	       literal in text art when ellipsizing it.

	   ranger-logical-depth
	       Maximum depth of logical expression evaluation ranger will look
	       through when evaluating outgoing edge ranges.

	   ranger-recompute-depth
	       Maximum depth of instruction chains to consider for
	       recomputation in the outgoing range calculator.

	   relation-block-limit
	       Maximum number of relations the oracle will register in a basic
	       block.

	   min-pagesize
	       Minimum page size for warning purposes.

	   openacc-kernels
	       Specify mode of OpenACC `kernels' constructs handling.  With
	       --param=openacc-kernels=decompose, OpenACC `kernels' constructs
	       are decomposed into parts, a sequence of compute constructs,
	       each then handled individually.	This is work in progress.
	       With --param=openacc-kernels=parloops, OpenACC `kernels'
	       constructs are handled by the parloops pass, en bloc.  This is
	       the current default.

	   openacc-privatization
	       Control whether the -fopt-info-omp-note and applicable
	       -fdump-tree-*-details options emit OpenACC privatization
	       diagnostics.  With --param=openacc-privatization=quiet, don't
	       diagnose.  This is the current default.	With
	       --param=openacc-privatization=noisy, do diagnose.

	   The following choices of name are available on AArch64 targets:

	   aarch64-vect-compare-costs
	       When vectorizing, consider using multiple different approaches
	       and use the cost model to choose the cheapest one.  This
	       includes:

	       *   Trying both SVE and Advanced SIMD, when SVE is available.

	       *   Trying to use 64-bit Advanced SIMD vectors for the smallest
		   data elements, rather than using 128-bit vectors for
		   everything.

	       *   Trying to use "unpacked" SVE vectors for smaller elements.
		   This includes storing smaller elements in larger containers
		   and accessing elements with extending loads and truncating
		   stores.

	   aarch64-float-recp-precision
	       The number of Newton iterations for calculating the reciprocal
	       for float type.	The precision of division is proportional to
	       this param when division approximation is enabled.  The default
	       value is 1.

	   aarch64-double-recp-precision
	       The number of Newton iterations for calculating the reciprocal
	       for double type.	 The precision of division is propotional to
	       this param when division approximation is enabled.  The default
	       value is 2.

	   aarch64-autovec-preference
	       Force an ISA selection strategy for auto-vectorization.
	       Accepts values from 0 to 4, inclusive.

	       0   Use the default heuristics.

	       1   Use only Advanced SIMD for auto-vectorization.

	       2   Use only SVE for auto-vectorization.

	       3   Use both Advanced SIMD and SVE.  Prefer Advanced SIMD when
		   the costs are deemed equal.

	       4   Use both Advanced SIMD and SVE.  Prefer SVE when the costs
		   are deemed equal.

	       The default value is 0.

	   aarch64-ldp-policy
	       Fine-grained policy for load pairs.  With
	       --param=aarch64-ldp-policy=default, use the policy of the
	       tuning structure.  This is the current default.	With
	       --param=aarch64-ldp-policy=always, emit ldp regardless of
	       alignment.  With --param=aarch64-ldp-policy=never, do not emit
	       ldp.  With --param=aarch64-ldp-policy=aligned, emit ldp only if
	       the source pointer is aligned to at least double the alignment
	       of the type.

	   aarch64-stp-policy
	       Fine-grained policy for store pairs.  With
	       --param=aarch64-stp-policy=default, use the policy of the
	       tuning structure.  This is the current default.	With
	       --param=aarch64-stp-policy=always, emit stp regardless of
	       alignment.  With --param=aarch64-stp-policy=never, do not emit
	       stp.  With --param=aarch64-stp-policy=aligned, emit stp only if
	       the source pointer is aligned to at least double the alignment
	       of the type.

	   aarch64-ldp-alias-check-limit
	       Limit on the number of alias checks performed by the AArch64
	       load/store pair fusion pass when attempting to form an ldp/stp.
	       Higher values make the pass more aggressive at re-ordering
	       loads over stores, at the expense of increased compile time.

	   aarch64-ldp-writeback
	       Param to control which writeback opportunities we try to handle
	       in the AArch64 load/store pair fusion pass.  A value of zero
	       disables writeback handling.  One means we try to form pairs
	       involving one or more existing individual writeback accesses
	       where possible.	A value of two means we also try to
	       opportunistically form writeback opportunities by folding in
	       trailing destructive updates of the base register used by a
	       pair.

	   aarch64-loop-vect-issue-rate-niters
	       The tuning for some AArch64 CPUs tries to take both latencies
	       and issue rates into account when deciding whether a loop
	       should be vectorized using SVE, vectorized using Advanced SIMD,
	       or not vectorized at all.  If this parameter is set to n, GCC
	       will not use this heuristic for loops that are known to execute
	       in fewer than n Advanced SIMD iterations.

	   aarch64-vect-unroll-limit
	       The vectorizer will use available tuning information to
	       determine whether it would be beneficial to unroll the main
	       vectorized loop and by how much.	 This parameter set's the
	       upper bound of how much the vectorizer will unroll the main
	       loop.  The default value is four.

	   The following choices of name are available on GCN targets:

	   gcn-preferred-vectorization-factor
	       Preferred vectorization factor: default, 32, 64.

	   The following choices of name are available on i386 and x86_64
	   targets:

	   x86-stlf-window-ninsns
	       Instructions number above which STFL stall penalty can be
	       compensated.

	   x86-stv-max-visits
	       The maximum number of use and def visits when discovering a STV
	       chain before the discovery is aborted.

   Program Instrumentation Options
       GCC supports a number of command-line options that control adding run-
       time instrumentation to the code it normally generates.	For example,
       one purpose of instrumentation is collect profiling statistics for use
       in finding program hot spots, code coverage analysis, or profile-guided
       optimizations.  Another class of program instrumentation is adding run-
       time checking to detect programming errors like invalid pointer
       dereferences or out-of-bounds array accesses, as well as deliberately
       hostile attacks such as stack smashing or C++ vtable hijacking.	There
       is also a general hook which can be used to implement other forms of
       tracing or function-level instrumentation for debug or program analysis
       purposes.

       -p
       -pg Generate extra code to write profile information suitable for the
	   analysis program prof (for -p) or gprof (for -pg).  You must use
	   this option when compiling the source files you want data about,
	   and you must also use it when linking.

	   You can use the function attribute "no_instrument_function" to
	   suppress profiling of individual functions when compiling with
	   these options.

       -fprofile-arcs
	   Add code so that program flow arcs are instrumented.	 During
	   execution the program records how many times each branch and call
	   is executed and how many times it is taken or returns.  On targets
	   that support constructors with priority support, profiling properly
	   handles constructors, destructors and C++ constructors (and
	   destructors) of classes which are used as a type of a global
	   variable.

	   When the compiled program exits it saves this data to a file called
	   auxname.gcda for each source file.  The data may be used for
	   profile-directed optimizations (-fbranch-probabilities), or for
	   test coverage analysis (-ftest-coverage).  Each object file's
	   auxname is generated from the name of the output file, if
	   explicitly specified and it is not the final executable, otherwise
	   it is the basename of the source file.  In both cases any suffix is
	   removed (e.g. foo.gcda for input file dir/foo.c, or dir/foo.gcda
	   for output file specified as -o dir/foo.o).

	   Note that if a command line directly links source files, the
	   corresponding .gcda files will be prefixed with the unsuffixed name
	   of the output file.	E.g. "gcc a.c b.c -o binary" would generate
	   binary-a.gcda and binary-b.gcda files.

       -fcondition-coverage
	   Add code so that program conditions are instrumented.  During
	   execution the program records what terms in a conditional
	   contributes to a decision, which can be used to verify that all
	   terms in a Boolean function are tested and have an independent
	   effect on the outcome of a decision.	 The result can be read with
	   "gcov --conditions".

       --coverage
	   This option is used to compile and link code instrumented for
	   coverage analysis.  The option is a synonym for -fprofile-arcs
	   -ftest-coverage (when compiling) and -lgcov (when linking).	See
	   the documentation for those options for more details.

	   *   Compile the source files with -fprofile-arcs plus optimization
	       and code generation options.  For test coverage analysis, use
	       the additional -ftest-coverage option.  You do not need to
	       profile every source file in a program.

	   *   Compile the source files additionally with -fprofile-abs-path
	       to create absolute path names in the .gcno files.  This allows
	       gcov to find the correct sources in projects where compilations
	       occur with different working directories.

	   *   Link your object files with -lgcov or -fprofile-arcs (the
	       latter implies the former).

	   *   Run the program on a representative workload to generate the
	       arc profile information.	 This may be repeated any number of
	       times.  You can run concurrent instances of your program, and
	       provided that the file system supports locking, the data files
	       will be correctly updated.  Unless a strict ISO C dialect
	       option is in effect, "fork" calls are detected and correctly
	       handled without double counting.

	       Moreover, an object file can be recompiled multiple times and
	       the corresponding .gcda file merges as long as the source file
	       and the compiler options are unchanged.

	   *   For profile-directed optimizations, compile the source files
	       again with the same optimization and code generation options
	       plus -fbranch-probabilities.

	   *   For test coverage analysis, use gcov to produce human readable
	       information from the .gcno and .gcda files.  Refer to the gcov
	       documentation for further information.

	   With -fprofile-arcs, for each function of your program GCC creates
	   a program flow graph, then finds a spanning tree for the graph.
	   Only arcs that are not on the spanning tree have to be
	   instrumented: the compiler adds code to count the number of times
	   that these arcs are executed.  When an arc is the only exit or only
	   entrance to a block, the instrumentation code can be added to the
	   block; otherwise, a new basic block must be created to hold the
	   instrumentation code.

	   With -fcondition-coverage, for each conditional in your program GCC
	   creates a bitset and records the exercised boolean values that have
	   an independent effect on the outcome of that expression.

       -ftest-coverage
	   Produce a notes file that the gcov code-coverage utility can use to
	   show program coverage.  Each source file's note file is called
	   auxname.gcno.  Refer to the -fprofile-arcs option above for a
	   description of auxname and instructions on how to generate test
	   coverage data.  Coverage data matches the source files more closely
	   if you do not optimize.

       -fprofile-abs-path
	   Automatically convert relative source file names to absolute path
	   names in the .gcno files.  This allows gcov to find the correct
	   sources in projects where compilations occur with different working
	   directories.

       -fprofile-dir=path
	   Set the directory to search for the profile data files in to path.
	   This option affects only the profile data generated by
	   -fprofile-generate, -ftest-coverage, -fprofile-arcs and used by
	   -fprofile-use and -fbranch-probabilities and its related options.
	   Both absolute and relative paths can be used.  By default, GCC uses
	   the current directory as path, thus the profile data file appears
	   in the same directory as the object file.  In order to prevent the
	   file name clashing, if the object file name is not an absolute
	   path, we mangle the absolute path of the sourcename.gcda file and
	   use it as the file name of a .gcda file.  See details about the
	   file naming in -fprofile-arcs.  See similar option -fprofile-note.

	   When an executable is run in a massive parallel environment, it is
	   recommended to save profile to different folders.  That can be done
	   with variables in path that are exported during run-time:

	   %p  process ID.

	   %q{VAR}
	       value of environment variable VAR

       -fprofile-generate
       -fprofile-generate=path
	   Enable options usually used for instrumenting application to
	   produce profile useful for later recompilation with profile
	   feedback based optimization.	 You must use -fprofile-generate both
	   when compiling and when linking your program.

	   The following options are enabled: -fprofile-arcs,
	   -fprofile-values, -finline-functions, and -fipa-bit-cp.

	   If path is specified, GCC looks at the path to find the profile
	   feedback data files. See -fprofile-dir.

	   To optimize the program based on the collected profile information,
	   use -fprofile-use.

       -fprofile-info-section
       -fprofile-info-section=name
	   Register the profile information in the specified section instead
	   of using a constructor/destructor.  The section name is name if it
	   is specified, otherwise the section name defaults to ".gcov_info".
	   A pointer to the profile information generated by -fprofile-arcs is
	   placed in the specified section for each translation unit.  This
	   option disables the profile information registration through a
	   constructor and it disables the profile information processing
	   through a destructor.  This option is not intended to be used in
	   hosted environments such as GNU/Linux.  It targets freestanding
	   environments (for example embedded systems) with limited resources
	   which do not support constructors/destructors or the C library file
	   I/O.

	   The linker could collect the input sections in a continuous memory
	   block and define start and end symbols.  A GNU linker script
	   example which defines a linker output section follows:

		     .gcov_info	     :
		     {
		       PROVIDE (__gcov_info_start = .);
		       KEEP (*(.gcov_info))
		       PROVIDE (__gcov_info_end = .);
		     }

	   The program could dump the profiling information registered in this
	   linker set for example like this:

		   #include <gcov.h>
		   #include <stdio.h>
		   #include <stdlib.h>

		   extern const struct gcov_info *const __gcov_info_start[];
		   extern const struct gcov_info *const __gcov_info_end[];

		   static void
		   dump (const void *d, unsigned n, void *arg)
		   {
		     const unsigned char *c = d;

		     for (unsigned i = 0; i < n; ++i)
		       printf ("%02x", c[i]);
		   }

		   static void
		   filename (const char *f, void *arg)
		   {
		     __gcov_filename_to_gcfn (f, dump, arg );
		   }

		   static void *
		   allocate (unsigned length, void *arg)
		   {
		     return malloc (length);
		   }

		   static void
		   dump_gcov_info (void)
		   {
		     const struct gcov_info *const *info = __gcov_info_start;
		     const struct gcov_info *const *end = __gcov_info_end;

		     /* Obfuscate variable to prevent compiler optimizations.  */
		     __asm__ ("" : "+r" (info));

		     while (info != end)
		     {
		       void *arg = NULL;
		       __gcov_info_to_gcda (*info, filename, dump, allocate, arg);
		       putchar ('\n');
		       ++info;
		     }
		   }

		   int
		   main (void)
		   {
		     dump_gcov_info ();
		     return 0;
		   }

	   The merge-stream subcommand of gcov-tool may be used to deserialize
	   the data stream generated by the "__gcov_filename_to_gcfn" and
	   "__gcov_info_to_gcda" functions and merge the profile information
	   into .gcda files on the host filesystem.

       -fprofile-note=path
	   If path is specified, GCC saves .gcno file into path location.  If
	   you combine the option with multiple source files, the .gcno file
	   will be overwritten.

       -fprofile-prefix-path=path
	   This option can be used in combination with
	   profile-generate=profile_dir and profile-use=profile_dir to inform
	   GCC where is the base directory of built source tree.  By default
	   profile_dir will contain files with mangled absolute paths of all
	   object files in the built project.  This is not desirable when
	   directory used to build the instrumented binary differs from the
	   directory used to build the binary optimized with profile feedback
	   because the profile data will not be found during the optimized
	   build.  In such setups -fprofile-prefix-path=path with path
	   pointing to the base directory of the build can be used to strip
	   the irrelevant part of the path and keep all file names relative to
	   the main build directory.

       -fprofile-prefix-map=old=new
	   When compiling files residing in directory old, record profiling
	   information (with --coverage) describing them as if the files
	   resided in directory new instead.  See also -ffile-prefix-map and
	   -fcanon-prefix-map.

       -fprofile-update=method
	   Alter the update method for an application instrumented for profile
	   feedback based optimization.	 The method argument should be one of
	   single, atomic or prefer-atomic.  The first one is useful for
	   single-threaded applications, while the second one prevents profile
	   corruption by emitting thread-safe code.

	   Warning: When an application does not properly join all threads (or
	   creates an detached thread), a profile file can be still corrupted.

	   Using prefer-atomic would be transformed either to atomic, when
	   supported by a target, or to single otherwise.  The GCC driver
	   automatically selects prefer-atomic when -pthread is present in the
	   command line, otherwise the default method is single.

	   If atomic is selected, then the profile information is updated
	   using atomic operations on a best-effort basis.  Ideally, the
	   profile information is updated through atomic operations in
	   hardware.  If the target platform does not support the required
	   atomic operations in hardware, however, libatomic is available,
	   then the profile information is updated through calls to libatomic.
	   If the target platform neither supports the required atomic
	   operations in hardware nor libatomic, then the profile information
	   is not atomically updated and a warning is issued.  In this case,
	   the obtained profiling information may be corrupt for multi-
	   threaded applications.

	   For performance reasons, if 64-bit counters are used for the
	   profiling information and the target platform only supports 32-bit
	   atomic operations in hardware, then the performance critical
	   profiling updates are done using two 32-bit atomic operations for
	   each counter update.	 If a signal interrupts these two operations
	   updating a counter, then the profiling information may be in an
	   inconsistent state.

       -fprofile-filter-files=regex
	   Instrument only functions from files whose name matches any of the
	   regular expressions (separated by semi-colons).

	   For example, -fprofile-filter-files=main\.c;module.*\.c will
	   instrument only main.c and all C files starting with 'module'.

       -fprofile-exclude-files=regex
	   Instrument only functions from files whose name does not match any
	   of the regular expressions (separated by semi-colons).

	   For example, -fprofile-exclude-files=/usr/.* will prevent
	   instrumentation of all files that are located in the /usr/ folder.

       -fprofile-reproducible=[multithreaded|parallel-runs|serial]
	   Control level of reproducibility of profile gathered by
	   "-fprofile-generate".  This makes it possible to rebuild program
	   with same outcome which is useful, for example, for distribution
	   packages.

	   With -fprofile-reproducible=serial the profile gathered by
	   -fprofile-generate is reproducible provided the trained program
	   behaves the same at each invocation of the train run, it is not
	   multi-threaded and profile data streaming is always done in the
	   same order.	Note that profile streaming happens at the end of
	   program run but also before "fork" function is invoked.

	   Note that it is quite common that execution counts of some part of
	   programs depends, for example, on length of temporary file names or
	   memory space randomization (that may affect hash-table collision
	   rate).  Such non-reproducible part of programs may be annotated by
	   "no_instrument_function" function attribute. gcov-dump with -l can
	   be used to dump gathered data and verify that they are indeed
	   reproducible.

	   With -fprofile-reproducible=parallel-runs collected profile stays
	   reproducible regardless the order of streaming of the data into
	   gcda files.	This setting makes it possible to run multiple
	   instances of instrumented program in parallel (such as with "make
	   -j"). This reduces quality of gathered data, in particular of
	   indirect call profiling.

       -fsanitize=address
	   Enable AddressSanitizer, a fast memory error detector.  Memory
	   access instructions are instrumented to detect out-of-bounds and
	   use-after-free bugs.	 The option enables
	   -fsanitize-address-use-after-scope.	See
	   <https://github.com/google/sanitizers/wiki/AddressSanitizer> for
	   more details.  The run-time behavior can be influenced using the
	   ASAN_OPTIONS environment variable.  When set to "help=1", the
	   available options are shown at startup of the instrumented program.
	   See
	   <https://github.com/google/sanitizers/wiki/AddressSanitizerFlags#run-time-flags>
	   for a list of supported options.  The option cannot be combined
	   with -fsanitize=thread or -fsanitize=hwaddress.  Note that the only
	   target -fsanitize=hwaddress is currently supported on is AArch64.

	   To get more accurate stack traces, it is possible to use options
	   such as -O0, -O1, or -Og (which, for instance, prevent most
	   function inlining), -fno-optimize-sibling-calls (which prevents
	   optimizing sibling and tail recursive calls; this option is
	   implicit for -O0, -O1, or -Og), or -fno-ipa-icf (which disables
	   Identical Code Folding for functions).  Since multiple runs of the
	   program may yield backtraces with different addresses due to ASLR
	   (Address Space Layout Randomization), it may be desirable to turn
	   ASLR off.  On Linux, this can be achieved with setarch `uname -m`
	   -R ./prog.

       -fsanitize=kernel-address
	   Enable AddressSanitizer for Linux kernel.  See
	   <https://github.com/google/kernel-sanitizers> for more details.

       -fsanitize=hwaddress
	   Enable Hardware-assisted AddressSanitizer, which uses a hardware
	   ability to ignore the top byte of a pointer to allow the detection
	   of memory errors with a low memory overhead.	 Memory access
	   instructions are instrumented to detect out-of-bounds and use-
	   after-free bugs.  The option enables
	   -fsanitize-address-use-after-scope.	See
	   <https://clang.llvm.org/docs/HardwareAssistedAddressSanitizerDesign.html>
	   for more details.  The run-time behavior can be influenced using
	   the HWASAN_OPTIONS environment variable.  When set to "help=1", the
	   available options are shown at startup of the instrumented program.
	   The option cannot be combined with -fsanitize=thread or
	   -fsanitize=address, and is currently only available on AArch64.

       -fsanitize=kernel-hwaddress
	   Enable Hardware-assisted AddressSanitizer for compilation of the
	   Linux kernel.  Similar to -fsanitize=kernel-address but using an
	   alternate instrumentation method, and similar to
	   -fsanitize=hwaddress but with instrumentation differences necessary
	   for compiling the Linux kernel.  These differences are to avoid
	   hwasan library initialization calls and to account for the stack
	   pointer having a different value in its top byte.

	   Note: This option has different defaults to the
	   -fsanitize=hwaddress.  Instrumenting the stack and alloca calls are
	   not on by default but are still possible by specifying the command-
	   line options --param hwasan-instrument-stack=1 and --param
	   hwasan-instrument-allocas=1 respectively. Using a random frame tag
	   is not implemented for kernel instrumentation.

       -fsanitize=pointer-compare
	   Instrument comparison operation (<, <=, >, >=) with pointer
	   operands.  The option must be combined with either
	   -fsanitize=kernel-address or -fsanitize=address The option cannot
	   be combined with -fsanitize=thread.	Note: By default the check is
	   disabled at run time.  To enable it, add
	   "detect_invalid_pointer_pairs=2" to the environment variable
	   ASAN_OPTIONS. Using "detect_invalid_pointer_pairs=1" detects
	   invalid operation only when both pointers are non-null.

       -fsanitize=pointer-subtract
	   Instrument subtraction with pointer operands.  The option must be
	   combined with either -fsanitize=kernel-address or
	   -fsanitize=address The option cannot be combined with
	   -fsanitize=thread.  Note: By default the check is disabled at run
	   time.  To enable it, add "detect_invalid_pointer_pairs=2" to the
	   environment variable ASAN_OPTIONS. Using
	   "detect_invalid_pointer_pairs=1" detects invalid operation only
	   when both pointers are non-null.

       -fsanitize=shadow-call-stack
	   Enable ShadowCallStack, a security enhancement mechanism used to
	   protect programs against return address overwrites (e.g. stack
	   buffer overflows.)  It works by saving a function's return address
	   to a separately allocated shadow call stack in the function
	   prologue and restoring the return address from the shadow call
	   stack in the function epilogue.  Instrumentation only occurs in
	   functions that need to save the return address to the stack.

	   Currently it only supports the aarch64 platform.  It is
	   specifically designed for linux kernels that enable the
	   CONFIG_SHADOW_CALL_STACK option.  For the user space programs,
	   runtime support is not currently provided in libc and libgcc.
	   Users who want to use this feature in user space need to provide
	   their own support for the runtime.  It should be noted that this
	   may cause the ABI rules to be broken.

	   On aarch64, the instrumentation makes use of the platform register
	   "x18".  This generally means that any code that may run on the same
	   thread as code compiled with ShadowCallStack must be compiled with
	   the flag -ffixed-x18, otherwise functions compiled without
	   -ffixed-x18 might clobber "x18" and so corrupt the shadow stack
	   pointer.

	   Also, because there is no userspace runtime support, code compiled
	   with ShadowCallStack cannot use exception handling.	Use
	   -fno-exceptions to turn off exceptions.

	   See <https://clang.llvm.org/docs/ShadowCallStack.html> for more
	   details.

       -fsanitize=thread
	   Enable ThreadSanitizer, a fast data race detector.  Memory access
	   instructions are instrumented to detect data race bugs.  See
	   <https://github.com/google/sanitizers/wiki#threadsanitizer> for
	   more details. The run-time behavior can be influenced using the
	   TSAN_OPTIONS environment variable; see
	   <https://github.com/google/sanitizers/wiki/ThreadSanitizerFlags>
	   for a list of supported options.  The option cannot be combined
	   with -fsanitize=address, -fsanitize=leak.

	   Note that sanitized atomic builtins cannot throw exceptions when
	   operating on invalid memory addresses with non-call exceptions
	   (-fnon-call-exceptions).

       -fsanitize=leak
	   Enable LeakSanitizer, a memory leak detector.  This option only
	   matters for linking of executables.	The executable is linked
	   against a library that overrides "malloc" and other allocator
	   functions.  See
	   <https://github.com/google/sanitizers/wiki/AddressSanitizerLeakSanitizer>
	   for more details.  The run-time behavior can be influenced using
	   the LSAN_OPTIONS environment variable.  The option cannot be
	   combined with -fsanitize=thread.

       -fsanitize=undefined
	   Enable UndefinedBehaviorSanitizer, a fast undefined behavior
	   detector.  Various computations are instrumented to detect
	   undefined behavior at runtime.  See
	   <https://clang.llvm.org/docs/UndefinedBehaviorSanitizer.html> for
	   more details.   The run-time behavior can be influenced using the
	   UBSAN_OPTIONS environment variable.	Current suboptions are:

	   -fsanitize=shift
	       This option enables checking that the result of a shift
	       operation is not undefined.  Note that what exactly is
	       considered undefined differs slightly between C and C++, as
	       well as between ISO C90 and C99, etc.  This option has two
	       suboptions, -fsanitize=shift-base and
	       -fsanitize=shift-exponent.

	   -fsanitize=shift-exponent
	       This option enables checking that the second argument of a
	       shift operation is not negative and is smaller than the
	       precision of the promoted first argument.

	   -fsanitize=shift-base
	       If the second argument of a shift operation is within range,
	       check that the result of a shift operation is not undefined.
	       Note that what exactly is considered undefined differs slightly
	       between C and C++, as well as between ISO C90 and C99, etc.

	   -fsanitize=integer-divide-by-zero
	       Detect integer division by zero.

	   -fsanitize=unreachable
	       With this option, the compiler turns the
	       "__builtin_unreachable" call into a diagnostics message call
	       instead.	 When reaching the "__builtin_unreachable" call, the
	       behavior is undefined.

	   -fsanitize=vla-bound
	       This option instructs the compiler to check that the size of a
	       variable length array is positive.

	   -fsanitize=null
	       This option enables pointer checking.  Particularly, the
	       application built with this option turned on will issue an
	       error message when it tries to dereference a NULL pointer, or
	       if a reference (possibly an rvalue reference) is bound to a
	       NULL pointer, or if a method is invoked on an object pointed by
	       a NULL pointer.

	   -fsanitize=return
	       This option enables return statement checking.  Programs built
	       with this option turned on will issue an error message when the
	       end of a non-void function is reached without actually
	       returning a value.  This option works in C++ only.

	   -fsanitize=signed-integer-overflow
	       This option enables signed integer overflow checking.  We check
	       that the result of "+", "*", and both unary and binary "-" does
	       not overflow in the signed arithmetics.	This also detects
	       "INT_MIN / -1" signed division.	Note, integer promotion rules
	       must be taken into account.  That is, the following is not an
	       overflow:

		       signed char a = SCHAR_MAX;
		       a++;

	   -fsanitize=bounds
	       This option enables instrumentation of array bounds.  Various
	       out of bounds accesses are detected.  Flexible array members,
	       flexible array member-like arrays, and initializers of
	       variables with static storage are not instrumented, with the
	       exception of flexible array member-like arrays for which
	       "-fstrict-flex-arrays" or "-fstrict-flex-arrays=" options or
	       "strict_flex_array" attributes say they shouldn't be treated
	       like flexible array member-like arrays.

	   -fsanitize=bounds-strict
	       This option enables strict instrumentation of array bounds.
	       Most out of bounds accesses are detected, including flexible
	       array member-like arrays.  Initializers of variables with
	       static storage are not instrumented.

	   -fsanitize=alignment
	       This option enables checking of alignment of pointers when they
	       are dereferenced, or when a reference is bound to
	       insufficiently aligned target, or when a method or constructor
	       is invoked on insufficiently aligned object.

	   -fsanitize=object-size
	       This option enables instrumentation of memory references using
	       the "__builtin_dynamic_object_size" function.  Various out of
	       bounds pointer accesses are detected.

	   -fsanitize=float-divide-by-zero
	       Detect floating-point division by zero.	Unlike other similar
	       options, -fsanitize=float-divide-by-zero is not enabled by
	       -fsanitize=undefined, since floating-point division by zero can
	       be a legitimate way of obtaining infinities and NaNs.

	   -fsanitize=float-cast-overflow
	       This option enables floating-point type to integer conversion
	       checking.  We check that the result of the conversion does not
	       overflow.  Unlike other similar options,
	       -fsanitize=float-cast-overflow is not enabled by
	       -fsanitize=undefined.  This option does not work well with
	       "FE_INVALID" exceptions enabled.

	   -fsanitize=nonnull-attribute
	       This option enables instrumentation of calls, checking whether
	       null values are not passed to arguments marked as requiring a
	       non-null value by the "nonnull" function attribute.

	   -fsanitize=returns-nonnull-attribute
	       This option enables instrumentation of return statements in
	       functions marked with "returns_nonnull" function attribute, to
	       detect returning of null values from such functions.

	   -fsanitize=bool
	       This option enables instrumentation of loads from bool.	If a
	       value other than 0/1 is loaded, a run-time error is issued.

	   -fsanitize=enum
	       This option enables instrumentation of loads from an enum type.
	       If a value outside the range of values for the enum type is
	       loaded, a run-time error is issued.

	   -fsanitize=vptr
	       This option enables instrumentation of C++ member function
	       calls, member accesses and some conversions between pointers to
	       base and derived classes, to verify the referenced object has
	       the correct dynamic type.

	   -fsanitize=pointer-overflow
	       This option enables instrumentation of pointer arithmetics.  If
	       the pointer arithmetics overflows, a run-time error is issued.

	   -fsanitize=builtin
	       This option enables instrumentation of arguments to selected
	       builtin functions.  If an invalid value is passed to such
	       arguments, a run-time error is issued.  E.g. passing 0 as the
	       argument to "__builtin_ctz" or "__builtin_clz" invokes
	       undefined behavior and is diagnosed by this option.

	   Note that sanitizers tend to increase the rate of false positive
	   warnings, most notably those around -Wmaybe-uninitialized.  We
	   recommend against combining -Werror and [the use of] sanitizers.

	   While -ftrapv causes traps for signed overflows to be emitted,
	   -fsanitize=undefined gives a diagnostic message.  This currently
	   works only for the C family of languages.

       -fno-sanitize=all
	   This option disables all previously enabled sanitizers.
	   -fsanitize=all is not allowed, as some sanitizers cannot be used
	   together.

       -fasan-shadow-offset=number
	   This option forces GCC to use custom shadow offset in
	   AddressSanitizer checks.  It is useful for experimenting with
	   different shadow memory layouts in Kernel AddressSanitizer.

       -fsanitize-sections=s1,s2,...
	   Sanitize global variables in selected user-defined sections.	 si
	   may contain wildcards.

       -fsanitize-recover[=opts]
	   -fsanitize-recover= controls error recovery mode for sanitizers
	   mentioned in comma-separated list of opts.  Enabling this option
	   for a sanitizer component causes it to attempt to continue running
	   the program as if no error happened.	 This means multiple runtime
	   errors can be reported in a single program run, and the exit code
	   of the program may indicate success even when errors have been
	   reported.  The -fno-sanitize-recover= option can be used to alter
	   this behavior: only the first detected error is reported and
	   program then exits with a non-zero exit code.

	   Currently this feature only works for -fsanitize=undefined (and its
	   suboptions except for -fsanitize=unreachable and
	   -fsanitize=return), -fsanitize=float-cast-overflow,
	   -fsanitize=float-divide-by-zero, -fsanitize=bounds-strict,
	   -fsanitize=kernel-address and -fsanitize=address.  For these
	   sanitizers error recovery is turned on by default, except
	   -fsanitize=address, for which this feature is experimental.
	   -fsanitize-recover=all and -fno-sanitize-recover=all is also
	   accepted, the former enables recovery for all sanitizers that
	   support it, the latter disables recovery for all sanitizers that
	   support it.

	   Even if a recovery mode is turned on the compiler side, it needs to
	   be also enabled on the runtime library side, otherwise the failures
	   are still fatal.  The runtime library defaults to "halt_on_error=0"
	   for ThreadSanitizer and UndefinedBehaviorSanitizer, while default
	   value for AddressSanitizer is "halt_on_error=1". This can be
	   overridden through setting the "halt_on_error" flag in the
	   corresponding environment variable.

	   Syntax without an explicit opts parameter is deprecated.  It is
	   equivalent to specifying an opts list of:

		   undefined,float-cast-overflow,float-divide-by-zero,bounds-strict

       -fsanitize-address-use-after-scope
	   Enable sanitization of local variables to detect use-after-scope
	   bugs.  The option sets -fstack-reuse to none.

       -fsanitize-trap[=opts]
	   The -fsanitize-trap= option instructs the compiler to report for
	   sanitizers mentioned in comma-separated list of opts undefined
	   behavior using "__builtin_trap" rather than a "libubsan" library
	   routine.  If this option is enabled for certain sanitizer, it takes
	   precedence over the -fsanitizer-recover= for that sanitizer,
	   "__builtin_trap" will be emitted and be fatal regardless of whether
	   recovery is enabled or disabled using -fsanitize-recover=.

	   The advantage of this is that the "libubsan" library is not needed
	   and is not linked in, so this is usable even in freestanding
	   environments.

	   Currently this feature works with -fsanitize=undefined (and its
	   suboptions except for -fsanitize=vptr),
	   -fsanitize=float-cast-overflow, -fsanitize=float-divide-by-zero and
	   -fsanitize=bounds-strict.  "-fsanitize-trap=all" can be also
	   specified, which enables it for "undefined" suboptions,
	   -fsanitize=float-cast-overflow, -fsanitize=float-divide-by-zero and
	   -fsanitize=bounds-strict.  If "-fsanitize-trap=undefined" or
	   "-fsanitize-trap=all" is used and "-fsanitize=vptr" is enabled on
	   the command line, the instrumentation is silently ignored as the
	   instrumentation always needs "libubsan" support,
	   -fsanitize-trap=vptr is not allowed.

       -fsanitize-undefined-trap-on-error
	   The -fsanitize-undefined-trap-on-error option is deprecated
	   equivalent of -fsanitize-trap=all.

       -fsanitize-coverage=trace-pc
	   Enable coverage-guided fuzzing code instrumentation.	 Inserts a
	   call to "__sanitizer_cov_trace_pc" into every basic block.

       -fsanitize-coverage=trace-cmp
	   Enable dataflow guided fuzzing code instrumentation.	 Inserts a
	   call to "__sanitizer_cov_trace_cmp1", "__sanitizer_cov_trace_cmp2",
	   "__sanitizer_cov_trace_cmp4" or "__sanitizer_cov_trace_cmp8" for
	   integral comparison with both operands variable or
	   "__sanitizer_cov_trace_const_cmp1",
	   "__sanitizer_cov_trace_const_cmp2",
	   "__sanitizer_cov_trace_const_cmp4" or
	   "__sanitizer_cov_trace_const_cmp8" for integral comparison with one
	   operand constant, "__sanitizer_cov_trace_cmpf" or
	   "__sanitizer_cov_trace_cmpd" for float or double comparisons and
	   "__sanitizer_cov_trace_switch" for switch statements.

       -fcf-protection=[full|branch|return|none|check]
	   Enable code instrumentation of control-flow transfers to increase
	   program security by checking that target addresses of control-flow
	   transfer instructions (such as indirect function call, function
	   return, indirect jump) are valid.  This prevents diverting the flow
	   of control to an unexpected target.	This is intended to protect
	   against such threats as Return-oriented Programming (ROP), and
	   similarly call/jmp-oriented programming (COP/JOP).

	   The value "branch" tells the compiler to implement checking of
	   validity of control-flow transfer at the point of indirect branch
	   instructions, i.e. call/jmp instructions.  The value "return"
	   implements checking of validity at the point of returning from a
	   function.  The value "full" is an alias for specifying both
	   "branch" and "return". The value "none" turns off instrumentation.

	   To override -fcf-protection, -fcf-protection=none needs to be added
	   and then with -fcf-protection=xxx.

	   The value "check" is used for the final link with link-time
	   optimization (LTO).	An error is issued if LTO object files are
	   compiled with different -fcf-protection values.  The value "check"
	   is ignored at the compile time.

	   The macro "__CET__" is defined when -fcf-protection is used.	 The
	   first bit of "__CET__" is set to 1 for the value "branch" and the
	   second bit of "__CET__" is set to 1 for the "return".

	   You can also use the "nocf_check" attribute to identify which
	   functions and calls should be skipped from instrumentation.

	   Currently the x86 GNU/Linux target provides an implementation based
	   on Intel Control-flow Enforcement Technology (CET) which works for
	   i686 processor or newer.

       -fharden-compares
	   For every logical test that survives gimple optimizations and is
	   not the condition in a conditional branch (for example, conditions
	   tested for conditional moves, or to store in boolean variables),
	   emit extra code to compute and verify the reversed condition, and
	   to call "__builtin_trap" if the results do not match.  Use with
	   -fharden-conditional-branches to cover all conditionals.

       -fharden-conditional-branches
	   For every non-vectorized conditional branch that survives gimple
	   optimizations, emit extra code to compute and verify the reversed
	   condition, and to call "__builtin_trap" if the result is
	   unexpected.	Use with -fharden-compares to cover all conditionals.

       -fharden-control-flow-redundancy
	   Emit extra code to set booleans when entering basic blocks, and to
	   verify and trap, at function exits, when the booleans do not form
	   an execution path that is compatible with the control flow graph.

	   Verification takes place before returns, before mandatory tail
	   calls (see below) and, optionally, before escaping exceptions with
	   -fhardcfr-check-exceptions, before returning calls with
	   -fhardcfr-check-returning-calls, and before noreturn calls with
	   -fhardcfr-check-noreturn-calls).  Tuning options --param hardcfr-
	   max-blocks and --param hardcfr-max-inline-blocks are available.

	   Tail call optimization takes place too late to affect control flow
	   redundancy, but calls annotated as mandatory tail calls by language
	   front-ends, and any calls marked early enough as potential tail
	   calls would also have verification issued before the call, but
	   these possibilities are merely theoretical, as these conditions can
	   only be met when using custom compiler plugins.

       -fhardcfr-skip-leaf
	   Disable -fharden-control-flow-redundancy in leaf functions.

       -fhardcfr-check-exceptions
	   When -fharden-control-flow-redundancy is active, check the recorded
	   execution path against the control flow graph at exception escape
	   points, as if the function body was wrapped with a cleanup handler
	   that performed the check and reraised.  This option is enabled by
	   default; use -fno-hardcfr-check-exceptions to disable it.

       -fhardcfr-check-returning-calls
	   When -fharden-control-flow-redundancy is active, check the recorded
	   execution path against the control flow graph before any function
	   call immediately followed by a return of its result, if any, so as
	   to not prevent tail-call optimization, whether or not it is
	   ultimately optimized to a tail call.

	   This option is enabled by default whenever sibling call
	   optimizations are enabled (see -foptimize-sibling-calls), but it
	   can be enabled (or disabled, using its negated form) explicitly,
	   regardless of the optimizations.

       -fhardcfr-check-noreturn-calls=[always|no-xthrow|nothrow|never]
	   When -fharden-control-flow-redundancy is active, check the recorded
	   execution path against the control flow graph before "noreturn"
	   calls, either all of them (always), those that aren't expected to
	   return control to the caller through an exception (no-xthrow, the
	   default), those that may not return control to the caller through
	   an exception either (nothrow), or none of them (never).

	   Checking before a "noreturn" function that may return control to
	   the caller through an exception may cause checking to be performed
	   more than once, if the exception is caught in the caller, whether
	   by a handler or a cleanup.  When -fhardcfr-check-exceptions is also
	   enabled, the compiler will avoid associating a "noreturn" call with
	   the implicitly-added cleanup handler, since it would be redundant
	   with the check performed before the call, but other handlers or
	   cleanups in the function, if activated, will modify the recorded
	   execution path and check it again when another checkpoint is hit.
	   The checkpoint may even be another "noreturn" call, so checking may
	   end up performed multiple times.

	   Various optimizers may cause calls to be marked as "noreturn"
	   and/or "nothrow", even in the absence of the corresponding
	   attributes, which may affect the placement of checks before calls,
	   as well as the addition of implicit cleanup handlers for them.
	   This unpredictability, and the fact that raising and reraising
	   exceptions frequently amounts to implicitly calling "noreturn"
	   functions, have made no-xthrow the default setting for this option:
	   it excludes from the "noreturn" treatment only internal functions
	   used to (re)raise exceptions, that are not affected by these
	   optimizations.

       -fhardened
	   Enable a set of flags for C and C++ that improve the security of
	   the generated code without affecting its ABI.  The precise flags
	   enabled may change between major releases of GCC, but are
	   currently:

	   -D_FORTIFY_SOURCE=3 -D_GLIBCXX_ASSERTIONS
	   -ftrivial-auto-var-init=zero -fPIE  -pie  -Wl,-z,relro,-z,now
	   -fstack-protector-strong -fstack-clash-protection
	   -fcf-protection=full (x86 GNU/Linux only)

	   The list of options enabled by -fhardened can be generated using
	   the --help=hardened option.

	   When the system glibc is older than 2.35, -D_FORTIFY_SOURCE=2 is
	   used instead.

	   This option is intended to be used in production builds, not merely
	   in debug builds.

	   Currently, -fhardened is only supported on GNU/Linux targets.

	   -fhardened only enables a particular option if it wasn't already
	   specified anywhere on the command line.  For instance, -fhardened
	   -fstack-protector will only enable -fstack-protector, but not
	   -fstack-protector-strong.

       -fstack-protector
	   Emit extra code to check for buffer overflows, such as stack
	   smashing attacks.  This is done by adding a guard variable to
	   functions with vulnerable objects.  This includes functions that
	   call "alloca", and functions with buffers larger than or equal to 8
	   bytes.  The guards are initialized when a function is entered and
	   then checked when the function exits.  If a guard check fails, an
	   error message is printed and the program exits.  Only variables
	   that are actually allocated on the stack are considered, optimized
	   away variables or variables allocated in registers don't count.

       -fstack-protector-all
	   Like -fstack-protector except that all functions are protected.

       -fstack-protector-strong
	   Like -fstack-protector but includes additional functions to be
	   protected --- those that have local array definitions, or have
	   references to local frame addresses.	 Only variables that are
	   actually allocated on the stack are considered, optimized away
	   variables or variables allocated in registers don't count.

       -fstack-protector-explicit
	   Like -fstack-protector but only protects those functions which have
	   the "stack_protect" attribute.

       -fstack-check
	   Generate code to verify that you do not go beyond the boundary of
	   the stack.  You should specify this flag if you are running in an
	   environment with multiple threads, but you only rarely need to
	   specify it in a single-threaded environment since stack overflow is
	   automatically detected on nearly all systems if there is only one
	   stack.

	   Note that this switch does not actually cause checking to be done;
	   the operating system or the language runtime must do that.  The
	   switch causes generation of code to ensure that they see the stack
	   being extended.

	   You can additionally specify a string parameter: no means no
	   checking, generic means force the use of old-style checking,
	   specific means use the best checking method and is equivalent to
	   bare -fstack-check.

	   Old-style checking is a generic mechanism that requires no specific
	   target support in the compiler but comes with the following
	   drawbacks:

	   1.  Modified allocation strategy for large objects: they are always
	       allocated dynamically if their size exceeds a fixed threshold.
	       Note this may change the semantics of some code.

	   2.  Fixed limit on the size of the static frame of functions: when
	       it is topped by a particular function, stack checking is not
	       reliable and a warning is issued by the compiler.

	   3.  Inefficiency: because of both the modified allocation strategy
	       and the generic implementation, code performance is hampered.

	   Note that old-style stack checking is also the fallback method for
	   specific if no target support has been added in the compiler.

	   -fstack-check= is designed for Ada's needs to detect infinite
	   recursion and stack overflows.  specific is an excellent choice
	   when compiling Ada code.  It is not generally sufficient to protect
	   against stack-clash attacks.	 To protect against those you want
	   -fstack-clash-protection.

       -fstack-clash-protection
	   Generate code to prevent stack clash style attacks.	When this
	   option is enabled, the compiler will only allocate one page of
	   stack space at a time and each page is accessed immediately after
	   allocation.	Thus, it prevents allocations from jumping over any
	   stack guard page provided by the operating system.

	   Most targets do not fully support stack clash protection.  However,
	   on those targets -fstack-clash-protection will protect dynamic
	   stack allocations.  -fstack-clash-protection may also provide
	   limited protection for static stack allocations if the target
	   supports -fstack-check=specific.

       -fstack-limit-register=reg
       -fstack-limit-symbol=sym
       -fno-stack-limit
	   Generate code to ensure that the stack does not grow beyond a
	   certain value, either the value of a register or the address of a
	   symbol.  If a larger stack is required, a signal is raised at run
	   time.  For most targets, the signal is raised before the stack
	   overruns the boundary, so it is possible to catch the signal
	   without taking special precautions.

	   For instance, if the stack starts at absolute address 0x80000000
	   and grows downwards, you can use the flags
	   -fstack-limit-symbol=__stack_limit and
	   -Wl,--defsym,__stack_limit=0x7ffe0000 to enforce a stack limit of
	   128KB.  Note that this may only work with the GNU linker.

	   You can locally override stack limit checking by using the
	   "no_stack_limit" function attribute.

       -fsplit-stack
	   Generate code to automatically split the stack before it overflows.
	   The resulting program has a discontiguous stack which can only
	   overflow if the program is unable to allocate any more memory.
	   This is most useful when running threaded programs, as it is no
	   longer necessary to calculate a good stack size to use for each
	   thread.  This is currently only implemented for the x86 targets
	   running GNU/Linux.

	   When code compiled with -fsplit-stack calls code compiled without
	   -fsplit-stack, there may not be much stack space available for the
	   latter code to run.	If compiling all code, including library code,
	   with -fsplit-stack is not an option, then the linker can fix up
	   these calls so that the code compiled without -fsplit-stack always
	   has a large stack.  Support for this is implemented in the gold
	   linker in GNU binutils release 2.21 and later.

       -fstrub=disable
	   Disable stack scrubbing entirely, ignoring any "strub" attributes.
	   See

       -fstrub=strict
	   Functions default to "strub" mode "disabled", and apply strictly
	   the restriction that only functions associated with
	   "strub"-"callable" modes ("at-calls", "callable" and
	   "always_inline" "internal") are "callable" by functions with
	   "strub"-enabled modes ("at-calls" and "internal").

       -fstrub=relaxed
	   Restore the default stack scrub ("strub") setting, namely, "strub"
	   is only enabled as required by "strub" attributes associated with
	   function and data types.  "Relaxed" means that strub contexts are
	   only prevented from calling functions explicitly associated with
	   "strub" mode "disabled".  This option is only useful to override
	   other -fstrub=* options that precede it in the command line.

       -fstrub=at-calls
	   Enable "at-calls" "strub" mode where viable.	 The primary use of
	   this option is for testing.	It exercises the "strub" machinery in
	   scenarios strictly local to a translation unit.  This "strub" mode
	   modifies function interfaces, so any function that is visible to
	   other translation units, or that has its address taken, will not be
	   affected by this option.  Optimization options may also affect
	   viability.  See the "strub" attribute documentation for details on
	   viability and eligibility requirements.

       -fstrub=internal
	   Enable "internal" "strub" mode where viable.	 The primary use of
	   this option is for testing.	This option is intended to exercise
	   thoroughly parts of the "strub" machinery that implement the less
	   efficient, but interface-preserving "strub" mode.  Functions that
	   would not be affected by this option are quite uncommon.

       -fstrub=all
	   Enable some "strub" mode where viable.  When both strub modes are
	   viable, "at-calls" is preferred.  -fdump-ipa-strubm adds function
	   attributes that tell which mode was selected for each function.
	   The primary use of this option is for testing, to exercise
	   thoroughly the "strub" machinery.

       -fvtable-verify=[std|preinit|none]
	   This option is only available when compiling C++ code.  It turns on
	   (or off, if using -fvtable-verify=none) the security feature that
	   verifies at run time, for every virtual call, that the vtable
	   pointer through which the call is made is valid for the type of the
	   object, and has not been corrupted or overwritten.  If an invalid
	   vtable pointer is detected at run time, an error is reported and
	   execution of the program is immediately halted.

	   This option causes run-time data structures to be built at program
	   startup, which are used for verifying the vtable pointers.  The
	   options std and preinit control the timing of when these data
	   structures are built.  In both cases the data structures are built
	   before execution reaches "main".  Using -fvtable-verify=std causes
	   the data structures to be built after shared libraries have been
	   loaded and initialized.  -fvtable-verify=preinit causes them to be
	   built before shared libraries have been loaded and initialized.

	   If this option appears multiple times in the command line with
	   different values specified, none takes highest priority over both
	   std and preinit; preinit takes priority over std.

       -fvtv-debug
	   When used in conjunction with -fvtable-verify=std or
	   -fvtable-verify=preinit, causes debug versions of the runtime
	   functions for the vtable verification feature to be called.	This
	   flag also causes the compiler to log information about which vtable
	   pointers it finds for each class.  This information is written to a
	   file named vtv_set_ptr_data.log in the directory named by the
	   environment variable VTV_LOGS_DIR if that is defined or the current
	   working directory otherwise.

	   Note:  This feature appends data to the log file. If you want a
	   fresh log file, be sure to delete any existing one.

       -fvtv-counts
	   This is a debugging flag.  When used in conjunction with
	   -fvtable-verify=std or -fvtable-verify=preinit, this causes the
	   compiler to keep track of the total number of virtual calls it
	   encounters and the number of verifications it inserts.  It also
	   counts the number of calls to certain run-time library functions
	   that it inserts and logs this information for each compilation
	   unit.  The compiler writes this information to a file named
	   vtv_count_data.log in the directory named by the environment
	   variable VTV_LOGS_DIR if that is defined or the current working
	   directory otherwise.	 It also counts the size of the vtable pointer
	   sets for each class, and writes this information to
	   vtv_class_set_sizes.log in the same directory.

	   Note:  This feature appends data to the log files.  To get fresh
	   log files, be sure to delete any existing ones.

       -finstrument-functions
	   Generate instrumentation calls for entry and exit to functions.
	   Just after function entry and just before function exit, the
	   following profiling functions are called with the address of the
	   current function and its call site.	(On some platforms,
	   "__builtin_return_address" does not work beyond the current
	   function, so the call site information may not be available to the
	   profiling functions otherwise.)

		   void __cyg_profile_func_enter (void *this_fn,
						  void *call_site);
		   void __cyg_profile_func_exit	 (void *this_fn,
						  void *call_site);

	   The first argument is the address of the start of the current
	   function, which may be looked up exactly in the symbol table.

	   This instrumentation is also done for functions expanded inline in
	   other functions.  The profiling calls indicate where, conceptually,
	   the inline function is entered and exited.  This means that
	   addressable versions of such functions must be available.  If all
	   your uses of a function are expanded inline, this may mean an
	   additional expansion of code size.  If you use "extern inline" in
	   your C code, an addressable version of such functions must be
	   provided.  (This is normally the case anyway, but if you get lucky
	   and the optimizer always expands the functions inline, you might
	   have gotten away without providing static copies.)

	   A function may be given the attribute "no_instrument_function", in
	   which case this instrumentation is not done.	 This can be used, for
	   example, for the profiling functions listed above, high-priority
	   interrupt routines, and any functions from which the profiling
	   functions cannot safely be called (perhaps signal handlers, if the
	   profiling routines generate output or allocate memory).

       -finstrument-functions-once
	   This is similar to -finstrument-functions, but the profiling
	   functions are called only once per instrumented function, i.e. the
	   first profiling function is called after the first entry into the
	   instrumented function and the second profiling function is called
	   before the exit corresponding to this first entry.

	   The definition of "once" for the purpose of this option is a little
	   vague because the implementation is not protected against data
	   races.  As a result, the implementation only guarantees that the
	   profiling functions are called at least once per process and at
	   most once per thread, but the calls are always paired, that is to
	   say, if a thread calls the first function, then it will call the
	   second function, unless it never reaches the exit of the
	   instrumented function.

       -finstrument-functions-exclude-file-list=file,file,...
	   Set the list of functions that are excluded from instrumentation
	   (see the description of -finstrument-functions).  If the file that
	   contains a function definition matches with one of file, then that
	   function is not instrumented.  The match is done on substrings: if
	   the file parameter is a substring of the file name, it is
	   considered to be a match.

	   For example:

		   -finstrument-functions-exclude-file-list=/bits/stl,include/sys

	   excludes any inline function defined in files whose pathnames
	   contain /bits/stl or include/sys.

	   If, for some reason, you want to include letter , in one of sym,
	   write ,. For example,
	   -finstrument-functions-exclude-file-list=',,tmp' (note the single
	   quote surrounding the option).

       -finstrument-functions-exclude-function-list=sym,sym,...
	   This is similar to -finstrument-functions-exclude-file-list, but
	   this option sets the list of function names to be excluded from
	   instrumentation.  The function name to be matched is its user-
	   visible name, such as "vector<int> blah(const vector<int> &)", not
	   the internal mangled name (e.g., "_Z4blahRSt6vectorIiSaIiEE").  The
	   match is done on substrings: if the sym parameter is a substring of
	   the function name, it is considered to be a match.  For C99 and C++
	   extended identifiers, the function name must be given in UTF-8, not
	   using universal character names.

       -fpatchable-function-entry=N[,M]
	   Generate N NOPs right at the beginning of each function, with the
	   function entry point before the Mth NOP.  If M is omitted, it
	   defaults to 0 so the function entry points to the address just at
	   the first NOP.  The NOP instructions reserve extra space which can
	   be used to patch in any desired instrumentation at run time,
	   provided that the code segment is writable.	The amount of space is
	   controllable indirectly via the number of NOPs; the NOP instruction
	   used corresponds to the instruction emitted by the internal GCC
	   back-end interface "gen_nop".  This behavior is target-specific and
	   may also depend on the architecture variant and/or other
	   compilation options.

	   For run-time identification, the starting addresses of these areas,
	   which correspond to their respective function entries minus M, are
	   additionally collected in the "__patchable_function_entries"
	   section of the resulting binary.

	   Note that the value of "__attribute__ ((patchable_function_entry
	   (N,M)))" takes precedence over command-line option
	   -fpatchable-function-entry=N,M.  This can be used to increase the
	   area size or to remove it completely on a single function.  If
	   "N=0", no pad location is recorded.

	   The NOP instructions are inserted at---and maybe before, depending
	   on M---the function entry address, even before the prologue.	 On
	   PowerPC with the ELFv2 ABI, for a function with dual entry points,
	   the local entry point is this function entry address.

	   The maximum value of N and M is 65535.  On PowerPC with the ELFv2
	   ABI, for a function with dual entry points, the supported values
	   for M are 0, 2, 6 and 14.

   Options Controlling the Preprocessor
       These options control the C preprocessor, which is run on each C source
       file before actual compilation.

       If you use the -E option, nothing is done except preprocessing.	Some
       of these options make sense only together with -E because they cause
       the preprocessor output to be unsuitable for actual compilation.

       In addition to the options listed here, there are a number of options
       to control search paths for include files documented in Directory
       Options.	 Options to control preprocessor diagnostics are listed in
       Warning Options.

       -D name
	   Predefine name as a macro, with definition 1.

       -D name=definition
	   The contents of definition are tokenized and processed as if they
	   appeared during translation phase three in a #define directive.  In
	   particular, the definition is truncated by embedded newline
	   characters.

	   If you are invoking the preprocessor from a shell or shell-like
	   program you may need to use the shell's quoting syntax to protect
	   characters such as spaces that have a meaning in the shell syntax.

	   If you wish to define a function-like macro on the command line,
	   write its argument list with surrounding parentheses before the
	   equals sign (if any).  Parentheses are meaningful to most shells,
	   so you should quote the option.  With sh and csh,
	   -D'name(args...)=definition' works.

	   -D and -U options are processed in the order they are given on the
	   command line.  All -imacros file and -include file options are
	   processed after all -D and -U options.

       -U name
	   Cancel any previous definition of name, either built in or provided
	   with a -D option.

       -include file
	   Process file as if "#include "file"" appeared as the first line of
	   the primary source file.  However, the first directory searched for
	   file is the preprocessor's working directory instead of the
	   directory containing the main source file.  If not found there, it
	   is searched for in the remainder of the "#include "..."" search
	   chain as normal.

	   If multiple -include options are given, the files are included in
	   the order they appear on the command line.

       -imacros file
	   Exactly like -include, except that any output produced by scanning
	   file is thrown away.	 Macros it defines remain defined.  This
	   allows you to acquire all the macros from a header without also
	   processing its declarations.

	   All files specified by -imacros are processed before all files
	   specified by -include.

       -undef
	   Do not predefine any system-specific or GCC-specific macros.	 The
	   standard predefined macros remain defined.

       -pthread
	   Define additional macros required for using the POSIX threads
	   library.  You should use this option consistently for both
	   compilation and linking.  This option is supported on GNU/Linux
	   targets, most other Unix derivatives, and also on x86 Cygwin and
	   MinGW targets.

       -M  Instead of outputting the result of preprocessing, output a rule
	   suitable for make describing the dependencies of the main source
	   file.  The preprocessor outputs one make rule containing the object
	   file name for that source file, a colon, and the names of all the
	   included files, including those coming from -include or -imacros
	   command-line options.

	   Unless specified explicitly (with -MT or -MQ), the object file name
	   consists of the name of the source file with any suffix replaced
	   with object file suffix and with any leading directory parts
	   removed.  If there are many included files then the rule is split
	   into several lines using \-newline.	The rule has no commands.

	   This option does not suppress the preprocessor's debug output, such
	   as -dM.  To avoid mixing such debug output with the dependency
	   rules you should explicitly specify the dependency output file with
	   -MF, or use an environment variable like DEPENDENCIES_OUTPUT.
	   Debug output is still sent to the regular output stream as normal.

	   Passing -M to the driver implies -E, and suppresses warnings with
	   an implicit -w.

       -MM Like -M but do not mention header files that are found in system
	   header directories, nor header files that are included, directly or
	   indirectly, from such a header.

	   This implies that the choice of angle brackets or double quotes in
	   an #include directive does not in itself determine whether that
	   header appears in -MM dependency output.

       -MF file
	   When used with -M or -MM, specifies a file to write the
	   dependencies to.  If no -MF switch is given the preprocessor sends
	   the rules to the same place it would send preprocessed output.

	   When used with the driver options -MD or -MMD, -MF overrides the
	   default dependency output file.

	   If file is -, then the dependencies are written to stdout.

       -MG In conjunction with an option such as -M requesting dependency
	   generation, -MG assumes missing header files are generated files
	   and adds them to the dependency list without raising an error.  The
	   dependency filename is taken directly from the "#include" directive
	   without prepending any path.	 -MG also suppresses preprocessed
	   output, as a missing header file renders this useless.

	   This feature is used in automatic updating of makefiles.

       -Mno-modules
	   Disable dependency generation for compiled module interfaces.

       -MP This option instructs CPP to add a phony target for each dependency
	   other than the main file, causing each to depend on nothing.	 These
	   dummy rules work around errors make gives if you remove header
	   files without updating the Makefile to match.

	   This is typical output:

		   test.o: test.c test.h

		   test.h:

       -MT target
	   Change the target of the rule emitted by dependency generation.  By
	   default CPP takes the name of the main input file, deletes any
	   directory components and any file suffix such as .c, and appends
	   the platform's usual object suffix.	The result is the target.

	   An -MT option sets the target to be exactly the string you specify.
	   If you want multiple targets, you can specify them as a single
	   argument to -MT, or use multiple -MT options.

	   For example, -MT '$(objpfx)foo.o' might give

		   $(objpfx)foo.o: foo.c

       -MQ target
	   Same as -MT, but it quotes any characters which are special to
	   Make.  -MQ '$(objpfx)foo.o' gives

		   $$(objpfx)foo.o: foo.c

	   The default target is automatically quoted, as if it were given
	   with -MQ.

       -MD -MD is equivalent to -M -MF file, except that -E is not implied.
	   The driver determines file based on whether an -o option is given.
	   If it is, the driver uses its argument but with a suffix of .d,
	   otherwise it takes the name of the input file, removes any
	   directory components and suffix, and applies a .d suffix.

	   If -MD is used in conjunction with -E, any -o switch is understood
	   to specify the dependency output file, but if used without -E, each
	   -o is understood to specify a target object file.

	   Since -E is not implied, -MD can be used to generate a dependency
	   output file as a side effect of the compilation process.

       -MMD
	   Like -MD except mention only user header files, not system header
	   files.

       -fpreprocessed
	   Indicate to the preprocessor that the input file has already been
	   preprocessed.  This suppresses things like macro expansion,
	   trigraph conversion, escaped newline splicing, and processing of
	   most directives.  The preprocessor still recognizes and removes
	   comments, so that you can pass a file preprocessed with -C to the
	   compiler without problems.  In this mode the integrated
	   preprocessor is little more than a tokenizer for the front ends.

	   -fpreprocessed is implicit if the input file has one of the
	   extensions .i, .ii or .mi.  These are the extensions that GCC uses
	   for preprocessed files created by -save-temps.

       -fdirectives-only
	   When preprocessing, handle directives, but do not expand macros.

	   The option's behavior depends on the -E and -fpreprocessed options.

	   With -E, preprocessing is limited to the handling of directives
	   such as "#define", "#ifdef", and "#error".  Other preprocessor
	   operations, such as macro expansion and trigraph conversion are not
	   performed.  In addition, the -dD option is implicitly enabled.

	   With -fpreprocessed, predefinition of command line and most builtin
	   macros is disabled.	Macros such as "__LINE__", which are
	   contextually dependent, are handled normally.  This enables
	   compilation of files previously preprocessed with "-E
	   -fdirectives-only".

	   With both -E and -fpreprocessed, the rules for -fpreprocessed take
	   precedence.	This enables full preprocessing of files previously
	   preprocessed with "-E -fdirectives-only".

       -fdollars-in-identifiers
	   Accept $ in identifiers.

       -fextended-identifiers
	   Accept universal character names and extended characters in
	   identifiers.	 This option is enabled by default for C99 (and later
	   C standard versions) and C++.

       -fno-canonical-system-headers
	   When preprocessing, do not shorten system header paths with
	   canonicalization.

       -fmax-include-depth=depth
	   Set the maximum depth of the nested #include. The default is 200.

       -ftabstop=width
	   Set the distance between tab stops.	This helps the preprocessor
	   report correct column numbers in warnings or errors, even if tabs
	   appear on the line.	If the value is less than 1 or greater than
	   100, the option is ignored.	The default is 8.

       -ftrack-macro-expansion[=level]
	   Track locations of tokens across macro expansions. This allows the
	   compiler to emit diagnostic about the current macro expansion stack
	   when a compilation error occurs in a macro expansion. Using this
	   option makes the preprocessor and the compiler consume more memory.
	   The level parameter can be used to choose the level of precision of
	   token location tracking thus decreasing the memory consumption if
	   necessary. Value 0 of level de-activates this option. Value 1
	   tracks tokens locations in a degraded mode for the sake of minimal
	   memory overhead. In this mode all tokens resulting from the
	   expansion of an argument of a function-like macro have the same
	   location. Value 2 tracks tokens locations completely. This value is
	   the most memory hungry.  When this option is given no argument, the
	   default parameter value is 2.

	   Note that "-ftrack-macro-expansion=2" is activated by default.

       -fmacro-prefix-map=old=new
	   When preprocessing files residing in directory old, expand the
	   "__FILE__" and "__BASE_FILE__" macros as if the files resided in
	   directory new instead.  This can be used to change an absolute path
	   to a relative path by using . for new which can result in more
	   reproducible builds that are location independent.  This option
	   also affects "__builtin_FILE()" during compilation.	See also
	   -ffile-prefix-map and -fcanon-prefix-map.

       -fexec-charset=charset
	   Set the execution character set, used for string and character
	   constants.  The default is UTF-8.  charset can be any encoding
	   supported by the system's "iconv" library routine.

       -fwide-exec-charset=charset
	   Set the wide execution character set, used for wide string and
	   character constants.	 The default is one of UTF-32BE, UTF-32LE,
	   UTF-16BE, or UTF-16LE, whichever corresponds to the width of
	   "wchar_t" and the big-endian or little-endian byte order being used
	   for code generation.	 As with -fexec-charset, charset can be any
	   encoding supported by the system's "iconv" library routine;
	   however, you will have problems with encodings that do not fit
	   exactly in "wchar_t".

       -finput-charset=charset
	   Set the input character set, used for translation from the
	   character set of the input file to the source character set used by
	   GCC.	 If the locale does not specify, or GCC cannot get this
	   information from the locale, the default is UTF-8.  This can be
	   overridden by either the locale or this command-line option.
	   Currently the command-line option takes precedence if there's a
	   conflict.  charset can be any encoding supported by the system's
	   "iconv" library routine.

       -fpch-deps
	   When using precompiled headers, this flag causes the dependency-
	   output flags to also list the files from the precompiled header's
	   dependencies.  If not specified, only the precompiled header are
	   listed and not the files that were used to create it, because those
	   files are not consulted when a precompiled header is used.

       -fpch-preprocess
	   This option allows use of a precompiled header together with -E.
	   It inserts a special "#pragma", "#pragma GCC pch_preprocess
	   "filename"" in the output to mark the place where the precompiled
	   header was found, and its filename.	When -fpreprocessed is in use,
	   GCC recognizes this "#pragma" and loads the PCH.

	   This option is off by default, because the resulting preprocessed
	   output is only really suitable as input to GCC.  It is switched on
	   by -save-temps.

	   You should not write this "#pragma" in your own code, but it is
	   safe to edit the filename if the PCH file is available in a
	   different location.	The filename may be absolute or it may be
	   relative to GCC's current directory.

       -fworking-directory
	   Enable generation of linemarkers in the preprocessor output that
	   let the compiler know the current working directory at the time of
	   preprocessing.  When this option is enabled, the preprocessor
	   emits, after the initial linemarker, a second linemarker with the
	   current working directory followed by two slashes.  GCC uses this
	   directory, when it's present in the preprocessed input, as the
	   directory emitted as the current working directory in some
	   debugging information formats.  This option is implicitly enabled
	   if debugging information is enabled, but this can be inhibited with
	   the negated form -fno-working-directory.  If the -P flag is present
	   in the command line, this option has no effect, since no "#line"
	   directives are emitted whatsoever.

       -A predicate=answer
	   Make an assertion with the predicate predicate and answer answer.
	   This form is preferred to the older form -A predicate(answer),
	   which is still supported, because it does not use shell special
	   characters.

       -A -predicate=answer
	   Cancel an assertion with the predicate predicate and answer answer.

       -C  Do not discard comments.  All comments are passed through to the
	   output file, except for comments in processed directives, which are
	   deleted along with the directive.

	   You should be prepared for side effects when using -C; it causes
	   the preprocessor to treat comments as tokens in their own right.
	   For example, comments appearing at the start of what would be a
	   directive line have the effect of turning that line into an
	   ordinary source line, since the first token on the line is no
	   longer a #.

       -CC Do not discard comments, including during macro expansion.  This is
	   like -C, except that comments contained within macros are also
	   passed through to the output file where the macro is expanded.

	   In addition to the side effects of the -C option, the -CC option
	   causes all C++-style comments inside a macro to be converted to
	   C-style comments.  This is to prevent later use of that macro from
	   inadvertently commenting out the remainder of the source line.

	   The -CC option is generally used to support lint comments.

       -P  Inhibit generation of linemarkers in the output from the
	   preprocessor.  This might be useful when running the preprocessor
	   on something that is not C code, and will be sent to a program
	   which might be confused by the linemarkers.

       -traditional
       -traditional-cpp
	   Try to imitate the behavior of pre-standard C preprocessors, as
	   opposed to ISO C preprocessors.  See the GNU CPP manual for
	   details.

	   Note that GCC does not otherwise attempt to emulate a pre-standard
	   C compiler, and these options are only supported with the -E
	   switch, or when invoking CPP explicitly.

       -trigraphs
	   Support ISO C trigraphs.  These are three-character sequences, all
	   starting with ??, that are defined by ISO C to stand for single
	   characters.	For example, ??/ stands for \, so '??/n' is a
	   character constant for a newline.

	   The nine trigraphs and their replacements are

		   Trigraph:	   ??(	??)  ??<  ??>  ??=  ??/	 ??'  ??!  ??-
		   Replacement:	     [	  ]    {    }	 #    \	   ^	|    ~

	   By default, GCC ignores trigraphs, but in standard-conforming modes
	   it converts them.  See the -std and -ansi options.

       -remap
	   Enable special code to work around file systems which only permit
	   very short file names, such as MS-DOS.

       -H  Print the name of each header file used, in addition to other
	   normal activities.  Each name is indented to show how deep in the
	   #include stack it is.  Precompiled header files are also printed,
	   even if they are found to be invalid; an invalid precompiled header
	   file is printed with ...x and a valid one with ...! .

       -dletters
	   Says to make debugging dumps during compilation as specified by
	   letters.  The flags documented here are those relevant to the
	   preprocessor.  Other letters are interpreted by the compiler
	   proper, or reserved for future versions of GCC, and so are silently
	   ignored.  If you specify letters whose behavior conflicts, the
	   result is undefined.

	   -dM Instead of the normal output, generate a list of #define
	       directives for all the macros defined during the execution of
	       the preprocessor, including predefined macros.  This gives you
	       a way of finding out what is predefined in your version of the
	       preprocessor.  Assuming you have no file foo.h, the command

		       touch foo.h; cpp -dM foo.h

	       shows all the predefined macros.

	       If you use -dM without the -E option, -dM is interpreted as a
	       synonym for -fdump-rtl-mach.

	   -dD Like -dM except that it outputs both the #define directives and
	       the result of preprocessing.  Both kinds of output go to the
	       standard output file.

	   -dN Like -dD, but emit only the macro names, not their expansions.

	   -dI Output #include directives in addition to the result of
	       preprocessing.

	   -dU Like -dD except that only macros that are expanded, or whose
	       definedness is tested in preprocessor directives, are output;
	       the output is delayed until the use or test of the macro; and
	       #undef directives are also output for macros tested but
	       undefined at the time.

       -fdebug-cpp
	   This option is only useful for debugging GCC.  When used from CPP
	   or with -E, it dumps debugging information about location maps.
	   Every token in the output is preceded by the dump of the map its
	   location belongs to.

	   When used from GCC without -E, this option has no effect.

       -Wp,option
	   You can use -Wp,option to bypass the compiler driver and pass
	   option directly through to the preprocessor.	 If option contains
	   commas, it is split into multiple options at the commas.  However,
	   many options are modified, translated or interpreted by the
	   compiler driver before being passed to the preprocessor, and -Wp
	   forcibly bypasses this phase.  The preprocessor's direct interface
	   is undocumented and subject to change, so whenever possible you
	   should avoid using -Wp and let the driver handle the options
	   instead.

       -Xpreprocessor option
	   Pass option as an option to the preprocessor.  You can use this to
	   supply system-specific preprocessor options that GCC does not
	   recognize.

	   If you want to pass an option that takes an argument, you must use
	   -Xpreprocessor twice, once for the option and once for the
	   argument.

       -no-integrated-cpp
	   Perform preprocessing as a separate pass before compilation.	 By
	   default, GCC performs preprocessing as an integrated part of input
	   tokenization and parsing.  If this option is provided, the
	   appropriate language front end (cc1, cc1plus, or cc1obj for C, C++,
	   and Objective-C, respectively) is instead invoked twice, once for
	   preprocessing only and once for actual compilation of the
	   preprocessed input.	This option may be useful in conjunction with
	   the -B or -wrapper options to specify an alternate preprocessor or
	   perform additional processing of the program source between normal
	   preprocessing and compilation.

       -flarge-source-files
	   Adjust GCC to expect large source files, at the expense of slower
	   compilation and higher memory usage.

	   Specifically, GCC normally tracks both column numbers and line
	   numbers within source files and it normally prints both of these
	   numbers in diagnostics.  However, once it has processed a certain
	   number of source lines, it stops tracking column numbers and only
	   tracks line numbers.	 This means that diagnostics for later lines
	   do not include column numbers.  It also means that options like
	   -Wmisleading-indentation cease to work at that point, although the
	   compiler prints a note if this happens.  Passing
	   -flarge-source-files significantly increases the number of source
	   lines that GCC can process before it stops tracking columns.

   Passing Options to the Assembler
       You can pass options to the assembler.

       -Wa,option
	   Pass option as an option to the assembler.  If option contains
	   commas, it is split into multiple options at the commas.

       -Xassembler option
	   Pass option as an option to the assembler.  You can use this to
	   supply system-specific assembler options that GCC does not
	   recognize.

	   If you want to pass an option that takes an argument, you must use
	   -Xassembler twice, once for the option and once for the argument.

   Options for Linking
       These options come into play when the compiler links object files into
       an executable output file.  They are meaningless if the compiler is not
       doing a link step.

       object-file-name
	   A file name that does not end in a special recognized suffix is
	   considered to name an object file or library.  (Object files are
	   distinguished from libraries by the linker according to the file
	   contents.)  If linking is done, these object files are used as
	   input to the linker.

       -c
       -S
       -E  If any of these options is used, then the linker is not run, and
	   object file names should not be used as arguments.

       -flinker-output=type
	   This option controls code generation of the link-time optimizer.
	   By default the linker output is automatically determined by the
	   linker plugin.  For debugging the compiler and if incremental
	   linking with a non-LTO object file is desired, it may be useful to
	   control the type manually.

	   If type is exec, code generation produces a static binary. In this
	   case -fpic and -fpie are both disabled.

	   If type is dyn, code generation produces a shared library.  In this
	   case -fpic or -fPIC is preserved, but not enabled automatically.
	   This allows to build shared libraries without position-independent
	   code on architectures where this is possible, i.e. on x86.

	   If type is pie, code generation produces an -fpie executable. This
	   results in similar optimizations as exec except that -fpie is not
	   disabled if specified at compilation time.

	   If type is rel, the compiler assumes that incremental linking is
	   done.  The sections containing intermediate code for link-time
	   optimization are merged, pre-optimized, and output to the resulting
	   object file. In addition, if -ffat-lto-objects is specified, binary
	   code is produced for future non-LTO linking. The object file
	   produced by incremental linking is smaller than a static library
	   produced from the same object files.	 At link time the result of
	   incremental linking also loads faster than a static library
	   assuming that the majority of objects in the library are used.

	   Finally nolto-rel configures the compiler for incremental linking
	   where code generation is forced, a final binary is produced, and
	   the intermediate code for later link-time optimization is stripped.
	   When multiple object files are linked together the resulting code
	   is better optimized than with link-time optimizations disabled (for
	   example, cross-module inlining happens), but most of benefits of
	   whole program optimizations are lost.

	   During the incremental link (by -r) the linker plugin defaults to
	   rel. With current interfaces to GNU Binutils it is however not
	   possible to incrementally link LTO objects and non-LTO objects into
	   a single mixed object file.	If any of object files in incremental
	   link cannot be used for link-time optimization, the linker plugin
	   issues a warning and uses nolto-rel. To maintain whole program
	   optimization, it is recommended to link such objects into static
	   library instead. Alternatively it is possible to use H.J. Lu's
	   binutils with support for mixed objects.

       -fuse-ld=bfd
	   Use the bfd linker instead of the default linker.

       -fuse-ld=gold
	   Use the gold linker instead of the default linker.

       -fuse-ld=lld
	   Use the LLVM lld linker instead of the default linker.

       -fuse-ld=mold
	   Use the Modern Linker (mold) instead of the default linker.

       -llibrary
       -l library
	   Search the library named library when linking.  (The second
	   alternative with the library as a separate argument is only for
	   POSIX compliance and is not recommended.)

	   The -l option is passed directly to the linker by GCC.  Refer to
	   your linker documentation for exact details.	 The general
	   description below applies to the GNU linker.

	   The linker searches a standard list of directories for the library.
	   The directories searched include several standard system
	   directories plus any that you specify with -L.

	   Static libraries are archives of object files, and have file names
	   like liblibrary.a.  Some targets also support shared libraries,
	   which typically have names like liblibrary.so.  If both static and
	   shared libraries are found, the linker gives preference to linking
	   with the shared library unless the -static option is used.

	   It makes a difference where in the command you write this option;
	   the linker searches and processes libraries and object files in the
	   order they are specified.  Thus, foo.o -lz bar.o searches library z
	   after file foo.o but before bar.o.  If bar.o refers to functions in
	   z, those functions may not be loaded.

       -lobjc
	   You need this special case of the -l option in order to link an
	   Objective-C or Objective-C++ program.

       -nostartfiles
	   Do not use the standard system startup files when linking.  The
	   standard system libraries are used normally, unless -nostdlib,
	   -nolibc, or -nodefaultlibs is used.

       -nodefaultlibs
	   Do not use the standard system libraries when linking.  Only the
	   libraries you specify are passed to the linker, and options
	   specifying linkage of the system libraries, such as -static-libgcc
	   or -shared-libgcc, are ignored.  The standard startup files are
	   used normally, unless -nostartfiles is used.

	   The compiler may generate calls to "memcmp", "memset", "memcpy" and
	   "memmove".  These entries are usually resolved by entries in libc.
	   These entry points should be supplied through some other mechanism
	   when this option is specified.

       -nolibc
	   Do not use the C library or system libraries tightly coupled with
	   it when linking.  Still link with the startup files, libgcc or
	   toolchain provided language support libraries such as libgnat,
	   libgfortran or libstdc++ unless options preventing their inclusion
	   are used as well.  This typically removes -lc from the link command
	   line, as well as system libraries that normally go with it and
	   become meaningless when absence of a C library is assumed, for
	   example -lpthread or -lm in some configurations.  This is intended
	   for bare-board targets when there is indeed no C library available.

       -nostdlib
	   Do not use the standard system startup files or libraries when
	   linking.  No startup files and only the libraries you specify are
	   passed to the linker, and options specifying linkage of the system
	   libraries, such as -static-libgcc or -shared-libgcc, are ignored.

	   The compiler may generate calls to "memcmp", "memset", "memcpy" and
	   "memmove".  These entries are usually resolved by entries in libc.
	   These entry points should be supplied through some other mechanism
	   when this option is specified.

	   One of the standard libraries bypassed by -nostdlib and
	   -nodefaultlibs is libgcc.a, a library of internal subroutines which
	   GCC uses to overcome shortcomings of particular machines, or
	   special needs for some languages.

	   In most cases, you need libgcc.a even when you want to avoid other
	   standard libraries.	In other words, when you specify -nostdlib or
	   -nodefaultlibs you should usually specify -lgcc as well.  This
	   ensures that you have no unresolved references to internal GCC
	   library subroutines.	 (An example of such an internal subroutine is
	   "__main", used to ensure C++ constructors are called.)

       -nostdlib++
	   Do not implicitly link with standard C++ libraries.

       -e entry
       --entry=entry
	   Specify that the program entry point is entry.  The argument is
	   interpreted by the linker; the GNU linker accepts either a symbol
	   name or an address.

       -pie
	   Produce a dynamically linked position independent executable on
	   targets that support it.  For predictable results, you must also
	   specify the same set of options used for compilation (-fpie, -fPIE,
	   or model suboptions) when you specify this linker option.

       -no-pie
	   Don't produce a dynamically linked position independent executable.

       -static-pie
	   Produce a static position independent executable on targets that
	   support it.	A static position independent executable is similar to
	   a static executable, but can be loaded at any address without a
	   dynamic linker.  For predictable results, you must also specify the
	   same set of options used for compilation (-fpie, -fPIE, or model
	   suboptions) when you specify this linker option.

       -pthread
	   Link with the POSIX threads library.	 This option is supported on
	   GNU/Linux targets, most other Unix derivatives, and also on x86
	   Cygwin and MinGW targets.  On some targets this option also sets
	   flags for the preprocessor, so it should be used consistently for
	   both compilation and linking.

       -r  Produce a relocatable object as output.  This is also known as
	   partial linking.

       -rdynamic
	   Pass the flag -export-dynamic to the ELF linker, on targets that
	   support it. This instructs the linker to add all symbols, not only
	   used ones, to the dynamic symbol table. This option is needed for
	   some uses of "dlopen" or to allow obtaining backtraces from within
	   a program.

       -s  Remove all symbol table and relocation information from the
	   executable.

       -static
	   On systems that support dynamic linking, this overrides -pie and
	   prevents linking with the shared libraries.	On other systems, this
	   option has no effect.

       -shared
	   Produce a shared object which can then be linked with other objects
	   to form an executable.  Not all systems support this option.	 For
	   predictable results, you must also specify the same set of options
	   used for compilation (-fpic, -fPIC, or model suboptions) when you
	   specify this linker option.[1]

       -shared-libgcc
       -static-libgcc
	   On systems that provide libgcc as a shared library, these options
	   force the use of either the shared or static version, respectively.
	   If no shared version of libgcc was built when the compiler was
	   configured, these options have no effect.

	   There are several situations in which an application should use the
	   shared libgcc instead of the static version.	 The most common of
	   these is when the application wishes to throw and catch exceptions
	   across different shared libraries.  In that case, each of the
	   libraries as well as the application itself should use the shared
	   libgcc.

	   Therefore, the G++ driver automatically adds -shared-libgcc
	   whenever you build a shared library or a main executable, because
	   C++ programs typically use exceptions, so this is the right thing
	   to do.

	   If, instead, you use the GCC driver to create shared libraries, you
	   may find that they are not always linked with the shared libgcc.
	   If GCC finds, at its configuration time, that you have a non-GNU
	   linker or a GNU linker that does not support option --eh-frame-hdr,
	   it links the shared version of libgcc into shared libraries by
	   default.  Otherwise, it takes advantage of the linker and optimizes
	   away the linking with the shared version of libgcc, linking with
	   the static version of libgcc by default.  This allows exceptions to
	   propagate through such shared libraries, without incurring
	   relocation costs at library load time.

	   However, if a library or main executable is supposed to throw or
	   catch exceptions, you must link it using the G++ driver, or using
	   the option -shared-libgcc, such that it is linked with the shared
	   libgcc.

       -static-libasan
	   When the -fsanitize=address option is used to link a program, the
	   GCC driver automatically links against libasan.  If libasan is
	   available as a shared library, and the -static option is not used,
	   then this links against the shared version of libasan.  The
	   -static-libasan option directs the GCC driver to link libasan
	   statically, without necessarily linking other libraries statically.

       -static-libtsan
	   When the -fsanitize=thread option is used to link a program, the
	   GCC driver automatically links against libtsan.  If libtsan is
	   available as a shared library, and the -static option is not used,
	   then this links against the shared version of libtsan.  The
	   -static-libtsan option directs the GCC driver to link libtsan
	   statically, without necessarily linking other libraries statically.

       -static-liblsan
	   When the -fsanitize=leak option is used to link a program, the GCC
	   driver automatically links against liblsan.	If liblsan is
	   available as a shared library, and the -static option is not used,
	   then this links against the shared version of liblsan.  The
	   -static-liblsan option directs the GCC driver to link liblsan
	   statically, without necessarily linking other libraries statically.

       -static-libubsan
	   When the -fsanitize=undefined option is used to link a program, the
	   GCC driver automatically links against libubsan.  If libubsan is
	   available as a shared library, and the -static option is not used,
	   then this links against the shared version of libubsan.  The
	   -static-libubsan option directs the GCC driver to link libubsan
	   statically, without necessarily linking other libraries statically.

       -static-libstdc++
	   When the g++ program is used to link a C++ program, it normally
	   automatically links against libstdc++.  If libstdc++ is available
	   as a shared library, and the -static option is not used, then this
	   links against the shared version of libstdc++.  That is normally
	   fine.  However, it is sometimes useful to freeze the version of
	   libstdc++ used by the program without going all the way to a fully
	   static link.	 The -static-libstdc++ option directs the g++ driver
	   to link libstdc++ statically, without necessarily linking other
	   libraries statically.

       -symbolic
	   Bind references to global symbols when building a shared object.
	   Warn about any unresolved references (unless overridden by the link
	   editor option -Xlinker -z -Xlinker defs).  Only a few systems
	   support this option.

       -T script
	   Use script as the linker script.  This option is supported by most
	   systems using the GNU linker.  On some targets, such as bare-board
	   targets without an operating system, the -T option may be required
	   when linking to avoid references to undefined symbols.

       -Xlinker option
	   Pass option as an option to the linker.  You can use this to supply
	   system-specific linker options that GCC does not recognize.

	   If you want to pass an option that takes a separate argument, you
	   must use -Xlinker twice, once for the option and once for the
	   argument.  For example, to pass -assert definitions, you must write
	   -Xlinker -assert -Xlinker definitions.  It does not work to write
	   -Xlinker "-assert definitions", because this passes the entire
	   string as a single argument, which is not what the linker expects.

	   When using the GNU linker, it is usually more convenient to pass
	   arguments to linker options using the option=value syntax than as
	   separate arguments.	For example, you can specify -Xlinker
	   -Map=output.map rather than -Xlinker -Map -Xlinker output.map.
	   Other linkers may not support this syntax for command-line options.

       -Wl,option
	   Pass option as an option to the linker.  If option contains commas,
	   it is split into multiple options at the commas.  You can use this
	   syntax to pass an argument to the option.  For example,
	   -Wl,-Map,output.map passes -Map output.map to the linker.  When
	   using the GNU linker, you can also get the same effect with
	   -Wl,-Map=output.map.

       -u symbol
	   Pretend the symbol symbol is undefined, to force linking of library
	   modules to define it.  You can use -u multiple times with different
	   symbols to force loading of additional library modules.

       -z keyword
	   -z is passed directly on to the linker along with the keyword
	   keyword. See the section in the documentation of your linker for
	   permitted values and their meanings.

   Options for Directory Search
       These options specify directories to search for header files, for
       libraries and for parts of the compiler:

       -I dir
       -iquote dir
       -isystem dir
       -idirafter dir
	   Add the directory dir to the list of directories to be searched for
	   header files during preprocessing.  If dir begins with = or
	   $SYSROOT, then the = or $SYSROOT is replaced by the sysroot prefix;
	   see --sysroot and -isysroot.

	   Directories specified with -iquote apply only to the quote form of
	   the directive, "#include "file"".  Directories specified with -I,
	   -isystem, or -idirafter apply to lookup for both the
	   "#include "file"" and "#include <file>" directives.

	   You can specify any number or combination of these options on the
	   command line to search for header files in several directories.
	   The lookup order is as follows:

	   1.  For the quote form of the include directive, the directory of
	       the current file is searched first.

	   2.  For the quote form of the include directive, the directories
	       specified by -iquote options are searched in left-to-right
	       order, as they appear on the command line.

	   3.  Directories specified with -I options are scanned in left-to-
	       right order.

	   4.  Directories specified with -isystem options are scanned in
	       left-to-right order.

	   5.  Standard system directories are scanned.

	   6.  Directories specified with -idirafter options are scanned in
	       left-to-right order.

	   You can use -I to override a system header file, substituting your
	   own version, since these directories are searched before the
	   standard system header file directories.  However, you should not
	   use this option to add directories that contain vendor-supplied
	   system header files; use -isystem for that.

	   The -isystem and -idirafter options also mark the directory as a
	   system directory, so that it gets the same special treatment that
	   is applied to the standard system directories.

	   If a standard system include directory, or a directory specified
	   with -isystem, is also specified with -I, the -I option is ignored.
	   The directory is still searched but as a system directory at its
	   normal position in the system include chain.	 This is to ensure
	   that GCC's procedure to fix buggy system headers and the ordering
	   for the "#include_next" directive are not inadvertently changed.
	   If you really need to change the search order for system
	   directories, use the -nostdinc and/or -isystem options.

       -I- Split the include path.  This option has been deprecated.  Please
	   use -iquote instead for -I directories before the -I- and remove
	   the -I- option.

	   Any directories specified with -I options before -I- are searched
	   only for headers requested with "#include "file""; they are not
	   searched for "#include <file>".  If additional directories are
	   specified with -I options after the -I-, those directories are
	   searched for all #include directives.

	   In addition, -I- inhibits the use of the directory of the current
	   file directory as the first search directory for "#include "file"".
	   There is no way to override this effect of -I-.

       -iprefix prefix
	   Specify prefix as the prefix for subsequent -iwithprefix options.
	   If the prefix represents a directory, you should include the final
	   /.

       -iwithprefix dir
       -iwithprefixbefore dir
	   Append dir to the prefix specified previously with -iprefix, and
	   add the resulting directory to the include search path.
	   -iwithprefixbefore puts it in the same place -I would; -iwithprefix
	   puts it where -idirafter would.

       -isysroot dir
	   This option is like the --sysroot option, but applies only to
	   header files (except for Darwin targets, where it applies to both
	   header files and libraries).	 See the --sysroot option for more
	   information.

       -imultilib dir
	   Use dir as a subdirectory of the directory containing target-
	   specific C++ headers.

       -nostdinc
	   Do not search the standard system directories for header files.
	   Only the directories explicitly specified with -I, -iquote,
	   -isystem, and/or -idirafter options (and the directory of the
	   current file, if appropriate) are searched.

       -nostdinc++
	   Do not search for header files in the C++-specific standard
	   directories, but do still search the other standard directories.
	   (This option is used when building the C++ library.)

       -iplugindir=dir
	   Set the directory to search for plugins that are passed by
	   -fplugin=name instead of -fplugin=path/name.so.  This option is not
	   meant to be used by the user, but only passed by the driver.

       -Ldir
	   Add directory dir to the list of directories to be searched for -l.

       -Bprefix
	   This option specifies where to find the executables, libraries,
	   include files, and data files of the compiler itself.

	   The compiler driver program runs one or more of the subprograms
	   cpp, cc1, as and ld.	 It tries prefix as a prefix for each program
	   it tries to run, both with and without machine/version/ for the
	   corresponding target machine and compiler version.

	   For each subprogram to be run, the compiler driver first tries the
	   -B prefix, if any.  If that name is not found, or if -B is not
	   specified, the driver tries two standard prefixes, /usr/lib/gcc/
	   and /usr/local/lib/gcc/.  If neither of those results in a file
	   name that is found, the unmodified program name is searched for
	   using the directories specified in your PATH environment variable.

	   The compiler checks to see if the path provided by -B refers to a
	   directory, and if necessary it adds a directory separator character
	   at the end of the path.

	   -B prefixes that effectively specify directory names also apply to
	   libraries in the linker, because the compiler translates these
	   options into -L options for the linker.  They also apply to include
	   files in the preprocessor, because the compiler translates these
	   options into -isystem options for the preprocessor.	In this case,
	   the compiler appends include to the prefix.

	   The runtime support file libgcc.a can also be searched for using
	   the -B prefix, if needed.  If it is not found there, the two
	   standard prefixes above are tried, and that is all.	The file is
	   left out of the link if it is not found by those means.

	   Another way to specify a prefix much like the -B prefix is to use
	   the environment variable GCC_EXEC_PREFIX.

	   As a special kludge, if the path provided by -B is [dir/]stageN/,
	   where N is a number in the range 0 to 9, then it is replaced by
	   [dir/]include.  This is to help with boot-strapping the compiler.

       -no-canonical-prefixes
	   Do not expand any symbolic links, resolve references to /../ or
	   /./, or make the path absolute when generating a relative prefix.

       --sysroot=dir
	   Use dir as the logical root directory for headers and libraries.
	   For example, if the compiler normally searches for headers in
	   /usr/include and libraries in /usr/lib, it instead searches
	   dir/usr/include and dir/usr/lib.

	   If you use both this option and the -isysroot option, then the
	   --sysroot option applies to libraries, but the -isysroot option
	   applies to header files.

	   The GNU linker (beginning with version 2.16) has the necessary
	   support for this option.  If your linker does not support this
	   option, the header file aspect of --sysroot still works, but the
	   library aspect does not.

       --no-sysroot-suffix
	   For some targets, a suffix is added to the root directory specified
	   with --sysroot, depending on the other options used, so that
	   headers may for example be found in dir/suffix/usr/include instead
	   of dir/usr/include.	This option disables the addition of such a
	   suffix.

   Options for Code Generation Conventions
       These machine-independent options control the interface conventions
       used in code generation.

       Most of them have both positive and negative forms; the negative form
       of -ffoo is -fno-foo.  In the table below, only one of the forms is
       listed---the one that is not the default.  You can figure out the other
       form by either removing no- or adding it.

       -fstack-reuse=reuse-level
	   This option controls stack space reuse for user declared local/auto
	   variables and compiler generated temporaries.  reuse_level can be
	   all, named_vars, or none. all enables stack reuse for all local
	   variables and temporaries, named_vars enables the reuse only for
	   user defined local variables with names, and none disables stack
	   reuse completely. The default value is all. The option is needed
	   when the program extends the lifetime of a scoped local variable or
	   a compiler generated temporary beyond the end point defined by the
	   language.  When a lifetime of a variable ends, and if the variable
	   lives in memory, the optimizing compiler has the freedom to reuse
	   its stack space with other temporaries or scoped local variables
	   whose live range does not overlap with it. Legacy code extending
	   local lifetime is likely to break with the stack reuse
	   optimization.

	   For example,

		      int *p;
		      {
			int local1;

			p = &local1;
			local1 = 10;
			....
		      }
		      {
			 int local2;
			 local2 = 20;
			 ...
		      }

		      if (*p == 10)  // out of scope use of local1
			{

			}

	   Another example:

		      struct A
		      {
			  A(int k) : i(k), j(k) { }
			  int i;
			  int j;
		      };

		      A *ap;

		      void foo(const A& ar)
		      {
			 ap = &ar;
		      }

		      void bar()
		      {
			 foo(A(10)); // temp object's lifetime ends when foo returns

			 {
			   A a(20);
			   ....
			 }
			 ap->i+= 10;  // ap references out of scope temp whose space
				      // is reused with a. What is the value of ap->i?
		      }

	   The lifetime of a compiler generated temporary is well defined by
	   the C++ standard. When a lifetime of a temporary ends, and if the
	   temporary lives in memory, the optimizing compiler has the freedom
	   to reuse its stack space with other temporaries or scoped local
	   variables whose live range does not overlap with it. However some
	   of the legacy code relies on the behavior of older compilers in
	   which temporaries' stack space is not reused, the aggressive stack
	   reuse can lead to runtime errors. This option is used to control
	   the temporary stack reuse optimization.

       -ftrapv
	   This option generates traps for signed overflow on addition,
	   subtraction, multiplication operations.  The options -ftrapv and
	   -fwrapv override each other, so using -ftrapv -fwrapv on the
	   command-line results in -fwrapv being effective.  Note that only
	   active options override, so using -ftrapv -fwrapv -fno-wrapv on the
	   command-line results in -ftrapv being effective.

       -fwrapv
	   This option instructs the compiler to assume that signed arithmetic
	   overflow of addition, subtraction and multiplication wraps around
	   using twos-complement representation.  This flag enables some
	   optimizations and disables others.  The options -ftrapv and -fwrapv
	   override each other, so using -ftrapv -fwrapv on the command-line
	   results in -fwrapv being effective.	Note that only active options
	   override, so using -ftrapv -fwrapv -fno-wrapv on the command-line
	   results in -ftrapv being effective.

       -fwrapv-pointer
	   This option instructs the compiler to assume that pointer
	   arithmetic overflow on addition and subtraction wraps around using
	   twos-complement representation.  This flag disables some
	   optimizations which assume pointer overflow is invalid.

       -fstrict-overflow
	   This option implies -fno-wrapv -fno-wrapv-pointer and when negated
	   implies -fwrapv -fwrapv-pointer.

       -fexceptions
	   Enable exception handling.  Generates extra code needed to
	   propagate exceptions.  For some targets, this implies GCC generates
	   frame unwind information for all functions, which can produce
	   significant data size overhead, although it does not affect
	   execution.  If you do not specify this option, GCC enables it by
	   default for languages like C++ that normally require exception
	   handling, and disables it for languages like C that do not normally
	   require it.	However, you may need to enable this option when
	   compiling C code that needs to interoperate properly with exception
	   handlers written in C++.  You may also wish to disable this option
	   if you are compiling older C++ programs that don't use exception
	   handling.

       -fnon-call-exceptions
	   Generate code that allows trapping instructions to throw
	   exceptions.	Note that this requires platform-specific runtime
	   support that does not exist everywhere.  Moreover, it only allows
	   trapping instructions to throw exceptions, i.e. memory references
	   or floating-point instructions.  It does not allow exceptions to be
	   thrown from arbitrary signal handlers such as "SIGALRM".  This
	   enables -fexceptions.

       -fdelete-dead-exceptions
	   Consider that instructions that may throw exceptions but don't
	   otherwise contribute to the execution of the program can be
	   optimized away.  This does not affect calls to functions except
	   those with the "pure" or "const" attributes.	 This option is
	   enabled by default for the Ada and C++ compilers, as permitted by
	   the language specifications.	 Optimization passes that cause dead
	   exceptions to be removed are enabled independently at different
	   optimization levels.

       -funwind-tables
	   Similar to -fexceptions, except that it just generates any needed
	   static data, but does not affect the generated code in any other
	   way.	 You normally do not need to enable this option; instead, a
	   language processor that needs this handling enables it on your
	   behalf.

       -fasynchronous-unwind-tables
	   Generate unwind table in DWARF format, if supported by target
	   machine.  The table is exact at each instruction boundary, so it
	   can be used for stack unwinding from asynchronous events (such as
	   debugger or garbage collector).

       -fno-gnu-unique
	   On systems with recent GNU assembler and C library, the C++
	   compiler uses the "STB_GNU_UNIQUE" binding to make sure that
	   definitions of template static data members and static local
	   variables in inline functions are unique even in the presence of
	   "RTLD_LOCAL"; this is necessary to avoid problems with a library
	   used by two different "RTLD_LOCAL" plugins depending on a
	   definition in one of them and therefore disagreeing with the other
	   one about the binding of the symbol.	 But this causes "dlclose" to
	   be ignored for affected DSOs; if your program relies on
	   reinitialization of a DSO via "dlclose" and "dlopen", you can use
	   -fno-gnu-unique.

       -fpcc-struct-return
	   Return "short" "struct" and "union" values in memory like longer
	   ones, rather than in registers.  This convention is less efficient,
	   but it has the advantage of allowing intercallability between GCC-
	   compiled files and files compiled with other compilers,
	   particularly the Portable C Compiler (pcc).

	   The precise convention for returning structures in memory depends
	   on the target configuration macros.

	   Short structures and unions are those whose size and alignment
	   match that of some integer type.

	   Warning: code compiled with the -fpcc-struct-return switch is not
	   binary compatible with code compiled with the -freg-struct-return
	   switch.  Use it to conform to a non-default application binary
	   interface.

       -freg-struct-return
	   Return "struct" and "union" values in registers when possible.
	   This is more efficient for small structures than
	   -fpcc-struct-return.

	   If you specify neither -fpcc-struct-return nor -freg-struct-return,
	   GCC defaults to whichever convention is standard for the target.
	   If there is no standard convention, GCC defaults to
	   -fpcc-struct-return, except on targets where GCC is the principal
	   compiler.  In those cases, we can choose the standard, and we chose
	   the more efficient register return alternative.

	   Warning: code compiled with the -freg-struct-return switch is not
	   binary compatible with code compiled with the -fpcc-struct-return
	   switch.  Use it to conform to a non-default application binary
	   interface.

       -fshort-enums
	   Allocate to an "enum" type only as many bytes as it needs for the
	   declared range of possible values.  Specifically, the "enum" type
	   is equivalent to the smallest integer type that has enough room.
	   This option has no effect for an enumeration type with a fixed
	   underlying type.

	   Warning: the -fshort-enums switch causes GCC to generate code that
	   is not binary compatible with code generated without that switch.
	   Use it to conform to a non-default application binary interface.

       -fshort-wchar
	   Override the underlying type for "wchar_t" to be "short unsigned
	   int" instead of the default for the target.	This option is useful
	   for building programs to run under WINE.

	   Warning: the -fshort-wchar switch causes GCC to generate code that
	   is not binary compatible with code generated without that switch.
	   Use it to conform to a non-default application binary interface.

       -fcommon
	   In C code, this option controls the placement of global variables
	   defined without an initializer, known as tentative definitions in
	   the C standard.  Tentative definitions are distinct from
	   declarations of a variable with the "extern" keyword, which do not
	   allocate storage.

	   The default is -fno-common, which specifies that the compiler
	   places uninitialized global variables in the BSS section of the
	   object file.	 This inhibits the merging of tentative definitions by
	   the linker so you get a multiple-definition error if the same
	   variable is accidentally defined in more than one compilation unit.

	   The -fcommon places uninitialized global variables in a common
	   block.  This allows the linker to resolve all tentative definitions
	   of the same variable in different compilation units to the same
	   object, or to a non-tentative definition.  This behavior is
	   inconsistent with C++, and on many targets implies a speed and code
	   size penalty on global variable references.	It is mainly useful to
	   enable legacy code to link without errors.

       -fno-ident
	   Ignore the "#ident" directive.

       -finhibit-size-directive
	   Don't output a ".size" assembler directive, or anything else that
	   would cause trouble if the function is split in the middle, and the
	   two halves are placed at locations far apart in memory.  This
	   option is used when compiling crtstuff.c; you should not need to
	   use it for anything else.

       -fverbose-asm
	   Put extra commentary information in the generated assembly code to
	   make it more readable.  This option is generally only of use to
	   those who actually need to read the generated assembly code
	   (perhaps while debugging the compiler itself).

	   -fno-verbose-asm, the default, causes the extra information to be
	   omitted and is useful when comparing two assembler files.

	   The added comments include:

	   *   information on the compiler version and command-line options,

	   *   the source code lines associated with the assembly
	       instructions, in the form FILENAME:LINENUMBER:CONTENT OF LINE,

	   *   hints on which high-level expressions correspond to the various
	       assembly instruction operands.

	   For example, given this C source file:

		   int test (int n)
		   {
		     int i;
		     int total = 0;

		     for (i = 0; i < n; i++)
		       total += i * i;

		     return total;
		   }

	   compiling to (x86_64) assembly via -S and emitting the result
	   direct to stdout via -o -

		   gcc -S test.c -fverbose-asm -Os -o -

	   gives output similar to this:

			   .file   "test.c"
		   # GNU C11 (GCC) version 7.0.0 20160809 (experimental) (x86_64-pc-linux-gnu)
		     [...snip...]
		   # options passed:
		     [...snip...]

			   .text
			   .globl  test
			   .type   test, @function
		   test:
		   .LFB0:
			   .cfi_startproc
		   # test.c:4:	 int total = 0;
			   xorl	   %eax, %eax	   # <retval>
		   # test.c:6:	 for (i = 0; i < n; i++)
			   xorl	   %edx, %edx	   # i
		   .L2:
		   # test.c:6:	 for (i = 0; i < n; i++)
			   cmpl	   %edi, %edx	   # n, i
			   jge	   .L5	   #,
		   # test.c:7:	   total += i * i;
			   movl	   %edx, %ecx	   # i, tmp92
			   imull   %edx, %ecx	   # i, tmp92
		   # test.c:6:	 for (i = 0; i < n; i++)
			   incl	   %edx	   # i
		   # test.c:7:	   total += i * i;
			   addl	   %ecx, %eax	   # tmp92, <retval>
			   jmp	   .L2	   #
		   .L5:
		   # test.c:10: }
			   ret
			   .cfi_endproc
		   .LFE0:
			   .size   test, .-test
			   .ident  "GCC: (GNU) 7.0.0 20160809 (experimental)"
			   .section	   .note.GNU-stack,"",@progbits

	   The comments are intended for humans rather than machines and hence
	   the precise format of the comments is subject to change.

       -frecord-gcc-switches
	   This switch causes the command line used to invoke the compiler to
	   be recorded into the object file that is being created.  This
	   switch is only implemented on some targets and the exact format of
	   the recording is target and binary file format dependent, but it
	   usually takes the form of a section containing ASCII text.  This
	   switch is related to the -fverbose-asm switch, but that switch only
	   records information in the assembler output file as comments, so it
	   never reaches the object file.  See also -grecord-gcc-switches for
	   another way of storing compiler options into the object file.

       -fpic
	   Generate position-independent code (PIC) suitable for use in a
	   shared library, if supported for the target machine.	 Such code
	   accesses all constant addresses through a global offset table
	   (GOT).  The dynamic loader resolves the GOT entries when the
	   program starts (the dynamic loader is not part of GCC; it is part
	   of the operating system).  If the GOT size for the linked
	   executable exceeds a machine-specific maximum size, you get an
	   error message from the linker indicating that -fpic does not work;
	   in that case, recompile with -fPIC instead.	(These maximums are 8k
	   on the SPARC, 28k on AArch64 and 32k on the m68k and RS/6000.  The
	   x86 has no such limit.)

	   Position-independent code requires special support, and therefore
	   works only on certain machines.  For the x86, GCC supports PIC for
	   System V but not for the Sun 386i.  Code generated for the IBM
	   RS/6000 is always position-independent.

	   When this flag is set, the macros "__pic__" and "__PIC__" are
	   defined to 1.

       -fPIC
	   If supported for the target machine, emit position-independent
	   code, suitable for dynamic linking and avoiding any limit on the
	   size of the global offset table.  This option makes a difference on
	   AArch64, m68k, PowerPC and SPARC.

	   Position-independent code requires special support, and therefore
	   works only on certain machines.

	   When this flag is set, the macros "__pic__" and "__PIC__" are
	   defined to 2.

       -fpie
       -fPIE
	   These options are similar to -fpic and -fPIC, but the generated
	   position-independent code can be only linked into executables.
	   Usually these options are used to compile code that will be linked
	   using the -pie GCC option.

	   -fpie and -fPIE both define the macros "__pie__" and "__PIE__".
	   The macros have the value 1 for -fpie and 2 for -fPIE.

       -fno-plt
	   Do not use the PLT for external function calls in position-
	   independent code.  Instead, load the callee address at call sites
	   from the GOT and branch to it.  This leads to more efficient code
	   by eliminating PLT stubs and exposing GOT loads to optimizations.
	   On architectures such as 32-bit x86 where PLT stubs expect the GOT
	   pointer in a specific register, this gives more register allocation
	   freedom to the compiler.  Lazy binding requires use of the PLT;
	   with -fno-plt all external symbols are resolved at load time.

	   Alternatively, the function attribute "noplt" can be used to avoid
	   calls through the PLT for specific external functions.

	   In position-dependent code, a few targets also convert calls to
	   functions that are marked to not use the PLT to use the GOT
	   instead.

       -fno-jump-tables
	   Do not use jump tables for switch statements even where it would be
	   more efficient than other code generation strategies.  This option
	   is of use in conjunction with -fpic or -fPIC for building code that
	   forms part of a dynamic linker and cannot reference the address of
	   a jump table.  On some targets, jump tables do not require a GOT
	   and this option is not needed.

       -fno-bit-tests
	   Do not use bit tests for switch statements even where it would be
	   more efficient than other code generation strategies.

       -ffixed-reg
	   Treat the register named reg as a fixed register; generated code
	   should never refer to it (except perhaps as a stack pointer, frame
	   pointer or in some other fixed role).

	   reg must be the name of a register.	The register names accepted
	   are machine-specific and are defined in the "REGISTER_NAMES" macro
	   in the machine description macro file.

	   This flag does not have a negative form, because it specifies a
	   three-way choice.

       -fcall-used-reg
	   Treat the register named reg as an allocable register that is
	   clobbered by function calls.	 It may be allocated for temporaries
	   or variables that do not live across a call.	 Functions compiled
	   this way do not save and restore the register reg.

	   It is an error to use this flag with the frame pointer or stack
	   pointer.  Use of this flag for other registers that have fixed
	   pervasive roles in the machine's execution model produces
	   disastrous results.

	   This flag does not have a negative form, because it specifies a
	   three-way choice.

       -fcall-saved-reg
	   Treat the register named reg as an allocable register saved by
	   functions.  It may be allocated even for temporaries or variables
	   that live across a call.  Functions compiled this way save and
	   restore the register reg if they use it.

	   It is an error to use this flag with the frame pointer or stack
	   pointer.  Use of this flag for other registers that have fixed
	   pervasive roles in the machine's execution model produces
	   disastrous results.

	   A different sort of disaster results from the use of this flag for
	   a register in which function values may be returned.

	   This flag does not have a negative form, because it specifies a
	   three-way choice.

       -fpack-struct[=n]
	   Without a value specified, pack all structure members together
	   without holes.  When a value is specified (which must be a small
	   power of two), pack structure members according to this value,
	   representing the maximum alignment (that is, objects with default
	   alignment requirements larger than this are output potentially
	   unaligned at the next fitting location.

	   Warning: the -fpack-struct switch causes GCC to generate code that
	   is not binary compatible with code generated without that switch.
	   Additionally, it makes the code suboptimal.	Use it to conform to a
	   non-default application binary interface.

       -fleading-underscore
	   This option and its counterpart, -fno-leading-underscore, forcibly
	   change the way C symbols are represented in the object file.	 One
	   use is to help link with legacy assembly code.

	   Warning: the -fleading-underscore switch causes GCC to generate
	   code that is not binary compatible with code generated without that
	   switch.  Use it to conform to a non-default application binary
	   interface.  Not all targets provide complete support for this
	   switch.

       -ftls-model=model
	   Alter the thread-local storage model to be used.  The model
	   argument should be one of global-dynamic, local-dynamic, initial-
	   exec or local-exec.	Note that the choice is subject to
	   optimization: the compiler may use a more efficient model for
	   symbols not visible outside of the translation unit, or if -fpic is
	   not given on the command line.

	   The default without -fpic is initial-exec; with -fpic the default
	   is global-dynamic.

       -ftrampolines
	   For targets that normally need trampolines for nested functions,
	   always generate them instead of using descriptors.  Otherwise, for
	   targets that do not need them, like for example HP-PA or IA-64, do
	   nothing.

	   A trampoline is a small piece of code that is created at run time
	   on the stack when the address of a nested function is taken, and is
	   used to call the nested function indirectly.	 Therefore, it
	   requires the stack to be made executable in order for the program
	   to work properly.

	   -fno-trampolines is enabled by default on a language by language
	   basis to let the compiler avoid generating them, if it computes
	   that this is safe, and replace them with descriptors.  Descriptors
	   are made up of data only, but the generated code must be prepared
	   to deal with them.  As of this writing, -fno-trampolines is enabled
	   by default only for Ada.

	   Moreover, code compiled with -ftrampolines and code compiled with
	   -fno-trampolines are not binary compatible if nested functions are
	   present.  This option must therefore be used on a program-wide
	   basis and be manipulated with extreme care.

	   For languages other than Ada, the "-ftrampolines" and
	   "-fno-trampolines" options currently have no effect, and
	   trampolines are always generated on platforms that need them for
	   nested functions.

       -ftrampoline-impl=[stack|heap]
	   By default, trampolines are generated on stack.  However, certain
	   platforms (such as the Apple M1) do not permit an executable stack.
	   Compiling with -ftrampoline-impl=heap generate calls to
	   "__gcc_nested_func_ptr_created" and "__gcc_nested_func_ptr_deleted"
	   in order to allocate and deallocate trampoline space on the
	   executable heap.  These functions are implemented in libgcc, and
	   will only be provided on specific targets: x86_64 Darwin, x86_64
	   and aarch64 Linux.  PLEASE NOTE: Heap trampolines are not
	   guaranteed to be correctly deallocated if you "setjmp", instantiate
	   nested functions, and then "longjmp" back to a state prior to
	   having allocated those nested functions.

       -fvisibility=[default|internal|hidden|protected]
	   Set the default ELF image symbol visibility to the specified
	   option---all symbols are marked with this unless overridden within
	   the code.  Using this feature can very substantially improve
	   linking and load times of shared object libraries, produce more
	   optimized code, provide near-perfect API export and prevent symbol
	   clashes.  It is strongly recommended that you use this in any
	   shared objects you distribute.

	   Despite the nomenclature, default always means public; i.e.,
	   available to be linked against from outside the shared object.
	   protected and internal are pretty useless in real-world usage so
	   the only other commonly used option is hidden.  The default if
	   -fvisibility isn't specified is default, i.e., make every symbol
	   public.

	   A good explanation of the benefits offered by ensuring ELF symbols
	   have the correct visibility is given by "How To Write Shared
	   Libraries" by Ulrich Drepper (which can be found at
	   <https://www.akkadia.org/drepper/>)---however a superior solution
	   made possible by this option to marking things hidden when the
	   default is public is to make the default hidden and mark things
	   public.  This is the norm with DLLs on Windows and with
	   -fvisibility=hidden and "__attribute__ ((visibility("default")))"
	   instead of "__declspec(dllexport)" you get almost identical
	   semantics with identical syntax.  This is a great boon to those
	   working with cross-platform projects.

	   For those adding visibility support to existing code, you may find
	   "#pragma GCC visibility" of use.  This works by you enclosing the
	   declarations you wish to set visibility for with (for example)
	   "#pragma GCC visibility push(hidden)" and "#pragma GCC visibility
	   pop".  Bear in mind that symbol visibility should be viewed as part
	   of the API interface contract and thus all new code should always
	   specify visibility when it is not the default; i.e., declarations
	   only for use within the local DSO should always be marked
	   explicitly as hidden as so to avoid PLT indirection
	   overheads---making this abundantly clear also aids readability and
	   self-documentation of the code.  Note that due to ISO C++
	   specification requirements, "operator new" and "operator delete"
	   must always be of default visibility.

	   Be aware that headers from outside your project, in particular
	   system headers and headers from any other library you use, may not
	   be expecting to be compiled with visibility other than the default.
	   You may need to explicitly say "#pragma GCC visibility
	   push(default)" before including any such headers.

	   "extern" declarations are not affected by -fvisibility, so a lot of
	   code can be recompiled with -fvisibility=hidden with no
	   modifications.  However, this means that calls to "extern"
	   functions with no explicit visibility use the PLT, so it is more
	   effective to use "__attribute ((visibility))" and/or "#pragma GCC
	   visibility" to tell the compiler which "extern" declarations should
	   be treated as hidden.

	   Note that -fvisibility does affect C++ vague linkage entities. This
	   means that, for instance, an exception class that is be thrown
	   between DSOs must be explicitly marked with default visibility so
	   that the type_info nodes are unified between the DSOs.

	   An overview of these techniques, their benefits and how to use them
	   is at <https://gcc.gnu.org/wiki/Visibility>.

       -fstrict-volatile-bitfields
	   This option should be used if accesses to volatile bit-fields (or
	   other structure fields, although the compiler usually honors those
	   types anyway) should use a single access of the width of the
	   field's type, aligned to a natural alignment if possible.  For
	   example, targets with memory-mapped peripheral registers might
	   require all such accesses to be 16 bits wide; with this flag you
	   can declare all peripheral bit-fields as "unsigned short" (assuming
	   short is 16 bits on these targets) to force GCC to use 16-bit
	   accesses instead of, perhaps, a more efficient 32-bit access.

	   If this option is disabled, the compiler uses the most efficient
	   instruction.	 In the previous example, that might be a 32-bit load
	   instruction, even though that accesses bytes that do not contain
	   any portion of the bit-field, or memory-mapped registers unrelated
	   to the one being updated.

	   In some cases, such as when the "packed" attribute is applied to a
	   structure field, it may not be possible to access the field with a
	   single read or write that is correctly aligned for the target
	   machine.  In this case GCC falls back to generating multiple
	   accesses rather than code that will fault or truncate the result at
	   run time.

	   Note:  Due to restrictions of the C/C++11 memory model, write
	   accesses are not allowed to touch non bit-field members.  It is
	   therefore recommended to define all bits of the field's type as
	   bit-field members.

	   The default value of this option is determined by the application
	   binary interface for the target processor.

       -fsync-libcalls
	   This option controls whether any out-of-line instance of the
	   "__sync" family of functions may be used to implement the C++11
	   "__atomic" family of functions.

	   The default value of this option is enabled, thus the only useful
	   form of the option is -fno-sync-libcalls.  This option is used in
	   the implementation of the libatomic runtime library.

   GCC Developer Options
       This section describes command-line options that are primarily of
       interest to GCC developers, including options to support compiler
       testing and investigation of compiler bugs and compile-time performance
       problems.  This includes options that produce debug dumps at various
       points in the compilation; that print statistics such as memory use and
       execution time; and that print information about GCC's configuration,
       such as where it searches for libraries.	 You should rarely need to use
       any of these options for ordinary compilation and linking tasks.

       Many developer options that cause GCC to dump output to a file take an
       optional =filename suffix. You can specify stdout or - to dump to
       standard output, and stderr for standard error.

       If =filename is omitted, a default dump file name is constructed by
       concatenating the base dump file name, a pass number, phase letter, and
       pass name.  The base dump file name is the name of output file produced
       by the compiler if explicitly specified and not an executable;
       otherwise it is the source file name.  The pass number is determined by
       the order passes are registered with the compiler's pass manager.  This
       is generally the same as the order of execution, but passes registered
       by plugins, target-specific passes, or passes that are otherwise
       registered late are numbered higher than the pass named final, even if
       they are executed earlier.  The phase letter is one of i (inter-
       procedural analysis), l (language-specific), r (RTL), or t (tree).  The
       files are created in the directory of the output file.

       -fcallgraph-info
       -fcallgraph-info=MARKERS
	   Makes the compiler output callgraph information for the program, on
	   a per-object-file basis.  The information is generated in the
	   common VCG format.  It can be decorated with additional, per-node
	   and/or per-edge information, if a list of comma-separated markers
	   is additionally specified.  When the "su" marker is specified, the
	   callgraph is decorated with stack usage information; it is
	   equivalent to -fstack-usage.	 When the "da" marker is specified,
	   the callgraph is decorated with information about dynamically
	   allocated objects.

	   When compiling with -flto, no callgraph information is output along
	   with the object file.  At LTO link time, -fcallgraph-info may
	   generate multiple callgraph information files next to intermediate
	   LTO output files.

       -dletters
       -fdump-rtl-pass
       -fdump-rtl-pass=filename
	   Says to make debugging dumps during compilation at times specified
	   by letters.	This is used for debugging the RTL-based passes of the
	   compiler.

	   Some -dletters switches have different meaning when -E is used for
	   preprocessing.

	   Debug dumps can be enabled with a -fdump-rtl switch or some -d
	   option letters.  Here are the possible letters for use in pass and
	   letters, and their meanings:

	   -fdump-rtl-alignments
	       Dump after branch alignments have been computed.

	   -fdump-rtl-asmcons
	       Dump after fixing rtl statements that have unsatisfied in/out
	       constraints.

	   -fdump-rtl-auto_inc_dec
	       Dump after auto-inc-dec discovery.  This pass is only run on
	       architectures that have auto inc or auto dec instructions.

	   -fdump-rtl-barriers
	       Dump after cleaning up the barrier instructions.

	   -fdump-rtl-bbpart
	       Dump after partitioning hot and cold basic blocks.

	   -fdump-rtl-bbro
	       Dump after block reordering.

	   -fdump-rtl-btl1
	   -fdump-rtl-btl2
	       -fdump-rtl-btl1 and -fdump-rtl-btl2 enable dumping after the
	       two branch target load optimization passes.

	   -fdump-rtl-bypass
	       Dump after jump bypassing and control flow optimizations.

	   -fdump-rtl-combine
	       Dump after the RTL instruction combination pass.

	   -fdump-rtl-compgotos
	       Dump after duplicating the computed gotos.

	   -fdump-rtl-ce1
	   -fdump-rtl-ce2
	   -fdump-rtl-ce3
	       -fdump-rtl-ce1, -fdump-rtl-ce2, and -fdump-rtl-ce3 enable
	       dumping after the three if conversion passes.

	   -fdump-rtl-cprop_hardreg
	       Dump after hard register copy propagation.

	   -fdump-rtl-csa
	       Dump after combining stack adjustments.

	   -fdump-rtl-cse1
	   -fdump-rtl-cse2
	       -fdump-rtl-cse1 and -fdump-rtl-cse2 enable dumping after the
	       two common subexpression elimination passes.

	   -fdump-rtl-dce
	       Dump after the standalone dead code elimination passes.

	   -fdump-rtl-dbr
	       Dump after delayed branch scheduling.

	   -fdump-rtl-dce1
	   -fdump-rtl-dce2
	       -fdump-rtl-dce1 and -fdump-rtl-dce2 enable dumping after the
	       two dead store elimination passes.

	   -fdump-rtl-eh
	       Dump after finalization of EH handling code.

	   -fdump-rtl-eh_ranges
	       Dump after conversion of EH handling range regions.

	   -fdump-rtl-expand
	       Dump after RTL generation.

	   -fdump-rtl-fwprop1
	   -fdump-rtl-fwprop2
	       -fdump-rtl-fwprop1 and -fdump-rtl-fwprop2 enable dumping after
	       the two forward propagation passes.

	   -fdump-rtl-gcse1
	   -fdump-rtl-gcse2
	       -fdump-rtl-gcse1 and -fdump-rtl-gcse2 enable dumping after
	       global common subexpression elimination.

	   -fdump-rtl-init-regs
	       Dump after the initialization of the registers.

	   -fdump-rtl-initvals
	       Dump after the computation of the initial value sets.

	   -fdump-rtl-into_cfglayout
	       Dump after converting to cfglayout mode.

	   -fdump-rtl-ira
	       Dump after iterated register allocation.

	   -fdump-rtl-jump
	       Dump after the second jump optimization.

	   -fdump-rtl-loop2
	       -fdump-rtl-loop2 enables dumping after the rtl loop
	       optimization passes.

	   -fdump-rtl-mach
	       Dump after performing the machine dependent reorganization
	       pass, if that pass exists.

	   -fdump-rtl-mode_sw
	       Dump after removing redundant mode switches.

	   -fdump-rtl-rnreg
	       Dump after register renumbering.

	   -fdump-rtl-outof_cfglayout
	       Dump after converting from cfglayout mode.

	   -fdump-rtl-peephole2
	       Dump after the peephole pass.

	   -fdump-rtl-postreload
	       Dump after post-reload optimizations.

	   -fdump-rtl-pro_and_epilogue
	       Dump after generating the function prologues and epilogues.

	   -fdump-rtl-sched1
	   -fdump-rtl-sched2
	       -fdump-rtl-sched1 and -fdump-rtl-sched2 enable dumping after
	       the basic block scheduling passes.

	   -fdump-rtl-ree
	       Dump after sign/zero extension elimination.

	   -fdump-rtl-seqabstr
	       Dump after common sequence discovery.

	   -fdump-rtl-shorten
	       Dump after shortening branches.

	   -fdump-rtl-sibling
	       Dump after sibling call optimizations.

	   -fdump-rtl-split1
	   -fdump-rtl-split2
	   -fdump-rtl-split3
	   -fdump-rtl-split4
	   -fdump-rtl-split5
	       These options enable dumping after five rounds of instruction
	       splitting.

	   -fdump-rtl-sms
	       Dump after modulo scheduling.  This pass is only run on some
	       architectures.

	   -fdump-rtl-stack
	       Dump after conversion from GCC's "flat register file" registers
	       to the x87's stack-like registers.  This pass is only run on
	       x86 variants.

	   -fdump-rtl-subreg1
	   -fdump-rtl-subreg2
	       -fdump-rtl-subreg1 and -fdump-rtl-subreg2 enable dumping after
	       the two subreg expansion passes.

	   -fdump-rtl-unshare
	       Dump after all rtl has been unshared.

	   -fdump-rtl-vartrack
	       Dump after variable tracking.

	   -fdump-rtl-vregs
	       Dump after converting virtual registers to hard registers.

	   -fdump-rtl-web
	       Dump after live range splitting.

	   -fdump-rtl-regclass
	   -fdump-rtl-subregs_of_mode_init
	   -fdump-rtl-subregs_of_mode_finish
	   -fdump-rtl-dfinit
	   -fdump-rtl-dfinish
	       These dumps are defined but always produce empty files.

	   -da
	   -fdump-rtl-all
	       Produce all the dumps listed above.

	   -dA Annotate the assembler output with miscellaneous debugging
	       information.

	   -dD Dump all macro definitions, at the end of preprocessing, in
	       addition to normal output.

	   -dH Produce a core dump whenever an error occurs.

	   -dp Annotate the assembler output with a comment indicating which
	       pattern and alternative is used.	 The length and cost of each
	       instruction are also printed.

	   -dP Dump the RTL in the assembler output as a comment before each
	       instruction.  Also turns on -dp annotation.

	   -dx Just generate RTL for a function instead of compiling it.
	       Usually used with -fdump-rtl-expand.

       -fdump-debug
	   Dump debugging information generated during the debug generation
	   phase.

       -fdump-earlydebug
	   Dump debugging information generated during the early debug
	   generation phase.

       -fdump-noaddr
	   When doing debugging dumps, suppress address output.	 This makes it
	   more feasible to use diff on debugging dumps for compiler
	   invocations with different compiler binaries and/or different text
	   / bss / data / heap / stack / dso start locations.

       -freport-bug
	   Collect and dump debug information into a temporary file if an
	   internal compiler error (ICE) occurs.

       -fdump-unnumbered
	   When doing debugging dumps, suppress instruction numbers and
	   address output.  This makes it more feasible to use diff on
	   debugging dumps for compiler invocations with different options, in
	   particular with and without -g.

       -fdump-unnumbered-links
	   When doing debugging dumps (see -d option above), suppress
	   instruction numbers for the links to the previous and next
	   instructions in a sequence.

       -fdump-ipa-switch
       -fdump-ipa-switch-options
	   Control the dumping at various stages of inter-procedural analysis
	   language tree to a file.  The file name is generated by appending a
	   switch specific suffix to the source file name, and the file is
	   created in the same directory as the output file.  The following
	   dumps are possible:

	   all Enables all inter-procedural analysis dumps.

	   cgraph
	       Dumps information about call-graph optimization, unused
	       function removal, and inlining decisions.

	   inline
	       Dump after function inlining.

	   strubm
	       Dump after selecting "strub" modes, and recording the
	       selections as function attributes.

	   strub
	       Dump "strub" transformations: interface changes, function
	       wrapping, and insertion of builtin calls for stack scrubbing
	       and watermarking.

	   Additionally, the options -optimized, -missed, -note, and -all can
	   be provided, with the same meaning as for -fopt-info, defaulting to
	   -optimized.

	   For example, -fdump-ipa-inline-optimized-missed will emit
	   information on callsites that were inlined, along with callsites
	   that were not inlined.

	   By default, the dump will contain messages about successful
	   optimizations (equivalent to -optimized) together with low-level
	   details about the analysis.

       -fdump-lang
	   Dump language-specific information.	The file name is made by
	   appending .lang to the source file name.

       -fdump-lang-all
       -fdump-lang-switch
       -fdump-lang-switch-options
       -fdump-lang-switch-options=filename
	   Control the dumping of language-specific information.  The options
	   and filename portions behave as described in the -fdump-tree
	   option.  The following switch values are accepted:

	   all Enable all language-specific dumps.

	   class
	       Dump class hierarchy information.  Virtual table information is
	       emitted unless 'slim' is specified.  This option is applicable
	       to C++ only.

	   module
	       Dump module information.	 Options lineno (locations), graph
	       (reachability), blocks (clusters), uid (serialization), alias
	       (mergeable), asmname (Elrond), eh (mapper) & vops (macros) may
	       provide additional information.	This option is applicable to
	       C++ only.

	   raw Dump the raw internal tree data.	 This option is applicable to
	       C++ only.

       -fdump-passes
	   Print on stderr the list of optimization passes that are turned on
	   and off by the current command-line options.

       -fdump-statistics-option
	   Enable and control dumping of pass statistics in a separate file.
	   The file name is generated by appending a suffix ending in
	   .statistics to the source file name, and the file is created in the
	   same directory as the output file.  If the -option form is used,
	   -stats causes counters to be summed over the whole compilation unit
	   while -details dumps every event as the passes generate them.  The
	   default with no option is to sum counters for each function
	   compiled.

       -fdump-tree-all
       -fdump-tree-switch
       -fdump-tree-switch-options
       -fdump-tree-switch-options=filename
	   Control the dumping at various stages of processing the
	   intermediate language tree to a file.  If the -options form is
	   used, options is a list of - separated options which control the
	   details of the dump.	 Not all options are applicable to all dumps;
	   those that are not meaningful are ignored.  The following options
	   are available

	   address
	       Print the address of each node.	Usually this is not meaningful
	       as it changes according to the environment and source file.
	       Its primary use is for tying up a dump file with a debug
	       environment.

	   asmname
	       If "DECL_ASSEMBLER_NAME" has been set for a given decl, use
	       that in the dump instead of "DECL_NAME".	 Its primary use is
	       ease of use working backward from mangled names in the assembly
	       file.

	   slim
	       When dumping front-end intermediate representations, inhibit
	       dumping of members of a scope or body of a function merely
	       because that scope has been reached.  Only dump such items when
	       they are directly reachable by some other path.

	       When dumping pretty-printed trees, this option inhibits dumping
	       the bodies of control structures.

	       When dumping RTL, print the RTL in slim (condensed) form
	       instead of the default LISP-like representation.

	   raw Print a raw representation of the tree.	By default, trees are
	       pretty-printed into a C-like representation.

	   details
	       Enable more detailed dumps (not honored by every dump option).
	       Also include information from the optimization passes.

	   stats
	       Enable dumping various statistics about the pass (not honored
	       by every dump option).

	   blocks
	       Enable showing basic block boundaries (disabled in raw dumps).

	   graph
	       For each of the other indicated dump files (-fdump-rtl-pass),
	       dump a representation of the control flow graph suitable for
	       viewing with GraphViz to file.passid.pass.dot.  Each function
	       in the file is pretty-printed as a subgraph, so that GraphViz
	       can render them all in a single plot.

	       This option currently only works for RTL dumps, and the RTL is
	       always dumped in slim form.

	   vops
	       Enable showing virtual operands for every statement.

	   lineno
	       Enable showing line numbers for statements.

	   uid Enable showing the unique ID ("DECL_UID") for each variable.

	   verbose
	       Enable showing the tree dump for each statement.

	   eh  Enable showing the EH region number holding each statement.

	   scev
	       Enable showing scalar evolution analysis details.

	   optimized
	       Enable showing optimization information (only available in
	       certain passes).

	   missed
	       Enable showing missed optimization information (only available
	       in certain passes).

	   note
	       Enable other detailed optimization information (only available
	       in certain passes).

	   all Turn on all options, except raw, slim, verbose and lineno.

	   optall
	       Turn on all optimization options, i.e., optimized, missed, and
	       note.

	   To determine what tree dumps are available or find the dump for a
	   pass of interest follow the steps below.

	   1.  Invoke GCC with -fdump-passes and in the stderr output look for
	       a code that corresponds to the pass you are interested in.  For
	       example, the codes "tree-evrp", "tree-vrp1", and "tree-vrp2"
	       correspond to the three Value Range Propagation passes.	The
	       number at the end distinguishes distinct invocations of the
	       same pass.

	   2.  To enable the creation of the dump file, append the pass code
	       to the -fdump- option prefix and invoke GCC with it.  For
	       example, to enable the dump from the Early Value Range
	       Propagation pass, invoke GCC with the -fdump-tree-evrp option.
	       Optionally, you may specify the name of the dump file.  If you
	       don't specify one, GCC creates as described below.

	   3.  Find the pass dump in a file whose name is composed of three
	       components separated by a period: the name of the source file
	       GCC was invoked to compile, a numeric suffix indicating the
	       pass number followed by the letter t for tree passes (and the
	       letter r for RTL passes), and finally the pass code.  For
	       example, the Early VRP pass dump might be in a file named
	       myfile.c.038t.evrp in the current working directory.  Note that
	       the numeric codes are not stable and may change from one
	       version of GCC to another.

       -fopt-info
       -fopt-info-options
       -fopt-info-options=filename
	   Controls optimization dumps from various optimization passes. If
	   the -options form is used, options is a list of - separated option
	   keywords to select the dump details and optimizations.

	   The options can be divided into three groups:

	   1.  options describing what kinds of messages should be emitted,

	   2.  options describing the verbosity of the dump, and

	   3.  options describing which optimizations should be included.

	   The options from each group can be freely mixed as they are non-
	   overlapping. However, in case of any conflicts, the later options
	   override the earlier options on the command line.

	   The following options control which kinds of messages should be
	   emitted:

	   optimized
	       Print information when an optimization is successfully applied.
	       It is up to a pass to decide which information is relevant. For
	       example, the vectorizer passes print the source location of
	       loops which are successfully vectorized.

	   missed
	       Print information about missed optimizations. Individual passes
	       control which information to include in the output.

	   note
	       Print verbose information about optimizations, such as certain
	       transformations, more detailed messages about decisions etc.

	   all Print detailed optimization information. This includes
	       optimized, missed, and note.

	   The following option controls the dump verbosity:

	   internals
	       By default, only "high-level" messages are emitted. This option
	       enables additional, more detailed, messages, which are likely
	       to only be of interest to GCC developers.

	   One or more of the following option keywords can be used to
	   describe a group of optimizations:

	   ipa Enable dumps from all interprocedural optimizations.

	   loop
	       Enable dumps from all loop optimizations.

	   inline
	       Enable dumps from all inlining optimizations.

	   omp Enable dumps from all OMP (Offloading and Multi Processing)
	       optimizations.

	   vec Enable dumps from all vectorization optimizations.

	   optall
	       Enable dumps from all optimizations. This is a superset of the
	       optimization groups listed above.

	   If options is omitted, it defaults to optimized-optall, which means
	   to dump messages about successful optimizations from all the
	   passes, omitting messages that are treated as "internals".

	   If the filename is provided, then the dumps from all the applicable
	   optimizations are concatenated into the filename.  Otherwise the
	   dump is output onto stderr. Though multiple -fopt-info options are
	   accepted, only one of them can include a filename. If other
	   filenames are provided then all but the first such option are
	   ignored.

	   Note that the output filename is overwritten in case of multiple
	   translation units. If a combined output from multiple translation
	   units is desired, stderr should be used instead.

	   In the following example, the optimization info is output to
	   stderr:

		   gcc -O3 -fopt-info

	   This example:

		   gcc -O3 -fopt-info-missed=missed.all

	   outputs missed optimization report from all the passes into
	   missed.all, and this one:

		   gcc -O2 -ftree-vectorize -fopt-info-vec-missed

	   prints information about missed optimization opportunities from
	   vectorization passes on stderr.  Note that -fopt-info-vec-missed is
	   equivalent to -fopt-info-missed-vec.	 The order of the optimization
	   group names and message types listed after -fopt-info does not
	   matter.

	   As another example,

		   gcc -O3 -fopt-info-inline-optimized-missed=inline.txt

	   outputs information about missed optimizations as well as optimized
	   locations from all the inlining passes into inline.txt.

	   Finally, consider:

		   gcc -fopt-info-vec-missed=vec.miss -fopt-info-loop-optimized=loop.opt

	   Here the two output filenames vec.miss and loop.opt are in conflict
	   since only one output file is allowed. In this case, only the first
	   option takes effect and the subsequent options are ignored. Thus
	   only vec.miss is produced which contains dumps from the vectorizer
	   about missed opportunities.

       -fsave-optimization-record
	   Write a SRCFILE.opt-record.json.gz file detailing what
	   optimizations were performed, for those optimizations that support
	   -fopt-info.

	   This option is experimental and the format of the data within the
	   compressed JSON file is subject to change.

	   It is roughly equivalent to a machine-readable version of
	   -fopt-info-all, as a collection of messages with source file, line
	   number and column number, with the following additional data for
	   each message:

	   *   the execution count of the code being optimized, along with
	       metadata about whether this was from actual profile data, or
	       just an estimate, allowing consumers to prioritize messages by
	       code hotness,

	   *   the function name of the code being optimized, where
	       applicable,

	   *   the "inlining chain" for the code being optimized, so that when
	       a function is inlined into several different places (which
	       might themselves be inlined), the reader can distinguish
	       between the copies,

	   *   objects identifying those parts of the message that refer to
	       expressions, statements or symbol-table nodes, which of these
	       categories they are, and, when available, their source code
	       location,

	   *   the GCC pass that emitted the message, and

	   *   the location in GCC's own code from which the message was
	       emitted

	   Additionally, some messages are logically nested within other
	   messages, reflecting implementation details of the optimization
	   passes.

       -fsched-verbose=n
	   On targets that use instruction scheduling, this option controls
	   the amount of debugging output the scheduler prints to the dump
	   files.

	   For n greater than zero, -fsched-verbose outputs the same
	   information as -fdump-rtl-sched1 and -fdump-rtl-sched2.  For n
	   greater than one, it also output basic block probabilities,
	   detailed ready list information and unit/insn info.	For n greater
	   than two, it includes RTL at abort point, control-flow and regions
	   info.  And for n over four, -fsched-verbose also includes
	   dependence info.

       -fenable-kind-pass
       -fdisable-kind-pass=range-list
	   This is a set of options that are used to explicitly disable/enable
	   optimization passes.	 These options are intended for use for
	   debugging GCC.  Compiler users should use regular options for
	   enabling/disabling passes instead.

	   -fdisable-ipa-pass
	       Disable IPA pass pass. pass is the pass name.  If the same pass
	       is statically invoked in the compiler multiple times, the pass
	       name should be appended with a sequential number starting from
	       1.

	   -fdisable-rtl-pass
	   -fdisable-rtl-pass=range-list
	       Disable RTL pass pass.  pass is the pass name.  If the same
	       pass is statically invoked in the compiler multiple times, the
	       pass name should be appended with a sequential number starting
	       from 1.	range-list is a comma-separated list of function
	       ranges or assembler names.  Each range is a number pair
	       separated by a colon.  The range is inclusive in both ends.  If
	       the range is trivial, the number pair can be simplified as a
	       single number.  If the function's call graph node's uid falls
	       within one of the specified ranges, the pass is disabled for
	       that function.  The uid is shown in the function header of a
	       dump file, and the pass names can be dumped by using option
	       -fdump-passes.

	   -fdisable-tree-pass
	   -fdisable-tree-pass=range-list
	       Disable tree pass pass.	See -fdisable-rtl for the description
	       of option arguments.

	   -fenable-ipa-pass
	       Enable IPA pass pass.  pass is the pass name.  If the same pass
	       is statically invoked in the compiler multiple times, the pass
	       name should be appended with a sequential number starting from
	       1.

	   -fenable-rtl-pass
	   -fenable-rtl-pass=range-list
	       Enable RTL pass pass.  See -fdisable-rtl for option argument
	       description and examples.

	   -fenable-tree-pass
	   -fenable-tree-pass=range-list
	       Enable tree pass pass.  See -fdisable-rtl for the description
	       of option arguments.

	   Here are some examples showing uses of these options.

		   # disable ccp1 for all functions
		      -fdisable-tree-ccp1
		   # disable complete unroll for function whose cgraph node uid is 1
		      -fenable-tree-cunroll=1
		   # disable gcse2 for functions at the following ranges [1,1],
		   # [300,400], and [400,1000]
		   # disable gcse2 for functions foo and foo2
		      -fdisable-rtl-gcse2=foo,foo2
		   # disable early inlining
		      -fdisable-tree-einline
		   # disable ipa inlining
		      -fdisable-ipa-inline
		   # enable tree full unroll
		      -fenable-tree-unroll

       -fchecking
       -fchecking=n
	   Enable internal consistency checking.  The default depends on the
	   compiler configuration.  -fchecking=2 enables further internal
	   consistency checking that might affect code generation.

       -frandom-seed=string
	   This option provides a seed that GCC uses in place of random
	   numbers in generating certain symbol names that have to be
	   different in every compiled file.  It is also used to place unique
	   stamps in coverage data files and the object files that produce
	   them.  You can use the -frandom-seed option to produce reproducibly
	   identical object files.

	   The string can either be a number (decimal, octal or hex) or an
	   arbitrary string (in which case it's converted to a number by
	   computing CRC32).

	   The string should be different for every file you compile.

       -save-temps
	   Store the usual "temporary" intermediate files permanently; name
	   them as auxiliary output files, as specified described under
	   -dumpbase and -dumpdir.

	   When used in combination with the -x command-line option,
	   -save-temps is sensible enough to avoid overwriting an input source
	   file with the same extension as an intermediate file.  The
	   corresponding intermediate file may be obtained by renaming the
	   source file before using -save-temps.

       -save-temps=cwd
	   Equivalent to -save-temps -dumpdir ./.

       -save-temps=obj
	   Equivalent to -save-temps -dumpdir outdir/, where outdir/ is the
	   directory of the output file specified after the -o option,
	   including any directory separators.	If the -o option is not used,
	   the -save-temps=obj switch behaves like -save-temps=cwd.

       -time[=file]
	   Report the CPU time taken by each subprocess in the compilation
	   sequence.  For C source files, this is the compiler proper and
	   assembler (plus the linker if linking is done).

	   Without the specification of an output file, the output looks like
	   this:

		   # cc1 0.12 0.01
		   # as 0.00 0.01

	   The first number on each line is the "user time", that is time
	   spent executing the program itself.	The second number is "system
	   time", time spent executing operating system routines on behalf of
	   the program.	 Both numbers are in seconds.

	   With the specification of an output file, the output is appended to
	   the named file, and it looks like this:

		   0.12 0.01 cc1 <options>
		   0.00 0.01 as <options>

	   The "user time" and the "system time" are moved before the program
	   name, and the options passed to the program are displayed, so that
	   one can later tell what file was being compiled, and with which
	   options.

       -fdump-final-insns[=file]
	   Dump the final internal representation (RTL) to file.  If the
	   optional argument is omitted (or if file is "."), the name of the
	   dump file is determined by appending ".gkd" to the dump base name,
	   see -dumpbase.

       -fcompare-debug[=opts]
	   If no error occurs during compilation, run the compiler a second
	   time, adding opts and -fcompare-debug-second to the arguments
	   passed to the second compilation.  Dump the final internal
	   representation in both compilations, and print an error if they
	   differ.

	   If the equal sign is omitted, the default -gtoggle is used.

	   The environment variable GCC_COMPARE_DEBUG, if defined, non-empty
	   and nonzero, implicitly enables -fcompare-debug.  If
	   GCC_COMPARE_DEBUG is defined to a string starting with a dash, then
	   it is used for opts, otherwise the default -gtoggle is used.

	   -fcompare-debug=, with the equal sign but without opts, is
	   equivalent to -fno-compare-debug, which disables the dumping of the
	   final representation and the second compilation, preventing even
	   GCC_COMPARE_DEBUG from taking effect.

	   To verify full coverage during -fcompare-debug testing, set
	   GCC_COMPARE_DEBUG to say -fcompare-debug-not-overridden, which GCC
	   rejects as an invalid option in any actual compilation (rather than
	   preprocessing, assembly or linking).	 To get just a warning,
	   setting GCC_COMPARE_DEBUG to -w%n-fcompare-debug not overridden
	   will do.

       -fcompare-debug-second
	   This option is implicitly passed to the compiler for the second
	   compilation requested by -fcompare-debug, along with options to
	   silence warnings, and omitting other options that would cause the
	   compiler to produce output to files or to standard output as a side
	   effect.  Dump files and preserved temporary files are renamed so as
	   to contain the ".gk" additional extension during the second
	   compilation, to avoid overwriting those generated by the first.

	   When this option is passed to the compiler driver, it causes the
	   first compilation to be skipped, which makes it useful for little
	   other than debugging the compiler proper.

       -gtoggle
	   Turn off generation of debug info, if leaving out this option
	   generates it, or turn it on at level 2 otherwise.  The position of
	   this argument in the command line does not matter; it takes effect
	   after all other options are processed, and it does so only once, no
	   matter how many times it is given.  This is mainly intended to be
	   used with -fcompare-debug.

       -fvar-tracking-assignments-toggle
	   Toggle -fvar-tracking-assignments, in the same way that -gtoggle
	   toggles -g.

       -Q  Makes the compiler print out each function name as it is compiled,
	   and print some statistics about each pass when it finishes.

       -ftime-report
	   Makes the compiler print some statistics to stderr about the time
	   consumed by each pass when it finishes.

	   If SARIF output of diagnostics was requested via
	   -fdiagnostics-format=sarif-file or
	   -fdiagnostics-format=sarif-stderr then the -ftime-report
	   information is instead emitted in JSON form as part of SARIF
	   output.  The precise format of this JSON data is subject to change,
	   and the values may not exactly match those emitted to stderr due to
	   being written out at a slightly different place within the
	   compiler.

       -ftime-report-details
	   Record the time consumed by infrastructure parts separately for
	   each pass.

       -fira-verbose=n
	   Control the verbosity of the dump file for the integrated register
	   allocator.  The default value is 5.	If the value n is greater or
	   equal to 10, the dump output is sent to stderr using the same
	   format as n minus 10.

       -flto-report
	   Prints a report with internal details on the workings of the link-
	   time optimizer.  The contents of this report vary from version to
	   version.  It is meant to be useful to GCC developers when
	   processing object files in LTO mode (via -flto).

	   Disabled by default.

       -flto-report-wpa
	   Like -flto-report, but only print for the WPA phase of link-time
	   optimization.

       -fmem-report
	   Makes the compiler print some statistics about permanent memory
	   allocation when it finishes.

       -fmem-report-wpa
	   Makes the compiler print some statistics about permanent memory
	   allocation for the WPA phase only.

       -fpre-ipa-mem-report
       -fpost-ipa-mem-report
	   Makes the compiler print some statistics about permanent memory
	   allocation before or after interprocedural optimization.

       -fmultiflags
	   This option enables multilib-aware "TFLAGS" to be used to build
	   target libraries with options different from those the compiler is
	   configured to use by default, through the use of specs set up by
	   compiler internals, by the target, or by builders at configure
	   time.

	   Like "TFLAGS", this allows the target libraries to be built for
	   portable baseline environments, while the compiler defaults to more
	   demanding ones.  That's useful because users can easily override
	   the defaults the compiler is configured to use to build their own
	   programs, if the defaults are not ideal for their target
	   environment, whereas rebuilding the runtime libraries is usually
	   not as easy or desirable.

	   Unlike "TFLAGS", the use of specs enables different flags to be
	   selected for different multilibs.  The way to accomplish that is to
	   build with make TFLAGS=-fmultiflags, after configuring
	   --with-specs=%{fmultiflags:...}.

	   This option is discarded by the driver once it's done processing
	   driver self spec.

	   It is also useful to check that "TFLAGS" are being used to build
	   all target libraries, by configuring a non-bootstrap compiler
	   --with-specs='%{!fmultiflags:%emissing TFLAGS}' and building the
	   compiler and target libraries.

       -fprofile-report
	   Makes the compiler print some statistics about consistency of the
	   (estimated) profile and effect of individual passes.

       -fstack-usage
	   Makes the compiler output stack usage information for the program,
	   on a per-function basis.  The filename for the dump is made by
	   appending .su to the auxname.  auxname is generated from the name
	   of the output file, if explicitly specified and it is not an
	   executable, otherwise it is the basename of the source file.	 An
	   entry is made up of three fields:

	   *   The name of the function.

	   *   A number of bytes.

	   *   One or more qualifiers: "static", "dynamic", "bounded".

	   The qualifier "static" means that the function manipulates the
	   stack statically: a fixed number of bytes are allocated for the
	   frame on function entry and released on function exit; no stack
	   adjustments are otherwise made in the function.  The second field
	   is this fixed number of bytes.

	   The qualifier "dynamic" means that the function manipulates the
	   stack dynamically: in addition to the static allocation described
	   above, stack adjustments are made in the body of the function, for
	   example to push/pop arguments around function calls.	 If the
	   qualifier "bounded" is also present, the amount of these
	   adjustments is bounded at compile time and the second field is an
	   upper bound of the total amount of stack used by the function.  If
	   it is not present, the amount of these adjustments is not bounded
	   at compile time and the second field only represents the bounded
	   part.

       -fstats
	   Emit statistics about front-end processing at the end of the
	   compilation.	 This option is supported only by the C++ front end,
	   and the information is generally only useful to the G++ development
	   team.

       -fdbg-cnt-list
	   Print the name and the counter upper bound for all debug counters.

       -fdbg-cnt=counter-value-list
	   Set the internal debug counter lower and upper bound.  counter-
	   value-list is a comma-separated list of
	   name:lower_bound1-upper_bound1 [:lower_bound2-upper_bound2...]
	   tuples which sets the name of the counter and list of closed
	   intervals.  The lower_bound is optional and is zero initialized if
	   not set.  For example, with -fdbg-cnt=dce:2-4:10-11,tail_call:10,
	   dbg_cnt(dce) returns true only for second, third, fourth, tenth and
	   eleventh invocation.	 For dbg_cnt(tail_call) true is returned for
	   first 10 invocations.

       -print-file-name=library
	   Print the full absolute name of the library file library that would
	   be used when linking---and don't do anything else.  With this
	   option, GCC does not compile or link anything; it just prints the
	   file name.

       -print-multi-directory
	   Print the directory name corresponding to the multilib selected by
	   any other switches present in the command line.  This directory is
	   supposed to exist in GCC_EXEC_PREFIX.

       -print-multi-lib
	   Print the mapping from multilib directory names to compiler
	   switches that enable them.  The directory name is separated from
	   the switches by ;, and each switch starts with an @ instead of the
	   -, without spaces between multiple switches.	 This is supposed to
	   ease shell processing.

       -print-multi-os-directory
	   Print the path to OS libraries for the selected multilib, relative
	   to some lib subdirectory.  If OS libraries are present in the lib
	   subdirectory and no multilibs are used, this is usually just ., if
	   OS libraries are present in libsuffix sibling directories this
	   prints e.g. ../lib64, ../lib or ../lib32, or if OS libraries are
	   present in lib/subdir subdirectories it prints e.g. amd64, sparcv9
	   or ev6.

       -print-multiarch
	   Print the path to OS libraries for the selected multiarch, relative
	   to some lib subdirectory.

       -print-prog-name=program
	   Like -print-file-name, but searches for a program such as cpp.

       -print-libgcc-file-name
	   Same as -print-file-name=libgcc.a.

	   This is useful when you use -nostdlib or -nodefaultlibs but you do
	   want to link with libgcc.a.	You can do:

		   gcc -nostdlib <files>... `gcc -print-libgcc-file-name`

       -print-search-dirs
	   Print the name of the configured installation directory and a list
	   of program and library directories gcc searches---and don't do
	   anything else.

	   This is useful when gcc prints the error message installation
	   problem, cannot exec cpp0: No such file or directory.  To resolve
	   this you either need to put cpp0 and the other compiler components
	   where gcc expects to find them, or you can set the environment
	   variable GCC_EXEC_PREFIX to the directory where you installed them.
	   Don't forget the trailing /.

       -print-sysroot
	   Print the target sysroot directory that is used during compilation.
	   This is the target sysroot specified either at configure time or
	   using the --sysroot option, possibly with an extra suffix that
	   depends on compilation options.  If no target sysroot is specified,
	   the option prints nothing.

       -print-sysroot-headers-suffix
	   Print the suffix added to the target sysroot when searching for
	   headers, or give an error if the compiler is not configured with
	   such a suffix---and don't do anything else.

       -dumpmachine
	   Print the compiler's target machine (for example,
	   i686-pc-linux-gnu)---and don't do anything else.

       -dumpversion
	   Print the compiler version (for example, 3.0, 6.3.0 or 7)---and
	   don't do anything else.  This is the compiler version used in
	   filesystem paths and specs. Depending on how the compiler has been
	   configured it can be just a single number (major version), two
	   numbers separated by a dot (major and minor version) or three
	   numbers separated by dots (major, minor and patchlevel version).

       -dumpfullversion
	   Print the full compiler version---and don't do anything else. The
	   output is always three numbers separated by dots, major, minor and
	   patchlevel version.

       -dumpspecs
	   Print the compiler's built-in specs---and don't do anything else.
	   (This is used when GCC itself is being built.)

   Machine-Dependent Options
       Each target machine supported by GCC can have its own options---for
       example, to allow you to compile for a particular processor variant or
       ABI, or to control optimizations specific to that machine.  By
       convention, the names of machine-specific options start with -m.

       Some configurations of the compiler also support additional target-
       specific options, usually for compatibility with other compilers on the
       same platform.

       AArch64 Options

       These options are defined for AArch64 implementations:

       -mabi=name
	   Generate code for the specified data model.	Permissible values are
	   ilp32 for SysV-like data model where int, long int and pointers are
	   32 bits, and lp64 for SysV-like data model where int is 32 bits,
	   but long int and pointers are 64 bits.

	   The default depends on the specific target configuration.  Note
	   that the LP64 and ILP32 ABIs are not link-compatible; you must
	   compile your entire program with the same ABI, and link with a
	   compatible set of libraries.

       -mbig-endian
	   Generate big-endian code.  This is the default when GCC is
	   configured for an aarch64_be-*-* target.

       -mgeneral-regs-only
	   Generate code which uses only the general-purpose registers.	 This
	   will prevent the compiler from using floating-point and Advanced
	   SIMD registers but will not impose any restrictions on the
	   assembler.

       -mlittle-endian
	   Generate little-endian code.	 This is the default when GCC is
	   configured for an aarch64-*-* but not an aarch64_be-*-* target.

       -mcmodel=tiny
	   Generate code for the tiny code model.  The program and its
	   statically defined symbols must be within 1MB of each other.
	   Programs can be statically or dynamically linked.

       -mcmodel=small
	   Generate code for the small code model.  The program and its
	   statically defined symbols must be within 4GB of each other.
	   Programs can be statically or dynamically linked.  This is the
	   default code model.

       -mcmodel=large
	   Generate code for the large code model.  This makes no assumptions
	   about addresses and sizes of sections.  Programs can be statically
	   linked only.	 The -mcmodel=large option is incompatible with
	   -mabi=ilp32, -fpic and -fPIC.

       -mtp=name
	   Specify the system register to use as a thread pointer.  The valid
	   values are tpidr_el0, tpidrro_el0, tpidr_el1, tpidr_el2, tpidr_el3.
	   For backwards compatibility the aliases el0, el1, el2, el3 are also
	   accepted.  The default setting is tpidr_el0.	 It is recommended to
	   compile all code intended to interoperate with the same value of
	   this option to avoid accessing a different thread pointer from the
	   wrong exception level.

       -mstrict-align
       -mno-strict-align
	   Avoid or allow generating memory accesses that may not be aligned
	   on a natural object boundary as described in the architecture
	   specification.

       -momit-leaf-frame-pointer
       -mno-omit-leaf-frame-pointer
	   Omit or keep the frame pointer in leaf functions.  The former
	   behavior is the default.

       -mstack-protector-guard=guard
       -mstack-protector-guard-reg=reg
       -mstack-protector-guard-offset=offset
	   Generate stack protection code using canary at guard.  Supported
	   locations are global for a global canary or sysreg for a canary in
	   an appropriate system register.

	   With the latter choice the options -mstack-protector-guard-reg=reg
	   and -mstack-protector-guard-offset=offset furthermore specify which
	   system register to use as base register for reading the canary, and
	   from what offset from that base register. There is no default
	   register or offset as this is entirely for use within the Linux
	   kernel.

       -mtls-dialect=desc
	   Use TLS descriptors as the thread-local storage mechanism for
	   dynamic accesses of TLS variables.  This is the default.

       -mtls-dialect=traditional
	   Use traditional TLS as the thread-local storage mechanism for
	   dynamic accesses of TLS variables.

       -mtls-size=size
	   Specify bit size of immediate TLS offsets.  Valid values are 12,
	   24, 32, 48.	This option requires binutils 2.26 or newer.

       -mfix-cortex-a53-835769
       -mno-fix-cortex-a53-835769
	   Enable or disable the workaround for the ARM Cortex-A53 erratum
	   number 835769.  This involves inserting a NOP instruction between
	   memory instructions and 64-bit integer multiply-accumulate
	   instructions.

       -mfix-cortex-a53-843419
       -mno-fix-cortex-a53-843419
	   Enable or disable the workaround for the ARM Cortex-A53 erratum
	   number 843419.  This erratum workaround is made at link time and
	   this will only pass the corresponding flag to the linker.

       -mlow-precision-recip-sqrt
       -mno-low-precision-recip-sqrt
	   Enable or disable the reciprocal square root approximation.	This
	   option only has an effect if -ffast-math or
	   -funsafe-math-optimizations is used as well.	 Enabling this reduces
	   precision of reciprocal square root results to about 16 bits for
	   single precision and to 32 bits for double precision.

       -mlow-precision-sqrt
       -mno-low-precision-sqrt
	   Enable or disable the square root approximation.  This option only
	   has an effect if -ffast-math or -funsafe-math-optimizations is used
	   as well.  Enabling this reduces precision of square root results to
	   about 16 bits for single precision and to 32 bits for double
	   precision.  If enabled, it implies -mlow-precision-recip-sqrt.

       -mlow-precision-div
       -mno-low-precision-div
	   Enable or disable the division approximation.  This option only has
	   an effect if -ffast-math or -funsafe-math-optimizations is used as
	   well.  Enabling this reduces precision of division results to about
	   16 bits for single precision and to 32 bits for double precision.

       -mtrack-speculation
       -mno-track-speculation
	   Enable or disable generation of additional code to track
	   speculative execution through conditional branches.	The tracking
	   state can then be used by the compiler when expanding calls to
	   "__builtin_speculation_safe_copy" to permit a more efficient code
	   sequence to be generated.

       -moutline-atomics
       -mno-outline-atomics
	   Enable or disable calls to out-of-line helpers to implement atomic
	   operations.	These helpers will, at runtime, determine if the LSE
	   instructions from ARMv8.1-A can be used; if not, they will use the
	   load/store-exclusive instructions that are present in the base
	   ARMv8.0 ISA.

	   This option is only applicable when compiling for the base ARMv8.0
	   instruction set.  If using a later revision, e.g. -march=armv8.1-a
	   or -march=armv8-a+lse, the ARMv8.1-Atomics instructions will be
	   used directly.  The same applies when using -mcpu= when the
	   selected cpu supports the lse feature.  This option is on by
	   default.

       -march=name
	   Specify the name of the target architecture and, optionally, one or
	   more feature modifiers.  This option has the form
	   -march=arch{+[no]feature}*.

	   The table below summarizes the permissible values for arch and the
	   features that they enable by default:

	   arch value : Architecture : Includes by default
	   armv8-a : Armv8-A : +fp, +simd
	   armv8.1-a : Armv8.1-A : armv8-a, +crc, +lse, +rdma
	   armv8.2-a : Armv8.2-A : armv8.1-a
	   armv8.3-a : Armv8.3-A : armv8.2-a, +pauth
	   armv8.4-a : Armv8.4-A : armv8.3-a, +flagm, +fp16fml, +dotprod
	   armv8.5-a : Armv8.5-A : armv8.4-a, +sb, +ssbs, +predres
	   armv8.6-a : Armv8.6-A : armv8.5-a, +bf16, +i8mm
	   armv8.7-a : Armv8.7-A : armv8.6-a, +ls64
	   armv8.8-a : Armv8.8-a : armv8.7-a, +mops
	   armv8.9-a : Armv8.9-a : armv8.8-a
	   armv9-a : Armv9-A : armv8.5-a, +sve, +sve2
	   armv9.1-a : Armv9.1-A : armv9-a, +bf16, +i8mm
	   armv9.2-a : Armv9.2-A : armv9.1-a, +ls64
	   armv9.3-a : Armv9.3-A : armv9.2-a, +mops
	   armv9.4-a : Armv9.4-A : armv9.3-a
	   armv8-r : Armv8-R : armv8-r

	   The value native is available on native AArch64 GNU/Linux and
	   causes the compiler to pick the architecture of the host system.
	   This option has no effect if the compiler is unable to recognize
	   the architecture of the host system,

	   The permissible values for feature are listed in the sub-section on
	   aarch64-feature-modifiers,,-march and -mcpu Feature Modifiers.
	   Where conflicting feature modifiers are specified, the right-most
	   feature is used.

	   GCC uses name to determine what kind of instructions it can emit
	   when generating assembly code.  If -march is specified without
	   either of -mtune or -mcpu also being specified, the code is tuned
	   to perform well across a range of target processors implementing
	   the target architecture.

       -mtune=name
	   Specify the name of the target processor for which GCC should tune
	   the performance of the code.	 Permissible values for this option
	   are: generic, cortex-a35, cortex-a53, cortex-a55, cortex-a57,
	   cortex-a72, cortex-a73, cortex-a75, cortex-a76, cortex-a76ae,
	   cortex-a77, cortex-a65, cortex-a65ae, cortex-a34, cortex-a78,
	   cortex-a78ae, cortex-a78c, ares, exynos-m1, emag, falkor,
	   neoverse-512tvb, neoverse-e1, neoverse-n1, neoverse-n2,
	   neoverse-v1, neoverse-v2, grace, qdf24xx, saphira, phecda, xgene1,
	   vulcan, octeontx, octeontx81,  octeontx83, octeontx2, octeontx2t98,
	   octeontx2t96 octeontx2t93, octeontx2f95, octeontx2f95n,
	   octeontx2f95mm, a64fx, thunderx, thunderxt88, thunderxt88p1,
	   thunderxt81, tsv110, thunderxt83, thunderx2t99, thunderx3t110,
	   zeus, cortex-a57.cortex-a53, cortex-a72.cortex-a53,
	   cortex-a73.cortex-a35, cortex-a73.cortex-a53,
	   cortex-a75.cortex-a55, cortex-a76.cortex-a55, cortex-r82,
	   cortex-x1, cortex-x1c, cortex-x2, cortex-x3, cortex-x4,
	   cortex-a510, cortex-a520, cortex-a710, cortex-a715, cortex-a720,
	   ampere1, ampere1a, ampere1b, cobalt-100 and native.

	   The values cortex-a57.cortex-a53, cortex-a72.cortex-a53,
	   cortex-a73.cortex-a35, cortex-a73.cortex-a53,
	   cortex-a75.cortex-a55, cortex-a76.cortex-a55 specify that GCC
	   should tune for a big.LITTLE system.

	   The value neoverse-512tvb specifies that GCC should tune for
	   Neoverse cores that (a) implement SVE and (b) have a total vector
	   bandwidth of 512 bits per cycle.  In other words, the option tells
	   GCC to tune for Neoverse cores that can execute 4 128-bit Advanced
	   SIMD arithmetic instructions a cycle and that can execute an
	   equivalent number of SVE arithmetic instructions per cycle (2 for
	   256-bit SVE, 4 for 128-bit SVE).  This is more general than tuning
	   for a specific core like Neoverse V1 but is more specific than the
	   default tuning described below.

	   Additionally on native AArch64 GNU/Linux systems the value native
	   tunes performance to the host system.  This option has no effect if
	   the compiler is unable to recognize the processor of the host
	   system.

	   Where none of -mtune=, -mcpu= or -march= are specified, the code is
	   tuned to perform well across a range of target processors.

	   This option cannot be suffixed by feature modifiers.

       -mcpu=name
	   Specify the name of the target processor, optionally suffixed by
	   one or more feature modifiers.  This option has the form
	   -mcpu=cpu{+[no]feature}*, where the permissible values for cpu are
	   the same as those available for -mtune.  The permissible values for
	   feature are documented in the sub-section on
	   aarch64-feature-modifiers,,-march and -mcpu Feature Modifiers.
	   Where conflicting feature modifiers are specified, the right-most
	   feature is used.

	   GCC uses name to determine what kind of instructions it can emit
	   when generating assembly code (as if by -march) and to determine
	   the target processor for which to tune for performance (as if by
	   -mtune).  Where this option is used in conjunction with -march or
	   -mtune, those options take precedence over the appropriate part of
	   this option.

	   -mcpu=neoverse-512tvb is special in that it does not refer to a
	   specific core, but instead refers to all Neoverse cores that (a)
	   implement SVE and (b) have a total vector bandwidth of 512 bits a
	   cycle.  Unless overridden by -march, -mcpu=neoverse-512tvb
	   generates code that can run on a Neoverse V1 core, since Neoverse
	   V1 is the first Neoverse core with these properties.	 Unless
	   overridden by -mtune, -mcpu=neoverse-512tvb tunes code in the same
	   way as for -mtune=neoverse-512tvb.

       -moverride=string
	   Override tuning decisions made by the back-end in response to a
	   -mtune= switch.  The syntax, semantics, and accepted values for
	   string in this option are not guaranteed to be consistent across
	   releases.

	   This option is only intended to be useful when developing GCC.

       -mverbose-cost-dump
	   Enable verbose cost model dumping in the debug dump files.  This
	   option is provided for use in debugging the compiler.

       -mpc-relative-literal-loads
       -mno-pc-relative-literal-loads
	   Enable or disable PC-relative literal loads.	 With this option
	   literal pools are accessed using a single instruction and emitted
	   after each function.	 This limits the maximum size of functions to
	   1MB.	 This is enabled by default for -mcmodel=tiny.

       -msign-return-address=scope
	   Select the function scope on which return address signing will be
	   applied.  Permissible values are none, which disables return
	   address signing, non-leaf, which enables pointer signing for
	   functions which are not leaf functions, and all, which enables
	   pointer signing for all functions.  The default value is none. This
	   option has been deprecated by -mbranch-protection.

       -mbranch-protection=none|standard|pac-ret[+leaf+b-key]|bti
	   Select the branch protection features to use.  none is the default
	   and turns off all types of branch protection.  standard turns on
	   all types of branch protection features.  If a feature has
	   additional tuning options, then standard sets it to its standard
	   level.  pac-ret[+leaf] turns on return address signing to its
	   standard level: signing functions that save the return address to
	   memory (non-leaf functions will practically always do this) using
	   the a-key.  The optional argument leaf can be used to extend the
	   signing to include leaf functions.  The optional argument b-key can
	   be used to sign the functions with the B-key instead of the A-key.
	   bti turns on branch target identification mechanism.

       -mharden-sls=opts
	   Enable compiler hardening against straight line speculation (SLS).
	   opts is a comma-separated list of the following options:

	   retbr
	   blr

	   In addition, -mharden-sls=all enables all SLS hardening while
	   -mharden-sls=none disables all SLS hardening.

       -mearly-ra=scope
	   Determine when to enable an early register allocation pass.	This
	   pass runs before instruction scheduling and tries to find a spill-
	   free allocation of floating-point and vector code.  It also tries
	   to make use of strided multi-register instructions, such as SME2's
	   strided LD1 and ST1.

	   The possible values of scope are: all, which runs the pass on all
	   functions; strided, which runs the pass on functions that have
	   access to strided multi-register instructions; and none, which
	   disables the pass.

	   -mearly-ra=all is the default for -O2 and above, and for -Os.
	   -mearly-ra=none is the default otherwise.

       -mearly-ldp-fusion
	   Enable the copy of the AArch64 load/store pair fusion pass that
	   runs before register allocation.  Enabled by default at -O and
	   above.

       -mlate-ldp-fusion
	   Enable the copy of the AArch64 load/store pair fusion pass that
	   runs after register allocation.  Enabled by default at -O and
	   above.

       -msve-vector-bits=bits
	   Specify the number of bits in an SVE vector register.  This option
	   only has an effect when SVE is enabled.

	   GCC supports two forms of SVE code generation: "vector-length
	   agnostic" output that works with any size of vector register and
	   "vector-length specific" output that allows GCC to make assumptions
	   about the vector length when it is useful for optimization reasons.
	   The possible values of bits are: scalable, 128, 256, 512, 1024 and
	   2048.  Specifying scalable selects vector-length agnostic output.
	   At present -msve-vector-bits=128 also generates vector-length
	   agnostic output for big-endian targets.  All other values generate
	   vector-length specific code.	 The behavior of these values may
	   change in future releases and no value except scalable should be
	   relied on for producing code that is portable across different
	   hardware SVE vector lengths.

	   The default is -msve-vector-bits=scalable, which produces vector-
	   length agnostic code.

       -march and -mcpu Feature Modifiers

       Feature modifiers used with -march and -mcpu can be any of the
       following and their inverses nofeature:

       crc Enable CRC extension.  This is on by default for -march=armv8.1-a.

       crypto
	   Enable Crypto extension.  This also enables Advanced SIMD and
	   floating-point instructions.

       fp  Enable floating-point instructions.	This is on by default for all
	   possible values for options -march and -mcpu.

       simd
	   Enable Advanced SIMD instructions.  This also enables floating-
	   point instructions.	This is on by default for all possible values
	   for options -march and -mcpu.

       sve Enable Scalable Vector Extension instructions.  This also enables
	   Advanced SIMD and floating-point instructions.

       lse Enable Large System Extension instructions.	This is on by default
	   for -march=armv8.1-a.

       rdma
	   Enable Round Double Multiply Accumulate instructions.  This is on
	   by default for -march=armv8.1-a.

       fp16
	   Enable FP16 extension.  This also enables floating-point
	   instructions.

       fp16fml
	   Enable FP16 fmla extension.	This also enables FP16 extensions and
	   floating-point instructions. This option is enabled by default for
	   -march=armv8.4-a. Use of this option with architectures prior to
	   Armv8.2-A is not supported.

       rcpc
	   Enable the RCpc extension.  This enables the use of the LDAPR
	   instructions for load-acquire atomic semantics, and passes it on to
	   the assembler, enabling inline asm statements to use instructions
	   from the RCpc extension.

       dotprod
	   Enable the Dot Product extension.  This also enables Advanced SIMD
	   instructions.

       aes Enable the Armv8-a aes and pmull crypto extension.  This also
	   enables Advanced SIMD instructions.

       sha2
	   Enable the Armv8-a sha2 crypto extension.  This also enables
	   Advanced SIMD instructions.

       sha3
	   Enable the sha512 and sha3 crypto extension.	 This also enables
	   Advanced SIMD instructions. Use of this option with architectures
	   prior to Armv8.2-A is not supported.

       sm4 Enable the sm3 and sm4 crypto extension.  This also enables
	   Advanced SIMD instructions.	Use of this option with architectures
	   prior to Armv8.2-A is not supported.

       profile
	   Enable the Statistical Profiling extension.	This option is only to
	   enable the extension at the assembler level and does not affect
	   code generation.

       rng Enable the Armv8.5-a Random Number instructions.  This option is
	   only to enable the extension at the assembler level and does not
	   affect code generation.

       memtag
	   Enable the Armv8.5-a Memory Tagging Extensions.  Use of this option
	   with architectures prior to Armv8.5-A is not supported.

       sb  Enable the Armv8-a Speculation Barrier instruction.	This option is
	   only to enable the extension at the assembler level and does not
	   affect code generation.  This option is enabled by default for
	   -march=armv8.5-a.

       ssbs
	   Enable the Armv8-a Speculative Store Bypass Safe instruction.  This
	   option is only to enable the extension at the assembler level and
	   does not affect code generation.  This option is enabled by default
	   for -march=armv8.5-a.

       predres
	   Enable the Armv8-a Execution and Data Prediction Restriction
	   instructions.  This option is only to enable the extension at the
	   assembler level and does not affect code generation.	 This option
	   is enabled by default for -march=armv8.5-a.

       sve2
	   Enable the Armv8-a Scalable Vector Extension 2.  This also enables
	   SVE instructions.

       sve2-bitperm
	   Enable SVE2 bitperm instructions.  This also enables SVE2
	   instructions.

       sve2-sm4
	   Enable SVE2 sm4 instructions.  This also enables SVE2 instructions.

       sve2-aes
	   Enable SVE2 aes instructions.  This also enables SVE2 instructions.

       sve2-sha3
	   Enable SVE2 sha3 instructions.  This also enables SVE2
	   instructions.

       tme Enable the Transactional Memory Extension.

       i8mm
	   Enable 8-bit Integer Matrix Multiply instructions.  This also
	   enables Advanced SIMD and floating-point instructions.  This option
	   is enabled by default for -march=armv8.6-a.	Use of this option
	   with architectures prior to Armv8.2-A is not supported.

       f32mm
	   Enable 32-bit Floating point Matrix Multiply instructions.  This
	   also enables SVE instructions.  Use of this option with
	   architectures prior to Armv8.2-A is not supported.

       f64mm
	   Enable 64-bit Floating point Matrix Multiply instructions.  This
	   also enables SVE instructions.  Use of this option with
	   architectures prior to Armv8.2-A is not supported.

       bf16
	   Enable brain half-precision floating-point instructions.  This also
	   enables Advanced SIMD and floating-point instructions.  This option
	   is enabled by default for -march=armv8.6-a.	Use of this option
	   with architectures prior to Armv8.2-A is not supported.

       ls64
	   Enable the 64-byte atomic load and store instructions for
	   accelerators.  This option is enabled by default for
	   -march=armv8.7-a.

       mops
	   Enable the instructions to accelerate memory operations like
	   "memcpy", "memmove", "memset".  This option is enabled by default
	   for -march=armv8.8-a

       flagm
	   Enable the Flag Manipulation instructions Extension.

       pauth
	   Enable the Pointer Authentication Extension.

       cssc
	   Enable the Common Short Sequence Compression instructions.

       sme Enable the Scalable Matrix Extension.

       sme-i16i64
	   Enable the FEAT_SME_I16I64 extension to SME.

       sme-f64f64
	   Enable the FEAT_SME_F64F64 extension to SME.	 +@item sme2 Enable
	   the Scalable Matrix Extension 2.  This also enables SME
	   instructions.

       lse128
	   Enable the LSE128 128-bit atomic instructions extension.  This also
	   enables LSE instructions.

       d128
	   Enable support for 128-bit system register read/write instructions.
	   This also enables the LSE128 extension.

       gcs Enable support for Armv9.4-a Guarded Control Stack extension.

       the Enable support for Armv8.9-a/9.4-a translation hardening extension.

       rcpc3
	   Enable the RCpc3 (Release Consistency) extension.

       Feature crypto implies aes, sha2, and simd, which implies fp.
       Conversely, nofp implies nosimd, which implies nocrypto, noaes and
       nosha2.

       Adapteva Epiphany Options

       These -m options are defined for Adapteva Epiphany:

       -mhalf-reg-file
	   Don't allocate any register in the range "r32"..."r63".  That
	   allows code to run on hardware variants that lack these registers.

       -mprefer-short-insn-regs
	   Preferentially allocate registers that allow short instruction
	   generation.	This can result in increased instruction count, so
	   this may either reduce or increase overall code size.

       -mbranch-cost=num
	   Set the cost of branches to roughly num "simple" instructions.
	   This cost is only a heuristic and is not guaranteed to produce
	   consistent results across releases.

       -mcmove
	   Enable the generation of conditional moves.

       -mnops=num
	   Emit num NOPs before every other generated instruction.

       -mno-soft-cmpsf
	   For single-precision floating-point comparisons, emit an "fsub"
	   instruction and test the flags.  This is faster than a software
	   comparison, but can get incorrect results in the presence of NaNs,
	   or when two different small numbers are compared such that their
	   difference is calculated as zero.  The default is -msoft-cmpsf,
	   which uses slower, but IEEE-compliant, software comparisons.

       -mstack-offset=num
	   Set the offset between the top of the stack and the stack pointer.
	   E.g., a value of 8 means that the eight bytes in the range
	   "sp+0...sp+7" can be used by leaf functions without stack
	   allocation.	Values other than 8 or 16 are untested and unlikely to
	   work.  Note also that this option changes the ABI; compiling a
	   program with a different stack offset than the libraries have been
	   compiled with generally does not work.  This option can be useful
	   if you want to evaluate if a different stack offset would give you
	   better code, but to actually use a different stack offset to build
	   working programs, it is recommended to configure the toolchain with
	   the appropriate --with-stack-offset=num option.

       -mno-round-nearest
	   Make the scheduler assume that the rounding mode has been set to
	   truncating.	The default is -mround-nearest.

       -mlong-calls
	   If not otherwise specified by an attribute, assume all calls might
	   be beyond the offset range of the "b" / "bl" instructions, and
	   therefore load the function address into a register before
	   performing a (otherwise direct) call.  This is the default.

       -mshort-calls
	   If not otherwise specified by an attribute, assume all direct calls
	   are in the range of the "b" / "bl" instructions, so use these
	   instructions for direct calls.  The default is -mlong-calls.

       -msmall16
	   Assume addresses can be loaded as 16-bit unsigned values.  This
	   does not apply to function addresses for which -mlong-calls
	   semantics are in effect.

       -mfp-mode=mode
	   Set the prevailing mode of the floating-point unit.	This
	   determines the floating-point mode that is provided and expected at
	   function call and return time.  Making this mode match the mode you
	   predominantly need at function start can make your programs smaller
	   and faster by avoiding unnecessary mode switches.

	   mode can be set to one the following values:

	   caller
	       Any mode at function entry is valid, and retained or restored
	       when the function returns, and when it calls other functions.
	       This mode is useful for compiling libraries or other
	       compilation units you might want to incorporate into different
	       programs with different prevailing FPU modes, and the
	       convenience of being able to use a single object file outweighs
	       the size and speed overhead for any extra mode switching that
	       might be needed, compared with what would be needed with a more
	       specific choice of prevailing FPU mode.

	   truncate
	       This is the mode used for floating-point calculations with
	       truncating (i.e. round towards zero) rounding mode.  That
	       includes conversion from floating point to integer.

	   round-nearest
	       This is the mode used for floating-point calculations with
	       round-to-nearest-or-even rounding mode.

	   int This is the mode used to perform integer calculations in the
	       FPU, e.g.  integer multiply, or integer multiply-and-
	       accumulate.

	   The default is -mfp-mode=caller

       -mno-split-lohi
       -mno-postinc
       -mno-postmodify
	   Code generation tweaks that disable, respectively, splitting of
	   32-bit loads, generation of post-increment addresses, and
	   generation of post-modify addresses.	 The defaults are msplit-lohi,
	   -mpost-inc, and -mpost-modify.

       -mnovect-double
	   Change the preferred SIMD mode to SImode.  The default is
	   -mvect-double, which uses DImode as preferred SIMD mode.

       -max-vect-align=num
	   The maximum alignment for SIMD vector mode types.  num may be 4 or
	   8.  The default is 8.  Note that this is an ABI change, even though
	   many library function interfaces are unaffected if they don't use
	   SIMD vector modes in places that affect size and/or alignment of
	   relevant types.

       -msplit-vecmove-early
	   Split vector moves into single word moves before reload.  In theory
	   this can give better register allocation, but so far the reverse
	   seems to be generally the case.

       -m1reg-reg
	   Specify a register to hold the constant -1, which makes loading
	   small negative constants and certain bitmasks faster.  Allowable
	   values for reg are r43 and r63, which specify use of that register
	   as a fixed register, and none, which means that no register is used
	   for this purpose.  The default is -m1reg-none.

       AMD GCN Options

       These options are defined specifically for the AMD GCN port.

       -march=gpu
       -mtune=gpu
	   Set architecture type or tuning for gpu. Supported values for gpu
	   are

	   fiji
	       Compile for GCN3 Fiji devices (gfx803).	Support deprecated;
	       availablility depends on how GCC has been configured, see
	       --with-arch and --with-multilib-list.

	   gfx900
	       Compile for GCN5 Vega 10 devices (gfx900).

	   gfx906
	       Compile for GCN5 Vega 20 devices (gfx906).

	   gfx908
	       Compile for CDNA1 Instinct MI100 series devices (gfx908).

	   gfx90a
	       Compile for CDNA2 Instinct MI200 series devices (gfx90a).

	   gfx90c
	       Compile for GCN5 Vega 7 devices (gfx90c).

	   gfx1030
	       Compile for RDNA2 gfx1030 devices (GFX10 series).

	   gfx1036
	       Compile for RDNA2 gfx1036 devices (GFX10 series).

	   gfx1100
	       Compile for RDNA3 gfx1100 devices (GFX11 series).

	   gfx1103
	       Compile for RDNA3 gfx1103 devices (GFX11 series).

       -msram-ecc=on
       -msram-ecc=off
       -msram-ecc=any
	   Compile binaries suitable for devices with the SRAM-ECC feature
	   enabled, disabled, or either mode.  This feature can be enabled
	   per-process on some devices.	 The compiled code must match the
	   device mode. The default is any, for devices that support it.

       -mstack-size=bytes
	   Specify how many bytes of stack space will be requested for each
	   GPU thread (wave-front).  Beware that there may be many threads and
	   limited memory available.  The size of the stack allocation may
	   also have an impact on run-time performance.	 The default is 32KB
	   when using OpenACC or OpenMP, and 1MB otherwise.

       -mxnack=on
       -mxnack=off
       -mxnack=any
	   Compile binaries suitable for devices with the XNACK feature
	   enabled, disabled, or either mode.  Some devices always require
	   XNACK and some allow the user to configure XNACK.  The compiled
	   code must match the device mode.  The default is -mxnack=any on
	   devices that support Unified Shared Memory, and -mxnack=no
	   otherwise.

       ARC Options

       The following options control the architecture variant for which code
       is being compiled:

       -mbarrel-shifter
	   Generate instructions supported by barrel shifter.  This is the
	   default unless -mcpu=ARC601 or -mcpu=ARCEM is in effect.

       -mjli-always
	   Force to call a function using jli_s instruction.  This option is
	   valid only for ARCv2 architecture.

       -mcpu=cpu
	   Set architecture type, register usage, and instruction scheduling
	   parameters for cpu.	There are also shortcut alias options
	   available for backward compatibility and convenience.  Supported
	   values for cpu are

	   arc600
	       Compile for ARC600.  Aliases: -mA6, -mARC600.

	   arc601
	       Compile for ARC601.  Alias: -mARC601.

	   arc700
	       Compile for ARC700.  Aliases: -mA7, -mARC700.  This is the
	       default when configured with --with-cpu=arc700.

	   arcem
	       Compile for ARC EM.

	   archs
	       Compile for ARC HS.

	   em  Compile for ARC EM CPU with no hardware extensions.

	   em4 Compile for ARC EM4 CPU.

	   em4_dmips
	       Compile for ARC EM4 DMIPS CPU.

	   em4_fpus
	       Compile for ARC EM4 DMIPS CPU with the single-precision
	       floating-point extension.

	   em4_fpuda
	       Compile for ARC EM4 DMIPS CPU with single-precision floating-
	       point and double assist instructions.

	   hs  Compile for ARC HS CPU with no hardware extensions except the
	       atomic instructions.

	   hs34
	       Compile for ARC HS34 CPU.

	   hs38
	       Compile for ARC HS38 CPU.

	   hs38_linux
	       Compile for ARC HS38 CPU with all hardware extensions on.

	   hs4x
	       Compile for ARC HS4x CPU.

	   hs4xd
	       Compile for ARC HS4xD CPU.

	   hs4x_rel31
	       Compile for ARC HS4x CPU release 3.10a.

	   arc600_norm
	       Compile for ARC 600 CPU with "norm" instructions enabled.

	   arc600_mul32x16
	       Compile for ARC 600 CPU with "norm" and 32x16-bit multiply
	       instructions enabled.

	   arc600_mul64
	       Compile for ARC 600 CPU with "norm" and "mul64"-family
	       instructions enabled.

	   arc601_norm
	       Compile for ARC 601 CPU with "norm" instructions enabled.

	   arc601_mul32x16
	       Compile for ARC 601 CPU with "norm" and 32x16-bit multiply
	       instructions enabled.

	   arc601_mul64
	       Compile for ARC 601 CPU with "norm" and "mul64"-family
	       instructions enabled.

	   nps400
	       Compile for ARC 700 on NPS400 chip.

	   em_mini
	       Compile for ARC EM minimalist configuration featuring reduced
	       register set.

       -mdpfp
       -mdpfp-compact
	   Generate double-precision FPX instructions, tuned for the compact
	   implementation.

       -mdpfp-fast
	   Generate double-precision FPX instructions, tuned for the fast
	   implementation.

       -mno-dpfp-lrsr
	   Disable "lr" and "sr" instructions from using FPX extension aux
	   registers.

       -mea
	   Generate extended arithmetic instructions.  Currently only "divaw",
	   "adds", "subs", and "sat16" are supported.  Only valid for
	   -mcpu=ARC700.

       -mno-mpy
	   Do not generate "mpy"-family instructions for ARC700.  This option
	   is deprecated.

       -mmul32x16
	   Generate 32x16-bit multiply and multiply-accumulate instructions.

       -mmul64
	   Generate "mul64" and "mulu64" instructions.	Only valid for
	   -mcpu=ARC600.

       -mnorm
	   Generate "norm" instructions.  This is the default if -mcpu=ARC700
	   is in effect.

       -mspfp
       -mspfp-compact
	   Generate single-precision FPX instructions, tuned for the compact
	   implementation.

       -mspfp-fast
	   Generate single-precision FPX instructions, tuned for the fast
	   implementation.

       -msimd
	   Enable generation of ARC SIMD instructions via target-specific
	   builtins.  Only valid for -mcpu=ARC700.

       -msoft-float
	   This option ignored; it is provided for compatibility purposes
	   only.  Software floating-point code is emitted by default, and this
	   default can overridden by FPX options; -mspfp, -mspfp-compact, or
	   -mspfp-fast for single precision, and -mdpfp, -mdpfp-compact, or
	   -mdpfp-fast for double precision.

       -mswap
	   Generate "swap" instructions.

       -matomic
	   This enables use of the locked load/store conditional extension to
	   implement atomic memory built-in functions.	Not available for ARC
	   6xx or ARC EM cores.

       -mdiv-rem
	   Enable "div" and "rem" instructions for ARCv2 cores.

       -mcode-density
	   Enable code density instructions for ARC EM.	 This option is on by
	   default for ARC HS.

       -mll64
	   Enable double load/store operations for ARC HS cores.

       -mtp-regno=regno
	   Specify thread pointer register number.

       -mmpy-option=multo
	   Compile ARCv2 code with a multiplier design option.	You can
	   specify the option using either a string or numeric value for
	   multo.  wlh1 is the default value.  The recognized values are:

	   0
	   none
	       No multiplier available.

	   1
	   w   16x16 multiplier, fully pipelined.  The following instructions
	       are enabled: "mpyw" and "mpyuw".

	   2
	   wlh1
	       32x32 multiplier, fully pipelined (1 stage).  The following
	       instructions are additionally enabled: "mpy", "mpyu", "mpym",
	       "mpymu", and "mpy_s".

	   3
	   wlh2
	       32x32 multiplier, fully pipelined (2 stages).  The following
	       instructions are additionally enabled: "mpy", "mpyu", "mpym",
	       "mpymu", and "mpy_s".

	   4
	   wlh3
	       Two 16x16 multipliers, blocking, sequential.  The following
	       instructions are additionally enabled: "mpy", "mpyu", "mpym",
	       "mpymu", and "mpy_s".

	   5
	   wlh4
	       One 16x16 multiplier, blocking, sequential.  The following
	       instructions are additionally enabled: "mpy", "mpyu", "mpym",
	       "mpymu", and "mpy_s".

	   6
	   wlh5
	       One 32x4 multiplier, blocking, sequential.  The following
	       instructions are additionally enabled: "mpy", "mpyu", "mpym",
	       "mpymu", and "mpy_s".

	   7
	   plus_dmpy
	       ARC HS SIMD support.

	   8
	   plus_macd
	       ARC HS SIMD support.

	   9
	   plus_qmacw
	       ARC HS SIMD support.

	   This option is only available for ARCv2 cores.

       -mfpu=fpu
	   Enables support for specific floating-point hardware extensions for
	   ARCv2 cores.	 Supported values for fpu are:

	   fpus
	       Enables support for single-precision floating-point hardware
	       extensions.

	   fpud
	       Enables support for double-precision floating-point hardware
	       extensions.  The single-precision floating-point extension is
	       also enabled.  Not available for ARC EM.

	   fpuda
	       Enables support for double-precision floating-point hardware
	       extensions using double-precision assist instructions.  The
	       single-precision floating-point extension is also enabled.
	       This option is only available for ARC EM.

	   fpuda_div
	       Enables support for double-precision floating-point hardware
	       extensions using double-precision assist instructions.  The
	       single-precision floating-point, square-root, and divide
	       extensions are also enabled.  This option is only available for
	       ARC EM.

	   fpuda_fma
	       Enables support for double-precision floating-point hardware
	       extensions using double-precision assist instructions.  The
	       single-precision floating-point and fused multiply and add
	       hardware extensions are also enabled.  This option is only
	       available for ARC EM.

	   fpuda_all
	       Enables support for double-precision floating-point hardware
	       extensions using double-precision assist instructions.  All
	       single-precision floating-point hardware extensions are also
	       enabled.	 This option is only available for ARC EM.

	   fpus_div
	       Enables support for single-precision floating-point, square-
	       root and divide hardware extensions.

	   fpud_div
	       Enables support for double-precision floating-point, square-
	       root and divide hardware extensions.  This option includes
	       option fpus_div. Not available for ARC EM.

	   fpus_fma
	       Enables support for single-precision floating-point and fused
	       multiply and add hardware extensions.

	   fpud_fma
	       Enables support for double-precision floating-point and fused
	       multiply and add hardware extensions.  This option includes
	       option fpus_fma.	 Not available for ARC EM.

	   fpus_all
	       Enables support for all single-precision floating-point
	       hardware extensions.

	   fpud_all
	       Enables support for all single- and double-precision floating-
	       point hardware extensions.  Not available for ARC EM.

       -mirq-ctrl-saved=register-range, blink, lp_count
	   Specifies general-purposes registers that the processor
	   automatically saves/restores on interrupt entry and exit.
	   register-range is specified as two registers separated by a dash.
	   The register range always starts with "r0", the upper limit is "fp"
	   register.  blink and lp_count are optional.	This option is only
	   valid for ARC EM and ARC HS cores.

       -mrgf-banked-regs=number
	   Specifies the number of registers replicated in second register
	   bank on entry to fast interrupt.  Fast interrupts are interrupts
	   with the highest priority level P0.	These interrupts save only PC
	   and STATUS32 registers to avoid memory transactions during
	   interrupt entry and exit sequences.	Use this option when you are
	   using fast interrupts in an ARC V2 family processor.	 Permitted
	   values are 4, 8, 16, and 32.

       -mlpc-width=width
	   Specify the width of the "lp_count" register.  Valid values for
	   width are 8, 16, 20, 24, 28 and 32 bits.  The default width is
	   fixed to 32 bits.  If the width is less than 32, the compiler does
	   not attempt to transform loops in your program to use the zero-
	   delay loop mechanism unless it is known that the "lp_count"
	   register can hold the required loop-counter value.  Depending on
	   the width specified, the compiler and run-time library might
	   continue to use the loop mechanism for various needs.  This option
	   defines macro "__ARC_LPC_WIDTH__" with the value of width.

       -mrf16
	   This option instructs the compiler to generate code for a 16-entry
	   register file.  This option defines the "__ARC_RF16__" preprocessor
	   macro.

       -mbranch-index
	   Enable use of "bi" or "bih" instructions to implement jump tables.

       The following options are passed through to the assembler, and also
       define preprocessor macro symbols.

       -mdsp-packa
	   Passed down to the assembler to enable the DSP Pack A extensions.
	   Also sets the preprocessor symbol "__Xdsp_packa".  This option is
	   deprecated.

       -mdvbf
	   Passed down to the assembler to enable the dual Viterbi butterfly
	   extension.  Also sets the preprocessor symbol "__Xdvbf".  This
	   option is deprecated.

       -mlock
	   Passed down to the assembler to enable the locked load/store
	   conditional extension.  Also sets the preprocessor symbol
	   "__Xlock".

       -mmac-d16
	   Passed down to the assembler.  Also sets the preprocessor symbol
	   "__Xxmac_d16".  This option is deprecated.

       -mmac-24
	   Passed down to the assembler.  Also sets the preprocessor symbol
	   "__Xxmac_24".  This option is deprecated.

       -mrtsc
	   Passed down to the assembler to enable the 64-bit time-stamp
	   counter extension instruction.  Also sets the preprocessor symbol
	   "__Xrtsc".  This option is deprecated.

       -mswape
	   Passed down to the assembler to enable the swap byte ordering
	   extension instruction.  Also sets the preprocessor symbol
	   "__Xswape".

       -mtelephony
	   Passed down to the assembler to enable dual- and single-operand
	   instructions for telephony.	Also sets the preprocessor symbol
	   "__Xtelephony".  This option is deprecated.

       -mxy
	   Passed down to the assembler to enable the XY memory extension.
	   Also sets the preprocessor symbol "__Xxy".

       The following options control how the assembly code is annotated:

       -misize
	   Annotate assembler instructions with estimated addresses.

       -mannotate-align
	   Does nothing.  Preserved for backward compatibility.

       The following options are passed through to the linker:

       -marclinux
	   Passed through to the linker, to specify use of the "arclinux"
	   emulation.  This option is enabled by default in tool chains built
	   for "arc-linux-uclibc" and "arceb-linux-uclibc" targets when
	   profiling is not requested.

       -marclinux_prof
	   Passed through to the linker, to specify use of the "arclinux_prof"
	   emulation.  This option is enabled by default in tool chains built
	   for "arc-linux-uclibc" and "arceb-linux-uclibc" targets when
	   profiling is requested.

       The following options control the semantics of generated code:

       -mlong-calls
	   Generate calls as register indirect calls, thus providing access to
	   the full 32-bit address range.

       -mmedium-calls
	   Don't use less than 25-bit addressing range for calls, which is the
	   offset available for an unconditional branch-and-link instruction.
	   Conditional execution of function calls is suppressed, to allow use
	   of the 25-bit range, rather than the 21-bit range with conditional
	   branch-and-link.  This is the default for tool chains built for
	   "arc-linux-uclibc" and "arceb-linux-uclibc" targets.

       -G num
	   Put definitions of externally-visible data in a small data section
	   if that data is no bigger than num bytes.  The default value of num
	   is 4 for any ARC configuration, or 8 when we have double load/store
	   operations.

       -mno-sdata
	   Do not generate sdata references.  This is the default for tool
	   chains built for "arc-linux-uclibc" and "arceb-linux-uclibc"
	   targets.

       -mvolatile-cache
	   Use ordinarily cached memory accesses for volatile references.
	   This is the default.

       -mno-volatile-cache
	   Enable cache bypass for volatile references.

       The following options fine tune code generation:

       -malign-call
	   Does nothing.  Preserved for backward compatibility.

       -mauto-modify-reg
	   Enable the use of pre/post modify with register displacement.

       -mbbit-peephole
	   Does nothing.  Preserved for backward compatibility.

       -mno-brcc
	   This option disables a target-specific pass in arc_reorg to
	   generate compare-and-branch ("brcc") instructions.  It has no
	   effect on generation of these instructions driven by the combiner
	   pass.

       -mcase-vector-pcrel
	   Use PC-relative switch case tables to enable case table shortening.
	   This is the default for -Os.

       -mcompact-casesi
	   Enable compact "casesi" pattern.  This is the default for -Os, and
	   only available for ARCv1 cores.  This option is deprecated.

       -mno-cond-exec
	   Disable the ARCompact-specific pass to generate conditional
	   execution instructions.

	   Due to delay slot scheduling and interactions between operand
	   numbers, literal sizes, instruction lengths, and the support for
	   conditional execution, the target-independent pass to generate
	   conditional execution is often lacking, so the ARC port has kept a
	   special pass around that tries to find more conditional execution
	   generation opportunities after register allocation, branch
	   shortening, and delay slot scheduling have been done.  This pass
	   generally, but not always, improves performance and code size, at
	   the cost of extra compilation time, which is why there is an option
	   to switch it off.  If you have a problem with call instructions
	   exceeding their allowable offset range because they are
	   conditionalized, you should consider using -mmedium-calls instead.

       -mearly-cbranchsi
	   Enable pre-reload use of the "cbranchsi" pattern.

       -mexpand-adddi
	   Expand "adddi3" and "subdi3" at RTL generation time into "add.f",
	   "adc" etc.  This option is deprecated.

       -mindexed-loads
	   Enable the use of indexed loads.  This can be problematic because
	   some optimizers then assume that indexed stores exist, which is not
	   the case.

       -mlra
	   Enable Local Register Allocation.  This is still experimental for
	   ARC, so by default the compiler uses standard reload (i.e.
	   -mno-lra).

       -mlra-priority-none
	   Don't indicate any priority for target registers.

       -mlra-priority-compact
	   Indicate target register priority for r0..r3 / r12..r15.

       -mlra-priority-noncompact
	   Reduce target register priority for r0..r3 / r12..r15.

       -mmillicode
	   When optimizing for size (using -Os), prologues and epilogues that
	   have to save or restore a large number of registers are often
	   shortened by using call to a special function in libgcc; this is
	   referred to as a millicode call.  As these calls can pose
	   performance issues, and/or cause linking issues when linking in a
	   nonstandard way, this option is provided to turn on or off
	   millicode call generation.

       -mcode-density-frame
	   This option enable the compiler to emit "enter" and "leave"
	   instructions.  These instructions are only valid for CPUs with
	   code-density feature.

       -mmixed-code
	   Does nothing.  Preserved for backward compatibility.

       -mq-class
	   Ths option is deprecated.  Enable q instruction alternatives.  This
	   is the default for -Os.

       -mRcq
	   Does nothing.  Preserved for backward compatibility.

       -mRcw
	   Does nothing.  Preserved for backward compatibility.

       -msize-level=level
	   Fine-tune size optimization with regards to instruction lengths and
	   alignment.  The recognized values for level are:

	   0   No size optimization.  This level is deprecated and treated
	       like 1.

	   1   Short instructions are used opportunistically.

	   2   In addition, alignment of loops and of code after barriers are
	       dropped.

	   3   In addition, optional data alignment is dropped, and the option
	       Os is enabled.

	   This defaults to 3 when -Os is in effect.  Otherwise, the behavior
	   when this is not set is equivalent to level 1.

       -mtune=cpu
	   Set instruction scheduling parameters for cpu, overriding any
	   implied by -mcpu=.

	   Supported values for cpu are

	   ARC600
	       Tune for ARC600 CPU.

	   ARC601
	       Tune for ARC601 CPU.

	   ARC700
	       Tune for ARC700 CPU with standard multiplier block.

	   ARC700-xmac
	       Tune for ARC700 CPU with XMAC block.

	   ARC725D
	       Tune for ARC725D CPU.

	   ARC750D
	       Tune for ARC750D CPU.

	   core3
	       Tune for ARCv2 core3 type CPU.  This option enable usage of
	       "dbnz" instruction.

	   release31a
	       Tune for ARC4x release 3.10a.

       -mmultcost=num
	   Cost to assume for a multiply instruction, with 4 being equal to a
	   normal instruction.

       -munalign-prob-threshold=probability
	   Does nothing.  Preserved for backward compatibility.

       The following options are maintained for backward compatibility, but
       are now deprecated and will be removed in a future release:

       -margonaut
	   Obsolete FPX.

       -mbig-endian
       -EB Compile code for big-endian targets.	 Use of these options is now
	   deprecated.	Big-endian code is supported by configuring GCC to
	   build "arceb-elf32" and "arceb-linux-uclibc" targets, for which big
	   endian is the default.

       -mlittle-endian
       -EL Compile code for little-endian targets.  Use of these options is
	   now deprecated.  Little-endian code is supported by configuring GCC
	   to build "arc-elf32" and "arc-linux-uclibc" targets, for which
	   little endian is the default.

       -mbarrel_shifter
	   Replaced by -mbarrel-shifter.

       -mdpfp_compact
	   Replaced by -mdpfp-compact.

       -mdpfp_fast
	   Replaced by -mdpfp-fast.

       -mdsp_packa
	   Replaced by -mdsp-packa.

       -mEA
	   Replaced by -mea.

       -mmac_24
	   Replaced by -mmac-24.

       -mmac_d16
	   Replaced by -mmac-d16.

       -mspfp_compact
	   Replaced by -mspfp-compact.

       -mspfp_fast
	   Replaced by -mspfp-fast.

       -mtune=cpu
	   Values arc600, arc601, arc700 and arc700-xmac for cpu are replaced
	   by ARC600, ARC601, ARC700 and ARC700-xmac respectively.

       -multcost=num
	   Replaced by -mmultcost.

       ARM Options

       These -m options are defined for the ARM port:

       -mabi=name
	   Generate code for the specified ABI.	 Permissible values are: apcs-
	   gnu, atpcs, aapcs, aapcs-linux and iwmmxt.

       -mapcs-frame
	   Generate a stack frame that is compliant with the ARM Procedure
	   Call Standard for all functions, even if this is not strictly
	   necessary for correct execution of the code.	 Specifying
	   -fomit-frame-pointer with this option causes the stack frames not
	   to be generated for leaf functions.	The default is
	   -mno-apcs-frame.  This option is deprecated.

       -mapcs
	   This is a synonym for -mapcs-frame and is deprecated.

       -mthumb-interwork
	   Generate code that supports calling between the ARM and Thumb
	   instruction sets.  Without this option, on pre-v5 architectures,
	   the two instruction sets cannot be reliably used inside one
	   program.  The default is -mno-thumb-interwork, since slightly
	   larger code is generated when -mthumb-interwork is specified.  In
	   AAPCS configurations this option is meaningless.

       -mno-sched-prolog
	   Prevent the reordering of instructions in the function prologue, or
	   the merging of those instruction with the instructions in the
	   function's body.  This means that all functions start with a
	   recognizable set of instructions (or in fact one of a choice from a
	   small set of different function prologues), and this information
	   can be used to locate the start of functions inside an executable
	   piece of code.  The default is -msched-prolog.

       -mfloat-abi=name
	   Specifies which floating-point ABI to use.  Permissible values are:
	   soft, softfp and hard.

	   Specifying soft causes GCC to generate output containing library
	   calls for floating-point operations.	 softfp allows the generation
	   of code using hardware floating-point instructions, but still uses
	   the soft-float calling conventions.	hard allows generation of
	   floating-point instructions and uses FPU-specific calling
	   conventions.

	   The default depends on the specific target configuration.  Note
	   that the hard-float and soft-float ABIs are not link-compatible;
	   you must compile your entire program with the same ABI, and link
	   with a compatible set of libraries.

       -mgeneral-regs-only
	   Generate code which uses only the general-purpose registers.	 This
	   will prevent the compiler from using floating-point and Advanced
	   SIMD registers but will not impose any restrictions on the
	   assembler.

       -mlittle-endian
	   Generate code for a processor running in little-endian mode.	 This
	   is the default for all standard configurations.

       -mbig-endian
	   Generate code for a processor running in big-endian mode; the
	   default is to compile code for a little-endian processor.

       -mbe8
       -mbe32
	   When linking a big-endian image select between BE8 and BE32
	   formats.  The option has no effect for little-endian images and is
	   ignored.  The default is dependent on the selected target
	   architecture.  For ARMv6 and later architectures the default is
	   BE8, for older architectures the default is BE32.  BE32 format has
	   been deprecated by ARM.

       -march=name[+extension...]
	   This specifies the name of the target ARM architecture.  GCC uses
	   this name to determine what kind of instructions it can emit when
	   generating assembly code.  This option can be used in conjunction
	   with or instead of the -mcpu= option.

	   Permissible names are: armv4t, armv5t, armv5te, armv6, armv6j,
	   armv6k, armv6kz, armv6t2, armv6z, armv6zk, armv7, armv7-a, armv7ve,
	   armv8-a, armv8.1-a, armv8.2-a, armv8.3-a, armv8.4-a, armv8.5-a,
	   armv8.6-a, armv9-a, armv7-r, armv8-r, armv6-m, armv6s-m, armv7-m,
	   armv7e-m, armv8-m.base, armv8-m.main, armv8.1-m.main, armv9-a,
	   iwmmxt and iwmmxt2.

	   Additionally, the following architectures, which lack support for
	   the Thumb execution state, are recognized but support is
	   deprecated: armv4.

	   Many of the architectures support extensions.  These can be added
	   by appending +extension to the architecture name.  Extension
	   options are processed in order and capabilities accumulate.	An
	   extension will also enable any necessary base extensions upon which
	   it depends.	For example, the +crypto extension will always enable
	   the +simd extension.	 The exception to the additive construction is
	   for extensions that are prefixed with +no...: these extensions
	   disable the specified option and any other extensions that may
	   depend on the presence of that extension.

	   For example, -march=armv7-a+simd+nofp+vfpv4 is equivalent to
	   writing -march=armv7-a+vfpv4 since the +simd option is entirely
	   disabled by the +nofp option that follows it.

	   Most extension names are generically named, but have an effect that
	   is dependent upon the architecture to which it is applied.  For
	   example, the +simd option can be applied to both armv7-a and
	   armv8-a architectures, but will enable the original ARMv7-A
	   Advanced SIMD (Neon) extensions for armv7-a and the ARMv8-A variant
	   for armv8-a.

	   The table below lists the supported extensions for each
	   architecture.  Architectures not mentioned do not support any
	   extensions.

	   armv5te
	   armv6
	   armv6j
	   armv6k
	   armv6kz
	   armv6t2
	   armv6z
	   armv6zk
	       +fp The VFPv2 floating-point instructions.  The extension
		   +vfpv2 can be used as an alias for this extension.

	       +nofp
		   Disable the floating-point instructions.

	   armv7
	       The common subset of the ARMv7-A, ARMv7-R and ARMv7-M
	       architectures.

	       +fp The VFPv3 floating-point instructions, with 16 double-
		   precision registers.	 The extension +vfpv3-d16 can be used
		   as an alias for this extension.  Note that floating-point
		   is not supported by the base ARMv7-M architecture, but is
		   compatible with both the ARMv7-A and ARMv7-R architectures.

	       +nofp
		   Disable the floating-point instructions.

	   armv7-a
	       +mp The multiprocessing extension.

	       +sec
		   The security extension.

	       +fp The VFPv3 floating-point instructions, with 16 double-
		   precision registers.	 The extension +vfpv3-d16 can be used
		   as an alias for this extension.

	       +simd
		   The Advanced SIMD (Neon) v1 and the VFPv3 floating-point
		   instructions.  The extensions +neon and +neon-vfpv3 can be
		   used as aliases for this extension.

	       +vfpv3
		   The VFPv3 floating-point instructions, with 32 double-
		   precision registers.

	       +vfpv3-d16-fp16
		   The VFPv3 floating-point instructions, with 16 double-
		   precision registers and the half-precision floating-point
		   conversion operations.

	       +vfpv3-fp16
		   The VFPv3 floating-point instructions, with 32 double-
		   precision registers and the half-precision floating-point
		   conversion operations.

	       +vfpv4-d16
		   The VFPv4 floating-point instructions, with 16 double-
		   precision registers.

	       +vfpv4
		   The VFPv4 floating-point instructions, with 32 double-
		   precision registers.

	       +neon-fp16
		   The Advanced SIMD (Neon) v1 and the VFPv3 floating-point
		   instructions, with the half-precision floating-point
		   conversion operations.

	       +neon-vfpv4
		   The Advanced SIMD (Neon) v2 and the VFPv4 floating-point
		   instructions.

	       +nosimd
		   Disable the Advanced SIMD instructions (does not disable
		   floating point).

	       +nofp
		   Disable the floating-point and Advanced SIMD instructions.

	   armv7ve
	       The extended version of the ARMv7-A architecture with support
	       for virtualization.

	       +fp The VFPv4 floating-point instructions, with 16 double-
		   precision registers.	 The extension +vfpv4-d16 can be used
		   as an alias for this extension.

	       +simd
		   The Advanced SIMD (Neon) v2 and the VFPv4 floating-point
		   instructions.  The extension +neon-vfpv4 can be used as an
		   alias for this extension.

	       +vfpv3-d16
		   The VFPv3 floating-point instructions, with 16 double-
		   precision registers.

	       +vfpv3
		   The VFPv3 floating-point instructions, with 32 double-
		   precision registers.

	       +vfpv3-d16-fp16
		   The VFPv3 floating-point instructions, with 16 double-
		   precision registers and the half-precision floating-point
		   conversion operations.

	       +vfpv3-fp16
		   The VFPv3 floating-point instructions, with 32 double-
		   precision registers and the half-precision floating-point
		   conversion operations.

	       +vfpv4-d16
		   The VFPv4 floating-point instructions, with 16 double-
		   precision registers.

	       +vfpv4
		   The VFPv4 floating-point instructions, with 32 double-
		   precision registers.

	       +neon
		   The Advanced SIMD (Neon) v1 and the VFPv3 floating-point
		   instructions.  The extension +neon-vfpv3 can be used as an
		   alias for this extension.

	       +neon-fp16
		   The Advanced SIMD (Neon) v1 and the VFPv3 floating-point
		   instructions, with the half-precision floating-point
		   conversion operations.

	       +nosimd
		   Disable the Advanced SIMD instructions (does not disable
		   floating point).

	       +nofp
		   Disable the floating-point and Advanced SIMD instructions.

	   armv8-a
	       +crc
		   The Cyclic Redundancy Check (CRC) instructions.

	       +simd
		   The ARMv8-A Advanced SIMD and floating-point instructions.

	       +crypto
		   The cryptographic instructions.

	       +nocrypto
		   Disable the cryptographic instructions.

	       +nofp
		   Disable the floating-point, Advanced SIMD and cryptographic
		   instructions.

	       +sb Speculation Barrier Instruction.

	       +predres
		   Execution and Data Prediction Restriction Instructions.

	   armv8.1-a
	       +simd
		   The ARMv8.1-A Advanced SIMD and floating-point
		   instructions.

	       +crypto
		   The cryptographic instructions.  This also enables the
		   Advanced SIMD and floating-point instructions.

	       +nocrypto
		   Disable the cryptographic instructions.

	       +nofp
		   Disable the floating-point, Advanced SIMD and cryptographic
		   instructions.

	       +sb Speculation Barrier Instruction.

	       +predres
		   Execution and Data Prediction Restriction Instructions.

	   armv8.2-a
	   armv8.3-a
	       +fp16
		   The half-precision floating-point data processing
		   instructions.  This also enables the Advanced SIMD and
		   floating-point instructions.

	       +fp16fml
		   The half-precision floating-point fmla extension.  This
		   also enables the half-precision floating-point extension
		   and Advanced SIMD and floating-point instructions.

	       +simd
		   The ARMv8.1-A Advanced SIMD and floating-point
		   instructions.

	       +crypto
		   The cryptographic instructions.  This also enables the
		   Advanced SIMD and floating-point instructions.

	       +dotprod
		   Enable the Dot Product extension.  This also enables
		   Advanced SIMD instructions.

	       +nocrypto
		   Disable the cryptographic extension.

	       +nofp
		   Disable the floating-point, Advanced SIMD and cryptographic
		   instructions.

	       +sb Speculation Barrier Instruction.

	       +predres
		   Execution and Data Prediction Restriction Instructions.

	       +i8mm
		   8-bit Integer Matrix Multiply instructions.	This also
		   enables Advanced SIMD and floating-point instructions.

	       +bf16
		   Brain half-precision floating-point instructions.  This
		   also enables Advanced SIMD and floating-point instructions.

	   armv8.4-a
	       +fp16
		   The half-precision floating-point data processing
		   instructions.  This also enables the Advanced SIMD and
		   floating-point instructions as well as the Dot Product
		   extension and the half-precision floating-point fmla
		   extension.

	       +simd
		   The ARMv8.3-A Advanced SIMD and floating-point instructions
		   as well as the Dot Product extension.

	       +crypto
		   The cryptographic instructions.  This also enables the
		   Advanced SIMD and floating-point instructions as well as
		   the Dot Product extension.

	       +nocrypto
		   Disable the cryptographic extension.

	       +nofp
		   Disable the floating-point, Advanced SIMD and cryptographic
		   instructions.

	       +sb Speculation Barrier Instruction.

	       +predres
		   Execution and Data Prediction Restriction Instructions.

	       +i8mm
		   8-bit Integer Matrix Multiply instructions.	This also
		   enables Advanced SIMD and floating-point instructions.

	       +bf16
		   Brain half-precision floating-point instructions.  This
		   also enables Advanced SIMD and floating-point instructions.

	   armv8.5-a
	       +fp16
		   The half-precision floating-point data processing
		   instructions.  This also enables the Advanced SIMD and
		   floating-point instructions as well as the Dot Product
		   extension and the half-precision floating-point fmla
		   extension.

	       +simd
		   The ARMv8.3-A Advanced SIMD and floating-point instructions
		   as well as the Dot Product extension.

	       +crypto
		   The cryptographic instructions.  This also enables the
		   Advanced SIMD and floating-point instructions as well as
		   the Dot Product extension.

	       +nocrypto
		   Disable the cryptographic extension.

	       +nofp
		   Disable the floating-point, Advanced SIMD and cryptographic
		   instructions.

	       +i8mm
		   8-bit Integer Matrix Multiply instructions.	This also
		   enables Advanced SIMD and floating-point instructions.

	       +bf16
		   Brain half-precision floating-point instructions.  This
		   also enables Advanced SIMD and floating-point instructions.

	   armv8.6-a
	       +fp16
		   The half-precision floating-point data processing
		   instructions.  This also enables the Advanced SIMD and
		   floating-point instructions as well as the Dot Product
		   extension and the half-precision floating-point fmla
		   extension.

	       +simd
		   The ARMv8.3-A Advanced SIMD and floating-point instructions
		   as well as the Dot Product extension.

	       +crypto
		   The cryptographic instructions.  This also enables the
		   Advanced SIMD and floating-point instructions as well as
		   the Dot Product extension.

	       +nocrypto
		   Disable the cryptographic extension.

	       +nofp
		   Disable the floating-point, Advanced SIMD and cryptographic
		   instructions.

	       +i8mm
		   8-bit Integer Matrix Multiply instructions.	This also
		   enables Advanced SIMD and floating-point instructions.

	       +bf16
		   Brain half-precision floating-point instructions.  This
		   also enables Advanced SIMD and floating-point instructions.

	   armv7-r
	       +fp.sp
		   The single-precision VFPv3 floating-point instructions.
		   The extension +vfpv3xd can be used as an alias for this
		   extension.

	       +fp The VFPv3 floating-point instructions with 16 double-
		   precision registers.	 The extension +vfpv3-d16 can be used
		   as an alias for this extension.

	       +vfpv3xd-d16-fp16
		   The single-precision VFPv3 floating-point instructions with
		   16 double-precision registers and the half-precision
		   floating-point conversion operations.

	       +vfpv3-d16-fp16
		   The VFPv3 floating-point instructions with 16 double-
		   precision registers and the half-precision floating-point
		   conversion operations.

	       +nofp
		   Disable the floating-point extension.

	       +idiv
		   The ARM-state integer division instructions.

	       +noidiv
		   Disable the ARM-state integer division extension.

	   armv7e-m
	       +fp The single-precision VFPv4 floating-point instructions.

	       +fpv5
		   The single-precision FPv5 floating-point instructions.

	       +fp.dp
		   The single- and double-precision FPv5 floating-point
		   instructions.

	       +nofp
		   Disable the floating-point extensions.

	   armv8.1-m.main
	       +dsp
		   The DSP instructions.

	       +mve
		   The M-Profile Vector Extension (MVE) integer instructions.

	       +mve.fp
		   The M-Profile Vector Extension (MVE) integer and single
		   precision floating-point instructions.

	       +fp The single-precision floating-point instructions.

	       +fp.dp
		   The single- and double-precision floating-point
		   instructions.

	       +nofp
		   Disable the floating-point extension.

	       +cdecp0, +cdecp1, ... , +cdecp7
		   Enable the Custom Datapath Extension (CDE) on selected
		   coprocessors according to the numbers given in the options
		   in the range 0 to 7.

	       +pacbti
		   Enable the Pointer Authentication and Branch Target
		   Identification Extension.

	   armv8-m.main
	       +dsp
		   The DSP instructions.

	       +nodsp
		   Disable the DSP extension.

	       +fp The single-precision floating-point instructions.

	       +fp.dp
		   The single- and double-precision floating-point
		   instructions.

	       +nofp
		   Disable the floating-point extension.

	       +cdecp0, +cdecp1, ... , +cdecp7
		   Enable the Custom Datapath Extension (CDE) on selected
		   coprocessors according to the numbers given in the options
		   in the range 0 to 7.

	   armv8-r
	       +crc
		   The Cyclic Redundancy Check (CRC) instructions.

	       +fp.sp
		   The single-precision FPv5 floating-point instructions.

	       +simd
		   The ARMv8-A Advanced SIMD and floating-point instructions.

	       +crypto
		   The cryptographic instructions.

	       +nocrypto
		   Disable the cryptographic instructions.

	       +nofp
		   Disable the floating-point, Advanced SIMD and cryptographic
		   instructions.

	   -march=native causes the compiler to auto-detect the architecture
	   of the build computer.  At present, this feature is only supported
	   on GNU/Linux, and not all architectures are recognized.  If the
	   auto-detect is unsuccessful the option has no effect.

       -mtune=name
	   This option specifies the name of the target ARM processor for
	   which GCC should tune the performance of the code.  For some ARM
	   implementations better performance can be obtained by using this
	   option.  Permissible names are: arm7tdmi, arm7tdmi-s, arm710t,
	   arm720t, arm740t, strongarm, strongarm110, strongarm1100,
	   strongarm1110, arm8, arm810, arm9, arm9e, arm920, arm920t, arm922t,
	   arm946e-s, arm966e-s, arm968e-s, arm926ej-s, arm940t, arm9tdmi,
	   arm10tdmi, arm1020t, arm1026ej-s, arm10e, arm1020e, arm1022e,
	   arm1136j-s, arm1136jf-s, mpcore, mpcorenovfp, arm1156t2-s,
	   arm1156t2f-s, arm1176jz-s, arm1176jzf-s, generic-armv7-a,
	   cortex-a5, cortex-a7, cortex-a8, cortex-a9, cortex-a12, cortex-a15,
	   cortex-a17, cortex-a32, cortex-a35, cortex-a53, cortex-a55,
	   cortex-a57, cortex-a72, cortex-a73, cortex-a75, cortex-a76,
	   cortex-a76ae, cortex-a77, cortex-a78, cortex-a78ae, cortex-a78c,
	   cortex-a710, ares, cortex-r4, cortex-r4f, cortex-r5, cortex-r7,
	   cortex-r8, cortex-r52, cortex-r52plus, cortex-m0, cortex-m0plus,
	   cortex-m1, cortex-m3, cortex-m4, cortex-m7, cortex-m23, cortex-m33,
	   cortex-m35p, cortex-m52, cortex-m55, cortex-m85, cortex-x1,
	   cortex-x1c, cortex-m1.small-multiply, cortex-m0.small-multiply,
	   cortex-m0plus.small-multiply, exynos-m1, marvell-pj4, neoverse-n1,
	   neoverse-n2, neoverse-v1, xscale, iwmmxt, iwmmxt2, ep9312, fa526,
	   fa626, fa606te, fa626te, fmp626, fa726te, star-mc1, xgene1.

	   Additionally, this option can specify that GCC should tune the
	   performance of the code for a big.LITTLE system.  Permissible names
	   are: cortex-a15.cortex-a7, cortex-a17.cortex-a7,
	   cortex-a57.cortex-a53, cortex-a72.cortex-a53,
	   cortex-a72.cortex-a35, cortex-a73.cortex-a53,
	   cortex-a75.cortex-a55, cortex-a76.cortex-a55.

	   -mtune=generic-arch specifies that GCC should tune the performance
	   for a blend of processors within architecture arch.	The aim is to
	   generate code that run well on the current most popular processors,
	   balancing between optimizations that benefit some CPUs in the
	   range, and avoiding performance pitfalls of other CPUs.  The
	   effects of this option may change in future GCC versions as CPU
	   models come and go.

	   -mtune permits the same extension options as -mcpu, but the
	   extension options do not affect the tuning of the generated code.

	   -mtune=native causes the compiler to auto-detect the CPU of the
	   build computer.  At present, this feature is only supported on
	   GNU/Linux, and not all architectures are recognized.	 If the auto-
	   detect is unsuccessful the option has no effect.

       -mcpu=name[+extension...]
	   This specifies the name of the target ARM processor.	 GCC uses this
	   name to derive the name of the target ARM architecture (as if
	   specified by -march) and the ARM processor type for which to tune
	   for performance (as if specified by -mtune).	 Where this option is
	   used in conjunction with -march or -mtune, those options take
	   precedence over the appropriate part of this option.

	   Many of the supported CPUs implement optional architectural
	   extensions.	Where this is so the architectural extensions are
	   normally enabled by default.	 If implementations that lack the
	   extension exist, then the extension syntax can be used to disable
	   those extensions that have been omitted.  For floating-point and
	   Advanced SIMD (Neon) instructions, the settings of the options
	   -mfloat-abi and -mfpu must also be considered: floating-point and
	   Advanced SIMD instructions will only be used if -mfloat-abi is not
	   set to soft; and any setting of -mfpu other than auto will override
	   the available floating-point and SIMD extension instructions.

	   For example, cortex-a9 can be found in three major configurations:
	   integer only, with just a floating-point unit or with floating-
	   point and Advanced SIMD.  The default is to enable all the
	   instructions, but the extensions +nosimd and +nofp can be used to
	   disable just the SIMD or both the SIMD and floating-point
	   instructions respectively.

	   Permissible names for this option are the same as those for -mtune.

	   The following extension options are common to the listed CPUs:

	   +nodsp
	       Disable the DSP instructions on cortex-m33, cortex-m35p,
	       cortex-m52, cortex-m55 and cortex-m85.  Also disable the
	       M-Profile Vector Extension (MVE) integer and single precision
	       floating-point instructions on cortex-m52, cortex-m55 and
	       cortex-m85.

	   +nopacbti
	       Disable the Pointer Authentication and Branch Target
	       Identification Extension on cortex-m52 and cortex-m85.

	   +nomve
	       Disable the M-Profile Vector Extension (MVE) integer and single
	       precision floating-point instructions on cortex-m52, cortex-m55
	       and cortex-m85.

	   +nomve.fp
	       Disable the M-Profile Vector Extension (MVE) single precision
	       floating-point instructions on cortex-m52, cortex-m55 and
	       cortex-m85.

	   +cdecp0, +cdecp1, ... , +cdecp7
	       Enable the Custom Datapath Extension (CDE) on selected
	       coprocessors according to the numbers given in the options in
	       the range 0 to 7 on cortex-m52 and cortex-m55.

	   +nofp
	       Disables the floating-point instructions on arm9e, arm946e-s,
	       arm966e-s, arm968e-s, arm10e, arm1020e, arm1022e, arm926ej-s,
	       arm1026ej-s, cortex-r5, cortex-r7, cortex-r8, cortex-m4,
	       cortex-m7, cortex-m33, cortex-m35p, cortex-m52, cortex-m55 and
	       cortex-m85.  Disables the floating-point and SIMD instructions
	       on generic-armv7-a, cortex-a5, cortex-a7, cortex-a8, cortex-a9,
	       cortex-a12, cortex-a15, cortex-a17, cortex-a15.cortex-a7,
	       cortex-a17.cortex-a7, cortex-a32, cortex-a35, cortex-a53 and
	       cortex-a55.

	   +nofp.dp
	       Disables the double-precision component of the floating-point
	       instructions on cortex-r5, cortex-r7, cortex-r8, cortex-r52,
	       cortex-r52plus and cortex-m7.

	   +nosimd
	       Disables the SIMD (but not floating-point) instructions on
	       generic-armv7-a, cortex-a5, cortex-a7 and cortex-a9.

	   +crypto
	       Enables the cryptographic instructions on cortex-a32,
	       cortex-a35, cortex-a53, cortex-a55, cortex-a57, cortex-a72,
	       cortex-a73, cortex-a75, exynos-m1, xgene1,
	       cortex-a57.cortex-a53, cortex-a72.cortex-a53,
	       cortex-a73.cortex-a35, cortex-a73.cortex-a53 and
	       cortex-a75.cortex-a55.

	   Additionally the generic-armv7-a pseudo target defaults to VFPv3
	   with 16 double-precision registers.	It supports the following
	   extension options: mp, sec, vfpv3-d16, vfpv3, vfpv3-d16-fp16,
	   vfpv3-fp16, vfpv4-d16, vfpv4, neon, neon-vfpv3, neon-fp16,
	   neon-vfpv4.	The meanings are the same as for the extensions to
	   -march=armv7-a.

	   -mcpu=generic-arch is also permissible, and is equivalent to
	   -march=arch -mtune=generic-arch.  See -mtune for more information.

	   -mcpu=native causes the compiler to auto-detect the CPU of the
	   build computer.  At present, this feature is only supported on
	   GNU/Linux, and not all architectures are recognized.	 If the auto-
	   detect is unsuccessful the option has no effect.

       -mfpu=name
	   This specifies what floating-point hardware (or hardware emulation)
	   is available on the target.	Permissible names are: auto, vfpv2,
	   vfpv3, vfpv3-fp16, vfpv3-d16, vfpv3-d16-fp16, vfpv3xd,
	   vfpv3xd-fp16, neon-vfpv3, neon-fp16, vfpv4, vfpv4-d16, fpv4-sp-d16,
	   neon-vfpv4, fpv5-d16, fpv5-sp-d16, fp-armv8, neon-fp-armv8 and
	   crypto-neon-fp-armv8.  Note that neon is an alias for neon-vfpv3
	   and vfp is an alias for vfpv2.

	   The setting auto is the default and is special.  It causes the
	   compiler to select the floating-point and Advanced SIMD
	   instructions based on the settings of -mcpu and -march.

	   If the selected floating-point hardware includes the NEON extension
	   (e.g. -mfpu=neon), note that floating-point operations are not
	   generated by GCC's auto-vectorization pass unless
	   -funsafe-math-optimizations is also specified.  This is because
	   NEON hardware does not fully implement the IEEE 754 standard for
	   floating-point arithmetic (in particular denormal values are
	   treated as zero), so the use of NEON instructions may lead to a
	   loss of precision.

	   You can also set the fpu name at function level by using the
	   target("fpu=") function attributes or pragmas.

       -mfp16-format=name
	   Specify the format of the "__fp16" half-precision floating-point
	   type.  Permissible names are none, ieee, and alternative; the
	   default is none, in which case the "__fp16" type is not defined.

       -mstructure-size-boundary=n
	   The sizes of all structures and unions are rounded up to a multiple
	   of the number of bits set by this option.  Permissible values are
	   8, 32 and 64.  The default value varies for different toolchains.
	   For the COFF targeted toolchain the default value is 8.  A value of
	   64 is only allowed if the underlying ABI supports it.

	   Specifying a larger number can produce faster, more efficient code,
	   but can also increase the size of the program.  Different values
	   are potentially incompatible.  Code compiled with one value cannot
	   necessarily expect to work with code or libraries compiled with
	   another value, if they exchange information using structures or
	   unions.

	   This option is deprecated.

       -mabort-on-noreturn
	   Generate a call to the function "abort" at the end of a "noreturn"
	   function.  It is executed if the function tries to return.

       -mlong-calls
       -mno-long-calls
	   Tells the compiler to perform function calls by first loading the
	   address of the function into a register and then performing a
	   subroutine call on this register.  This switch is needed if the
	   target function lies outside of the 64-megabyte addressing range of
	   the offset-based version of subroutine call instruction.

	   Even if this switch is enabled, not all function calls are turned
	   into long calls.  The heuristic is that static functions, functions
	   that have the "short_call" attribute, functions that are inside the
	   scope of a "#pragma no_long_calls" directive, and functions whose
	   definitions have already been compiled within the current
	   compilation unit are not turned into long calls.  The exceptions to
	   this rule are that weak function definitions, functions with the
	   "long_call" attribute or the "section" attribute, and functions
	   that are within the scope of a "#pragma long_calls" directive are
	   always turned into long calls.

	   This feature is not enabled by default.  Specifying -mno-long-calls
	   restores the default behavior, as does placing the function calls
	   within the scope of a "#pragma long_calls_off" directive.  Note
	   these switches have no effect on how the compiler generates code to
	   handle function calls via function pointers.

       -msingle-pic-base
	   Treat the register used for PIC addressing as read-only, rather
	   than loading it in the prologue for each function.  The runtime
	   system is responsible for initializing this register with an
	   appropriate value before execution begins.

       -mpic-register=reg
	   Specify the register to be used for PIC addressing.	For standard
	   PIC base case, the default is any suitable register determined by
	   compiler.  For single PIC base case, the default is R9 if target is
	   EABI based or stack-checking is enabled, otherwise the default is
	   R10.

       -mpic-data-is-text-relative
	   Assume that the displacement between the text and data segments is
	   fixed at static link time.  This permits using PC-relative
	   addressing operations to access data known to be in the data
	   segment.  For non-VxWorks RTP targets, this option is enabled by
	   default.  When disabled on such targets, it will enable
	   -msingle-pic-base by default.

       -mpoke-function-name
	   Write the name of each function into the text section, directly
	   preceding the function prologue.  The generated code is similar to
	   this:

			t0
			    .ascii "arm_poke_function_name", 0
			    .align
			t1
			    .word 0xff000000 + (t1 - t0)
			arm_poke_function_name
			    mov	    ip, sp
			    stmfd   sp!, {fp, ip, lr, pc}
			    sub	    fp, ip, #4

	   When performing a stack backtrace, code can inspect the value of
	   "pc" stored at "fp + 0".  If the trace function then looks at
	   location "pc - 12" and the top 8 bits are set, then we know that
	   there is a function name embedded immediately preceding this
	   location and has length "((pc[-3]) & 0xff000000)".

       -mthumb
       -marm
	   Select between generating code that executes in ARM and Thumb
	   states.  The default for most configurations is to generate code
	   that executes in ARM state, but the default can be changed by
	   configuring GCC with the --with-mode=state configure option.

	   You can also override the ARM and Thumb mode for each function by
	   using the target("thumb") and target("arm") function attributes or
	   pragmas.

       -mflip-thumb
	   Switch ARM/Thumb modes on alternating functions.  This option is
	   provided for regression testing of mixed Thumb/ARM code generation,
	   and is not intended for ordinary use in compiling code.

       -mtpcs-frame
	   Generate a stack frame that is compliant with the Thumb Procedure
	   Call Standard for all non-leaf functions.  (A leaf function is one
	   that does not call any other functions.)  The default is
	   -mno-tpcs-frame.

       -mtpcs-leaf-frame
	   Generate a stack frame that is compliant with the Thumb Procedure
	   Call Standard for all leaf functions.  (A leaf function is one that
	   does not call any other functions.)	The default is
	   -mno-apcs-leaf-frame.

       -mcallee-super-interworking
	   Gives all externally visible functions in the file being compiled
	   an ARM instruction set header which switches to Thumb mode before
	   executing the rest of the function.	This allows these functions to
	   be called from non-interworking code.  This option is not valid in
	   AAPCS configurations because interworking is enabled by default.

       -mcaller-super-interworking
	   Allows calls via function pointers (including virtual functions) to
	   execute correctly regardless of whether the target code has been
	   compiled for interworking or not.  There is a small overhead in the
	   cost of executing a function pointer if this option is enabled.
	   This option is not valid in AAPCS configurations because
	   interworking is enabled by default.

       -mtp=name
	   Specify the access model for the thread local storage pointer.  The
	   model soft generates calls to "__aeabi_read_tp".  Other accepted
	   models are tpidrurw, tpidruro and tpidrprw which fetch the thread
	   pointer from the corresponding system register directly (supported
	   from the arm6k architecture and later).  These system registers are
	   accessed through the CP15 co-processor interface and the argument
	   cp15 is also accepted as a convenience alias of tpidruro.  The
	   argument auto uses the best available method for the selected
	   processor.  The default setting is auto.

       -mtls-dialect=dialect
	   Specify the dialect to use for accessing thread local storage.  Two
	   dialects are supported---gnu and gnu2.  The gnu dialect selects the
	   original GNU scheme for supporting local and global dynamic TLS
	   models.  The gnu2 dialect selects the GNU descriptor scheme, which
	   provides better performance for shared libraries.  The GNU
	   descriptor scheme is compatible with the original scheme, but does
	   require new assembler, linker and library support.  Initial and
	   local exec TLS models are unaffected by this option and always use
	   the original scheme.

       -mword-relocations
	   Only generate absolute relocations on word-sized values (i.e.
	   R_ARM_ABS32).  This is enabled by default on targets (uClinux,
	   SymbianOS) where the runtime loader imposes this restriction, and
	   when -fpic or -fPIC is specified. This option conflicts with
	   -mslow-flash-data.

       -mfix-cortex-m3-ldrd
	   Some Cortex-M3 cores can cause data corruption when "ldrd"
	   instructions with overlapping destination and base registers are
	   used.  This option avoids generating these instructions.  This
	   option is enabled by default when -mcpu=cortex-m3 is specified.

       -mfix-cortex-a57-aes-1742098
       -mno-fix-cortex-a57-aes-1742098
       -mfix-cortex-a72-aes-1655431
       -mno-fix-cortex-a72-aes-1655431
	   Enable (disable) mitigation for an erratum on Cortex-A57 and
	   Cortex-A72 that affects the AES cryptographic instructions.	This
	   option is enabled by default when either -mcpu=cortex-a57 or
	   -mcpu=cortex-a72 is specified.

       -munaligned-access
       -mno-unaligned-access
	   Enables (or disables) reading and writing of 16- and 32- bit values
	   from addresses that are not 16- or 32- bit aligned.	By default
	   unaligned access is disabled for all pre-ARMv6, all ARMv6-M and for
	   ARMv8-M Baseline architectures, and enabled for all other
	   architectures.  If unaligned access is not enabled then words in
	   packed data structures are accessed a byte at a time.

	   The ARM attribute "Tag_CPU_unaligned_access" is set in the
	   generated object file to either true or false, depending upon the
	   setting of this option.  If unaligned access is enabled then the
	   preprocessor symbol "__ARM_FEATURE_UNALIGNED" is also defined.

       -mneon-for-64bits
	   This option is deprecated and has no effect.

       -mslow-flash-data
	   Assume loading data from flash is slower than fetching instruction.
	   Therefore literal load is minimized for better performance.	This
	   option is only supported when compiling for ARMv7 M-profile and off
	   by default. It conflicts with -mword-relocations.

       -masm-syntax-unified
	   Assume inline assembler is using unified asm syntax.	 The default
	   is currently off which implies divided syntax.  This option has no
	   impact on Thumb2. However, this may change in future releases of
	   GCC.	 Divided syntax should be considered deprecated.

       -mrestrict-it
	   Restricts generation of IT blocks to conform to the rules of
	   ARMv8-A.  IT blocks can only contain a single 16-bit instruction
	   from a select set of instructions. This option is on by default for
	   ARMv8-A Thumb mode.

       -mprint-tune-info
	   Print CPU tuning information as comment in assembler file.  This is
	   an option used only for regression testing of the compiler and not
	   intended for ordinary use in compiling code.	 This option is
	   disabled by default.

       -mverbose-cost-dump
	   Enable verbose cost model dumping in the debug dump files.  This
	   option is provided for use in debugging the compiler.

       -mpure-code
	   Do not allow constant data to be placed in code sections.
	   Additionally, when compiling for ELF object format give all text
	   sections the ELF processor-specific section attribute
	   "SHF_ARM_PURECODE".	This option is only available when generating
	   non-pic code for M-profile targets.

       -mcmse
	   Generate secure code as per the "ARMv8-M Security Extensions:
	   Requirements on Development Tools Engineering Specification", which
	   can be found on
	   <https://developer.arm.com/documentation/ecm0359818/latest/>.

       -mfix-cmse-cve-2021-35465
	   Mitigate against a potential security issue with the "VLLDM"
	   instruction in some M-profile devices when using CMSE
	   (CVE-2021-365465).  This option is enabled by default when the
	   option -mcpu= is used with "cortex-m33", "cortex-m35p",
	   "cortex-m52", "cortex-m55", "cortex-m85" or "star-mc1". The option
	   -mno-fix-cmse-cve-2021-35465 can be used to disable the mitigation.

       -mstack-protector-guard=guard
       -mstack-protector-guard-offset=offset
	   Generate stack protection code using canary at guard.  Supported
	   locations are global for a global canary or tls for a canary
	   accessible via the TLS register. The option
	   -mstack-protector-guard-offset= is for use with
	   -fstack-protector-guard=tls and not for use in user-land code.

       -mfdpic
       -mno-fdpic
	   Select the FDPIC ABI, which uses 64-bit function descriptors to
	   represent pointers to functions.  When the compiler is configured
	   for "arm-*-uclinuxfdpiceabi" targets, this option is on by default
	   and implies -fPIE if none of the PIC/PIE-related options is
	   provided.  On other targets, it only enables the FDPIC-specific
	   code generation features, and the user should explicitly provide
	   the PIC/PIE-related options as needed.

	   Note that static linking is not supported because it would still
	   involve the dynamic linker when the program self-relocates.	If
	   such behavior is acceptable, use -static and -Wl,-dynamic-linker
	   options.

	   The opposite -mno-fdpic option is useful (and required) to build
	   the Linux kernel using the same ("arm-*-uclinuxfdpiceabi")
	   toolchain as the one used to build the userland programs.

       -mbranch-protection=none|standard|pac-ret[+leaf][+bti]|bti[+pac-
       ret[+leaf]]
	   Enable branch protection features (armv8.1-m.main only).  none
	   generate code without branch protection or return address signing.
	   standard[+leaf] generate code with all branch protection features
	   enabled at their standard level.  pac-ret[+leaf] generate code with
	   return address signing set to its standard level, which is to sign
	   all functions that save the return address to memory.  leaf When
	   return address signing is enabled, also sign leaf functions even if
	   they do not write the return address to memory.  +bti Add landing-
	   pad instructions at the permitted targets of indirect branch
	   instructions.

	   If the +pacbti architecture extension is not enabled, then all
	   branch protection and return address signing operations are
	   constrained to use only the instructions defined in the
	   architectural-NOP space. The generated code will remain backwards-
	   compatible with earlier versions of the architecture, but the
	   additional security can be enabled at run time on processors that
	   support the PACBTI extension.

	   Branch target enforcement using BTI can only be enabled at runtime
	   if all code in the application has been compiled with at least
	   -mbranch-protection=bti.

	   Any setting other than none is supported only on armv8-m.main or
	   later.

	   The default is to generate code without branch protection or return
	   address signing.

       AVR Options

       These options are defined for AVR implementations:

       -mmcu=mcu
	   Specify the AVR instruction set architecture (ISA) or device type.
	   The default for this option is "avr2".

	   The following AVR devices and ISAs are supported.  Note: A complete
	   device support consists of startup code "crtmcu.o", a device header
	   "avr/io*.h", a device library "libmcu.a" and a device-specs
	   ("https://gcc.gnu.org/wiki/avr-gcc#spec-files") file "specs-mcu".
	   Only the latter is provided by the compiler according the supported
	   "mcu"s below.  The rest is supported by AVR-LibC
	   ("https://www.nongnu.org/avr-libc/"), or by means of "atpack"
	   ("https://gcc.gnu.org/wiki/avr-gcc#atpack") files from the hardware
	   manufacturer.

	   "avr2"
	       "Classic" devices with up to 8 KiB of program memory.  mcu =
	       "attiny22", "attiny26", "at90s2313", "at90s2323", "at90s2333",
	       "at90s2343", "at90s4414", "at90s4433", "at90s4434",
	       "at90c8534", "at90s8515", "at90s8535".

	   "avr25"
	       "Classic" devices with up to 8 KiB of program memory and with
	       the "MOVW" instruction.	mcu = "attiny13", "attiny13a",
	       "attiny24", "attiny24a", "attiny25", "attiny261", "attiny261a",
	       "attiny2313", "attiny2313a", "attiny43u", "attiny44",
	       "attiny44a", "attiny45", "attiny48", "attiny441", "attiny461",
	       "attiny461a", "attiny4313", "attiny84", "attiny84a",
	       "attiny85", "attiny87", "attiny88", "attiny828", "attiny841",
	       "attiny861", "attiny861a", "ata5272", "ata6616c", "at86rf401".

	   "avr3"
	       "Classic" devices with 16 KiB up to 64 KiB of program memory.
	       mcu = "at76c711", "at43usb355".

	   "avr31"
	       "Classic" devices with 128 KiB of program memory.  mcu =
	       "atmega103", "at43usb320".

	   "avr35"
	       "Classic" devices with 16 KiB up to 64 KiB of program memory
	       and with the "MOVW" instruction.	 mcu = "attiny167",
	       "attiny1634", "atmega8u2", "atmega16u2", "atmega32u2",
	       "ata5505", "ata6617c", "ata664251", "at90usb82", "at90usb162".

	   "avr4"
	       "Enhanced" devices with up to 8 KiB of program memory.  mcu =
	       "atmega48", "atmega48a", "atmega48p", "atmega48pa",
	       "atmega48pb", "atmega8", "atmega8a", "atmega8hva", "atmega88",
	       "atmega88a", "atmega88p", "atmega88pa", "atmega88pb",
	       "atmega8515", "atmega8535", "ata5795", "ata6285", "ata6286",
	       "ata6289", "ata6612c", "at90pwm1", "at90pwm2", "at90pwm2b",
	       "at90pwm3", "at90pwm3b", "at90pwm81".

	   "avr5"
	       "Enhanced" devices with 16 KiB up to 64 KiB of program memory.
	       mcu = "atmega16", "atmega16a", "atmega16hva", "atmega16hva2",
	       "atmega16hvb", "atmega16hvbrevb", "atmega16m1", "atmega16u4",
	       "atmega161", "atmega162", "atmega163", "atmega164a",
	       "atmega164p", "atmega164pa", "atmega165", "atmega165a",
	       "atmega165p", "atmega165pa", "atmega168", "atmega168a",
	       "atmega168p", "atmega168pa", "atmega168pb", "atmega169",
	       "atmega169a", "atmega169p", "atmega169pa", "atmega32",
	       "atmega32a", "atmega32c1", "atmega32hvb", "atmega32hvbrevb",
	       "atmega32m1", "atmega32u4", "atmega32u6", "atmega323",
	       "atmega324a", "atmega324p", "atmega324pa", "atmega324pb",
	       "atmega325", "atmega325a", "atmega325p", "atmega325pa",
	       "atmega328", "atmega328p", "atmega328pb", "atmega329",
	       "atmega329a", "atmega329p", "atmega329pa", "atmega3250",
	       "atmega3250a", "atmega3250p", "atmega3250pa", "atmega3290",
	       "atmega3290a", "atmega3290p", "atmega3290pa", "atmega406",
	       "atmega64", "atmega64a", "atmega64c1", "atmega64hve",
	       "atmega64hve2", "atmega64m1", "atmega64rfr2", "atmega640",
	       "atmega644", "atmega644a", "atmega644p", "atmega644pa",
	       "atmega644rfr2", "atmega645", "atmega645a", "atmega645p",
	       "atmega649", "atmega649a", "atmega649p", "atmega6450",
	       "atmega6450a", "atmega6450p", "atmega6490", "atmega6490a",
	       "atmega6490p", "ata5790", "ata5790n", "ata5791", "ata6613c",
	       "ata6614q", "ata5782", "ata5831", "ata8210", "ata8510",
	       "ata5787", "ata5835", "ata5700m322", "ata5702m322",
	       "at90pwm161", "at90pwm216", "at90pwm316", "at90can32",
	       "at90can64", "at90scr100", "at90usb646", "at90usb647", "at94k",
	       "m3000".

	   "avr51"
	       "Enhanced" devices with 128 KiB of program memory.  mcu =
	       "atmega128", "atmega128a", "atmega128rfa1", "atmega128rfr2",
	       "atmega1280", "atmega1281", "atmega1284", "atmega1284p",
	       "atmega1284rfr2", "at90can128", "at90usb1286", "at90usb1287".

	   "avr6"
	       "Enhanced" devices with 3-byte PC, i.e. with more than 128 KiB
	       of program memory.  mcu = "atmega256rfr2", "atmega2560",
	       "atmega2561", "atmega2564rfr2".

	   "avrxmega2"
	       "XMEGA" devices with more than 8 KiB and up to 64 KiB of
	       program memory.	mcu = "atxmega8e5", "atxmega16a4",
	       "atxmega16a4u", "atxmega16c4", "atxmega16d4", "atxmega16e5",
	       "atxmega32a4", "atxmega32a4u", "atxmega32c3", "atxmega32c4",
	       "atxmega32d3", "atxmega32d4", "atxmega32e5", "avr64da28",
	       "avr64da32", "avr64da48", "avr64da64", "avr64db28",
	       "avr64db32", "avr64db48", "avr64db64", "avr64dd14",
	       "avr64dd20", "avr64dd28", "avr64dd32", "avr64du28",
	       "avr64du32", "avr64ea28", "avr64ea32", "avr64ea48".

	   "avrxmega3"
	       "XMEGA" devices with up to 64 KiB of combined program memory
	       and RAM, and with program memory visible in the RAM address
	       space.  mcu = "attiny202", "attiny204", "attiny212",
	       "attiny214", "attiny402", "attiny404", "attiny406",
	       "attiny412", "attiny414", "attiny416", "attiny416auto",
	       "attiny417", "attiny424", "attiny426", "attiny427",
	       "attiny804", "attiny806", "attiny807", "attiny814",
	       "attiny816", "attiny817", "attiny824", "attiny826",
	       "attiny827", "attiny1604", "attiny1606", "attiny1607",
	       "attiny1614", "attiny1616", "attiny1617", "attiny1624",
	       "attiny1626", "attiny1627", "attiny3214", "attiny3216",
	       "attiny3217", "attiny3224", "attiny3226", "attiny3227",
	       "atmega808", "atmega809", "atmega1608", "atmega1609",
	       "atmega3208", "atmega3209", "atmega4808", "atmega4809",
	       "avr16dd14", "avr16dd20", "avr16dd28", "avr16dd32",
	       "avr16du14", "avr16du20", "avr16du28", "avr16du32",
	       "avr16ea28", "avr16ea32", "avr16ea48", "avr16eb14",
	       "avr16eb20", "avr16eb28", "avr16eb32", "avr32da28",
	       "avr32da32", "avr32da48", "avr32db28", "avr32db32",
	       "avr32db48", "avr32dd14", "avr32dd20", "avr32dd28",
	       "avr32dd32", "avr32du14", "avr32du20", "avr32du28",
	       "avr32du32", "avr32ea28", "avr32ea32", "avr32ea48".

	   "avrxmega4"
	       "XMEGA" devices with more than 64 KiB and up to 128 KiB of
	       program memory.	mcu = "atxmega64a3", "atxmega64a3u",
	       "atxmega64a4u", "atxmega64b1", "atxmega64b3", "atxmega64c3",
	       "atxmega64d3", "atxmega64d4", "avr128da28", "avr128da32",
	       "avr128da48", "avr128da64", "avr128db28", "avr128db32",
	       "avr128db48", "avr128db64".

	   "avrxmega5"
	       "XMEGA" devices with more than 64 KiB and up to 128 KiB of
	       program memory and more than 64 KiB of RAM.  mcu =
	       "atxmega64a1", "atxmega64a1u".

	   "avrxmega6"
	       "XMEGA" devices with more than 128 KiB of program memory.  mcu
	       = "atxmega128a3", "atxmega128a3u", "atxmega128b1",
	       "atxmega128b3", "atxmega128c3", "atxmega128d3", "atxmega128d4",
	       "atxmega192a3", "atxmega192a3u", "atxmega192c3",
	       "atxmega192d3", "atxmega256a3", "atxmega256a3b",
	       "atxmega256a3bu", "atxmega256a3u", "atxmega256c3",
	       "atxmega256d3", "atxmega384c3", "atxmega384d3".

	   "avrxmega7"
	       "XMEGA" devices with more than 128 KiB of program memory and
	       more than 64 KiB of RAM.	 mcu = "atxmega128a1",
	       "atxmega128a1u", "atxmega128a4u".

	   "avrtiny"
	       "Reduced Tiny" Tiny core devices with only 16 general purpose
	       registers and 512 B up to 4 KiB of program memory.  mcu =
	       "attiny4", "attiny5", "attiny9", "attiny10", "attiny102",
	       "attiny104", "attiny20", "attiny40".

	   "avr1"
	       This ISA is implemented by the minimal AVR core and supported
	       for assembler only.  mcu = "attiny11", "attiny12", "attiny15",
	       "attiny28", "at90s1200".

       -mabsdata
	   Assume that all data in static storage can be accessed by LDS / STS
	   instructions.  This option has only an effect on reduced Tiny
	   devices like ATtiny40.  See also the "absdata" AVR Variable
	   Attributes,variable attribute.

       -maccumulate-args
	   Accumulate outgoing function arguments and acquire/release the
	   needed stack space for outgoing function arguments once in function
	   prologue/epilogue.  Without this option, outgoing arguments are
	   pushed before calling a function and popped afterwards.

	   Popping the arguments after the function call can be expensive on
	   AVR so that accumulating the stack space might lead to smaller
	   executables because arguments need not be removed from the stack
	   after such a function call.

	   This option can lead to reduced code size for functions that
	   perform several calls to functions that get their arguments on the
	   stack like calls to printf-like functions.

       -mbranch-cost=cost
	   Set the branch costs for conditional branch instructions to cost.
	   Reasonable values for cost are small, non-negative integers. The
	   default branch cost is 0.

       -mcall-prologues
	   Functions prologues/epilogues are expanded as calls to appropriate
	   subroutines.	 Code size is smaller.

       -mfuse-add
       -mno-fuse-add
       -mfuse-add=level
	   Optimize indirect memory accesses on reduced Tiny devices.  The
	   default uses "level=1" for optimizations -Og and -O1, and "level=2"
	   for higher optimizations.  Valid values for level are 0, 1 and 2.

       -mdouble=bits
       -mlong-double=bits
	   Set the size (in bits) of the "double" or "long double" type,
	   respectively.  Possible values for bits are 32 and 64.  Whether or
	   not a specific value for bits is allowed depends on the
	   "--with-double=" and "--with-long-double=" configure options
	   ("https://gcc.gnu.org/install/configure.html#avr"), and the same
	   applies for the default values of the options.

       -mgas-isr-prologues
	   Interrupt service routines (ISRs) may use the "__gcc_isr" pseudo
	   instruction supported by GNU Binutils.  If this option is on, the
	   feature can still be disabled for individual ISRs by means of the
	   AVR Function Attributes,,"no_gccisr" function attribute.  This
	   feature is activated per default if optimization is on (but not
	   with -Og, @pxref{Optimize Options}), and if GNU Binutils support
	   PR21683 ("https://sourceware.org/PR21683").

       -mint8
	   Assume "int" to be 8-bit integer.  This affects the sizes of all
	   types: a "char" is 1 byte, an "int" is 1 byte, a "long" is 2 bytes,
	   and "long long" is 4 bytes.	Please note that this option does not
	   conform to the C standards, but it results in smaller code size.

       -mmain-is-OS_task
	   Do not save registers in "main".  The effect is the same like
	   attaching attribute AVR Function Attributes,,"OS_task" to "main".
	   It is activated per default if optimization is on.

       -mno-interrupts
	   Generated code is not compatible with hardware interrupts.  Code
	   size is smaller.

       -mrelax
	   Try to replace "CALL" resp. "JMP" instruction by the shorter
	   "RCALL" resp. "RJMP" instruction if applicable.  Setting -mrelax
	   just adds the --mlink-relax option to the assembler's command line
	   and the --relax option to the linker's command line.

	   Jump relaxing is performed by the linker because jump offsets are
	   not known before code is located. Therefore, the assembler code
	   generated by the compiler is the same, but the instructions in the
	   executable may differ from instructions in the assembler code.

	   Relaxing must be turned on if linker stubs are needed, see the
	   section on "EIND" and linker stubs below.

       -mrodata-in-ram
       -mno-rodata-in-ram
	   Locate the ".rodata" sections for read-only data in RAM resp.  in
	   program memory.  For most devices, there is no choice and this
	   option acts rather like an assertion.

	   Since v14 and for the AVR64* and AVR128* devices, ".rodata" is
	   located in flash memory per default, provided the required GNU
	   Binutils support (PR31124 ("https://sourceware.org/PR31124")) is
	   available.  In that case, -mrodata-in-ram can be used to return to
	   the old layout with ".rodata" in RAM.

       -mstrict-X
	   Use address register "X" in a way proposed by the hardware.	This
	   means that "X" is only used in indirect, post-increment or pre-
	   decrement addressing.

	   Without this option, the "X" register may be used in the same way
	   as "Y" or "Z" which then is emulated by additional instructions.
	   For example, loading a value with "X+const" addressing with a small
	   non-negative "const < 64" to a register Rn is performed as

		   adiw r26, const   ; X += const
		   ld	<Rn>, X	       ; <Rn> = *X
		   sbiw r26, const   ; X -= const

       -mtiny-stack
	   Only change the lower 8 bits of the stack pointer.

       -mfract-convert-truncate
	   Allow to use truncation instead of rounding towards zero for
	   fractional fixed-point types.

       -nodevicelib
	   Don't link against AVR-LibC's device specific library "lib<mcu>.a".

       -nodevicespecs
	   Don't add -specs=device-specs/specs-mcu to the compiler driver's
	   command line.  The user takes responsibility for supplying the sub-
	   processes like compiler proper, assembler and linker with
	   appropriate command line options.  This means that the user has to
	   supply her private device specs file by means of -specs=path-to-
	   specs-file.	There is no more need for option -mmcu=mcu.

	   This option can also serve as a replacement for the older way of
	   specifying custom device-specs files that needed -B some-path to
	   point to a directory which contains a folder named "device-specs"
	   which contains a specs file named "specs-mcu", where mcu was
	   specified by -mmcu=mcu.

       -Waddr-space-convert
	   Warn about conversions between address spaces in the case where the
	   resulting address space is not contained in the incoming address
	   space.

       -Wmisspelled-isr
	   Warn if the ISR is misspelled, i.e. without __vector prefix.
	   Enabled by default.

       "EIND" and Devices with More Than 128 Ki Bytes of Flash

       Pointers in the implementation are 16 bits wide.	 The address of a
       function or label is represented as word address so that indirect jumps
       and calls can target any code address in the range of 64 Ki words.

       In order to facilitate indirect jump on devices with more than 128 Ki
       bytes of program memory space, there is a special function register
       called "EIND" that serves as most significant part of the target
       address when "EICALL" or "EIJMP" instructions are used.

       Indirect jumps and calls on these devices are handled as follows by the
       compiler and are subject to some limitations:

       *   The compiler never sets "EIND".

       *   The compiler uses "EIND" implicitly in "EICALL"/"EIJMP"
	   instructions or might read "EIND" directly in order to emulate an
	   indirect call/jump by means of a "RET" instruction.

       *   The compiler assumes that "EIND" never changes during the startup
	   code or during the application. In particular, "EIND" is not
	   saved/restored in function or interrupt service routine
	   prologue/epilogue.

       *   For indirect calls to functions and computed goto, the linker
	   generates stubs. Stubs are jump pads sometimes also called
	   trampolines. Thus, the indirect call/jump jumps to such a stub.
	   The stub contains a direct jump to the desired address.

       *   Linker relaxation must be turned on so that the linker generates
	   the stubs correctly in all situations. See the compiler option
	   -mrelax and the linker option --relax.  There are corner cases
	   where the linker is supposed to generate stubs but aborts without
	   relaxation and without a helpful error message.

       *   The default linker script is arranged for code with "EIND = 0".  If
	   code is supposed to work for a setup with "EIND != 0", a custom
	   linker script has to be used in order to place the sections whose
	   name start with ".trampolines" into the segment where "EIND" points
	   to.

       *   The startup code from libgcc never sets "EIND".  Notice that
	   startup code is a blend of code from libgcc and AVR-LibC.  For the
	   impact of AVR-LibC on "EIND", see the AVR-LibC user manual
	   ("https://www.nongnu.org/avr-libc/user-manual/").

       *   It is legitimate for user-specific startup code to set up "EIND"
	   early, for example by means of initialization code located in
	   section ".init3". Such code runs prior to general startup code that
	   initializes RAM and calls constructors, but after the bit of
	   startup code from AVR-LibC that sets "EIND" to the segment where
	   the vector table is located.

		   #include <avr/io.h>

		   static void
		   __attribute__((section(".init3"),naked,used,no_instrument_function))
		   init3_set_eind (void)
		   {
		     __asm volatile ("ldi r24,pm_hh8(__trampolines_start)\n\t"
				     "out %i0,r24" :: "n" (&EIND) : "r24","memory");
		   }

	   The "__trampolines_start" symbol is defined in the linker script.

       *   Stubs are generated automatically by the linker if the following
	   two conditions are met:

	   -<The address of a label is taken by means of the "gs" modifier>
	       (short for generate stubs) like so:

		       LDI r24, lo8(gs(<func>))
		       LDI r25, hi8(gs(<func>))

	   -<The final location of that label is in a code segment>
	       outside the segment where the stubs are located.

       *   The compiler emits such "gs" modifiers for code labels in the
	   following situations:

	   -<Taking address of a function or code label.>
	   -<Computed goto.>
	   -<If prologue-save function is used, see -mcall-prologues>
	       command-line option.

	   -<Switch/case dispatch tables. If you do not want such dispatch>
	       tables you can specify the -fno-jump-tables command-line
	       option.

	   -<C and C++ constructors/destructors called during
	   startup/shutdown.>
	   -<If the tools hit a gs() modifier explained above.>
       *   Jumping to non-symbolic addresses like so is not supported:

		   int main (void)
		   {
		       /* Call function at word address 0x2 */
		       return ((int(*)(void)) 0x2)();
		   }

	   Instead, a stub has to be set up, i.e. the function has to be
	   called through a symbol ("func_4" in the example):

		   int main (void)
		   {
		       extern int func_4 (void);

		       /* Call function at byte address 0x4 */
		       return func_4();
		   }

	   and the application be linked with -Wl,--defsym,func_4=0x4.
	   Alternatively, "func_4" can be defined in the linker script.

       Handling of the "RAMPD", "RAMPX", "RAMPY" and "RAMPZ" Special Function
       Registers

       Some AVR devices support memories larger than the 64 KiB range that can
       be accessed with 16-bit pointers.  To access memory locations outside
       this 64 KiB range, the content of a "RAMP" register is used as high
       part of the address: The "X", "Y", "Z" address register is concatenated
       with the "RAMPX", "RAMPY", "RAMPZ" special function register,
       respectively, to get a wide address. Similarly, "RAMPD" is used
       together with direct addressing.

       *   The startup code initializes the "RAMP" special function registers
	   with zero.

       *   If a AVR Named Address Spaces,named address space other than
	   generic or "__flash" is used, then "RAMPZ" is set as needed before
	   the operation.

       *   If the device supports RAM larger than 64 KiB and the compiler
	   needs to change "RAMPZ" to accomplish an operation, "RAMPZ" is
	   reset to zero after the operation.

       *   If the device comes with a specific "RAMP" register, the ISR
	   prologue/epilogue saves/restores that SFR and initializes it with
	   zero in case the ISR code might (implicitly) use it.

       *   RAM larger than 64 KiB is not supported by GCC for AVR targets.  If
	   you use inline assembler to read from locations outside the 16-bit
	   address range and change one of the "RAMP" registers, you must
	   reset it to zero after the access.

       AVR Built-in Macros

       GCC defines several built-in macros so that the user code can test for
       the presence or absence of features.  Almost any of the following
       built-in macros are deduced from device capabilities and thus triggered
       by the -mmcu= command-line option.

       For even more AVR-specific built-in macros see AVR Named Address Spaces
       and AVR Built-in Functions.

       "__AVR_ARCH__"
	   Build-in macro that resolves to a decimal number that identifies
	   the architecture and depends on the -mmcu=mcu option.  Possible
	   values are:

	   2, 25, 3, 31, 35, 4, 5, 51, 6

	   for mcu="avr2", "avr25", "avr3", "avr31", "avr35", "avr4", "avr5",
	   "avr51", "avr6",

	   respectively and

	   100, 102, 103, 104, 105, 106, 107

	   for mcu="avrtiny", "avrxmega2", "avrxmega3", "avrxmega4",
	   "avrxmega5", "avrxmega6", "avrxmega7", respectively.	 If mcu
	   specifies a device, this built-in macro is set accordingly. For
	   example, with -mmcu=atmega8 the macro is defined to 4.

       "__AVR_Device__"
	   Setting -mmcu=device defines this built-in macro which reflects the
	   device's name. For example, -mmcu=atmega8 defines the built-in
	   macro "__AVR_ATmega8__", -mmcu=attiny261a defines
	   "__AVR_ATtiny261A__", etc.

	   The built-in macros' names follow the scheme "__AVR_Device__" where
	   Device is the device name as from the AVR user manual. The
	   difference between Device in the built-in macro and device in
	   -mmcu=device is that the latter is always lowercase.

	   If device is not a device but only a core architecture like avr51,
	   this macro is not defined.

       "__AVR_DEVICE_NAME__"
	   Setting -mmcu=device defines this built-in macro to the device's
	   name. For example, with -mmcu=atmega8 the macro is defined to
	   "atmega8".

	   If device is not a device but only a core architecture like avr51,
	   this macro is not defined.

       "__AVR_XMEGA__"
	   The device / architecture belongs to the XMEGA family of devices.

       "__AVR_HAVE_ADIW__"
	   The device has the "ADIW" and "SBIW" instructions.

       "__AVR_HAVE_ELPM__"
	   The device has the "ELPM" instruction.

       "__AVR_HAVE_ELPMX__"
	   The device has the "ELPM Rn,Z" and "ELPM Rn,Z+" instructions.

       "__AVR_HAVE_LPMX__"
	   The device has the "LPM Rn,Z" and "LPM Rn,Z+" instructions.

       "__AVR_HAVE_MOVW__"
	   The device has the "MOVW" instruction to perform 16-bit register-
	   register moves.

       "__AVR_HAVE_MUL__"
	   The device has a hardware multiplier.

       "__AVR_HAVE_JMP_CALL__"
	   The device has the "JMP" and "CALL" instructions.  This is the case
	   for devices with more than 8 KiB of program memory.

       "__AVR_HAVE_EIJMP_EICALL__"
       "__AVR_3_BYTE_PC__"
	   The device has the "EIJMP" and "EICALL" instructions.  This is the
	   case for devices with more than 128 KiB of program memory.  This
	   also means that the program counter (PC) is 3 bytes wide.

       "__AVR_2_BYTE_PC__"
	   The program counter (PC) is 2 bytes wide. This is the case for
	   devices with up to 128 KiB of program memory.

       "__AVR_HAVE_8BIT_SP__"
       "__AVR_HAVE_16BIT_SP__"
	   The stack pointer (SP) register is treated as 8-bit respectively
	   16-bit register by the compiler.  The definition of these macros is
	   affected by -mtiny-stack.

       "__AVR_HAVE_SPH__"
       "__AVR_SP8__"
	   The device has the SPH (high part of stack pointer) special
	   function register or has an 8-bit stack pointer, respectively.  The
	   definition of these macros is affected by -mmcu= and in the cases
	   of -mmcu=avr2 and -mmcu=avr25 also by -msp8.

       "__AVR_HAVE_RAMPD__"
       "__AVR_HAVE_RAMPX__"
       "__AVR_HAVE_RAMPY__"
       "__AVR_HAVE_RAMPZ__"
	   The device has the "RAMPD", "RAMPX", "RAMPY", "RAMPZ" special
	   function register, respectively.

       "__NO_INTERRUPTS__"
	   This macro reflects the -mno-interrupts command-line option.

       "__AVR_ERRATA_SKIP__"
       "__AVR_ERRATA_SKIP_JMP_CALL__"
	   Some AVR devices (AT90S8515, ATmega103) must not skip 32-bit
	   instructions because of a hardware erratum.	Skip instructions are
	   "SBRS", "SBRC", "SBIS", "SBIC" and "CPSE".  The second macro is
	   only defined if "__AVR_HAVE_JMP_CALL__" is also set.

       "__AVR_ISA_RMW__"
	   The device has Read-Modify-Write instructions (XCH, LAC, LAS and
	   LAT).

       "__AVR_SFR_OFFSET__=offset"
	   Instructions that can address I/O special function registers
	   directly like "IN", "OUT", "SBI", etc. may use a different address
	   as if addressed by an instruction to access RAM like "LD" or "STS".
	   This offset depends on the device architecture and has to be
	   subtracted from the RAM address in order to get the respective I/O
	   address.

       "__AVR_SHORT_CALLS__"
	   The -mshort-calls command line option is set.

       "__AVR_PM_BASE_ADDRESS__=addr"
	   Some devices support reading from flash memory by means of "LD*"
	   instructions.  The flash memory is seen in the data address space
	   at an offset of "__AVR_PM_BASE_ADDRESS__".  If this macro is not
	   defined, this feature is not available.  If defined, the address
	   space is linear and there is no need to put ".rodata" into RAM.
	   This is handled by the default linker description file, and is
	   currently available for "avrtiny" and "avrxmega3".  Even more
	   convenient, there is no need to use address spaces like "__flash"
	   or features like attribute "progmem" and "pgm_read_*".

       "__AVR_HAVE_FLMAP__"
	   This macro is defined provided the following conditions are met:

	   *<The device has the "NVMCTRL_CTRLB.FLMAP" bitfield.>
	       This applies to the AVR64* and AVR128* devices.

	   *<It's not known at assembler-time which emulation will be used.>

	   This implies the compiler was configured with GNU Binutils that
	   implement PR31124 ("https://sourceware.org/PR31124").

       "__AVR_RODATA_IN_RAM__"
	   This macro is undefined when the code is compiled for a core
	   architecture.

	   When the code is compiled for a device, the macro is defined to 1
	   when the ".rodata" sections for read-only data is located in RAM;
	   and defined to 0, otherwise.

       "__WITH_AVRLIBC__"
	   The compiler is configured to be used together with AVR-Libc.  See
	   the --with-avrlibc configure option.

       "__HAVE_DOUBLE_MULTILIB__"
	   Defined if -mdouble= acts as a multilib option.

       "__HAVE_DOUBLE32__"
       "__HAVE_DOUBLE64__"
	   Defined if the compiler supports 32-bit double resp. 64-bit double.
	   The actual layout is specified by option -mdouble=.

       "__DEFAULT_DOUBLE__"
	   The size in bits of "double" if -mdouble= is not set.  To test the
	   layout of "double" in a program, use the built-in macro
	   "__SIZEOF_DOUBLE__".

       "__HAVE_LONG_DOUBLE32__"
       "__HAVE_LONG_DOUBLE64__"
       "__HAVE_LONG_DOUBLE_MULTILIB__"
       "__DEFAULT_LONG_DOUBLE__"
	   Same as above, but for "long double" instead of "double".

       "__WITH_DOUBLE_COMPARISON__"
	   Reflects the "--with-double-comparison={tristate|bool|libf7}"
	   configure option ("https://gcc.gnu.org/install/configure.html#avr")
	   and is defined to 2 or 3.

       "__WITH_LIBF7_LIBGCC__"
       "__WITH_LIBF7_MATH__"
       "__WITH_LIBF7_MATH_SYMBOLS__"
	   Reflects the "--with-libf7={libgcc|math|math-symbols}"
	   configure option
	   ("https://gcc.gnu.org/install/configure.html#avr").

       AVR Internal Options

       The following options are used internally by the compiler and to
       communicate between device specs files and the compiler proper. You
       don't need to set these options by hand, in particular they are not
       optimization options.  Using these options in the wrong way may lead to
       sub-optimal or wrong code.  They are documented for completeness, and
       in order to get a better understanding of device specs
       ("https://gcc.gnu.org/wiki/avr-gcc#spec-files") files.

       -mn-flash=num
	   Assume that the flash memory has a size of num times 64 KiB.	 This
	   determines which "__flashN" address spaces are available.

       -mflmap
	   The device has the "FLMAP" bit field located in special function
	   register "NVMCTRL_CTRLB".

       -mrmw
	   Assume that the device supports the Read-Modify-Write instructions
	   "XCH", "LAC", "LAS" and "LAT".

       -mshort-calls
	   Assume that "RJMP" and "RCALL" can target the whole program memory.
	   This option is used for multilib generation and selection for the
	   devices from architecture "avrxmega3".

       -mskip-bug
	   Generate code without skips ("CPSE", "SBRS", "SBRC", "SBIS",
	   "SBIC") over 32-bit instructions.

       -msp8
	   Treat the stack pointer register as an 8-bit register, i.e. assume
	   the high byte of the stack pointer is zero.	This option is used by
	   the compiler to select and build multilibs for architectures "avr2"
	   and "avr25".	 These architectures mix devices with and without
	   "SPH".

       Blackfin Options

       -mcpu=cpu[-sirevision]
	   Specifies the name of the target Blackfin processor.	 Currently,
	   cpu can be one of bf512, bf514, bf516, bf518, bf522, bf523, bf524,
	   bf525, bf526, bf527, bf531, bf532, bf533, bf534, bf536, bf537,
	   bf538, bf539, bf542, bf544, bf547, bf548, bf549, bf542m, bf544m,
	   bf547m, bf548m, bf549m, bf561, bf592.

	   The optional sirevision specifies the silicon revision of the
	   target Blackfin processor.  Any workarounds available for the
	   targeted silicon revision are enabled.  If sirevision is none, no
	   workarounds are enabled.  If sirevision is any, all workarounds for
	   the targeted processor are enabled.	The "__SILICON_REVISION__"
	   macro is defined to two hexadecimal digits representing the major
	   and minor numbers in the silicon revision.  If sirevision is none,
	   the "__SILICON_REVISION__" is not defined.  If sirevision is any,
	   the "__SILICON_REVISION__" is defined to be 0xffff.	If this
	   optional sirevision is not used, GCC assumes the latest known
	   silicon revision of the targeted Blackfin processor.

	   GCC defines a preprocessor macro for the specified cpu.  For the
	   bfin-elf toolchain, this option causes the hardware BSP provided by
	   libgloss to be linked in if -msim is not given.

	   Without this option, bf532 is used as the processor by default.

	   Note that support for bf561 is incomplete.  For bf561, only the
	   preprocessor macro is defined.

       -msim
	   Specifies that the program will be run on the simulator.  This
	   causes the simulator BSP provided by libgloss to be linked in.
	   This option has effect only for bfin-elf toolchain.	Certain other
	   options, such as -mid-shared-library and -mfdpic, imply -msim.

       -momit-leaf-frame-pointer
	   Don't keep the frame pointer in a register for leaf functions.
	   This avoids the instructions to save, set up and restore frame
	   pointers and makes an extra register available in leaf functions.

       -mspecld-anomaly
	   When enabled, the compiler ensures that the generated code does not
	   contain speculative loads after jump instructions. If this option
	   is used, "__WORKAROUND_SPECULATIVE_LOADS" is defined.

       -mno-specld-anomaly
	   Don't generate extra code to prevent speculative loads from
	   occurring.

       -mcsync-anomaly
	   When enabled, the compiler ensures that the generated code does not
	   contain CSYNC or SSYNC instructions too soon after conditional
	   branches.  If this option is used, "__WORKAROUND_SPECULATIVE_SYNCS"
	   is defined.

       -mno-csync-anomaly
	   Don't generate extra code to prevent CSYNC or SSYNC instructions
	   from occurring too soon after a conditional branch.

       -mlow64k
	   When enabled, the compiler is free to take advantage of the
	   knowledge that the entire program fits into the low 64k of memory.

       -mno-low64k
	   Assume that the program is arbitrarily large.  This is the default.

       -mstack-check-l1
	   Do stack checking using information placed into L1 scratchpad
	   memory by the uClinux kernel.

       -mid-shared-library
	   Generate code that supports shared libraries via the library ID
	   method.  This allows for execute in place and shared libraries in
	   an environment without virtual memory management.  This option
	   implies -fPIC.  With a bfin-elf target, this option implies -msim.

       -mno-id-shared-library
	   Generate code that doesn't assume ID-based shared libraries are
	   being used.	This is the default.

       -mleaf-id-shared-library
	   Generate code that supports shared libraries via the library ID
	   method, but assumes that this library or executable won't link
	   against any other ID shared libraries.  That allows the compiler to
	   use faster code for jumps and calls.

       -mno-leaf-id-shared-library
	   Do not assume that the code being compiled won't link against any
	   ID shared libraries.	 Slower code is generated for jump and call
	   insns.

       -mshared-library-id=n
	   Specifies the identification number of the ID-based shared library
	   being compiled.  Specifying a value of 0 generates more compact
	   code; specifying other values forces the allocation of that number
	   to the current library but is no more space- or time-efficient than
	   omitting this option.

       -msep-data
	   Generate code that allows the data segment to be located in a
	   different area of memory from the text segment.  This allows for
	   execute in place in an environment without virtual memory
	   management by eliminating relocations against the text section.

       -mno-sep-data
	   Generate code that assumes that the data segment follows the text
	   segment.  This is the default.

       -mlong-calls
       -mno-long-calls
	   Tells the compiler to perform function calls by first loading the
	   address of the function into a register and then performing a
	   subroutine call on this register.  This switch is needed if the
	   target function lies outside of the 24-bit addressing range of the
	   offset-based version of subroutine call instruction.

	   This feature is not enabled by default.  Specifying -mno-long-calls
	   restores the default behavior.  Note these switches have no effect
	   on how the compiler generates code to handle function calls via
	   function pointers.

       -mfast-fp
	   Link with the fast floating-point library. This library relaxes
	   some of the IEEE floating-point standard's rules for checking
	   inputs against Not-a-Number (NAN), in the interest of performance.

       -minline-plt
	   Enable inlining of PLT entries in function calls to functions that
	   are not known to bind locally.  It has no effect without -mfdpic.

       -mmulticore
	   Build a standalone application for multicore Blackfin processors.
	   This option causes proper start files and link scripts supporting
	   multicore to be used, and defines the macro "__BFIN_MULTICORE".  It
	   can only be used with -mcpu=bf561[-sirevision].

	   This option can be used with -mcorea or -mcoreb, which selects the
	   one-application-per-core programming model.	Without -mcorea or
	   -mcoreb, the single-application/dual-core programming model is
	   used. In this model, the main function of Core B should be named as
	   "coreb_main".

	   If this option is not used, the single-core application programming
	   model is used.

       -mcorea
	   Build a standalone application for Core A of BF561 when using the
	   one-application-per-core programming model. Proper start files and
	   link scripts are used to support Core A, and the macro
	   "__BFIN_COREA" is defined.  This option can only be used in
	   conjunction with -mmulticore.

       -mcoreb
	   Build a standalone application for Core B of BF561 when using the
	   one-application-per-core programming model. Proper start files and
	   link scripts are used to support Core B, and the macro
	   "__BFIN_COREB" is defined. When this option is used, "coreb_main"
	   should be used instead of "main".  This option can only be used in
	   conjunction with -mmulticore.

       -msdram
	   Build a standalone application for SDRAM. Proper start files and
	   link scripts are used to put the application into SDRAM, and the
	   macro "__BFIN_SDRAM" is defined.  The loader should initialize
	   SDRAM before loading the application.

       -micplb
	   Assume that ICPLBs are enabled at run time.	This has an effect on
	   certain anomaly workarounds.	 For Linux targets, the default is to
	   assume ICPLBs are enabled; for standalone applications the default
	   is off.

       C6X Options

       -march=name
	   This specifies the name of the target architecture.	GCC uses this
	   name to determine what kind of instructions it can emit when
	   generating assembly code.  Permissible names are: c62x, c64x,
	   c64x+, c67x, c67x+, c674x.

       -mbig-endian
	   Generate code for a big-endian target.

       -mlittle-endian
	   Generate code for a little-endian target.  This is the default.

       -msim
	   Choose startup files and linker script suitable for the simulator.

       -msdata=default
	   Put small global and static data in the ".neardata" section, which
	   is pointed to by register "B14".  Put small uninitialized global
	   and static data in the ".bss" section, which is adjacent to the
	   ".neardata" section.	 Put small read-only data into the ".rodata"
	   section.  The corresponding sections used for large pieces of data
	   are ".fardata", ".far" and ".const".

       -msdata=all
	   Put all data, not just small objects, into the sections reserved
	   for small data, and use addressing relative to the "B14" register
	   to access them.

       -msdata=none
	   Make no use of the sections reserved for small data, and use
	   absolute addresses to access all data.  Put all initialized global
	   and static data in the ".fardata" section, and all uninitialized
	   data in the ".far" section.	Put all constant data into the
	   ".const" section.

       CRIS Options

       These options are defined specifically for the CRIS ports.

       -march=architecture-type
       -mcpu=architecture-type
	   Generate code for the specified architecture.  The choices for
	   architecture-type are v3, v8 and v10 for respectively ETRAX 4,
	   ETRAX 100, and ETRAX 100 LX.	 Default is v0.

       -mtune=architecture-type
	   Tune to architecture-type everything applicable about the generated
	   code, except for the ABI and the set of available instructions.
	   The choices for architecture-type are the same as for
	   -march=architecture-type.

       -mmax-stack-frame=n
	   Warn when the stack frame of a function exceeds n bytes.

       -metrax4
       -metrax100
	   The options -metrax4 and -metrax100 are synonyms for -march=v3 and
	   -march=v8 respectively.

       -mmul-bug-workaround
       -mno-mul-bug-workaround
	   Work around a bug in the "muls" and "mulu" instructions for CPU
	   models where it applies.  This option is disabled by default.

       -mpdebug
	   Enable CRIS-specific verbose debug-related information in the
	   assembly code.  This option also has the effect of turning off the
	   #NO_APP formatted-code indicator to the assembler at the beginning
	   of the assembly file.

       -mcc-init
	   Do not use condition-code results from previous instruction; always
	   emit compare and test instructions before use of condition codes.

       -mno-side-effects
	   Do not emit instructions with side effects in addressing modes
	   other than post-increment.

       -mstack-align
       -mno-stack-align
       -mdata-align
       -mno-data-align
       -mconst-align
       -mno-const-align
	   These options (no- options) arrange (eliminate arrangements) for
	   the stack frame, individual data and constants to be aligned for
	   the maximum single data access size for the chosen CPU model.  The
	   default is to arrange for 32-bit alignment.	ABI details such as
	   structure layout are not affected by these options.

       -m32-bit
       -m16-bit
       -m8-bit
	   Similar to the stack- data- and const-align options above, these
	   options arrange for stack frame, writable data and constants to all
	   be 32-bit, 16-bit or 8-bit aligned.	The default is 32-bit
	   alignment.

       -mno-prologue-epilogue
       -mprologue-epilogue
	   With -mno-prologue-epilogue, the normal function prologue and
	   epilogue which set up the stack frame are omitted and no return
	   instructions or return sequences are generated in the code.	Use
	   this option only together with visual inspection of the compiled
	   code: no warnings or errors are generated when call-saved registers
	   must be saved, or storage for local variables needs to be
	   allocated.

       -melf
	   Legacy no-op option.

       -sim
	   This option arranges to link with input-output functions from a
	   simulator library.  Code, initialized data and zero-initialized
	   data are allocated consecutively.

       -sim2
	   Like -sim, but pass linker options to locate initialized data at
	   0x40000000 and zero-initialized data at 0x80000000.

       C-SKY Options

       GCC supports these options when compiling for C-SKY V2 processors.

       -march=arch
	   Specify the C-SKY target architecture.  Valid values for arch are:
	   ck801, ck802, ck803, ck807, and ck810.  The default is ck810.

       -mcpu=cpu
	   Specify the C-SKY target processor.	Valid values for cpu are:
	   ck801, ck801t, ck802, ck802t, ck802j, ck803, ck803h, ck803t,
	   ck803ht, ck803f, ck803fh, ck803e, ck803eh, ck803et, ck803eht,
	   ck803ef, ck803efh, ck803ft, ck803eft, ck803efht, ck803r1, ck803hr1,
	   ck803tr1, ck803htr1, ck803fr1, ck803fhr1, ck803er1, ck803ehr1,
	   ck803etr1, ck803ehtr1, ck803efr1, ck803efhr1, ck803ftr1,
	   ck803eftr1, ck803efhtr1, ck803s, ck803st, ck803se, ck803sf,
	   ck803sef, ck803seft, ck807e, ck807ef, ck807, ck807f, ck810e,
	   ck810et, ck810ef, ck810eft, ck810, ck810v, ck810f, ck810t, ck810fv,
	   ck810tv, ck810ft, and ck810ftv.

       -mbig-endian
       -EB
       -mlittle-endian
       -EL Select big- or little-endian code.  The default is little-endian.

       -mfloat-abi=name
	   Specifies which floating-point ABI to use.  Permissible values are:
	   soft, softfp and hard.

	   Specifying soft causes GCC to generate output containing library
	   calls for floating-point operations.	 softfp allows the generation
	   of code using hardware floating-point instructions, but still uses
	   the soft-float calling conventions.	hard allows generation of
	   floating-point instructions and uses FPU-specific calling
	   conventions.

	   The default depends on the specific target configuration.  Note
	   that the hard-float and soft-float ABIs are not link-compatible;
	   you must compile your entire program with the same ABI, and link
	   with a compatible set of libraries.

       -mhard-float
       -msoft-float
	   Select hardware or software floating-point implementations.	The
	   default is soft float.

       -mdouble-float
       -mno-double-float
	   When -mhard-float is in effect, enable generation of double-
	   precision float instructions.  This is the default except when
	   compiling for CK803.

       -mfdivdu
       -mno-fdivdu
	   When -mhard-float is in effect, enable generation of "frecipd",
	   "fsqrtd", and "fdivd" instructions.	This is the default except
	   when compiling for CK803.

       -mfpu=fpu
	   Select the floating-point processor.	 This option can only be used
	   with -mhard-float.  Values for fpu are fpv2_sf (equivalent to
	   -mno-double-float -mno-fdivdu), fpv2 (-mdouble-float -mno-divdu),
	   and fpv2_divd (-mdouble-float -mdivdu).

       -melrw
       -mno-elrw
	   Enable the extended "lrw" instruction.  This option defaults to on
	   for CK801 and off otherwise.

       -mistack
       -mno-istack
	   Enable interrupt stack instructions; the default is off.

	   The -mistack option is required to handle the "interrupt" and "isr"
	   function attributes.

       -mmp
	   Enable multiprocessor instructions; the default is off.

       -mcp
	   Enable coprocessor instructions; the default is off.

       -mcache
	   Enable coprocessor instructions; the default is off.

       -msecurity
	   Enable C-SKY security instructions; the default is off.

       -mtrust
	   Enable C-SKY trust instructions; the default is off.

       -mdsp
       -medsp
       -mvdsp
	   Enable C-SKY DSP, Enhanced DSP, or Vector DSP instructions,
	   respectively.  All of these options default to off.

       -mdiv
       -mno-div
	   Generate divide instructions.  Default is off.

       -msmart
       -mno-smart
	   Generate code for Smart Mode, using only registers numbered 0-7 to
	   allow use of 16-bit instructions.  This option is ignored for CK801
	   where this is the required behavior, and it defaults to on for
	   CK802.  For other targets, the default is off.

       -mhigh-registers
       -mno-high-registers
	   Generate code using the high registers numbered 16-31.  This option
	   is not supported on CK801, CK802, or CK803, and is enabled by
	   default for other processors.

       -manchor
       -mno-anchor
	   Generate code using global anchor symbol addresses.

       -mpushpop
       -mno-pushpop
	   Generate code using "push" and "pop" instructions.  This option
	   defaults to on.

       -mmultiple-stld
       -mstm
       -mno-multiple-stld
       -mno-stm
	   Generate code using "stm" and "ldm" instructions.  This option
	   isn't supported on CK801 but is enabled by default on other
	   processors.

       -mconstpool
       -mno-constpool
	   Create constant pools in the compiler instead of deferring it to
	   the assembler.  This option is the default and required for correct
	   code generation on CK801 and CK802, and is optional on other
	   processors.

       -mstack-size
       -mno-stack-size
	   Emit ".stack_size" directives for each function in the assembly
	   output.  This option defaults to off.

       -mccrt
       -mno-ccrt
	   Generate code for the C-SKY compiler runtime instead of libgcc.
	   This option defaults to off.

       -mbranch-cost=n
	   Set the branch costs to roughly "n" instructions.  The default is
	   1.

       -msched-prolog
       -mno-sched-prolog
	   Permit scheduling of function prologue and epilogue sequences.
	   Using this option can result in code that is not compliant with the
	   C-SKY V2 ABI prologue requirements and that cannot be debugged or
	   backtraced.	It is disabled by default.

       -msim
	   Links the library libsemi.a which is in compatible with simulator.
	   Applicable to ELF compiler only.

       Darwin Options

       These options are defined for all architectures running the Darwin
       operating system.

       FSF GCC on Darwin does not create "fat" object files; it creates an
       object file for the single architecture that GCC was built to target.
       Apple's GCC on Darwin does create "fat" files if multiple -arch options
       are used; it does so by running the compiler or linker multiple times
       and joining the results together with lipo.

       The subtype of the file created (like ppc7400 or ppc970 or i686) is
       determined by the flags that specify the ISA that GCC is targeting,
       like -mcpu or -march.  The -force_cpusubtype_ALL option can be used to
       override this.

       The Darwin tools vary in their behavior when presented with an ISA
       mismatch.  The assembler, as, only permits instructions to be used that
       are valid for the subtype of the file it is generating, so you cannot
       put 64-bit instructions in a ppc750 object file.	 The linker for shared
       libraries, /usr/bin/libtool, fails and prints an error if asked to
       create a shared library with a less restrictive subtype than its input
       files (for instance, trying to put a ppc970 object file in a ppc7400
       library).  The linker for executables, ld, quietly gives the executable
       the most restrictive subtype of any of its input files.

       -Fdir
	   Add the framework directory dir to the head of the list of
	   directories to be searched for header files.	 These directories are
	   interleaved with those specified by -I options and are scanned in a
	   left-to-right order.

	   A framework directory is a directory with frameworks in it.	A
	   framework is a directory with a Headers and/or PrivateHeaders
	   directory contained directly in it that ends in .framework.	The
	   name of a framework is the name of this directory excluding the
	   .framework.	Headers associated with the framework are found in one
	   of those two directories, with Headers being searched first.	 A
	   subframework is a framework directory that is in a framework's
	   Frameworks directory.  Includes of subframework headers can only
	   appear in a header of a framework that contains the subframework,
	   or in a sibling subframework header.	 Two subframeworks are
	   siblings if they occur in the same framework.  A subframework
	   should not have the same name as a framework; a warning is issued
	   if this is violated.	 Currently a subframework cannot have
	   subframeworks; in the future, the mechanism may be extended to
	   support this.  The standard frameworks can be found in
	   /System/Library/Frameworks and /Library/Frameworks.	An example
	   include looks like "#include <Framework/header.h>", where Framework
	   denotes the name of the framework and header.h is found in the
	   PrivateHeaders or Headers directory.

       -iframeworkdir
	   Like -F except the directory is a treated as a system directory.
	   The main difference between this -iframework and -F is that with
	   -iframework the compiler does not warn about constructs contained
	   within header files found via dir.  This option is valid only for
	   the C family of languages.

       -gused
	   Emit debugging information for symbols that are used.  For stabs
	   debugging format, this enables -feliminate-unused-debug-symbols.
	   This is by default ON.

       -gfull
	   Emit debugging information for all symbols and types.

       -fconstant-cfstrings
	   The -fconstant-cfstrings is an alias for -mconstant-cfstrings.

       -mconstant-cfstrings
	   When the NeXT runtime is being used (the default on these systems),
	   override any -fconstant-string-class setting and cause "@"...""
	   literals to be laid out as constant CoreFoundation strings.

       -mmacosx-version-min=version
	   The earliest version of MacOS X that this executable will run on is
	   version.  Typical values supported for version include 12, 10.12,
	   and 10.5.8.

	   If the compiler was built to use the system's headers by default,
	   then the default for this option is the system version on which the
	   compiler is running, otherwise the default is to make choices that
	   are compatible with as many systems and code bases as possible.

       -mkernel
	   Enable kernel development mode.  The -mkernel option sets -static,
	   -fno-common, -fno-use-cxa-atexit, -fno-exceptions,
	   -fno-non-call-exceptions, -fapple-kext, -fno-weak and -fno-rtti
	   where applicable.  This mode also sets -mno-altivec, -msoft-float,
	   -fno-builtin and -mlong-branch for PowerPC targets.

       -mone-byte-bool
	   Override the defaults for "bool" so that "sizeof(bool)==1".	By
	   default sizeof(bool) is 4 when compiling for Darwin/PowerPC and 1
	   when compiling for Darwin/x86, so this option has no effect on x86.

	   Warning: The -mone-byte-bool switch causes GCC to generate code
	   that is not binary compatible with code generated without that
	   switch.  Using this switch may require recompiling all other
	   modules in a program, including system libraries.  Use this switch
	   to conform to a non-default data model.

       -mfix-and-continue
       -ffix-and-continue
       -findirect-data
	   Generate code suitable for fast turnaround development, such as to
	   allow GDB to dynamically load .o files into already-running
	   programs.  -findirect-data and -ffix-and-continue are provided for
	   backwards compatibility.

       -all_load
	   Loads all members of static archive libraries.  See man ld(1) for
	   more information.

       -arch_errors_fatal
	   Cause the errors having to do with files that have the wrong
	   architecture to be fatal.

       -bind_at_load
	   Causes the output file to be marked such that the dynamic linker
	   will bind all undefined references when the file is loaded or
	   launched.

       -bundle
	   Produce a Mach-o bundle format file.	 See man ld(1) for more
	   information.

       -bundle_loader executable
	   This option specifies the executable that will load the build
	   output file being linked.  See man ld(1) for more information.

       -dynamiclib
	   When passed this option, GCC produces a dynamic library instead of
	   an executable when linking, using the Darwin libtool command.

       -force_cpusubtype_ALL
	   This causes GCC's output file to have the ALL subtype, instead of
	   one controlled by the -mcpu or -march option.

       -nodefaultrpaths
	   Do not add default run paths for the compiler library directories
	   to executables, modules or dynamic libraries. On macOS 10.5 and
	   later, the embedded runpath is added by default unless the user
	   adds -nodefaultrpaths to the link line. Run paths are needed (and
	   therefore enforced) to build on macOS version 10.11 or later.

       -allowable_client  client_name
       -client_name
       -compatibility_version
       -current_version
       -dead_strip
       -dependency-file
       -dylib_file
       -dylinker_install_name
       -dynamic
       -exported_symbols_list
       -filelist
       -flat_namespace
       -force_flat_namespace
       -headerpad_max_install_names
       -image_base
       -init
       -install_name
       -keep_private_externs
       -multi_module
       -multiply_defined
       -multiply_defined_unused
       -noall_load
       -no_dead_strip_inits_and_terms
       -nofixprebinding
       -nomultidefs
       -noprebind
       -noseglinkedit
       -pagezero_size
       -prebind
       -prebind_all_twolevel_modules
       -private_bundle
       -read_only_relocs
       -sectalign
       -sectobjectsymbols
       -whyload
       -seg1addr
       -sectcreate
       -sectobjectsymbols
       -sectorder
       -segaddr
       -segs_read_only_addr
       -segs_read_write_addr
       -seg_addr_table
       -seg_addr_table_filename
       -seglinkedit
       -segprot
       -segs_read_only_addr
       -segs_read_write_addr
       -single_module
       -static
       -sub_library
       -sub_umbrella
       -twolevel_namespace
       -umbrella
       -undefined
       -unexported_symbols_list
       -weak_reference_mismatches
       -whatsloaded
	   These options are passed to the Darwin linker.  The Darwin linker
	   man page describes them in detail.

       DEC Alpha Options

       These -m options are defined for the DEC Alpha implementations:

       -mno-soft-float
       -msoft-float
	   Use (do not use) the hardware floating-point instructions for
	   floating-point operations.  When -msoft-float is specified,
	   functions in libgcc.a are used to perform floating-point
	   operations.	Unless they are replaced by routines that emulate the
	   floating-point operations, or compiled in such a way as to call
	   such emulations routines, these routines issue floating-point
	   operations.	 If you are compiling for an Alpha without floating-
	   point operations, you must ensure that the library is built so as
	   not to call them.

	   Note that Alpha implementations without floating-point operations
	   are required to have floating-point registers.

       -mfp-reg
       -mno-fp-regs
	   Generate code that uses (does not use) the floating-point register
	   set.	 -mno-fp-regs implies -msoft-float.  If the floating-point
	   register set is not used, floating-point operands are passed in
	   integer registers as if they were integers and floating-point
	   results are passed in $0 instead of $f0.  This is a non-standard
	   calling sequence, so any function with a floating-point argument or
	   return value called by code compiled with -mno-fp-regs must also be
	   compiled with that option.

	   A typical use of this option is building a kernel that does not
	   use, and hence need not save and restore, any floating-point
	   registers.

       -mieee
	   The Alpha architecture implements floating-point hardware optimized
	   for maximum performance.  It is mostly compliant with the IEEE
	   floating-point standard.  However, for full compliance, software
	   assistance is required.  This option generates code fully IEEE-
	   compliant code except that the inexact-flag is not maintained (see
	   below).  If this option is turned on, the preprocessor macro
	   "_IEEE_FP" is defined during compilation.  The resulting code is
	   less efficient but is able to correctly support denormalized
	   numbers and exceptional IEEE values such as not-a-number and
	   plus/minus infinity.	 Other Alpha compilers call this option
	   -ieee_with_no_inexact.

       -mieee-with-inexact
	   This is like -mieee except the generated code also maintains the
	   IEEE inexact-flag.  Turning on this option causes the generated
	   code to implement fully-compliant IEEE math.	 In addition to
	   "_IEEE_FP", "_IEEE_FP_EXACT" is defined as a preprocessor macro.
	   On some Alpha implementations the resulting code may execute
	   significantly slower than the code generated by default.  Since
	   there is very little code that depends on the inexact-flag, you
	   should normally not specify this option.  Other Alpha compilers
	   call this option -ieee_with_inexact.

       -mfp-trap-mode=trap-mode
	   This option controls what floating-point related traps are enabled.
	   Other Alpha compilers call this option -fptm trap-mode.  The trap
	   mode can be set to one of four values:

	   n   This is the default (normal) setting.  The only traps that are
	       enabled are the ones that cannot be disabled in software (e.g.,
	       division by zero trap).

	   u   In addition to the traps enabled by n, underflow traps are
	       enabled as well.

	   su  Like u, but the instructions are marked to be safe for software
	       completion (see Alpha architecture manual for details).

	   sui Like su, but inexact traps are enabled as well.

       -mfp-rounding-mode=rounding-mode
	   Selects the IEEE rounding mode.  Other Alpha compilers call this
	   option -fprm rounding-mode.	The rounding-mode can be one of:

	   n   Normal IEEE rounding mode.  Floating-point numbers are rounded
	       towards the nearest machine number or towards the even machine
	       number in case of a tie.

	   m   Round towards minus infinity.

	   c   Chopped rounding mode.  Floating-point numbers are rounded
	       towards zero.

	   d   Dynamic rounding mode.  A field in the floating-point control
	       register (fpcr, see Alpha architecture reference manual)
	       controls the rounding mode in effect.  The C library
	       initializes this register for rounding towards plus infinity.
	       Thus, unless your program modifies the fpcr, d corresponds to
	       round towards plus infinity.

       -mtrap-precision=trap-precision
	   In the Alpha architecture, floating-point traps are imprecise.
	   This means without software assistance it is impossible to recover
	   from a floating trap and program execution normally needs to be
	   terminated.	GCC can generate code that can assist operating system
	   trap handlers in determining the exact location that caused a
	   floating-point trap.	 Depending on the requirements of an
	   application, different levels of precisions can be selected:

	   p   Program precision.  This option is the default and means a trap
	       handler can only identify which program caused a floating-point
	       exception.

	   f   Function precision.  The trap handler can determine the
	       function that caused a floating-point exception.

	   i   Instruction precision.  The trap handler can determine the
	       exact instruction that caused a floating-point exception.

	   Other Alpha compilers provide the equivalent options called
	   -scope_safe and -resumption_safe.

       -mieee-conformant
	   This option marks the generated code as IEEE conformant.  You must
	   not use this option unless you also specify -mtrap-precision=i and
	   either -mfp-trap-mode=su or -mfp-trap-mode=sui.  Its only effect is
	   to emit the line .eflag 48 in the function prologue of the
	   generated assembly file.

       -mbuild-constants
	   Normally GCC examines a 32- or 64-bit integer constant to see if it
	   can construct it from smaller constants in two or three
	   instructions.  If it cannot, it outputs the constant as a literal
	   and generates code to load it from the data segment at run time.

	   Use this option to require GCC to construct all integer constants
	   using code, even if it takes more instructions (the maximum is
	   six).

	   You typically use this option to build a shared library dynamic
	   loader.  Itself a shared library, it must relocate itself in memory
	   before it can find the variables and constants in its own data
	   segment.

       -mbwx
       -mno-bwx
       -mcix
       -mno-cix
       -mfix
       -mno-fix
       -mmax
       -mno-max
	   Indicate whether GCC should generate code to use the optional BWX,
	   CIX, FIX and MAX instruction sets.  The default is to use the
	   instruction sets supported by the CPU type specified via -mcpu=
	   option or that of the CPU on which GCC was built if none is
	   specified.

       -mfloat-vax
       -mfloat-ieee
	   Generate code that uses (does not use) VAX F and G floating-point
	   arithmetic instead of IEEE single and double precision.

       -mexplicit-relocs
       -mno-explicit-relocs
	   Older Alpha assemblers provided no way to generate symbol
	   relocations except via assembler macros.  Use of these macros does
	   not allow optimal instruction scheduling.  GNU binutils as of
	   version 2.12 supports a new syntax that allows the compiler to
	   explicitly mark which relocations should apply to which
	   instructions.  This option is mostly useful for debugging, as GCC
	   detects the capabilities of the assembler when it is built and sets
	   the default accordingly.

       -msmall-data
       -mlarge-data
	   When -mexplicit-relocs is in effect, static data is accessed via
	   gp-relative relocations.  When -msmall-data is used, objects 8
	   bytes long or smaller are placed in a small data area (the ".sdata"
	   and ".sbss" sections) and are accessed via 16-bit relocations off
	   of the $gp register.	 This limits the size of the small data area
	   to 64KB, but allows the variables to be directly accessed via a
	   single instruction.

	   The default is -mlarge-data.	 With this option the data area is
	   limited to just below 2GB.  Programs that require more than 2GB of
	   data must use "malloc" or "mmap" to allocate the data in the heap
	   instead of in the program's data segment.

	   When generating code for shared libraries, -fpic implies
	   -msmall-data and -fPIC implies -mlarge-data.

       -msmall-text
       -mlarge-text
	   When -msmall-text is used, the compiler assumes that the code of
	   the entire program (or shared library) fits in 4MB, and is thus
	   reachable with a branch instruction.	 When -msmall-data is used,
	   the compiler can assume that all local symbols share the same $gp
	   value, and thus reduce the number of instructions required for a
	   function call from 4 to 1.

	   The default is -mlarge-text.

       -mcpu=cpu_type
	   Set the instruction set and instruction scheduling parameters for
	   machine type cpu_type.  You can specify either the EV style name or
	   the corresponding chip number.  GCC supports scheduling parameters
	   for the EV4, EV5 and EV6 family of processors and chooses the
	   default values for the instruction set from the processor you
	   specify.  If you do not specify a processor type, GCC defaults to
	   the processor on which the compiler was built.

	   Supported values for cpu_type are

	   ev4
	   ev45
	   21064
	       Schedules as an EV4 and has no instruction set extensions.

	   ev5
	   21164
	       Schedules as an EV5 and has no instruction set extensions.

	   ev56
	   21164a
	       Schedules as an EV5 and supports the BWX extension.

	   pca56
	   21164pc
	   21164PC
	       Schedules as an EV5 and supports the BWX and MAX extensions.

	   ev6
	   21264
	       Schedules as an EV6 and supports the BWX, FIX, and MAX
	       extensions.

	   ev67
	   21264a
	       Schedules as an EV6 and supports the BWX, CIX, FIX, and MAX
	       extensions.

	   Native toolchains also support the value native, which selects the
	   best architecture option for the host processor.  -mcpu=native has
	   no effect if GCC does not recognize the processor.

       -mtune=cpu_type
	   Set only the instruction scheduling parameters for machine type
	   cpu_type.  The instruction set is not changed.

	   Native toolchains also support the value native, which selects the
	   best architecture option for the host processor.  -mtune=native has
	   no effect if GCC does not recognize the processor.

       -mmemory-latency=time
	   Sets the latency the scheduler should assume for typical memory
	   references as seen by the application.  This number is highly
	   dependent on the memory access patterns used by the application and
	   the size of the external cache on the machine.

	   Valid options for time are

	   number
	       A decimal number representing clock cycles.

	   L1
	   L2
	   L3
	   main
	       The compiler contains estimates of the number of clock cycles
	       for "typical" EV4 & EV5 hardware for the Level 1, 2 & 3 caches
	       (also called Dcache, Scache, and Bcache), as well as to main
	       memory.	Note that L3 is only valid for EV5.

       eBPF Options

       -mframe-limit=bytes
	   This specifies the hard limit for frame sizes, in bytes.
	   Currently, the value that can be specified should be less than or
	   equal to 32767.  Defaults to whatever limit is imposed by the
	   version of the Linux kernel targeted.

       -mbig-endian
	   Generate code for a big-endian target.

       -mlittle-endian
	   Generate code for a little-endian target.  This is the default.

       -mjmpext
       -mno-jmpext
	   Enable or disable generation of extra conditional-branch
	   instructions.  Enabled for CPU v2 and above.

       -mjmp32
       -mno-jmp32
	   Enable or disable generation of 32-bit jump instructions.  Enabled
	   for CPU v3 and above.

       -malu32
       -mno-alu32
	   Enable or disable generation of 32-bit ALU instructions.  Enabled
	   for CPU v3 and above.

       -mv3-atomics
       -mno-v3-atomics
	   Enable or disable instructions for general atomic operations
	   introduced in CPU v3.  Enabled for CPU v3 and above.

       -mbswap
       -mno-bswap
	   Enable or disable byte swap instructions.  Enabled for CPU v4 and
	   above.

       -msdiv
       -mno-sdiv
	   Enable or disable signed division and modulus instructions.
	   Enabled for CPU v4 and above.

       -msmov
       -mno-smov
	   Enable or disable sign-extending move and memory load instructions.
	   Enabled for CPU v4 and above.

       -mcpu=version
	   This specifies which version of the eBPF ISA to target. Newer
	   versions may not be supported by all kernels. The default is v4.

	   Supported values for version are:

	   v1  The first stable eBPF ISA with no special features or
	       extensions.

	   v2  Supports the jump extensions, as in -mjmpext.

	   v3  All features of v2, plus:

	       -<32-bit jump operations, as in -mjmp32>
	       -<32-bit ALU operations, as in -malu32>
	       -<general atomic operations, as in -mv3-atomics>
	   v4  All features of v3, plus:

	       -<Byte swap instructions, as in -mbswap>
	       -<Signed division and modulus instructions, as in -msdiv>
	       -<Sign-extending move and memory load instructions, as in
	       -msmov>
       -mco-re
	   Enable BPF Compile Once - Run Everywhere (CO-RE) support. Requires
	   and is implied by -gbtf.

       -mno-co-re
	   Disable BPF Compile Once - Run Everywhere (CO-RE) support. BPF CO-
	   RE support is enabled by default when generating BTF debug
	   information for the BPF target.

       -mxbpf
	   Generate code for an expanded version of BPF, which relaxes some of
	   the restrictions imposed by the BPF architecture:

	   -<Save and restore callee-saved registers at function entry and>
	       exit, respectively.

       -masm=dialect
	   Outputs assembly instructions using eBPF selected dialect.  The
	   default is pseudoc.

	   Supported values for dialect are:

	   normal
	       Outputs normal assembly dialect.

	   pseudoc
	       Outputs pseudo-c assembly dialect.

       -minline-memops-threshold=bytes
	   Specifies a size threshold in bytes at or below which memmove,
	   memcpy and memset shall always be expanded inline.  Operations
	   dealing with sizes larger than this threshold would have to be
	   implemented using a library call instead of being expanded inline,
	   but since BPF doesn't allow libcalls, exceeding this threshold
	   results in a compile-time error.  The default is 1024 bytes.

       FR30 Options

       These options are defined specifically for the FR30 port.

       -msmall-model
	   Use the small address space model.  This can produce smaller code,
	   but it does assume that all symbolic values and addresses fit into
	   a 20-bit range.

       -mno-lsim
	   Assume that runtime support has been provided and so there is no
	   need to include the simulator library (libsim.a) on the linker
	   command line.

       FT32 Options

       These options are defined specifically for the FT32 port.

       -msim
	   Specifies that the program will be run on the simulator.  This
	   causes an alternate runtime startup and library to be linked.  You
	   must not use this option when generating programs that will run on
	   real hardware; you must provide your own runtime library for
	   whatever I/O functions are needed.

       -mlra
	   Enable Local Register Allocation.  This is still experimental for
	   FT32, so by default the compiler uses standard reload.

       -mnodiv
	   Do not use div and mod instructions.

       -mft32b
	   Enable use of the extended instructions of the FT32B processor.

       -mcompress
	   Compress all code using the Ft32B code compression scheme.

       -mnopm
	   Do not generate code that reads program memory.

       FRV Options

       -mgpr-32
	   Only use the first 32 general-purpose registers.

       -mgpr-64
	   Use all 64 general-purpose registers.

       -mfpr-32
	   Use only the first 32 floating-point registers.

       -mfpr-64
	   Use all 64 floating-point registers.

       -mhard-float
	   Use hardware instructions for floating-point operations.

       -msoft-float
	   Use library routines for floating-point operations.

       -malloc-cc
	   Dynamically allocate condition code registers.

       -mfixed-cc
	   Do not try to dynamically allocate condition code registers, only
	   use "icc0" and "fcc0".

       -mdword
	   Change ABI to use double word insns.

       -mno-dword
	   Do not use double word instructions.

       -mdouble
	   Use floating-point double instructions.

       -mno-double
	   Do not use floating-point double instructions.

       -mmedia
	   Use media instructions.

       -mno-media
	   Do not use media instructions.

       -mmuladd
	   Use multiply and add/subtract instructions.

       -mno-muladd
	   Do not use multiply and add/subtract instructions.

       -mfdpic
	   Select the FDPIC ABI, which uses function descriptors to represent
	   pointers to functions.  Without any PIC/PIE-related options, it
	   implies -fPIE.  With -fpic or -fpie, it assumes GOT entries and
	   small data are within a 12-bit range from the GOT base address;
	   with -fPIC or -fPIE, GOT offsets are computed with 32 bits.	With a
	   bfin-elf target, this option implies -msim.

       -minline-plt
	   Enable inlining of PLT entries in function calls to functions that
	   are not known to bind locally.  It has no effect without -mfdpic.
	   It's enabled by default if optimizing for speed and compiling for
	   shared libraries (i.e., -fPIC or -fpic), or when an optimization
	   option such as -O3 or above is present in the command line.

       -mTLS
	   Assume a large TLS segment when generating thread-local code.

       -mtls
	   Do not assume a large TLS segment when generating thread-local
	   code.

       -mgprel-ro
	   Enable the use of "GPREL" relocations in the FDPIC ABI for data
	   that is known to be in read-only sections.  It's enabled by
	   default, except for -fpic or -fpie: even though it may help make
	   the global offset table smaller, it trades 1 instruction for 4.
	   With -fPIC or -fPIE, it trades 3 instructions for 4, one of which
	   may be shared by multiple symbols, and it avoids the need for a GOT
	   entry for the referenced symbol, so it's more likely to be a win.
	   If it is not, -mno-gprel-ro can be used to disable it.

       -multilib-library-pic
	   Link with the (library, not FD) pic libraries.  It's implied by
	   -mlibrary-pic, as well as by -fPIC and -fpic without -mfdpic.  You
	   should never have to use it explicitly.

       -mlinked-fp
	   Follow the EABI requirement of always creating a frame pointer
	   whenever a stack frame is allocated.	 This option is enabled by
	   default and can be disabled with -mno-linked-fp.

       -mlong-calls
	   Use indirect addressing to call functions outside the current
	   compilation unit.  This allows the functions to be placed anywhere
	   within the 32-bit address space.

       -malign-labels
	   Try to align labels to an 8-byte boundary by inserting NOPs into
	   the previous packet.	 This option only has an effect when VLIW
	   packing is enabled.	It doesn't create new packets; it merely adds
	   NOPs to existing ones.

       -mlibrary-pic
	   Generate position-independent EABI code.

       -macc-4
	   Use only the first four media accumulator registers.

       -macc-8
	   Use all eight media accumulator registers.

       -mpack
	   Pack VLIW instructions.

       -mno-pack
	   Do not pack VLIW instructions.

       -mno-eflags
	   Do not mark ABI switches in e_flags.

       -mcond-move
	   Enable the use of conditional-move instructions (default).

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mno-cond-move
	   Disable the use of conditional-move instructions.

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mscc
	   Enable the use of conditional set instructions (default).

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mno-scc
	   Disable the use of conditional set instructions.

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mcond-exec
	   Enable the use of conditional execution (default).

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mno-cond-exec
	   Disable the use of conditional execution.

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mvliw-branch
	   Run a pass to pack branches into VLIW instructions (default).

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mno-vliw-branch
	   Do not run a pass to pack branches into VLIW instructions.

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mmulti-cond-exec
	   Enable optimization of "&&" and "||" in conditional execution
	   (default).

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mno-multi-cond-exec
	   Disable optimization of "&&" and "||" in conditional execution.

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mnested-cond-exec
	   Enable nested conditional execution optimizations (default).

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -mno-nested-cond-exec
	   Disable nested conditional execution optimizations.

	   This switch is mainly for debugging the compiler and will likely be
	   removed in a future version.

       -moptimize-membar
	   This switch removes redundant "membar" instructions from the
	   compiler-generated code.  It is enabled by default.

       -mno-optimize-membar
	   This switch disables the automatic removal of redundant "membar"
	   instructions from the generated code.

       -mtomcat-stats
	   Cause gas to print out tomcat statistics.

       -mcpu=cpu
	   Select the processor type for which to generate code.  Possible
	   values are frv, fr550, tomcat, fr500, fr450, fr405, fr400, fr300
	   and simple.

       GNU/Linux Options

       These -m options are defined for GNU/Linux targets:

       -mglibc
	   Use the GNU C library.  This is the default except on
	   *-*-linux-*uclibc*, *-*-linux-*musl* and *-*-linux-*android*
	   targets.

       -muclibc
	   Use uClibc C library.  This is the default on *-*-linux-*uclibc*
	   targets.

       -mmusl
	   Use the musl C library.  This is the default on *-*-linux-*musl*
	   targets.

       -mbionic
	   Use Bionic C library.  This is the default on *-*-linux-*android*
	   targets.

       -mandroid
	   Compile code compatible with Android platform.  This is the default
	   on *-*-linux-*android* targets.

	   When compiling, this option enables -mbionic, -fPIC,
	   -fno-exceptions and -fno-rtti by default.  When linking, this
	   option makes the GCC driver pass Android-specific options to the
	   linker.  Finally, this option causes the preprocessor macro
	   "__ANDROID__" to be defined.

       -tno-android-cc
	   Disable compilation effects of -mandroid, i.e., do not enable
	   -mbionic, -fPIC, -fno-exceptions and -fno-rtti by default.

       -tno-android-ld
	   Disable linking effects of -mandroid, i.e., pass standard Linux
	   linking options to the linker.

       H8/300 Options

       These -m options are defined for the H8/300 implementations:

       -mrelax
	   Shorten some address references at link time, when possible; uses
	   the linker option -relax.

       -mh Generate code for the H8/300H.

       -ms Generate code for the H8S.

       -mn Generate code for the H8S and H8/300H in the normal mode.  This
	   switch must be used either with -mh or -ms.

       -ms2600
	   Generate code for the H8S/2600.  This switch must be used with -ms.

       -mexr
	   Extended registers are stored on stack before execution of function
	   with monitor attribute. Default option is -mexr.  This option is
	   valid only for H8S targets.

       -mno-exr
	   Extended registers are not stored on stack before execution of
	   function with monitor attribute. Default option is -mno-exr.	 This
	   option is valid only for H8S targets.

       -mint32
	   Make "int" data 32 bits by default.

       -malign-300
	   On the H8/300H and H8S, use the same alignment rules as for the
	   H8/300.  The default for the H8/300H and H8S is to align longs and
	   floats on 4-byte boundaries.	 -malign-300 causes them to be aligned
	   on 2-byte boundaries.  This option has no effect on the H8/300.

       HPPA Options

       These -m options are defined for the HPPA family of computers:

       -march=architecture-type
	   Generate code for the specified architecture.  The choices for
	   architecture-type are 1.0 for PA 1.0, 1.1 for PA 1.1, and 2.0 for
	   PA 2.0 processors.  Refer to /usr/lib/sched.models on an HP-UX
	   system to determine the proper architecture option for your
	   machine.  Code compiled for lower numbered architectures runs on
	   higher numbered architectures, but not the other way around.

       -mpa-risc-1-0
       -mpa-risc-1-1
       -mpa-risc-2-0
	   Synonyms for -march=1.0, -march=1.1, and -march=2.0 respectively.

       -matomic-libcalls
	   Generate libcalls for atomic loads and stores when sync libcalls
	   are disabled.  This option is enabled by default.  It only affects
	   the generation of atomic libcalls by the HPPA backend.

	   Both the sync and libatomic libcall implementations use locking.
	   As a result, processor stores are not atomic with respect to other
	   atomic operations.  Processor loads up to DImode are atomic with
	   respect to other atomic operations provided they are implemented as
	   a single access.

	   The PA-RISC architecture does not support any atomic operations in
	   hardware except for the "ldcw" instruction.	Thus, all atomic
	   support is implemented using sync and atomic libcalls.  Sync
	   libcall support is in libgcc.a.  Atomic libcall support is in
	   libatomic.

	   This option generates "__atomic_exchange" calls for atomic stores.
	   It also provides special handling for atomic DImode accesses on
	   32-bit targets.

       -mbig-switch
	   Does nothing.  Preserved for backward compatibility.

       -mcaller-copies
	   The caller copies function arguments passed by hidden reference.
	   This option should be used with care as it is not compatible with
	   the default 32-bit runtime.	However, only aggregates larger than
	   eight bytes are passed by hidden reference and the option provides
	   better compatibility with OpenMP.

       -mcoherent-ldcw
	   Use ldcw/ldcd coherent cache-control hint.

       -mdisable-fpregs
	   Disable floating-point registers.  Equivalent to "-msoft-float".

       -mdisable-indexing
	   Prevent the compiler from using indexing address modes.  This
	   avoids some rather obscure problems when compiling MIG generated
	   code under MACH.

       -mfast-indirect-calls
	   Generate code that assumes calls never cross space boundaries.
	   This allows GCC to emit code that performs faster indirect calls.

	   This option does not work in the presence of shared libraries or
	   nested functions.

       -mfixed-range=register-range
	   Generate code treating the given register range as fixed registers.
	   A fixed register is one that the register allocator cannot use.
	   This is useful when compiling kernel code.  A register range is
	   specified as two registers separated by a dash.  Multiple register
	   ranges can be specified separated by a comma.

       -mgas
	   Enable the use of assembler directives only GAS understands.

       -mgnu-ld
	   Use options specific to GNU ld.  This passes -shared to ld when
	   building a shared library.  It is the default when GCC is
	   configured, explicitly or implicitly, with the GNU linker.  This
	   option does not affect which ld is called; it only changes what
	   parameters are passed to that ld.  The ld that is called is
	   determined by the --with-ld configure option, GCC's program search
	   path, and finally by the user's PATH.  The linker used by GCC can
	   be printed using which `gcc -print-prog-name=ld`.  This option is
	   only available on the 64-bit HP-UX GCC, i.e. configured with
	   hppa*64*-*-hpux*.

       -mhp-ld
	   Use options specific to HP ld.  This passes -b to ld when building
	   a shared library and passes +Accept TypeMismatch to ld on all
	   links.  It is the default when GCC is configured, explicitly or
	   implicitly, with the HP linker.  This option does not affect which
	   ld is called; it only changes what parameters are passed to that
	   ld.	The ld that is called is determined by the --with-ld configure
	   option, GCC's program search path, and finally by the user's PATH.
	   The linker used by GCC can be printed using which `gcc
	   -print-prog-name=ld`.  This option is only available on the 64-bit
	   HP-UX GCC, i.e. configured with hppa*64*-*-hpux*.

       -mlinker-opt
	   Enable the optimization pass in the HP-UX linker.  Note this makes
	   symbolic debugging impossible.  It also triggers a bug in the HP-UX
	   8 and HP-UX 9 linkers in which they give bogus error messages when
	   linking some programs.

       -mlong-calls
	   Generate code that uses long call sequences.	 This ensures that a
	   call is always able to reach linker generated stubs.	 The default
	   is to generate long calls only when the distance from the call site
	   to the beginning of the function or translation unit, as the case
	   may be, exceeds a predefined limit set by the branch type being
	   used.  The limits for normal calls are 7,600,000 and 240,000 bytes,
	   respectively for the PA 2.0 and PA 1.X architectures.  Sibcalls are
	   always limited at 240,000 bytes.

	   Distances are measured from the beginning of functions when using
	   the -ffunction-sections option, or when using the -mgas and
	   -mno-portable-runtime options together under HP-UX with the SOM
	   linker.

	   It is normally not desirable to use this option as it degrades
	   performance.	 However, it may be useful in large applications,
	   particularly when partial linking is used to build the application.

	   The types of long calls used depends on the capabilities of the
	   assembler and linker, and the type of code being generated.	The
	   impact on systems that support long absolute calls, and long pic
	   symbol-difference or pc-relative calls should be relatively small.
	   However, an indirect call is used on 32-bit ELF systems in pic code
	   and it is quite long.

       -mlong-load-store
	   Generate 3-instruction load and store sequences as sometimes
	   required by the HP-UX 10 linker.  This is equivalent to the +k
	   option to the HP compilers.

       -mjump-in-delay
	   This option is ignored and provided for compatibility purposes
	   only.

       -mno-space-regs
	   Generate code that assumes the target has no space registers.  This
	   allows GCC to generate faster indirect calls and use unscaled index
	   address modes.

	   Such code is suitable for level 0 PA systems and kernels.

       -mordered
	   Assume memory references are ordered and barriers are not needed.

       -mportable-runtime
	   Use the portable calling conventions proposed by HP for ELF
	   systems.

       -mschedule=cpu-type
	   Schedule code according to the constraints for the machine type
	   cpu-type.  The choices for cpu-type are 700 7100, 7100LC, 7200,
	   7300 and 8000.  Refer to /usr/lib/sched.models on an HP-UX system
	   to determine the proper scheduling option for your machine.	The
	   default scheduling is 8000.

       -msio
	   Generate the predefine, "_SIO", for server IO.  The default is
	   -mwsio.  This generates the predefines, "__hp9000s700",
	   "__hp9000s700__" and "_WSIO", for workstation IO.  These options
	   are available under HP-UX and HI-UX.

       -msoft-float
	   Generate output containing library calls for floating point.
	   Warning: the requisite libraries are not available for all HPPA
	   targets.  Normally the facilities of the machine's usual C compiler
	   are used, but this cannot be done directly in cross-compilation.
	   You must make your own arrangements to provide suitable library
	   functions for cross-compilation.

	   -msoft-float changes the calling convention in the output file;
	   therefore, it is only useful if you compile all of a program with
	   this option.	 In particular, you need to compile libgcc.a, the
	   library that comes with GCC, with -msoft-float in order for this to
	   work.

       -msoft-mult
	   Use software integer multiplication.

	   This disables the use of the "xmpyu" instruction.

       -munix=unix-std
	   Generate compiler predefines and select a startfile for the
	   specified UNIX standard.  The choices for unix-std are 93, 95 and
	   98.	93 is supported on all HP-UX versions.	95 is available on HP-
	   UX 10.10 and later.	98 is available on HP-UX 11.11 and later.  The
	   default values are 93 for HP-UX 10.00, 95 for HP-UX 10.10 though to
	   11.00, and 98 for HP-UX 11.11 and later.

	   -munix=93 provides the same predefines as GCC 3.3 and 3.4.
	   -munix=95 provides additional predefines for "XOPEN_UNIX" and
	   "_XOPEN_SOURCE_EXTENDED", and the startfile unix95.o.  -munix=98
	   provides additional predefines for "_XOPEN_UNIX",
	   "_XOPEN_SOURCE_EXTENDED", "_INCLUDE__STDC_A1_SOURCE" and
	   "_INCLUDE_XOPEN_SOURCE_500", and the startfile unix98.o.

	   It is important to note that this option changes the interfaces for
	   various library routines.  It also affects the operational behavior
	   of the C library.  Thus, extreme care is needed in using this
	   option.

	   Library code that is intended to operate with more than one UNIX
	   standard must test, set and restore the variable
	   "__xpg4_extended_mask" as appropriate.  Most GNU software doesn't
	   provide this capability.

       -nolibdld
	   Suppress the generation of link options to search libdld.sl when
	   the -static option is specified on HP-UX 10 and later.

       -static
	   The HP-UX implementation of setlocale in libc has a dependency on
	   libdld.sl.  There isn't an archive version of libdld.sl.  Thus,
	   when the -static option is specified, special link options are
	   needed to resolve this dependency.

	   On HP-UX 10 and later, the GCC driver adds the necessary options to
	   link with libdld.sl when the -static option is specified.  This
	   causes the resulting binary to be dynamic.  On the 64-bit port, the
	   linkers generate dynamic binaries by default in any case.  The
	   -nolibdld option can be used to prevent the GCC driver from adding
	   these link options.

       -threads
	   Add support for multithreading with the dce thread library under
	   HP-UX.  This option sets flags for both the preprocessor and
	   linker.

       IA-64 Options

       These are the -m options defined for the Intel IA-64 architecture.

       -mbig-endian
	   Generate code for a big-endian target.  This is the default for HP-
	   UX.

       -mlittle-endian
	   Generate code for a little-endian target.  This is the default for
	   AIX5 and GNU/Linux.

       -mgnu-as
       -mno-gnu-as
	   Generate (or don't) code for the GNU assembler.  This is the
	   default.

       -mgnu-ld
       -mno-gnu-ld
	   Generate (or don't) code for the GNU linker.	 This is the default.

       -mno-pic
	   Generate code that does not use a global pointer register.  The
	   result is not position independent code, and violates the IA-64
	   ABI.

       -mvolatile-asm-stop
       -mno-volatile-asm-stop
	   Generate (or don't) a stop bit immediately before and after
	   volatile asm statements.

       -mregister-names
       -mno-register-names
	   Generate (or don't) in, loc, and out register names for the stacked
	   registers.  This may make assembler output more readable.

       -mno-sdata
       -msdata
	   Disable (or enable) optimizations that use the small data section.
	   This may be useful for working around optimizer bugs.

       -mconstant-gp
	   Generate code that uses a single constant global pointer value.
	   This is useful when compiling kernel code.

       -mauto-pic
	   Generate code that is self-relocatable.  This implies
	   -mconstant-gp.  This is useful when compiling firmware code.

       -minline-float-divide-min-latency
	   Generate code for inline divides of floating-point values using the
	   minimum latency algorithm.

       -minline-float-divide-max-throughput
	   Generate code for inline divides of floating-point values using the
	   maximum throughput algorithm.

       -mno-inline-float-divide
	   Do not generate inline code for divides of floating-point values.

       -minline-int-divide-min-latency
	   Generate code for inline divides of integer values using the
	   minimum latency algorithm.

       -minline-int-divide-max-throughput
	   Generate code for inline divides of integer values using the
	   maximum throughput algorithm.

       -mno-inline-int-divide
	   Do not generate inline code for divides of integer values.

       -minline-sqrt-min-latency
	   Generate code for inline square roots using the minimum latency
	   algorithm.

       -minline-sqrt-max-throughput
	   Generate code for inline square roots using the maximum throughput
	   algorithm.

       -mno-inline-sqrt
	   Do not generate inline code for "sqrt".

       -mfused-madd
       -mno-fused-madd
	   Do (don't) generate code that uses the fused multiply/add or
	   multiply/subtract instructions.  The default is to use these
	   instructions.

       -mno-dwarf2-asm
       -mdwarf2-asm
	   Don't (or do) generate assembler code for the DWARF line number
	   debugging info.  This may be useful when not using the GNU
	   assembler.

       -mearly-stop-bits
       -mno-early-stop-bits
	   Allow stop bits to be placed earlier than immediately preceding the
	   instruction that triggered the stop bit.  This can improve
	   instruction scheduling, but does not always do so.

       -mfixed-range=register-range
	   Generate code treating the given register range as fixed registers.
	   A fixed register is one that the register allocator cannot use.
	   This is useful when compiling kernel code.  A register range is
	   specified as two registers separated by a dash.  Multiple register
	   ranges can be specified separated by a comma.

       -mtls-size=tls-size
	   Specify bit size of immediate TLS offsets.  Valid values are 14,
	   22, and 64.

       -mtune=cpu-type
	   Tune the instruction scheduling for a particular CPU, Valid values
	   are itanium, itanium1, merced, itanium2, and mckinley.

       -milp32
       -mlp64
	   Generate code for a 32-bit or 64-bit environment.  The 32-bit
	   environment sets int, long and pointer to 32 bits.  The 64-bit
	   environment sets int to 32 bits and long and pointer to 64 bits.
	   These are HP-UX specific flags.

       -mno-sched-br-data-spec
       -msched-br-data-spec
	   (Dis/En)able data speculative scheduling before reload.  This
	   results in generation of "ld.a" instructions and the corresponding
	   check instructions ("ld.c" / "chk.a").  The default setting is
	   disabled.

       -msched-ar-data-spec
       -mno-sched-ar-data-spec
	   (En/Dis)able data speculative scheduling after reload.  This
	   results in generation of "ld.a" instructions and the corresponding
	   check instructions ("ld.c" / "chk.a").  The default setting is
	   enabled.

       -mno-sched-control-spec
       -msched-control-spec
	   (Dis/En)able control speculative scheduling.	 This feature is
	   available only during region scheduling (i.e. before reload).  This
	   results in generation of the "ld.s" instructions and the
	   corresponding check instructions "chk.s".  The default setting is
	   disabled.

       -msched-br-in-data-spec
       -mno-sched-br-in-data-spec
	   (En/Dis)able speculative scheduling of the instructions that are
	   dependent on the data speculative loads before reload.  This is
	   effective only with -msched-br-data-spec enabled.  The default
	   setting is enabled.

       -msched-ar-in-data-spec
       -mno-sched-ar-in-data-spec
	   (En/Dis)able speculative scheduling of the instructions that are
	   dependent on the data speculative loads after reload.  This is
	   effective only with -msched-ar-data-spec enabled.  The default
	   setting is enabled.

       -msched-in-control-spec
       -mno-sched-in-control-spec
	   (En/Dis)able speculative scheduling of the instructions that are
	   dependent on the control speculative loads.	This is effective only
	   with -msched-control-spec enabled.  The default setting is enabled.

       -mno-sched-prefer-non-data-spec-insns
       -msched-prefer-non-data-spec-insns
	   If enabled, data-speculative instructions are chosen for schedule
	   only if there are no other choices at the moment.  This makes the
	   use of the data speculation much more conservative.	The default
	   setting is disabled.

       -mno-sched-prefer-non-control-spec-insns
       -msched-prefer-non-control-spec-insns
	   If enabled, control-speculative instructions are chosen for
	   schedule only if there are no other choices at the moment.  This
	   makes the use of the control speculation much more conservative.
	   The default setting is disabled.

       -mno-sched-count-spec-in-critical-path
       -msched-count-spec-in-critical-path
	   If enabled, speculative dependencies are considered during
	   computation of the instructions priorities.	This makes the use of
	   the speculation a bit more conservative.  The default setting is
	   disabled.

       -msched-spec-ldc
	   Use a simple data speculation check.	 This option is on by default.

       -msched-control-spec-ldc
	   Use a simple check for control speculation.	This option is on by
	   default.

       -msched-stop-bits-after-every-cycle
	   Place a stop bit after every cycle when scheduling.	This option is
	   on by default.

       -msched-fp-mem-deps-zero-cost
	   Assume that floating-point stores and loads are not likely to cause
	   a conflict when placed into the same instruction group.  This
	   option is disabled by default.

       -msel-sched-dont-check-control-spec
	   Generate checks for control speculation in selective scheduling.
	   This flag is disabled by default.

       -msched-max-memory-insns=max-insns
	   Limit on the number of memory insns per instruction group, giving
	   lower priority to subsequent memory insns attempting to schedule in
	   the same instruction group. Frequently useful to prevent cache bank
	   conflicts.  The default value is 1.

       -msched-max-memory-insns-hard-limit
	   Makes the limit specified by msched-max-memory-insns a hard limit,
	   disallowing more than that number in an instruction group.
	   Otherwise, the limit is "soft", meaning that non-memory operations
	   are preferred when the limit is reached, but memory operations may
	   still be scheduled.

       LM32 Options

       These -m options are defined for the LatticeMico32 architecture:

       -mbarrel-shift-enabled
	   Enable barrel-shift instructions.

       -mdivide-enabled
	   Enable divide and modulus instructions.

       -mmultiply-enabled
	   Enable multiply instructions.

       -msign-extend-enabled
	   Enable sign extend instructions.

       -muser-enabled
	   Enable user-defined instructions.

       LoongArch Options

       These command-line options are defined for LoongArch targets:

       -march=arch-type
	   Generate instructions for the machine type arch-type.  -march=arch-
	   type allows GCC to generate code that may not run at all on
	   processors other than the one indicated.

	   The choices for arch-type are:

	   native
	       Local processor type detected by the native compiler.

	   loongarch64
	       Generic LoongArch 64-bit processor.

	   la464
	       LoongArch LA464-based processor with LSX, LASX.

	   la664
	       LoongArch LA664-based processor with LSX, LASX and all
	       LoongArch v1.1 instructions.

	   la64v1.0
	       LoongArch64 ISA version 1.0.

	   la64v1.1
	       LoongArch64 ISA version 1.1.

	   More information about LoongArch ISA versions can be found at
	   <https://github.com/loongson/la-toolchain-conventions>.

       -mtune=tune-type
	   Optimize the generated code for the given processor target.

	   The choices for tune-type are:

	   native
	       Local processor type detected by the native compiler.

	   generic
	       Generic LoongArch processor.

	   loongarch64
	       Generic LoongArch 64-bit processor.

	   la464
	       LoongArch LA464 core.

	   la664
	       LoongArch LA664 core.

       -mabi=base-abi-type
	   Generate code for the specified calling convention.	base-abi-type
	   can be one of:

	   lp64d
	       Uses 64-bit general purpose registers and 32/64-bit floating-
	       point registers for parameter passing.  Data model is LP64,
	       where int is 32 bits, while long int and pointers are 64 bits.

	   lp64f
	       Uses 64-bit general purpose registers and 32-bit floating-point
	       registers for parameter passing.	 Data model is LP64, where int
	       is 32 bits, while long int and pointers are 64 bits.

	   lp64s
	       Uses 64-bit general purpose registers and no floating-point
	       registers for parameter passing.	 Data model is LP64, where int
	       is 32 bits, while long int and pointers are 64 bits.

       -mfpu=fpu-type
	   Generate code for the specified FPU type, which can be one of:

	   64  Allow the use of hardware floating-point instructions for
	       32-bit and 64-bit operations.

	   32  Allow the use of hardware floating-point instructions for
	       32-bit operations.

	   none
	   0   Prevent the use of hardware floating-point instructions.

       -msimd=simd-type
	   Enable generation of LoongArch SIMD instructions for vectorization
	   and via builtin functions.  The value can be one of:

	   lasx
	       Enable generating instructions from the 256-bit LoongArch
	       Advanced SIMD Extension (LASX) and the 128-bit LoongArch SIMD
	       Extension (LSX).

	   lsx Enable generating instructions from the 128-bit LoongArch SIMD
	       Extension (LSX).

	   none
	       No LoongArch SIMD instruction may be generated.

       -msoft-float
	   Force -mfpu=none and prevents the use of floating-point registers
	   for parameter passing.  This option may change the target ABI.

       -msingle-float
	   Force -mfpu=32 and allow the use of 32-bit floating-point registers
	   for parameter passing.  This option may change the target ABI.

       -mdouble-float
	   Force -mfpu=64 and allow the use of 32/64-bit floating-point
	   registers for parameter passing.  This option may change the target
	   ABI.

       -mlasx
       -mno-lasx
       -mlsx
       -mno-lsx
	   Incrementally adjust the scope of the SIMD extensions (none / LSX /
	   LASX) that can be used by the compiler for code generation.
	   Enabling LASX with mlasx automatically enables LSX, and diabling
	   LSX with mno-lsx automatically disables LASX.  These driver-only
	   options act upon the final msimd configuration state and make
	   incremental chagnes in the order they appear on the GCC driver's
	   command line, deriving the final / canonicalized msimd option that
	   is passed to the compiler proper.

       -mbranch-cost=n
	   Set the cost of branches to roughly n instructions.

       -mcheck-zero-division
       -mno-check-zero-divison
	   Trap (do not trap) on integer division by zero.  The default is
	   -mcheck-zero-division for -O0 or -Og, and -mno-check-zero-division
	   for other optimization levels.

       -mcond-move-int
       -mno-cond-move-int
	   Conditional moves for integral data in general-purpose registers
	   are enabled (disabled).  The default is -mcond-move-int.

       -mcond-move-float
       -mno-cond-move-float
	   Conditional moves for floating-point registers are enabled
	   (disabled).	The default is -mcond-move-float.

       -mmemcpy
       -mno-memcpy
	   Force (do not force) the use of "memcpy" for non-trivial block
	   moves.  The default is -mno-memcpy, which allows GCC to inline most
	   constant-sized copies.  Setting optimization level to -Os also
	   forces the use of "memcpy", but -mno-memcpy may override this
	   behavior if explicitly specified, regardless of the order these
	   options on the command line.

       -mstrict-align
       -mno-strict-align
	   Avoid or allow generating memory accesses that may not be aligned
	   on a natural object boundary as described in the architecture
	   specification. The default is -mno-strict-align.

       -msmall-data-limit=number
	   Put global and static data smaller than number bytes into a special
	   section (on some targets).  The default value is 0.

       -mmax-inline-memcpy-size=n
	   Inline all block moves (such as calls to "memcpy" or structure
	   copies) less than or equal to n bytes.  The default value of n is
	   1024.

       -mcmodel=code-model
	   Set the code model to one of:

	   tiny-static (Not implemented yet)
	   tiny (Not implemented yet)
	   normal
	       The text segment must be within 128MB addressing space.	The
	       data segment must be within 2GB addressing space.

	   medium
	       The text segment and data segment must be within 2GB addressing
	       space.

	   large (Not implemented yet)
	   extreme
	       This mode does not limit the size of the code segment and data
	       segment.	 The -mcmodel=extreme option is incompatible with
	       -fplt and/or -mexplicit-relocs=none.

	   The default code model is "normal".

       -mexplicit-relocs=style
	   Set when to use assembler relocation operators when dealing with
	   symbolic addresses.	The alternative is to use assembler macros
	   instead, which may limit instruction scheduling but allow linker
	   relaxation.	with -mexplicit-relocs=none the assembler macros are
	   always used, with -mexplicit-relocs=always the assembler relocation
	   operators are always used, with -mexplicit-relocs=auto the compiler
	   will use the relocation operators where the linker relaxation is
	   impossible to improve the code quality, and macros elsewhere.  The
	   default value for the option is determined with the assembler
	   capability detected during GCC build-time and the setting of
	   -mrelax: -mexplicit-relocs=none if the assembler does not support
	   relocation operators at all, -mexplicit-relocs=always if the
	   assembler supports relocation operators but -mrelax is not enabled,
	   -mexplicit-relocs=auto if the assembler supports relocation
	   operators and -mrelax is enabled.

       -mexplicit-relocs
	   An alias of -mexplicit-relocs=always for backward compatibility.

       -mno-explicit-relocs
	   An alias of -mexplicit-relocs=none for backward compatibility.

       -mdirect-extern-access
       -mno-direct-extern-access
	   Do not use or use GOT to access external symbols.  The default is
	   -mno-direct-extern-access: GOT is used for external symbols with
	   default visibility, but not used for other external symbols.

	   With -mdirect-extern-access, GOT is not used and all external
	   symbols are PC-relatively addressed.	 It is only suitable for
	   environments where no dynamic link is performed, like firmwares, OS
	   kernels, executables linked with -static or -static-pie.
	   -mdirect-extern-access is not compatible with -fPIC or -fpic.

       -mrelax
       -mno-relax
	   Take (do not take) advantage of linker relaxations.	If
	   -mpass-mrelax-to-as is enabled, this option is also passed to the
	   assembler.  The default is determined during GCC build-time by
	   detecting corresponding assembler support: -mrelax if the assembler
	   supports both the -mrelax option and the conditional branch
	   relaxation (it's required or the ".align" directives and
	   conditional branch instructions in the assembly code outputted by
	   GCC may be rejected by the assembler because of a relocation
	   overflow), -mno-relax otherwise.

       -mpass-mrelax-to-as
       -mno-pass-mrelax-to-as
	   Pass (do not pass) the -mrelax or -mno-relax option to the
	   assembler.  The default is determined during GCC build-time by
	   detecting corresponding assembler support: -mpass-mrelax-to-as if
	   the assembler supports the -mrelax option, -mno-pass-mrelax-to-as
	   otherwise.  This option is mostly useful for debugging, or
	   interoperation with assemblers different from the build-time one.

       -mrecip
	   This option enables use of the reciprocal estimate and reciprocal
	   square root estimate instructions with additional Newton-Raphson
	   steps to increase precision instead of doing a divide or square
	   root and divide for floating-point arguments.  These instructions
	   are generated only when -funsafe-math-optimizations is enabled
	   together with -ffinite-math-only and -fno-trapping-math.  This
	   option is off by default. Before you can use this option, you must
	   sure the target CPU supports frecipe and frsqrte instructions.
	   Note that while the throughput of the sequence is higher than the
	   throughput of the non-reciprocal instruction, the precision of the
	   sequence can be decreased by up to 2 ulp (i.e. the inverse of 1.0
	   equals 0.99999994).

       -mrecip=opt
	   This option controls which reciprocal estimate instructions may be
	   used.  opt is a comma-separated list of options, which may be
	   preceded by a ! to invert the option:

	   all Enable all estimate instructions.

	   default
	       Enable the default instructions, equivalent to -mrecip.

	   none
	       Disable all estimate instructions, equivalent to -mno-recip.

	   div Enable the approximation for scalar division.

	   vec-div
	       Enable the approximation for vectorized division.

	   sqrt
	       Enable the approximation for scalar square root.

	   vec-sqrt
	       Enable the approximation for vectorized square root.

	   rsqrt
	       Enable the approximation for scalar reciprocal square root.

	   vec-rsqrt
	       Enable the approximation for vectorized reciprocal square root.

	   So, for example, -mrecip=all,!sqrt enables all of the reciprocal
	   approximations, except for scalar square root.

       -mfrecipe
       -mno-frecipe
	   Use (do not use) "frecipe.{s/d}" and "frsqrte.{s/d}" instructions.
	   When build with -march=la664, it is enabled by default.  The
	   default is -mno-frecipe.

       -mdiv32
       -mno-div32
	   Use (do not use) "div.w[u]" and "mod.w[u]" instructions with input
	   not sign-extended.  When build with -march=la664, it is enabled by
	   default.  The default is -mno-div32.

       -mlam-bh
       -mno-lam-bh
	   Use (do not use) "am{swap/add}[_db].{b/h}" instructions.  When
	   build with -march=la664, it is enabled by default.  The default is
	   -mno-lam-bh.

       -mlamcas
       -mno-lamcas
	   Use (do not use) "amcas[_db].{b/h/w/d}" instructions.  When build
	   with -march=la664, it is enabled by default.	 The default is
	   -mno-lamcas.

       -mld-seq-sa
       -mno-ld-seq-sa
	   Whether a load-load barrier ("dbar 0x700") is needed.  When build
	   with -march=la664, it is enabled by default.	 The default is
	   -mno-ld-seq-sa, the load-load barrier is needed.

       -mtls-dialect=opt
	   This option controls which tls dialect may be used for general
	   dynamic and local dynamic TLS models.

	   trad
	       Use traditional TLS. This is the default.

	   desc
	       Use TLS descriptors.

       --param loongarch-vect-unroll-limit=n
	   The vectorizer will use available tuning information to determine
	   whether it would be beneficial to unroll the main vectorized loop
	   and by how much.  This parameter set's the upper bound of how much
	   the vectorizer will unroll the main loop.  The default value is
	   six.

       M32C Options

       -mcpu=name
	   Select the CPU for which code is generated.	name may be one of r8c
	   for the R8C/Tiny series, m16c for the M16C (up to /60) series,
	   m32cm for the M16C/80 series, or m32c for the M32C/80 series.

       -msim
	   Specifies that the program will be run on the simulator.  This
	   causes an alternate runtime library to be linked in which supports,
	   for example, file I/O.  You must not use this option when
	   generating programs that will run on real hardware; you must
	   provide your own runtime library for whatever I/O functions are
	   needed.

       -memregs=number
	   Specifies the number of memory-based pseudo-registers GCC uses
	   during code generation.  These pseudo-registers are used like real
	   registers, so there is a tradeoff between GCC's ability to fit the
	   code into available registers, and the performance penalty of using
	   memory instead of registers.	 Note that all modules in a program
	   must be compiled with the same value for this option.  Because of
	   that, you must not use this option with GCC's default runtime
	   libraries.

       M32R/D Options

       These -m options are defined for Renesas M32R/D architectures:

       -m32r2
	   Generate code for the M32R/2.

       -m32rx
	   Generate code for the M32R/X.

       -m32r
	   Generate code for the M32R.	This is the default.

       -mmodel=small
	   Assume all objects live in the lower 16MB of memory (so that their
	   addresses can be loaded with the "ld24" instruction), and assume
	   all subroutines are reachable with the "bl" instruction.  This is
	   the default.

	   The addressability of a particular object can be set with the
	   "model" attribute.

       -mmodel=medium
	   Assume objects may be anywhere in the 32-bit address space (the
	   compiler generates "seth/add3" instructions to load their
	   addresses), and assume all subroutines are reachable with the "bl"
	   instruction.

       -mmodel=large
	   Assume objects may be anywhere in the 32-bit address space (the
	   compiler generates "seth/add3" instructions to load their
	   addresses), and assume subroutines may not be reachable with the
	   "bl" instruction (the compiler generates the much slower
	   "seth/add3/jl" instruction sequence).

       -msdata=none
	   Disable use of the small data area.	Variables are put into one of
	   ".data", ".bss", or ".rodata" (unless the "section" attribute has
	   been specified).  This is the default.

	   The small data area consists of sections ".sdata" and ".sbss".
	   Objects may be explicitly put in the small data area with the
	   "section" attribute using one of these sections.

       -msdata=sdata
	   Put small global and static data in the small data area, but do not
	   generate special code to reference them.

       -msdata=use
	   Put small global and static data in the small data area, and
	   generate special instructions to reference them.

       -G num
	   Put global and static objects less than or equal to num bytes into
	   the small data or BSS sections instead of the normal data or BSS
	   sections.  The default value of num is 8.  The -msdata option must
	   be set to one of sdata or use for this option to have any effect.

	   All modules should be compiled with the same -G num value.
	   Compiling with different values of num may or may not work; if it
	   doesn't the linker gives an error message---incorrect code is not
	   generated.

       -mdebug
	   Makes the M32R-specific code in the compiler display some
	   statistics that might help in debugging programs.

       -malign-loops
	   Align all loops to a 32-byte boundary.

       -mno-align-loops
	   Do not enforce a 32-byte alignment for loops.  This is the default.

       -missue-rate=number
	   Issue number instructions per cycle.	 number can only be 1 or 2.

       -mbranch-cost=number
	   number can only be 1 or 2.  If it is 1 then branches are preferred
	   over conditional code, if it is 2, then the opposite applies.

       -mflush-trap=number
	   Specifies the trap number to use to flush the cache.	 The default
	   is 12.  Valid numbers are between 0 and 15 inclusive.

       -mno-flush-trap
	   Specifies that the cache cannot be flushed by using a trap.

       -mflush-func=name
	   Specifies the name of the operating system function to call to
	   flush the cache.  The default is _flush_cache, but a function call
	   is only used if a trap is not available.

       -mno-flush-func
	   Indicates that there is no OS function for flushing the cache.

       M680x0 Options

       These are the -m options defined for M680x0 and ColdFire processors.
       The default settings depend on which architecture was selected when the
       compiler was configured; the defaults for the most common choices are
       given below.

       -march=arch
	   Generate code for a specific M680x0 or ColdFire instruction set
	   architecture.  Permissible values of arch for M680x0 architectures
	   are: 68000, 68010, 68020, 68030, 68040, 68060 and cpu32.  ColdFire
	   architectures are selected according to Freescale's ISA
	   classification and the permissible values are: isaa, isaaplus, isab
	   and isac.

	   GCC defines a macro "__mcfarch__" whenever it is generating code
	   for a ColdFire target.  The arch in this macro is one of the -march
	   arguments given above.

	   When used together, -march and -mtune select code that runs on a
	   family of similar processors but that is optimized for a particular
	   microarchitecture.

       -mcpu=cpu
	   Generate code for a specific M680x0 or ColdFire processor.  The
	   M680x0 cpus are: 68000, 68010, 68020, 68030, 68040, 68060, 68302,
	   68332 and cpu32.  The ColdFire cpus are given by the table below,
	   which also classifies the CPUs into families:

	   Family : -mcpu arguments
	   51 : 51 51ac 51ag 51cn 51em 51je 51jf 51jg 51jm 51mm 51qe 51qm
	   5206 : 5202 5204 5206
	   5206e : 5206e
	   5208 : 5207 5208
	   5211a : 5210a 5211a
	   5213 : 5211 5212 5213
	   5216 : 5214 5216
	   52235 : 52230 52231 52232 52233 52234 52235
	   5225 : 5224 5225
	   52259 : 52252 52254 52255 52256 52258 52259
	   5235 : 5232 5233 5234 5235 523x
	   5249 : 5249
	   5250 : 5250
	   5271 : 5270 5271
	   5272 : 5272
	   5275 : 5274 5275
	   5282 : 5280 5281 5282 528x
	   53017 : 53011 53012 53013 53014 53015 53016 53017
	   5307 : 5307
	   5329 : 5327 5328 5329 532x
	   5373 : 5372 5373 537x
	   5407 : 5407
	   5475 : 5470 5471 5472 5473 5474 5475 547x 5480 5481 5482 5483 5484
	   5485

	   -mcpu=cpu overrides -march=arch if arch is compatible with cpu.
	   Other combinations of -mcpu and -march are rejected.

	   GCC defines the macro "__mcf_cpu_cpu" when ColdFire target cpu is
	   selected.  It also defines "__mcf_family_family", where the value
	   of family is given by the table above.

       -mtune=tune
	   Tune the code for a particular microarchitecture within the
	   constraints set by -march and -mcpu.	 The M680x0 microarchitectures
	   are: 68000, 68010, 68020, 68030, 68040, 68060 and cpu32.  The
	   ColdFire microarchitectures are: cfv1, cfv2, cfv3, cfv4 and cfv4e.

	   You can also use -mtune=68020-40 for code that needs to run
	   relatively well on 68020, 68030 and 68040 targets.  -mtune=68020-60
	   is similar but includes 68060 targets as well.  These two options
	   select the same tuning decisions as -m68020-40 and -m68020-60
	   respectively.

	   GCC defines the macros "__mcarch" and "__mcarch__" when tuning for
	   680x0 architecture arch.  It also defines "mcarch" unless either
	   -ansi or a non-GNU -std option is used.  If GCC is tuning for a
	   range of architectures, as selected by -mtune=68020-40 or
	   -mtune=68020-60, it defines the macros for every architecture in
	   the range.

	   GCC also defines the macro "__muarch__" when tuning for ColdFire
	   microarchitecture uarch, where uarch is one of the arguments given
	   above.

       -m68000
       -mc68000
	   Generate output for a 68000.	 This is the default when the compiler
	   is configured for 68000-based systems.  It is equivalent to
	   -march=68000.

	   Use this option for microcontrollers with a 68000 or EC000 core,
	   including the 68008, 68302, 68306, 68307, 68322, 68328 and 68356.

       -m68010
	   Generate output for a 68010.	 This is the default when the compiler
	   is configured for 68010-based systems.  It is equivalent to
	   -march=68010.

       -m68020
       -mc68020
	   Generate output for a 68020.	 This is the default when the compiler
	   is configured for 68020-based systems.  It is equivalent to
	   -march=68020.

       -m68030
	   Generate output for a 68030.	 This is the default when the compiler
	   is configured for 68030-based systems.  It is equivalent to
	   -march=68030.

       -m68040
	   Generate output for a 68040.	 This is the default when the compiler
	   is configured for 68040-based systems.  It is equivalent to
	   -march=68040.

	   This option inhibits the use of 68881/68882 instructions that have
	   to be emulated by software on the 68040.  Use this option if your
	   68040 does not have code to emulate those instructions.

       -m68060
	   Generate output for a 68060.	 This is the default when the compiler
	   is configured for 68060-based systems.  It is equivalent to
	   -march=68060.

	   This option inhibits the use of 68020 and 68881/68882 instructions
	   that have to be emulated by software on the 68060.  Use this option
	   if your 68060 does not have code to emulate those instructions.

       -mcpu32
	   Generate output for a CPU32.	 This is the default when the compiler
	   is configured for CPU32-based systems.  It is equivalent to
	   -march=cpu32.

	   Use this option for microcontrollers with a CPU32 or CPU32+ core,
	   including the 68330, 68331, 68332, 68333, 68334, 68336, 68340,
	   68341, 68349 and 68360.

       -m5200
	   Generate output for a 520X ColdFire CPU.  This is the default when
	   the compiler is configured for 520X-based systems.  It is
	   equivalent to -mcpu=5206, and is now deprecated in favor of that
	   option.

	   Use this option for microcontroller with a 5200 core, including the
	   MCF5202, MCF5203, MCF5204 and MCF5206.

       -m5206e
	   Generate output for a 5206e ColdFire CPU.  The option is now
	   deprecated in favor of the equivalent -mcpu=5206e.

       -m528x
	   Generate output for a member of the ColdFire 528X family.  The
	   option is now deprecated in favor of the equivalent -mcpu=528x.

       -m5307
	   Generate output for a ColdFire 5307 CPU.  The option is now
	   deprecated in favor of the equivalent -mcpu=5307.

       -m5407
	   Generate output for a ColdFire 5407 CPU.  The option is now
	   deprecated in favor of the equivalent -mcpu=5407.

       -mcfv4e
	   Generate output for a ColdFire V4e family CPU (e.g. 547x/548x).
	   This includes use of hardware floating-point instructions.  The
	   option is equivalent to -mcpu=547x, and is now deprecated in favor
	   of that option.

       -m68020-40
	   Generate output for a 68040, without using any of the new
	   instructions.  This results in code that can run relatively
	   efficiently on either a 68020/68881 or a 68030 or a 68040.  The
	   generated code does use the 68881 instructions that are emulated on
	   the 68040.

	   The option is equivalent to -march=68020 -mtune=68020-40.

       -m68020-60
	   Generate output for a 68060, without using any of the new
	   instructions.  This results in code that can run relatively
	   efficiently on either a 68020/68881 or a 68030 or a 68040.  The
	   generated code does use the 68881 instructions that are emulated on
	   the 68060.

	   The option is equivalent to -march=68020 -mtune=68020-60.

       -mhard-float
       -m68881
	   Generate floating-point instructions.  This is the default for
	   68020 and above, and for ColdFire devices that have an FPU.	It
	   defines the macro "__HAVE_68881__" on M680x0 targets and
	   "__mcffpu__" on ColdFire targets.

       -msoft-float
	   Do not generate floating-point instructions; use library calls
	   instead.  This is the default for 68000, 68010, and 68832 targets.
	   It is also the default for ColdFire devices that have no FPU.

       -mdiv
       -mno-div
	   Generate (do not generate) ColdFire hardware divide and remainder
	   instructions.  If -march is used without -mcpu, the default is "on"
	   for ColdFire architectures and "off" for M680x0 architectures.
	   Otherwise, the default is taken from the target CPU (either the
	   default CPU, or the one specified by -mcpu).	 For example, the
	   default is "off" for -mcpu=5206 and "on" for -mcpu=5206e.

	   GCC defines the macro "__mcfhwdiv__" when this option is enabled.

       -mshort
	   Consider type "int" to be 16 bits wide, like "short int".
	   Additionally, parameters passed on the stack are also aligned to a
	   16-bit boundary even on targets whose API mandates promotion to
	   32-bit.

       -mno-short
	   Do not consider type "int" to be 16 bits wide.  This is the
	   default.

       -mnobitfield
       -mno-bitfield
	   Do not use the bit-field instructions.  The -m68000, -mcpu32 and
	   -m5200 options imply -mnobitfield.

       -mbitfield
	   Do use the bit-field instructions.  The -m68020 option implies
	   -mbitfield.	This is the default if you use a configuration
	   designed for a 68020.

       -mrtd
	   Use a different function-calling convention, in which functions
	   that take a fixed number of arguments return with the "rtd"
	   instruction, which pops their arguments while returning.  This
	   saves one instruction in the caller since there is no need to pop
	   the arguments there.

	   This calling convention is incompatible with the one normally used
	   on Unix, so you cannot use it if you need to call libraries
	   compiled with the Unix compiler.

	   Also, you must provide function prototypes for all functions that
	   take variable numbers of arguments (including "printf"); otherwise
	   incorrect code is generated for calls to those functions.

	   In addition, seriously incorrect code results if you call a
	   function with too many arguments.  (Normally, extra arguments are
	   harmlessly ignored.)

	   The "rtd" instruction is supported by the 68010, 68020, 68030,
	   68040, 68060 and CPU32 processors, but not by the 68000 or 5200.

	   The default is -mno-rtd.

       -malign-int
       -mno-align-int
	   Control whether GCC aligns "int", "long", "long long", "float",
	   "double", and "long double" variables on a 32-bit boundary
	   (-malign-int) or a 16-bit boundary (-mno-align-int).	 Aligning
	   variables on 32-bit boundaries produces code that runs somewhat
	   faster on processors with 32-bit busses at the expense of more
	   memory.

	   Warning: if you use the -malign-int switch, GCC aligns structures
	   containing the above types differently than most published
	   application binary interface specifications for the m68k.

	   Use the pc-relative addressing mode of the 68000 directly, instead
	   of using a global offset table.  At present, this option implies
	   -fpic, allowing at most a 16-bit offset for pc-relative addressing.
	   -fPIC is not presently supported with -mpcrel, though this could be
	   supported for 68020 and higher processors.

       -mno-strict-align
       -mstrict-align
	   Do not (do) assume that unaligned memory references are handled by
	   the system.

       -msep-data
	   Generate code that allows the data segment to be located in a
	   different area of memory from the text segment.  This allows for
	   execute-in-place in an environment without virtual memory
	   management.	This option implies -fPIC.

       -mno-sep-data
	   Generate code that assumes that the data segment follows the text
	   segment.  This is the default.

       -mid-shared-library
	   Generate code that supports shared libraries via the library ID
	   method.  This allows for execute-in-place and shared libraries in
	   an environment without virtual memory management.  This option
	   implies -fPIC.

       -mno-id-shared-library
	   Generate code that doesn't assume ID-based shared libraries are
	   being used.	This is the default.

       -mshared-library-id=n
	   Specifies the identification number of the ID-based shared library
	   being compiled.  Specifying a value of 0 generates more compact
	   code; specifying other values forces the allocation of that number
	   to the current library, but is no more space- or time-efficient
	   than omitting this option.

       -mxgot
       -mno-xgot
	   When generating position-independent code for ColdFire, generate
	   code that works if the GOT has more than 8192 entries.  This code
	   is larger and slower than code generated without this option.  On
	   M680x0 processors, this option is not needed; -fPIC suffices.

	   GCC normally uses a single instruction to load values from the GOT.
	   While this is relatively efficient, it only works if the GOT is
	   smaller than about 64k.  Anything larger causes the linker to
	   report an error such as:

		   relocation truncated to fit: R_68K_GOT16O foobar

	   If this happens, you should recompile your code with -mxgot.	 It
	   should then work with very large GOTs.  However, code generated
	   with -mxgot is less efficient, since it takes 4 instructions to
	   fetch the value of a global symbol.

	   Note that some linkers, including newer versions of the GNU linker,
	   can create multiple GOTs and sort GOT entries.  If you have such a
	   linker, you should only need to use -mxgot when compiling a single
	   object file that accesses more than 8192 GOT entries.  Very few do.

	   These options have no effect unless GCC is generating position-
	   independent code.

       -mlong-jump-table-offsets
	   Use 32-bit offsets in "switch" tables.  The default is to use
	   16-bit offsets.

       MCore Options

       These are the -m options defined for the Motorola M*Core processors.

       -mhardlit
       -mno-hardlit
	   Inline constants into the code stream if it can be done in two
	   instructions or less.

       -mdiv
       -mno-div
	   Use the divide instruction.	(Enabled by default).

       -mrelax-immediate
       -mno-relax-immediate
	   Allow arbitrary-sized immediates in bit operations.

       -mwide-bitfields
       -mno-wide-bitfields
	   Always treat bit-fields as "int"-sized.

       -m4byte-functions
       -mno-4byte-functions
	   Force all functions to be aligned to a 4-byte boundary.

       -mcallgraph-data
       -mno-callgraph-data
	   Emit callgraph information.

       -mslow-bytes
       -mno-slow-bytes
	   Prefer word access when reading byte quantities.

       -mlittle-endian
       -mbig-endian
	   Generate code for a little-endian target.

       -m210
       -m340
	   Generate code for the 210 processor.

       -mno-lsim
	   Assume that runtime support has been provided and so omit the
	   simulator library (libsim.a) from the linker command line.

       -mstack-increment=size
	   Set the maximum amount for a single stack increment operation.
	   Large values can increase the speed of programs that contain
	   functions that need a large amount of stack space, but they can
	   also trigger a segmentation fault if the stack is extended too
	   much.  The default value is 0x1000.

       MicroBlaze Options

       -msoft-float
	   Use software emulation for floating point (default).

       -mhard-float
	   Use hardware floating-point instructions.

       -mmemcpy
	   Do not optimize block moves, use "memcpy".

       -mno-clearbss
	   This option is deprecated.  Use -fno-zero-initialized-in-bss
	   instead.

       -mcpu=cpu-type
	   Use features of, and schedule code for, the given CPU.  Supported
	   values are in the format vX.YY.Z, where X is a major version, YY is
	   the minor version, and Z is compatibility code.  Example values are
	   v3.00.a, v4.00.b, v5.00.a, v5.00.b, v6.00.a.

       -mxl-soft-mul
	   Use software multiply emulation (default).

       -mxl-soft-div
	   Use software emulation for divides (default).

       -mxl-barrel-shift
	   Use the hardware barrel shifter.

       -mxl-pattern-compare
	   Use pattern compare instructions.

       -msmall-divides
	   Use table lookup optimization for small signed integer divisions.

       -mxl-stack-check
	   This option is deprecated.  Use -fstack-check instead.

       -mxl-gp-opt
	   Use GP-relative ".sdata"/".sbss" sections.

       -mxl-multiply-high
	   Use multiply high instructions for high part of 32x32 multiply.

       -mxl-float-convert
	   Use hardware floating-point conversion instructions.

       -mxl-float-sqrt
	   Use hardware floating-point square root instruction.

       -mbig-endian
	   Generate code for a big-endian target.

       -mlittle-endian
	   Generate code for a little-endian target.

       -mxl-reorder
	   Use reorder instructions (swap and byte reversed load/store).

       -mxl-mode-app-model
	   Select application model app-model.	Valid models are

	   executable
	       normal executable (default), uses startup code crt0.o.

	   xmdstub
	       for use with Xilinx Microprocessor Debugger (XMD) based
	       software intrusive debug agent called xmdstub. This uses
	       startup file crt1.o and sets the start address of the program
	       to 0x800.

	   bootstrap
	       for applications that are loaded using a bootloader.  This
	       model uses startup file crt2.o which does not contain a
	       processor reset vector handler. This is suitable for
	       transferring control on a processor reset to the bootloader
	       rather than the application.

	   novectors
	       for applications that do not require any of the MicroBlaze
	       vectors. This option may be useful for applications running
	       within a monitoring application. This model uses crt3.o as a
	       startup file.

	   Option -xl-mode-app-model is a deprecated alias for -mxl-mode-app-
	   model.

       -mpic-data-is-text-relative
	   Assume that the displacement between the text and data segments is
	   fixed at static link time.  This allows data to be referenced by
	   offset from start of text address instead of GOT since PC-relative
	   addressing is not supported.

       MIPS Options

       -EB Generate big-endian code.

       -EL Generate little-endian code.	 This is the default for mips*el-*-*
	   configurations.

       -march=arch
	   Generate code that runs on arch, which can be the name of a generic
	   MIPS ISA, or the name of a particular processor.  The ISA names
	   are: mips1, mips2, mips3, mips4, mips32, mips32r2, mips32r3,
	   mips32r5, mips32r6, mips64, mips64r2, mips64r3, mips64r5 and
	   mips64r6.  The processor names are: 4kc, 4km, 4kp, 4ksc, 4kec,
	   4kem, 4kep, 4ksd, 5kc, 5kf, 20kc, 24kc, 24kf2_1, 24kf1_1, 24kec,
	   24kef2_1, 24kef1_1, 34kc, 34kf2_1, 34kf1_1, 34kn, 74kc, 74kf2_1,
	   74kf1_1, 74kf3_2, 1004kc, 1004kf2_1, 1004kf1_1, i6400, i6500,
	   interaptiv, loongson2e, loongson2f, loongson3a, gs464, gs464e,
	   gs264e, m4k, m14k, m14kc, m14ke, m14kec, m5100, m5101, octeon,
	   octeon+, octeon2, octeon3, orion, p5600, p6600, r2000, r3000,
	   r3900, r4000, r4400, r4600, r4650, r4700, r5900, r6000, r8000,
	   rm7000, rm9000, r10000, r12000, r14000, r16000, sb1, sr71000,
	   vr4100, vr4111, vr4120, vr4130, vr4300, vr5000, vr5400, vr5500, xlr
	   and xlp.  The special value from-abi selects the most compatible
	   architecture for the selected ABI (that is, mips1 for 32-bit ABIs
	   and mips3 for 64-bit ABIs).

	   The native Linux/GNU toolchain also supports the value native,
	   which selects the best architecture option for the host processor.
	   -march=native has no effect if GCC does not recognize the
	   processor.

	   In processor names, a final 000 can be abbreviated as k (for
	   example, -march=r2k).  Prefixes are optional, and vr may be written
	   r.

	   Names of the form nf2_1 refer to processors with FPUs clocked at
	   half the rate of the core, names of the form nf1_1 refer to
	   processors with FPUs clocked at the same rate as the core, and
	   names of the form nf3_2 refer to processors with FPUs clocked a
	   ratio of 3:2 with respect to the core.  For compatibility reasons,
	   nf is accepted as a synonym for nf2_1 while nx and bfx are accepted
	   as synonyms for nf1_1.

	   GCC defines two macros based on the value of this option.  The
	   first is "_MIPS_ARCH", which gives the name of target architecture,
	   as a string.	 The second has the form "_MIPS_ARCH_foo", where foo
	   is the capitalized value of "_MIPS_ARCH".  For example,
	   -march=r2000 sets "_MIPS_ARCH" to "r2000" and defines the macro
	   "_MIPS_ARCH_R2000".

	   Note that the "_MIPS_ARCH" macro uses the processor names given
	   above.  In other words, it has the full prefix and does not
	   abbreviate 000 as k.	 In the case of from-abi, the macro names the
	   resolved architecture (either "mips1" or "mips3").  It names the
	   default architecture when no -march option is given.

       -mtune=arch
	   Optimize for arch.  Among other things, this option controls the
	   way instructions are scheduled, and the perceived cost of
	   arithmetic operations.  The list of arch values is the same as for
	   -march.

	   When this option is not used, GCC optimizes for the processor
	   specified by -march.	 By using -march and -mtune together, it is
	   possible to generate code that runs on a family of processors, but
	   optimize the code for one particular member of that family.

	   -mtune defines the macros "_MIPS_TUNE" and "_MIPS_TUNE_foo", which
	   work in the same way as the -march ones described above.

       -mips1
	   Equivalent to -march=mips1.

       -mips2
	   Equivalent to -march=mips2.

       -mips3
	   Equivalent to -march=mips3.

       -mips4
	   Equivalent to -march=mips4.

       -mips32
	   Equivalent to -march=mips32.

       -mips32r3
	   Equivalent to -march=mips32r3.

       -mips32r5
	   Equivalent to -march=mips32r5.

       -mips32r6
	   Equivalent to -march=mips32r6.

       -mips64
	   Equivalent to -march=mips64.

       -mips64r2
	   Equivalent to -march=mips64r2.

       -mips64r3
	   Equivalent to -march=mips64r3.

       -mips64r5
	   Equivalent to -march=mips64r5.

       -mips64r6
	   Equivalent to -march=mips64r6.

       -mips16
       -mno-mips16
	   Generate (do not generate) MIPS16 code.  If GCC is targeting a
	   MIPS32 or MIPS64 architecture, it makes use of the MIPS16e ASE.

	   MIPS16 code generation can also be controlled on a per-function
	   basis by means of "mips16" and "nomips16" attributes.

       -mmips16e2
       -mno-mips16e2
	   Use (do not use) the MIPS16e2 ASE.  This option modifies the
	   behavior of the -mips16 option such that it targets the MIPS16e2
	   ASE.

       -mflip-mips16
	   Generate MIPS16 code on alternating functions.  This option is
	   provided for regression testing of mixed MIPS16/non-MIPS16 code
	   generation, and is not intended for ordinary use in compiling user
	   code.

       -minterlink-compressed
       -mno-interlink-compressed
	   Require (do not require) that code using the standard
	   (uncompressed) MIPS ISA be link-compatible with MIPS16 and
	   microMIPS code, and vice versa.

	   For example, code using the standard ISA encoding cannot jump
	   directly to MIPS16 or microMIPS code; it must either use a call or
	   an indirect jump.  -minterlink-compressed therefore disables direct
	   jumps unless GCC knows that the target of the jump is not
	   compressed.

       -minterlink-mips16
       -mno-interlink-mips16
	   Aliases of -minterlink-compressed and -mno-interlink-compressed.
	   These options predate the microMIPS ASE and are retained for
	   backwards compatibility.

       -mabi=32
       -mabi=o64
       -mabi=n32
       -mabi=64
       -mabi=eabi
	   Generate code for the given ABI.

	   Note that the EABI has a 32-bit and a 64-bit variant.  GCC normally
	   generates 64-bit code when you select a 64-bit architecture, but
	   you can use -mgp32 to get 32-bit code instead.

	   For information about the O64 ABI, see
	   <https://gcc.gnu.org/projects/mipso64-abi.html>.

	   GCC supports a variant of the o32 ABI in which floating-point
	   registers are 64 rather than 32 bits wide.  You can select this
	   combination with -mabi=32 -mfp64.  This ABI relies on the "mthc1"
	   and "mfhc1" instructions and is therefore only supported for
	   MIPS32R2, MIPS32R3 and MIPS32R5 processors.

	   The register assignments for arguments and return values remain the
	   same, but each scalar value is passed in a single 64-bit register
	   rather than a pair of 32-bit registers.  For example, scalar
	   floating-point values are returned in $f0 only, not a $f0/$f1 pair.
	   The set of call-saved registers also remains the same in that the
	   even-numbered double-precision registers are saved.

	   Two additional variants of the o32 ABI are supported to enable a
	   transition from 32-bit to 64-bit registers.	These are FPXX
	   (-mfpxx) and FP64A (-mfp64 -mno-odd-spreg).	The FPXX extension
	   mandates that all code must execute correctly when run using 32-bit
	   or 64-bit registers.	 The code can be interlinked with either FP32
	   or FP64, but not both.  The FP64A extension is similar to the FP64
	   extension but forbids the use of odd-numbered single-precision
	   registers.  This can be used in conjunction with the "FRE" mode of
	   FPUs in MIPS32R5 processors and allows both FP32 and FP64A code to
	   interlink and run in the same process without changing FPU modes.

       -mabicalls
       -mno-abicalls
	   Generate (do not generate) code that is suitable for SVR4-style
	   dynamic objects.  -mabicalls is the default for SVR4-based systems.

       -mshared
       -mno-shared
	   Generate (do not generate) code that is fully position-independent,
	   and that can therefore be linked into shared libraries.  This
	   option only affects -mabicalls.

	   All -mabicalls code has traditionally been position-independent,
	   regardless of options like -fPIC and -fpic.	However, as an
	   extension, the GNU toolchain allows executables to use absolute
	   accesses for locally-binding symbols.  It can also use shorter GP
	   initialization sequences and generate direct calls to locally-
	   defined functions.  This mode is selected by -mno-shared.

	   -mno-shared depends on binutils 2.16 or higher and generates
	   objects that can only be linked by the GNU linker.  However, the
	   option does not affect the ABI of the final executable; it only
	   affects the ABI of relocatable objects.  Using -mno-shared
	   generally makes executables both smaller and quicker.

	   -mshared is the default.

       -mplt
       -mno-plt
	   Assume (do not assume) that the static and dynamic linkers support
	   PLTs and copy relocations.  This option only affects -mno-shared
	   -mabicalls.	For the n64 ABI, this option has no effect without
	   -msym32.

	   You can make -mplt the default by configuring GCC with
	   --with-mips-plt.  The default is -mno-plt otherwise.

       -mxgot
       -mno-xgot
	   Lift (do not lift) the usual restrictions on the size of the global
	   offset table.

	   GCC normally uses a single instruction to load values from the GOT.
	   While this is relatively efficient, it only works if the GOT is
	   smaller than about 64k.  Anything larger causes the linker to
	   report an error such as:

		   relocation truncated to fit: R_MIPS_GOT16 foobar

	   If this happens, you should recompile your code with -mxgot.	 This
	   works with very large GOTs, although the code is also less
	   efficient, since it takes three instructions to fetch the value of
	   a global symbol.

	   Note that some linkers can create multiple GOTs.  If you have such
	   a linker, you should only need to use -mxgot when a single object
	   file accesses more than 64k's worth of GOT entries.	Very few do.

	   These options have no effect unless GCC is generating position
	   independent code.

       -mgp32
	   Assume that general-purpose registers are 32 bits wide.

       -mgp64
	   Assume that general-purpose registers are 64 bits wide.

       -mfp32
	   Assume that floating-point registers are 32 bits wide.

       -mfp64
	   Assume that floating-point registers are 64 bits wide.

       -mfpxx
	   Do not assume the width of floating-point registers.

       -mhard-float
	   Use floating-point coprocessor instructions.

       -msoft-float
	   Do not use floating-point coprocessor instructions.	Implement
	   floating-point calculations using library calls instead.

       -mno-float
	   Equivalent to -msoft-float, but additionally asserts that the
	   program being compiled does not perform any floating-point
	   operations.	This option is presently supported only by some bare-
	   metal MIPS configurations, where it may select a special set of
	   libraries that lack all floating-point support (including, for
	   example, the floating-point "printf" formats).  If code compiled
	   with -mno-float accidentally contains floating-point operations, it
	   is likely to suffer a link-time or run-time failure.

       -msingle-float
	   Assume that the floating-point coprocessor only supports single-
	   precision operations.

       -mdouble-float
	   Assume that the floating-point coprocessor supports double-
	   precision operations.  This is the default.

       -modd-spreg
       -mno-odd-spreg
	   Enable the use of odd-numbered single-precision floating-point
	   registers for the o32 ABI.  This is the default for processors that
	   are known to support these registers.  When using the o32 FPXX ABI,
	   -mno-odd-spreg is set by default.

       -mabs=2008
       -mabs=legacy
	   These options control the treatment of the special not-a-number
	   (NaN) IEEE 754 floating-point data with the "abs.fmt" and "neg.fmt"
	   machine instructions.

	   By default or when -mabs=legacy is used the legacy treatment is
	   selected.  In this case these instructions are considered
	   arithmetic and avoided where correct operation is required and the
	   input operand might be a NaN.  A longer sequence of instructions
	   that manipulate the sign bit of floating-point datum manually is
	   used instead unless the -ffinite-math-only option has also been
	   specified.

	   The -mabs=2008 option selects the IEEE 754-2008 treatment.  In this
	   case these instructions are considered non-arithmetic and therefore
	   operating correctly in all cases, including in particular where the
	   input operand is a NaN.  These instructions are therefore always
	   used for the respective operations.

       -mnan=2008
       -mnan=legacy
	   These options control the encoding of the special not-a-number
	   (NaN) IEEE 754 floating-point data.

	   The -mnan=legacy option selects the legacy encoding.	 In this case
	   quiet NaNs (qNaNs) are denoted by the first bit of their trailing
	   significand field being 0, whereas signaling NaNs (sNaNs) are
	   denoted by the first bit of their trailing significand field being
	   1.

	   The -mnan=2008 option selects the IEEE 754-2008 encoding.  In this
	   case qNaNs are denoted by the first bit of their trailing
	   significand field being 1, whereas sNaNs are denoted by the first
	   bit of their trailing significand field being 0.

	   The default is -mnan=legacy unless GCC has been configured with
	   --with-nan=2008.

       -mllsc
       -mno-llsc
	   Use (do not use) ll, sc, and sync instructions to implement atomic
	   memory built-in functions.  When neither option is specified, GCC
	   uses the instructions if the target architecture supports them.

	   -mllsc is useful if the runtime environment can emulate the
	   instructions and -mno-llsc can be useful when compiling for
	   nonstandard ISAs.  You can make either option the default by
	   configuring GCC with --with-llsc and --without-llsc respectively.
	   --with-llsc is the default for some configurations; see the
	   installation documentation for details.

       -mdsp
       -mno-dsp
	   Use (do not use) revision 1 of the MIPS DSP ASE.
	     This option defines the preprocessor macro "__mips_dsp".  It also
	   defines "__mips_dsp_rev" to 1.

       -mdspr2
       -mno-dspr2
	   Use (do not use) revision 2 of the MIPS DSP ASE.
	     This option defines the preprocessor macros "__mips_dsp" and
	   "__mips_dspr2".  It also defines "__mips_dsp_rev" to 2.

       -msmartmips
       -mno-smartmips
	   Use (do not use) the MIPS SmartMIPS ASE.

       -mpaired-single
       -mno-paired-single
	   Use (do not use) paired-single floating-point instructions.
	     This option requires hardware floating-point support to be
	   enabled.

       -mdmx
       -mno-mdmx
	   Use (do not use) MIPS Digital Media Extension instructions.	This
	   option can only be used when generating 64-bit code and requires
	   hardware floating-point support to be enabled.

       -mips3d
       -mno-mips3d
	   Use (do not use) the MIPS-3D ASE.  The option -mips3d implies
	   -mpaired-single.

       -mmicromips
       -mno-micromips
	   Generate (do not generate) microMIPS code.

	   MicroMIPS code generation can also be controlled on a per-function
	   basis by means of "micromips" and "nomicromips" attributes.

       -mmt
       -mno-mt
	   Use (do not use) MT Multithreading instructions.

       -mmcu
       -mno-mcu
	   Use (do not use) the MIPS MCU ASE instructions.

       -meva
       -mno-eva
	   Use (do not use) the MIPS Enhanced Virtual Addressing instructions.

       -mvirt
       -mno-virt
	   Use (do not use) the MIPS Virtualization (VZ) instructions.

       -mxpa
       -mno-xpa
	   Use (do not use) the MIPS eXtended Physical Address (XPA)
	   instructions.

       -mcrc
       -mno-crc
	   Use (do not use) the MIPS Cyclic Redundancy Check (CRC)
	   instructions.

       -mginv
       -mno-ginv
	   Use (do not use) the MIPS Global INValidate (GINV) instructions.

       -mloongson-mmi
       -mno-loongson-mmi
	   Use (do not use) the MIPS Loongson MultiMedia extensions
	   Instructions (MMI).

       -mloongson-ext
       -mno-loongson-ext
	   Use (do not use) the MIPS Loongson EXTensions (EXT) instructions.

       -mloongson-ext2
       -mno-loongson-ext2
	   Use (do not use) the MIPS Loongson EXTensions r2 (EXT2)
	   instructions.

       -mlong64
	   Force "long" types to be 64 bits wide.  See -mlong32 for an
	   explanation of the default and the way that the pointer size is
	   determined.

       -mlong32
	   Force "long", "int", and pointer types to be 32 bits wide.

	   The default size of "int"s, "long"s and pointers depends on the
	   ABI.	 All the supported ABIs use 32-bit "int"s.  The n64 ABI uses
	   64-bit "long"s, as does the 64-bit EABI; the others use 32-bit
	   "long"s.  Pointers are the same size as "long"s, or the same size
	   as integer registers, whichever is smaller.

       -msym32
       -mno-sym32
	   Assume (do not assume) that all symbols have 32-bit values,
	   regardless of the selected ABI.  This option is useful in
	   combination with -mabi=64 and -mno-abicalls because it allows GCC
	   to generate shorter and faster references to symbolic addresses.

       -G num
	   Put definitions of externally-visible data in a small data section
	   if that data is no bigger than num bytes.  GCC can then generate
	   more efficient accesses to the data; see -mgpopt for details.

	   The default -G option depends on the configuration.

       -mlocal-sdata
       -mno-local-sdata
	   Extend (do not extend) the -G behavior to local data too, such as
	   to static variables in C.  -mlocal-sdata is the default for all
	   configurations.

	   If the linker complains that an application is using too much small
	   data, you might want to try rebuilding the less performance-
	   critical parts with -mno-local-sdata.  You might also want to build
	   large libraries with -mno-local-sdata, so that the libraries leave
	   more room for the main program.

       -mextern-sdata
       -mno-extern-sdata
	   Assume (do not assume) that externally-defined data is in a small
	   data section if the size of that data is within the -G limit.
	   -mextern-sdata is the default for all configurations.

	   If you compile a module Mod with -mextern-sdata -G num -mgpopt, and
	   Mod references a variable Var that is no bigger than num bytes, you
	   must make sure that Var is placed in a small data section.  If Var
	   is defined by another module, you must either compile that module
	   with a high-enough -G setting or attach a "section" attribute to
	   Var's definition.  If Var is common, you must link the application
	   with a high-enough -G setting.

	   The easiest way of satisfying these restrictions is to compile and
	   link every module with the same -G option.  However, you may wish
	   to build a library that supports several different small data
	   limits.  You can do this by compiling the library with the highest
	   supported -G setting and additionally using -mno-extern-sdata to
	   stop the library from making assumptions about externally-defined
	   data.

       -mgpopt
       -mno-gpopt
	   Use (do not use) GP-relative accesses for symbols that are known to
	   be in a small data section; see -G, -mlocal-sdata and
	   -mextern-sdata.  -mgpopt is the default for all configurations.

	   -mno-gpopt is useful for cases where the $gp register might not
	   hold the value of "_gp".  For example, if the code is part of a
	   library that might be used in a boot monitor, programs that call
	   boot monitor routines pass an unknown value in $gp.	(In such
	   situations, the boot monitor itself is usually compiled with -G0.)

	   -mno-gpopt implies -mno-local-sdata and -mno-extern-sdata.

       -membedded-data
       -mno-embedded-data
	   Allocate variables to the read-only data section first if possible,
	   then next in the small data section if possible, otherwise in data.
	   This gives slightly slower code than the default, but reduces the
	   amount of RAM required when executing, and thus may be preferred
	   for some embedded systems.

       -muninit-const-in-rodata
       -mno-uninit-const-in-rodata
	   Put uninitialized "const" variables in the read-only data section.
	   This option is only meaningful in conjunction with -membedded-data.

       -mcode-readable=setting
	   Specify whether GCC may generate code that reads from executable
	   sections.  There are three possible settings:

	   -mcode-readable=yes
	       Instructions may freely access executable sections.  This is
	       the default setting.

	   -mcode-readable=pcrel
	       MIPS16 PC-relative load instructions can access executable
	       sections, but other instructions must not do so.	 This option
	       is useful on 4KSc and 4KSd processors when the code TLBs have
	       the Read Inhibit bit set.  It is also useful on processors that
	       can be configured to have a dual instruction/data SRAM
	       interface and that, like the M4K, automatically redirect PC-
	       relative loads to the instruction RAM.

	   -mcode-readable=no
	       Instructions must not access executable sections.  This option
	       can be useful on targets that are configured to have a dual
	       instruction/data SRAM interface but that (unlike the M4K) do
	       not automatically redirect PC-relative loads to the instruction
	       RAM.

       -msplit-addresses
       -mno-split-addresses
	   Enable (disable) use of the %hi() and %lo() assembler relocation
	   operators.  This option has been superseded by -mexplicit-relocs
	   but is retained for backwards compatibility.

       -mexplicit-relocs=none
       -mexplicit-relocs=base
       -mexplicit-relocs=pcrel
       -mexplicit-relocs
       -mno-explicit-relocs
	   These options control whether explicit relocs (such as %gp_rel) are
	   used.  The default value depends on the version of GAS when GCC
	   itself was built.

	   The "base" explicit-relocs support introdunced into GAS in 2001.
	   The "pcrel" explicit-relocs support introdunced into GAS in 2014,
	   which supports %pcrel_hi and %pcrel_lo.

       -mcheck-zero-division
       -mno-check-zero-division
	   Trap (do not trap) on integer division by zero.

	   The default is -mcheck-zero-division.

       -mdivide-traps
       -mdivide-breaks
	   MIPS systems check for division by zero by generating either a
	   conditional trap or a break instruction.  Using traps results in
	   smaller code, but is only supported on MIPS II and later.  Also,
	   some versions of the Linux kernel have a bug that prevents trap
	   from generating the proper signal ("SIGFPE").  Use -mdivide-traps
	   to allow conditional traps on architectures that support them and
	   -mdivide-breaks to force the use of breaks.

	   The default is usually -mdivide-traps, but this can be overridden
	   at configure time using --with-divide=breaks.  Divide-by-zero
	   checks can be completely disabled using -mno-check-zero-division.

       -mload-store-pairs
       -mno-load-store-pairs
	   Enable (disable) an optimization that pairs consecutive load or
	   store instructions to enable load/store bonding.  This option is
	   enabled by default but only takes effect when the selected
	   architecture is known to support bonding.

       -mstrict-align
       -mno-strict-align
       -munaligned-access
       -mno-unaligned-access
	   Disable (enable) direct unaligned access for MIPS Release 6.
	   MIPSr6 requires load/store unaligned-access support, by hardware or
	   trap&emulate.  So -mstrict-align may be needed by kernel.  The
	   options -munaligned-access and -mno-unaligned-access are obsoleted,
	   and only for backward-compatible.

       -mmemcpy
       -mno-memcpy
	   Force (do not force) the use of "memcpy" for non-trivial block
	   moves.  The default is -mno-memcpy, which allows GCC to inline most
	   constant-sized copies.

       -mlong-calls
       -mno-long-calls
	   Disable (do not disable) use of the "jal" instruction.  Calling
	   functions using "jal" is more efficient but requires the caller and
	   callee to be in the same 256 megabyte segment.

	   This option has no effect on abicalls code.	The default is
	   -mno-long-calls.

       -mmad
       -mno-mad
	   Enable (disable) use of the "mad", "madu" and "mul" instructions,
	   as provided by the R4650 ISA.

       -mimadd
       -mno-imadd
	   Enable (disable) use of the "madd" and "msub" integer instructions.
	   The default is -mimadd on architectures that support "madd" and
	   "msub" except for the 74k architecture where it was found to
	   generate slower code.

       -mfused-madd
       -mno-fused-madd
	   Enable (disable) use of the floating-point multiply-accumulate
	   instructions, when they are available.  The default is
	   -mfused-madd.

	   On the R8000 CPU when multiply-accumulate instructions are used,
	   the intermediate product is calculated to infinite precision and is
	   not subject to the FCSR Flush to Zero bit.  This may be undesirable
	   in some circumstances.  On other processors the result is
	   numerically identical to the equivalent computation using separate
	   multiply, add, subtract and negate instructions.

       -nocpp
	   Tell the MIPS assembler to not run its preprocessor over user
	   assembler files (with a .s suffix) when assembling them.

       -mfix-24k
       -mno-fix-24k
	   Work around the 24K E48 (lost data on stores during refill) errata.
	   The workarounds are implemented by the assembler rather than by
	   GCC.

       -mfix-r4000
       -mno-fix-r4000
	   Work around certain R4000 CPU errata:

	   -   A double-word or a variable shift may give an incorrect result
	       if executed immediately after starting an integer division.

	   -   A double-word or a variable shift may give an incorrect result
	       if executed while an integer multiplication is in progress.

	   -   An integer division may give an incorrect result if started in
	       a delay slot of a taken branch or a jump.

       -mfix-r4400
       -mno-fix-r4400
	   Work around certain R4400 CPU errata:

	   -   A double-word or a variable shift may give an incorrect result
	       if executed immediately after starting an integer division.

       -mfix-r10000
       -mno-fix-r10000
	   Work around certain R10000 errata:

	   -   "ll"/"sc" sequences may not behave atomically on revisions
	       prior to 3.0.  They may deadlock on revisions 2.6 and earlier.

	   This option can only be used if the target architecture supports
	   branch-likely instructions.	-mfix-r10000 is the default when
	   -march=r10000 is used; -mno-fix-r10000 is the default otherwise.

       -mfix-r5900
       -mno-fix-r5900
	   Do not attempt to schedule the preceding instruction into the delay
	   slot of a branch instruction placed at the end of a short loop of
	   six instructions or fewer and always schedule a "nop" instruction
	   there instead.  The short loop bug under certain conditions causes
	   loops to execute only once or twice, due to a hardware bug in the
	   R5900 chip.	The workaround is implemented by the assembler rather
	   than by GCC.

       -mfix-rm7000
       -mno-fix-rm7000
	   Work around the RM7000 "dmult"/"dmultu" errata.  The workarounds
	   are implemented by the assembler rather than by GCC.

       -mfix-vr4120
       -mno-fix-vr4120
	   Work around certain VR4120 errata:

	   -   "dmultu" does not always produce the correct result.

	   -   "div" and "ddiv" do not always produce the correct result if
	       one of the operands is negative.

	   The workarounds for the division errata rely on special functions
	   in libgcc.a.	 At present, these functions are only provided by the
	   "mips64vr*-elf" configurations.

	   Other VR4120 errata require a NOP to be inserted between certain
	   pairs of instructions.  These errata are handled by the assembler,
	   not by GCC itself.

       -mfix-vr4130
	   Work around the VR4130 "mflo"/"mfhi" errata.	 The workarounds are
	   implemented by the assembler rather than by GCC, although GCC
	   avoids using "mflo" and "mfhi" if the VR4130 "macc", "macchi",
	   "dmacc" and "dmacchi" instructions are available instead.

       -mfix-sb1
       -mno-fix-sb1
	   Work around certain SB-1 CPU core errata.  (This flag currently
	   works around the SB-1 revision 2 "F1" and "F2" floating-point
	   errata.)

       -mr10k-cache-barrier=setting
	   Specify whether GCC should insert cache barriers to avoid the side
	   effects of speculation on R10K processors.

	   In common with many processors, the R10K tries to predict the
	   outcome of a conditional branch and speculatively executes
	   instructions from the "taken" branch.  It later aborts these
	   instructions if the predicted outcome is wrong.  However, on the
	   R10K, even aborted instructions can have side effects.

	   This problem only affects kernel stores and, depending on the
	   system, kernel loads.  As an example, a speculatively-executed
	   store may load the target memory into cache and mark the cache line
	   as dirty, even if the store itself is later aborted.	 If a DMA
	   operation writes to the same area of memory before the "dirty" line
	   is flushed, the cached data overwrites the DMA-ed data.  See the
	   R10K processor manual for a full description, including other
	   potential problems.

	   One workaround is to insert cache barrier instructions before every
	   memory access that might be speculatively executed and that might
	   have side effects even if aborted.  -mr10k-cache-barrier=setting
	   controls GCC's implementation of this workaround.  It assumes that
	   aborted accesses to any byte in the following regions does not have
	   side effects:

	   1.  the memory occupied by the current function's stack frame;

	   2.  the memory occupied by an incoming stack argument;

	   3.  the memory occupied by an object with a link-time-constant
	       address.

	   It is the kernel's responsibility to ensure that speculative
	   accesses to these regions are indeed safe.

	   If the input program contains a function declaration such as:

		   void foo (void);

	   then the implementation of "foo" must allow "j foo" and "jal foo"
	   to be executed speculatively.  GCC honors this restriction for
	   functions it compiles itself.  It expects non-GCC functions (such
	   as hand-written assembly code) to do the same.

	   The option has three forms:

	   -mr10k-cache-barrier=load-store
	       Insert a cache barrier before a load or store that might be
	       speculatively executed and that might have side effects even if
	       aborted.

	   -mr10k-cache-barrier=store
	       Insert a cache barrier before a store that might be
	       speculatively executed and that might have side effects even if
	       aborted.

	   -mr10k-cache-barrier=none
	       Disable the insertion of cache barriers.	 This is the default
	       setting.

       -mflush-func=func
       -mno-flush-func
	   Specifies the function to call to flush the I and D caches, or to
	   not call any such function.	If called, the function must take the
	   same arguments as the common "_flush_func", that is, the address of
	   the memory range for which the cache is being flushed, the size of
	   the memory range, and the number 3 (to flush both caches).  The
	   default depends on the target GCC was configured for, but commonly
	   is either "_flush_func" or "__cpu_flush".

       -mbranch-cost=num
	   Set the cost of branches to roughly num "simple" instructions.
	   This cost is only a heuristic and is not guaranteed to produce
	   consistent results across releases.	A zero cost redundantly
	   selects the default, which is based on the -mtune setting.

       -mbranch-likely
       -mno-branch-likely
	   Enable or disable use of Branch Likely instructions, regardless of
	   the default for the selected architecture.  By default, Branch
	   Likely instructions may be generated if they are supported by the
	   selected architecture.  An exception is for the MIPS32 and MIPS64
	   architectures and processors that implement those architectures;
	   for those, Branch Likely instructions are not be generated by
	   default because the MIPS32 and MIPS64 architectures specifically
	   deprecate their use.

       -mcompact-branches=never
       -mcompact-branches=optimal
       -mcompact-branches=always
	   These options control which form of branches will be generated.
	   The default is -mcompact-branches=optimal.

	   The -mcompact-branches=never option ensures that compact branch
	   instructions will never be generated.

	   The -mcompact-branches=always option ensures that a compact branch
	   instruction will be generated if available for MIPS Release 6
	   onwards.  If a compact branch instruction is not available (or
	   pre-R6), a delay slot form of the branch will be used instead.

	   If it is used for MIPS16/microMIPS targets, it will be just ignored
	   now.	 The behaviour for MIPS16/microMIPS may change in future,
	   since they do have some compact branch instructions.

	   The -mcompact-branches=optimal option will cause a delay slot
	   branch to be used if one is available in the current ISA and the
	   delay slot is successfully filled.  If the delay slot is not
	   filled, a compact branch will be chosen if one is available.

       -mfp-exceptions
       -mno-fp-exceptions
	   Specifies whether FP exceptions are enabled.	 This affects how FP
	   instructions are scheduled for some processors.  The default is
	   that FP exceptions are enabled.

	   For instance, on the SB-1, if FP exceptions are disabled, and we
	   are emitting 64-bit code, then we can use both FP pipes.
	   Otherwise, we can only use one FP pipe.

       -mvr4130-align
       -mno-vr4130-align
	   The VR4130 pipeline is two-way superscalar, but can only issue two
	   instructions together if the first one is 8-byte aligned.  When
	   this option is enabled, GCC aligns pairs of instructions that it
	   thinks should execute in parallel.

	   This option only has an effect when optimizing for the VR4130.  It
	   normally makes code faster, but at the expense of making it bigger.
	   It is enabled by default at optimization level -O3.

       -msynci
       -mno-synci
	   Enable (disable) generation of "synci" instructions on
	   architectures that support it.  The "synci" instructions (if
	   enabled) are generated when "__builtin___clear_cache" is compiled.

	   This option defaults to -mno-synci, but the default can be
	   overridden by configuring GCC with --with-synci.

	   When compiling code for single processor systems, it is generally
	   safe to use "synci".	 However, on many multi-core (SMP) systems, it
	   does not invalidate the instruction caches on all cores and may
	   lead to undefined behavior.

       -mrelax-pic-calls
       -mno-relax-pic-calls
	   Try to turn PIC calls that are normally dispatched via register $25
	   into direct calls.  This is only possible if the linker can resolve
	   the destination at link time and if the destination is within range
	   for a direct call.

	   -mrelax-pic-calls is the default if GCC was configured to use an
	   assembler and a linker that support the ".reloc" assembly directive
	   and -mexplicit-relocs is in effect.	With -mno-explicit-relocs,
	   this optimization can be performed by the assembler and the linker
	   alone without help from the compiler.

       -mmcount-ra-address
       -mno-mcount-ra-address
	   Emit (do not emit) code that allows "_mcount" to modify the calling
	   function's return address.  When enabled, this option extends the
	   usual "_mcount" interface with a new ra-address parameter, which
	   has type "intptr_t *" and is passed in register $12.	 "_mcount" can
	   then modify the return address by doing both of the following:

	   *   Returning the new address in register $31.

	   *   Storing the new address in "*ra-address", if ra-address is
	       nonnull.

	   The default is -mno-mcount-ra-address.

       -mframe-header-opt
       -mno-frame-header-opt
	   Enable (disable) frame header optimization in the o32 ABI.  When
	   using the o32 ABI, calling functions will allocate 16 bytes on the
	   stack for the called function to write out register arguments.
	   When enabled, this optimization will suppress the allocation of the
	   frame header if it can be determined that it is unused.

	   This optimization is off by default at all optimization levels.

       -mlxc1-sxc1
       -mno-lxc1-sxc1
	   When applicable, enable (disable) the generation of "lwxc1",
	   "swxc1", "ldxc1", "sdxc1" instructions.  Enabled by default.

       -mmadd4
       -mno-madd4
	   When applicable, enable (disable) the generation of 4-operand
	   "madd.s", "madd.d" and related instructions.	 Enabled by default.

       MMIX Options

       These options are defined for the MMIX:

       -mlibfuncs
       -mno-libfuncs
	   Specify that intrinsic library functions are being compiled,
	   passing all values in registers, no matter the size.

       -mepsilon
       -mno-epsilon
	   Generate floating-point comparison instructions that compare with
	   respect to the "rE" epsilon register.

       -mabi=mmixware
       -mabi=gnu
	   Generate code that passes function parameters and return values
	   that (in the called function) are seen as registers $0 and up, as
	   opposed to the GNU ABI which uses global registers $231 and up.

       -mzero-extend
       -mno-zero-extend
	   When reading data from memory in sizes shorter than 64 bits, use
	   (do not use) zero-extending load instructions by default, rather
	   than sign-extending ones.

       -mknuthdiv
       -mno-knuthdiv
	   Make the result of a division yielding a remainder have the same
	   sign as the divisor.	 With the default, -mno-knuthdiv, the sign of
	   the remainder follows the sign of the dividend.  Both methods are
	   arithmetically valid, the latter being almost exclusively used.

       -mtoplevel-symbols
       -mno-toplevel-symbols
	   Prepend (do not prepend) a : to all global symbols, so the assembly
	   code can be used with the "PREFIX" assembly directive.

       -melf
	   Generate an executable in the ELF format, rather than the default
	   mmo format used by the mmix simulator.

       -mbranch-predict
       -mno-branch-predict
	   Use (do not use) the probable-branch instructions, when static
	   branch prediction indicates a probable branch.

       -mbase-addresses
       -mno-base-addresses
	   Generate (do not generate) code that uses base addresses.  Using a
	   base address automatically generates a request (handled by the
	   assembler and the linker) for a constant to be set up in a global
	   register.  The register is used for one or more base address
	   requests within the range 0 to 255 from the value held in the
	   register.  The generally leads to short and fast code, but the
	   number of different data items that can be addressed is limited.
	   This means that a program that uses lots of static data may require
	   -mno-base-addresses.

       -msingle-exit
       -mno-single-exit
	   Force (do not force) generated code to have a single exit point in
	   each function.

       MN10300 Options

       These -m options are defined for Matsushita MN10300 architectures:

       -mmult-bug
	   Generate code to avoid bugs in the multiply instructions for the
	   MN10300 processors.	This is the default.

       -mno-mult-bug
	   Do not generate code to avoid bugs in the multiply instructions for
	   the MN10300 processors.

       -mam33
	   Generate code using features specific to the AM33 processor.

       -mno-am33
	   Do not generate code using features specific to the AM33 processor.
	   This is the default.

       -mam33-2
	   Generate code using features specific to the AM33/2.0 processor.

       -mam34
	   Generate code using features specific to the AM34 processor.

       -mtune=cpu-type
	   Use the timing characteristics of the indicated CPU type when
	   scheduling instructions.  This does not change the targeted
	   processor type.  The CPU type must be one of mn10300, am33, am33-2
	   or am34.

       -mreturn-pointer-on-d0
	   When generating a function that returns a pointer, return the
	   pointer in both "a0" and "d0".  Otherwise, the pointer is returned
	   only in "a0", and attempts to call such functions without a
	   prototype result in errors.	Note that this option is on by
	   default; use -mno-return-pointer-on-d0 to disable it.

       -mno-crt0
	   Do not link in the C run-time initialization object file.

       -mrelax
	   Indicate to the linker that it should perform a relaxation
	   optimization pass to shorten branches, calls and absolute memory
	   addresses.  This option only has an effect when used on the command
	   line for the final link step.

	   This option makes symbolic debugging impossible.

       -mliw
	   Allow the compiler to generate Long Instruction Word instructions
	   if the target is the AM33 or later.	This is the default.  This
	   option defines the preprocessor macro "__LIW__".

       -mno-liw
	   Do not allow the compiler to generate Long Instruction Word
	   instructions.  This option defines the preprocessor macro
	   "__NO_LIW__".

       -msetlb
	   Allow the compiler to generate the SETLB and Lcc instructions if
	   the target is the AM33 or later.  This is the default.  This option
	   defines the preprocessor macro "__SETLB__".

       -mno-setlb
	   Do not allow the compiler to generate SETLB or Lcc instructions.
	   This option defines the preprocessor macro "__NO_SETLB__".

       Moxie Options

       -meb
	   Generate big-endian code.  This is the default for moxie-*-*
	   configurations.

       -mel
	   Generate little-endian code.

       -mmul.x
	   Generate mul.x and umul.x instructions.  This is the default for
	   moxiebox-*-* configurations.

       -mno-crt0
	   Do not link in the C run-time initialization object file.

       MSP430 Options

       These options are defined for the MSP430:

       -masm-hex
	   Force assembly output to always use hex constants.  Normally such
	   constants are signed decimals, but this option is available for
	   testsuite and/or aesthetic purposes.

       -mmcu=
	   Select the MCU to target.  This is used to create a C preprocessor
	   symbol based upon the MCU name, converted to upper case and pre-
	   and post-fixed with __.  This in turn is used by the msp430.h
	   header file to select an MCU-specific supplementary header file.

	   The option also sets the ISA to use.	 If the MCU name is one that
	   is known to only support the 430 ISA then that is selected,
	   otherwise the 430X ISA is selected.	A generic MCU name of msp430
	   can also be used to select the 430 ISA.  Similarly the generic
	   msp430x MCU name selects the 430X ISA.

	   In addition an MCU-specific linker script is added to the linker
	   command line.  The script's name is the name of the MCU with .ld
	   appended.  Thus specifying -mmcu=xxx on the gcc command line
	   defines the C preprocessor symbol "__XXX__" and cause the linker to
	   search for a script called xxx.ld.

	   The ISA and hardware multiply supported for the different MCUs is
	   hard-coded into GCC.	 However, an external devices.csv file can be
	   used to extend device support beyond those that have been hard-
	   coded.

	   GCC searches for the devices.csv file using the following methods
	   in the given precedence order, where the first method takes
	   precendence over the second which takes precedence over the third.

	   Include path specified with "-I" and "-L"
	       devices.csv will be searched for in each of the directories
	       specified by include paths and linker library search paths.

	   Path specified by the environment variable MSP430_GCC_INCLUDE_DIR
	       Define the value of the global environment variable
	       MSP430_GCC_INCLUDE_DIR to the full path to the directory
	       containing devices.csv, and GCC will search this directory for
	       devices.csv.  If devices.csv is found, this directory will also
	       be registered as an include path, and linker library path.
	       Header files and linker scripts in this directory can therefore
	       be used without manually specifying "-I" and "-L" on the
	       command line.

	   The msp430-elf{,bare}/include/devices directory
	       Finally, GCC will examine msp430-elf{,bare}/include/devices
	       from the toolchain root directory.  This directory does not
	       exist in a default installation, but if the user has created it
	       and copied devices.csv there, then the MCU data will be read.
	       As above, this directory will also be registered as an include
	       path, and linker library path.

	   If none of the above search methods find devices.csv, then the
	   hard-coded MCU data is used.

       -mwarn-mcu
       -mno-warn-mcu
	   This option enables or disables warnings about conflicts between
	   the MCU name specified by the -mmcu option and the ISA set by the
	   -mcpu option and/or the hardware multiply support set by the
	   -mhwmult option.  It also toggles warnings about unrecognized MCU
	   names.  This option is on by default.

       -mcpu=
	   Specifies the ISA to use.  Accepted values are msp430, msp430x and
	   msp430xv2.  This option is deprecated.  The -mmcu= option should be
	   used to select the ISA.

       -msim
	   Link to the simulator runtime libraries and linker script.
	   Overrides any scripts that would be selected by the -mmcu= option.

       -mlarge
	   Use large-model addressing (20-bit pointers, 20-bit "size_t").

       -msmall
	   Use small-model addressing (16-bit pointers, 16-bit "size_t").

       -mrelax
	   This option is passed to the assembler and linker, and allows the
	   linker to perform certain optimizations that cannot be done until
	   the final link.

       mhwmult=
	   Describes the type of hardware multiply supported by the target.
	   Accepted values are none for no hardware multiply, 16bit for the
	   original 16-bit-only multiply supported by early MCUs.  32bit for
	   the 16/32-bit multiply supported by later MCUs and f5series for the
	   16/32-bit multiply supported by F5-series MCUs.  A value of auto
	   can also be given.  This tells GCC to deduce the hardware multiply
	   support based upon the MCU name provided by the -mmcu option.  If
	   no -mmcu option is specified or if the MCU name is not recognized
	   then no hardware multiply support is assumed.  "auto" is the
	   default setting.

	   Hardware multiplies are normally performed by calling a library
	   routine.  This saves space in the generated code.  When compiling
	   at -O3 or higher however the hardware multiplier is invoked inline.
	   This makes for bigger, but faster code.

	   The hardware multiply routines disable interrupts whilst running
	   and restore the previous interrupt state when they finish.  This
	   makes them safe to use inside interrupt handlers as well as in
	   normal code.

       -minrt
	   Enable the use of a minimum runtime environment - no static
	   initializers or constructors.  This is intended for memory-
	   constrained devices.	 The compiler includes special symbols in some
	   objects that tell the linker and runtime which code fragments are
	   required.

       -mtiny-printf
	   Enable reduced code size "printf" and "puts" library functions.
	   The tiny implementations of these functions are not reentrant, so
	   must be used with caution in multi-threaded applications.

	   Support for streams has been removed and the string to be printed
	   will always be sent to stdout via the "write" syscall.  The string
	   is not buffered before it is sent to write.

	   This option requires Newlib Nano IO, so GCC must be configured with
	   --enable-newlib-nano-formatted-io.

       -mmax-inline-shift=
	   This option takes an integer between 0 and 64 inclusive, and sets
	   the maximum number of inline shift instructions which should be
	   emitted to perform a shift operation by a constant amount.  When
	   this value needs to be exceeded, an mspabi helper function is used
	   instead.  The default value is 4.

	   This only affects cases where a shift by multiple positions cannot
	   be completed with a single instruction (e.g. all shifts >1 on the
	   430 ISA).

	   Shifts of a 32-bit value are at least twice as costly, so the value
	   passed for this option is divided by 2 and the resulting value used
	   instead.

       -mcode-region=
       -mdata-region=
	   These options tell the compiler where to place functions and data
	   that do not have one of the "lower", "upper", "either" or "section"
	   attributes.	Possible values are "lower", "upper", "either" or
	   "any".  The first three behave like the corresponding attribute.
	   The fourth possible value - "any" - is the default.	It leaves
	   placement entirely up to the linker script and how it assigns the
	   standard sections (".text", ".data", etc) to the memory regions.

       -msilicon-errata=
	   This option passes on a request to assembler to enable the fixes
	   for the named silicon errata.

       -msilicon-errata-warn=
	   This option passes on a request to the assembler to enable warning
	   messages when a silicon errata might need to be applied.

       -mwarn-devices-csv
       -mno-warn-devices-csv
	   Warn if devices.csv is not found or there are problem parsing it
	   (default: on).

       NDS32 Options

       These options are defined for NDS32 implementations:

       -mbig-endian
	   Generate code in big-endian mode.

       -mlittle-endian
	   Generate code in little-endian mode.

       -mreduced-regs
	   Use reduced-set registers for register allocation.

       -mfull-regs
	   Use full-set registers for register allocation.

       -mcmov
	   Generate conditional move instructions.

       -mno-cmov
	   Do not generate conditional move instructions.

       -mext-perf
	   Generate performance extension instructions.

       -mno-ext-perf
	   Do not generate performance extension instructions.

       -mext-perf2
	   Generate performance extension 2 instructions.

       -mno-ext-perf2
	   Do not generate performance extension 2 instructions.

       -mext-string
	   Generate string extension instructions.

       -mno-ext-string
	   Do not generate string extension instructions.

       -mv3push
	   Generate v3 push25/pop25 instructions.

       -mno-v3push
	   Do not generate v3 push25/pop25 instructions.

       -m16-bit
	   Generate 16-bit instructions.

       -mno-16-bit
	   Do not generate 16-bit instructions.

       -misr-vector-size=num
	   Specify the size of each interrupt vector, which must be 4 or 16.

       -mcache-block-size=num
	   Specify the size of each cache block, which must be a power of 2
	   between 4 and 512.

       -march=arch
	   Specify the name of the target architecture.

       -mcmodel=code-model
	   Set the code model to one of

	   small
	       All the data and read-only data segments must be within 512KB
	       addressing space.  The text segment must be within 16MB
	       addressing space.

	   medium
	       The data segment must be within 512KB while the read-only data
	       segment can be within 4GB addressing space.  The text segment
	       should be still within 16MB addressing space.

	   large
	       All the text and data segments can be within 4GB addressing
	       space.

       -mctor-dtor
	   Enable constructor/destructor feature.

       -mrelax
	   Guide linker to relax instructions.

       Nios II Options

       These are the options defined for the Altera Nios II processor.

       -G num
	   Put global and static objects less than or equal to num bytes into
	   the small data or BSS sections instead of the normal data or BSS
	   sections.  The default value of num is 8.

       -mgpopt=option
       -mgpopt
       -mno-gpopt
	   Generate (do not generate) GP-relative accesses.  The following
	   option names are recognized:

	   none
	       Do not generate GP-relative accesses.

	   local
	       Generate GP-relative accesses for small data objects that are
	       not external, weak, or uninitialized common symbols.  Also use
	       GP-relative addressing for objects that have been explicitly
	       placed in a small data section via a "section" attribute.

	   global
	       As for local, but also generate GP-relative accesses for small
	       data objects that are external, weak, or common.	 If you use
	       this option, you must ensure that all parts of your program
	       (including libraries) are compiled with the same -G setting.

	   data
	       Generate GP-relative accesses for all data objects in the
	       program.	 If you use this option, the entire data and BSS
	       segments of your program must fit in 64K of memory and you must
	       use an appropriate linker script to allocate them within the
	       addressable range of the global pointer.

	   all Generate GP-relative addresses for function pointers as well as
	       data pointers.  If you use this option, the entire text, data,
	       and BSS segments of your program must fit in 64K of memory and
	       you must use an appropriate linker script to allocate them
	       within the addressable range of the global pointer.

	   -mgpopt is equivalent to -mgpopt=local, and -mno-gpopt is
	   equivalent to -mgpopt=none.

	   The default is -mgpopt except when -fpic or -fPIC is specified to
	   generate position-independent code.	Note that the Nios II ABI does
	   not permit GP-relative accesses from shared libraries.

	   You may need to specify -mno-gpopt explicitly when building
	   programs that include large amounts of small data, including large
	   GOT data sections.  In this case, the 16-bit offset for GP-relative
	   addressing may not be large enough to allow access to the entire
	   small data section.

       -mgprel-sec=regexp
	   This option specifies additional section names that can be accessed
	   via GP-relative addressing.	It is most useful in conjunction with
	   "section" attributes on variable declarations and a custom linker
	   script.  The regexp is a POSIX Extended Regular Expression.

	   This option does not affect the behavior of the -G option, and the
	   specified sections are in addition to the standard ".sdata" and
	   ".sbss" small-data sections that are recognized by -mgpopt.

       -mr0rel-sec=regexp
	   This option specifies names of sections that can be accessed via a
	   16-bit offset from "r0"; that is, in the low 32K or high 32K of the
	   32-bit address space.  It is most useful in conjunction with
	   "section" attributes on variable declarations and a custom linker
	   script.  The regexp is a POSIX Extended Regular Expression.

	   In contrast to the use of GP-relative addressing for small data,
	   zero-based addressing is never generated by default and there are
	   no conventional section names used in standard linker scripts for
	   sections in the low or high areas of memory.

       -mel
       -meb
	   Generate little-endian (default) or big-endian (experimental) code,
	   respectively.

       -march=arch
	   This specifies the name of the target Nios II architecture.	GCC
	   uses this name to determine what kind of instructions it can emit
	   when generating assembly code.  Permissible names are: r1, r2.

	   The preprocessor macro "__nios2_arch__" is available to programs,
	   with value 1 or 2, indicating the targeted ISA level.

       -mbypass-cache
       -mno-bypass-cache
	   Force all load and store instructions to always bypass cache by
	   using I/O variants of the instructions. The default is not to
	   bypass the cache.

       -mno-cache-volatile
       -mcache-volatile
	   Volatile memory access bypass the cache using the I/O variants of
	   the load and store instructions. The default is not to bypass the
	   cache.

       -mno-fast-sw-div
       -mfast-sw-div
	   Do not use table-based fast divide for small numbers. The default
	   is to use the fast divide at -O3 and above.

       -mno-hw-mul
       -mhw-mul
       -mno-hw-mulx
       -mhw-mulx
       -mno-hw-div
       -mhw-div
	   Enable or disable emitting "mul", "mulx" and "div" family of
	   instructions by the compiler. The default is to emit "mul" and not
	   emit "div" and "mulx".

       -mbmx
       -mno-bmx
       -mcdx
       -mno-cdx
	   Enable or disable generation of Nios II R2 BMX (bit manipulation)
	   and CDX (code density) instructions.	 Enabling these instructions
	   also requires -march=r2.  Since these instructions are optional
	   extensions to the R2 architecture, the default is not to emit them.

       -mcustom-insn=N
       -mno-custom-insn
	   Each -mcustom-insn=N option enables use of a custom instruction
	   with encoding N when generating code that uses insn.	 For example,
	   -mcustom-fadds=253 generates custom instruction 253 for single-
	   precision floating-point add operations instead of the default
	   behavior of using a library call.

	   The following values of insn are supported.	Except as otherwise
	   noted, floating-point operations are expected to be implemented
	   with normal IEEE 754 semantics and correspond directly to the C
	   operators or the equivalent GCC built-in functions.

	   Single-precision floating point:

	   fadds, fsubs, fdivs, fmuls
	       Binary arithmetic operations.

	   fnegs
	       Unary negation.

	   fabss
	       Unary absolute value.

	   fcmpeqs, fcmpges, fcmpgts, fcmples, fcmplts, fcmpnes
	       Comparison operations.

	   fmins, fmaxs
	       Floating-point minimum and maximum.  These instructions are
	       only generated if -ffinite-math-only is specified.

	   fsqrts
	       Unary square root operation.

	   fcoss, fsins, ftans, fatans, fexps, flogs
	       Floating-point trigonometric and exponential functions.	These
	       instructions are only generated if -funsafe-math-optimizations
	       is also specified.

	   Double-precision floating point:

	   faddd, fsubd, fdivd, fmuld
	       Binary arithmetic operations.

	   fnegd
	       Unary negation.

	   fabsd
	       Unary absolute value.

	   fcmpeqd, fcmpged, fcmpgtd, fcmpled, fcmpltd, fcmpned
	       Comparison operations.

	   fmind, fmaxd
	       Double-precision minimum and maximum.  These instructions are
	       only generated if -ffinite-math-only is specified.

	   fsqrtd
	       Unary square root operation.

	   fcosd, fsind, ftand, fatand, fexpd, flogd
	       Double-precision trigonometric and exponential functions.
	       These instructions are only generated if
	       -funsafe-math-optimizations is also specified.

	   Conversions:

	   fextsd
	       Conversion from single precision to double precision.

	   ftruncds
	       Conversion from double precision to single precision.

	   fixsi, fixsu, fixdi, fixdu
	       Conversion from floating point to signed or unsigned integer
	       types, with truncation towards zero.

	   round
	       Conversion from single-precision floating point to signed
	       integer, rounding to the nearest integer and ties away from
	       zero.  This corresponds to the "__builtin_lroundf" function
	       when -fno-math-errno is used.

	   floatis, floatus, floatid, floatud
	       Conversion from signed or unsigned integer types to floating-
	       point types.

	   In addition, all of the following transfer instructions for
	   internal registers X and Y must be provided to use any of the
	   double-precision floating-point instructions.  Custom instructions
	   taking two double-precision source operands expect the first
	   operand in the 64-bit register X.  The other operand (or only
	   operand of a unary operation) is given to the custom arithmetic
	   instruction with the least significant half in source register src1
	   and the most significant half in src2.  A custom instruction that
	   returns a double-precision result returns the most significant 32
	   bits in the destination register and the other half in 32-bit
	   register Y.	GCC automatically generates the necessary code
	   sequences to write register X and/or read register Y when double-
	   precision floating-point instructions are used.

	   fwrx
	       Write src1 into the least significant half of X and src2 into
	       the most significant half of X.

	   fwry
	       Write src1 into Y.

	   frdxhi, frdxlo
	       Read the most or least (respectively) significant half of X and
	       store it in dest.

	   frdy
	       Read the value of Y and store it into dest.

	   Note that you can gain more local control over generation of Nios
	   II custom instructions by using the target("custom-insn=N") and
	   target("no-custom-insn") function attributes or pragmas.

       -mcustom-fpu-cfg=name
	   This option enables a predefined, named set of custom instruction
	   encodings (see -mcustom-insn above).	 Currently, the following sets
	   are defined:

	   -mcustom-fpu-cfg=60-1 is equivalent to: -mcustom-fmuls=252
	   -mcustom-fadds=253 -mcustom-fsubs=254 -fsingle-precision-constant

	   -mcustom-fpu-cfg=60-2 is equivalent to: -mcustom-fmuls=252
	   -mcustom-fadds=253 -mcustom-fsubs=254 -mcustom-fdivs=255
	   -fsingle-precision-constant

	   -mcustom-fpu-cfg=72-3 is equivalent to: -mcustom-floatus=243
	   -mcustom-fixsi=244 -mcustom-floatis=245 -mcustom-fcmpgts=246
	   -mcustom-fcmples=249 -mcustom-fcmpeqs=250 -mcustom-fcmpnes=251
	   -mcustom-fmuls=252 -mcustom-fadds=253 -mcustom-fsubs=254
	   -mcustom-fdivs=255 -fsingle-precision-constant

	   -mcustom-fpu-cfg=fph2 is equivalent to: -mcustom-fabss=224
	   -mcustom-fnegs=225 -mcustom-fcmpnes=226 -mcustom-fcmpeqs=227
	   -mcustom-fcmpges=228 -mcustom-fcmpgts=229 -mcustom-fcmples=230
	   -mcustom-fcmplts=231 -mcustom-fmaxs=232 -mcustom-fmins=233
	   -mcustom-round=248 -mcustom-fixsi=249 -mcustom-floatis=250
	   -mcustom-fsqrts=251 -mcustom-fmuls=252 -mcustom-fadds=253
	   -mcustom-fsubs=254 -mcustom-fdivs=255

	   Custom instruction assignments given by individual -mcustom-insn=
	   options override those given by -mcustom-fpu-cfg=, regardless of
	   the order of the options on the command line.

	   Note that you can gain more local control over selection of a FPU
	   configuration by using the target("custom-fpu-cfg=name") function
	   attribute or pragma.

	   The name fph2 is an abbreviation for Nios II Floating Point
	   Hardware 2 Component.  Please note that the custom instructions
	   enabled by -mcustom-fmins=233 and -mcustom-fmaxs=234 are only
	   generated if -ffinite-math-only is specified.  The custom
	   instruction enabled by -mcustom-round=248 is only generated if
	   -fno-math-errno is specified.  In contrast to the other
	   configurations, -fsingle-precision-constant is not set.

       These additional -m options are available for the Altera Nios II ELF
       (bare-metal) target:

       -mhal
	   Link with HAL BSP.  This suppresses linking with the GCC-provided C
	   runtime startup and termination code, and is typically used in
	   conjunction with -msys-crt0= to specify the location of the
	   alternate startup code provided by the HAL BSP.

       -msmallc
	   Link with a limited version of the C library, -lsmallc, rather than
	   Newlib.

       -msys-crt0=startfile
	   startfile is the file name of the startfile (crt0) to use when
	   linking.  This option is only useful in conjunction with -mhal.

       -msys-lib=systemlib
	   systemlib is the library name of the library that provides low-
	   level system calls required by the C library, e.g. "read" and
	   "write".  This option is typically used to link with a library
	   provided by a HAL BSP.

       Nvidia PTX Options

       These options are defined for Nvidia PTX:

       -m64
	   Ignored, but preserved for backward compatibility.  Only 64-bit ABI
	   is supported.

       -march=architecture-string
	   Generate code for the specified PTX ISA target architecture (e.g.
	   sm_35).  Valid architecture strings are sm_30, sm_35, sm_53, sm_70,
	   sm_75 and sm_80.  The default depends on how the compiler has been
	   configured, see --with-arch.

	   This option sets the value of the preprocessor macro "__PTX_SM__";
	   for instance, for sm_35, it has the value 350.

       -misa=architecture-string
	   Alias of -march=.

       -march-map=architecture-string
	   Select the closest available -march= value that is not more
	   capable.  For instance, for -march-map=sm_50 select -march=sm_35,
	   and for -march-map=sm_53 select -march=sm_53.

       -mptx=version-string
	   Generate code for the specified PTX ISA version (e.g. 7.0).	Valid
	   version strings include 3.1, 6.0, 6.3, and 7.0.  The default PTX
	   ISA version is 6.0, unless a higher version is required for
	   specified PTX ISA target architecture via option -march=.

	   This option sets the values of the preprocessor macros
	   "__PTX_ISA_VERSION_MAJOR__" and "__PTX_ISA_VERSION_MINOR__"; for
	   instance, for 3.1 the macros have the values 3 and 1, respectively.

       -mmainkernel
	   Link in code for a __main kernel.  This is for stand-alone instead
	   of offloading execution.

       -moptimize
	   Apply partitioned execution optimizations.  This is the default
	   when any level of optimization is selected.

       -msoft-stack
	   Generate code that does not use ".local" memory directly for stack
	   storage. Instead, a per-warp stack pointer is maintained
	   explicitly. This enables variable-length stack allocation (with
	   variable-length arrays or "alloca"), and when global memory is used
	   for underlying storage, makes it possible to access automatic
	   variables from other threads, or with atomic instructions. This
	   code generation variant is used for OpenMP offloading, but the
	   option is exposed on its own for the purpose of testing the
	   compiler; to generate code suitable for linking into programs using
	   OpenMP offloading, use option -mgomp.

       -muniform-simt
	   Switch to code generation variant that allows to execute all
	   threads in each warp, while maintaining memory state and side
	   effects as if only one thread in each warp was active outside of
	   OpenMP SIMD regions.	 All atomic operations and calls to runtime
	   (malloc, free, vprintf) are conditionally executed (iff current
	   lane index equals the master lane index), and the register being
	   assigned is copied via a shuffle instruction from the master lane.
	   Outside of SIMD regions lane 0 is the master; inside, each thread
	   sees itself as the master.  Shared memory array "int __nvptx_uni[]"
	   stores all-zeros or all-ones bitmasks for each warp, indicating
	   current mode (0 outside of SIMD regions).  Each thread can bitwise-
	   and the bitmask at position "tid.y" with current lane index to
	   compute the master lane index.

       -mgomp
	   Generate code for use in OpenMP offloading: enables -msoft-stack
	   and -muniform-simt options, and selects corresponding multilib
	   variant.

       OpenRISC Options

       These options are defined for OpenRISC:

       -mboard=name
	   Configure a board specific runtime.	This will be passed to the
	   linker for newlib board library linking.  The default is "or1ksim".

       -mnewlib
	   This option is ignored; it is for compatibility purposes only.
	   This used to select linker and preprocessor options for use with
	   newlib.

       -msoft-div
       -mhard-div
	   Select software or hardware divide ("l.div", "l.divu")
	   instructions.  This default is hardware divide.

       -msoft-mul
       -mhard-mul
	   Select software or hardware multiply ("l.mul", "l.muli")
	   instructions.  This default is hardware multiply.

       -msoft-float
       -mhard-float
	   Select software or hardware for floating point operations.  The
	   default is software.

       -mdouble-float
	   When -mhard-float is selected, enables generation of double-
	   precision floating point instructions.  By default functions from
	   libgcc are used to perform double-precision floating point
	   operations.

       -munordered-float
	   When -mhard-float is selected, enables generation of unordered
	   floating point compare and set flag ("lf.sfun*") instructions.  By
	   default functions from libgcc are used to perform unordered
	   floating point compare and set flag operations.

       -mcmov
	   Enable generation of conditional move ("l.cmov") instructions.  By
	   default the equivalent will be generated using set and branch.

       -mror
	   Enable generation of rotate right ("l.ror") instructions.  By
	   default functions from libgcc are used to perform rotate right
	   operations.

       -mrori
	   Enable generation of rotate right with immediate ("l.rori")
	   instructions.  By default functions from libgcc are used to perform
	   rotate right with immediate operations.

       -msext
	   Enable generation of sign extension ("l.ext*") instructions.	 By
	   default memory loads are used to perform sign extension.

       -msfimm
	   Enable generation of compare and set flag with immediate ("l.sf*i")
	   instructions.  By default extra instructions will be generated to
	   store the immediate to a register first.

       -mshftimm
	   Enable generation of shift with immediate ("l.srai", "l.srli",
	   "l.slli") instructions.  By default extra instructions will be
	   generated to store the immediate to a register first.

       -mcmodel=small
	   Generate OpenRISC code for the small model: The GOT is limited to
	   64k. This is the default model.

       -mcmodel=large
	   Generate OpenRISC code for the large model: The GOT may grow up to
	   4G in size.

       PDP-11 Options

       These options are defined for the PDP-11:

       -mfpu
	   Use hardware FPP floating point.  This is the default.  (FIS
	   floating point on the PDP-11/40 is not supported.)  Implies -m45.

       -msoft-float
	   Do not use hardware floating point.

       -mac0
	   Return floating-point results in ac0 (fr0 in Unix assembler
	   syntax).

       -mno-ac0
	   Return floating-point results in memory.  This is the default.

       -m40
	   Generate code for a PDP-11/40.  Implies -msoft-float -mno-split.

       -m45
	   Generate code for a PDP-11/45.  This is the default.

       -m10
	   Generate code for a PDP-11/10.  Implies -msoft-float -mno-split.

       -mint16
       -mno-int32
	   Use 16-bit "int".  This is the default.

       -mint32
       -mno-int16
	   Use 32-bit "int".

       -msplit
	   Target has split instruction and data space.	 Implies -m45.

       -munix-asm
	   Use Unix assembler syntax.

       -mdec-asm
	   Use DEC assembler syntax.

       -mgnu-asm
	   Use GNU assembler syntax.  This is the default.

       -mlra
	   Use the new LRA register allocator.	By default, the old "reload"
	   allocator is used.

       PowerPC Options

       These are listed under

       PRU Options

       These command-line options are defined for PRU target:

       -minrt
	   Link with a minimum runtime environment.  This can significantly
	   reduce the size of the final ELF binary, but some standard C
	   runtime features are removed.

	   This option disables support for static initializers and
	   constructors.  Beware that the compiler could still generate code
	   with static initializers and constructors.  It is up to the
	   programmer to ensure that the source program will not use those
	   features.

	   The minimal startup code would not pass "argc" and "argv" arguments
	   to "main", so the latter must be declared as "int main (void)".
	   This is already the norm for most firmware projects.

       -mmcu=mcu
	   Specify the PRU hardware variant to use.  A correspondingly named
	   spec file would be loaded, passing the memory region sizes to the
	   linker and defining hardware-specific C macros.

	   Newlib provides only the "sim" spec, intended for running
	   regression tests using a simulator.	Specs for real hardware can be
	   obtained by installing the GnuPruMcu
	   ("https://github.com/dinuxbg/gnuprumcu/") package.

       -mno-relax
	   Make GCC pass the --no-relax command-line option to the linker
	   instead of the --relax option.

       -mloop
	   Allow (or do not allow) GCC to use the LOOP instruction.

       -mabi=variant
	   Specify the ABI variant to output code for.	-mabi=ti selects the
	   unmodified TI ABI while -mabi=gnu selects a GNU variant that copes
	   more naturally with certain GCC assumptions.	 These are the
	   differences:

	   Function Pointer Size
	       TI ABI specifies that function (code) pointers are 16-bit,
	       whereas GNU supports only 32-bit data and code pointers.

	   Optional Return Value Pointer
	       Function return values larger than 64 bits are passed by using
	       a hidden pointer as the first argument of the function.	TI
	       ABI, though, mandates that the pointer can be NULL in case the
	       caller is not using the returned value.	GNU always passes and
	       expects a valid return value pointer.

	   The current -mabi=ti implementation simply raises a compile error
	   when any of the above code constructs is detected.  As a
	   consequence the standard C library cannot be built and it is
	   omitted when linking with -mabi=ti.

	   Relaxation is a GNU feature and for safety reasons is disabled when
	   using -mabi=ti.  The TI toolchain does not emit relocations for
	   QBBx instructions, so the GNU linker cannot adjust them when
	   shortening adjacent LDI32 pseudo instructions.

       RISC-V Options

       These command-line options are defined for RISC-V targets:

       -mbranch-cost=n
	   Set the cost of branches to roughly n instructions.

       -mplt
       -mno-plt
	   When generating PIC code, do or don't allow the use of PLTs.
	   Ignored for non-PIC.	 The default is -mplt.

       -mabi=ABI-string
	   Specify integer and floating-point calling convention.  ABI-string
	   contains two parts: the size of integer types and the registers
	   used for floating-point types.  For example -march=rv64ifd
	   -mabi=lp64d means that long and pointers are 64-bit (implicitly
	   defining int to be 32-bit), and that floating-point values up to 64
	   bits wide are passed in F registers.	 Contrast this with
	   -march=rv64ifd -mabi=lp64f, which still allows the compiler to
	   generate code that uses the F and D extensions but only allows
	   floating-point values up to 32 bits long to be passed in registers;
	   or -march=rv64ifd -mabi=lp64, in which no floating-point arguments
	   will be passed in registers.

	   The default for this argument is system dependent, users who want a
	   specific calling convention should specify one explicitly.  The
	   valid calling conventions are: ilp32, ilp32f, ilp32d, lp64, lp64f,
	   and lp64d.  Some calling conventions are impossible to implement on
	   some ISAs: for example, -march=rv32if -mabi=ilp32d is invalid
	   because the ABI requires 64-bit values be passed in F registers,
	   but F registers are only 32 bits wide.  There are also the ilp32e
	   ABI that can only be used with the rv32e architecture and the lp64e
	   ABI that can only be used with the rv64e.  Those ABIs are not well
	   specified at present, and are subject to change.

       -mfdiv
       -mno-fdiv
	   Do or don't use hardware floating-point divide and square root
	   instructions.  This requires the F or D extensions for floating-
	   point registers.  The default is to use them if the specified
	   architecture has these instructions.

       -mdiv
       -mno-div
	   Do or don't use hardware instructions for integer division.	This
	   requires the M extension.  The default is to use them if the
	   specified architecture has these instructions.

       -misa-spec=ISA-spec-string
	   Specify the version of the RISC-V Unprivileged (formerly User-
	   Level) ISA specification to produce code conforming to.  The
	   possibilities for ISA-spec-string are:

	   2.2 Produce code conforming to version 2.2.

	   20190608
	       Produce code conforming to version 20190608.

	   20191213
	       Produce code conforming to version 20191213.

	   The default is -misa-spec=20191213 unless GCC has been configured
	   with --with-isa-spec= specifying a different default version.

       -march=ISA-string
	   Generate code for given RISC-V ISA (e.g. rv64im).  ISA strings must
	   be lower-case.  Examples include rv64i, rv32g, rv32e, and rv32imaf.
	   Additionally, a special value help (-march=help) is accepted to
	   list all supported extensions.

	   The syntax of the ISA string is defined as follows:

	   "The string must start with rv32 or rv64, followed by"
	       i, e, or g, referred to as the base ISA.

	   "The subsequent part of the string is a list of extension names.
	   Extension"
	       names can be categorized as multi-letter (e.g. zba) and single-
	       letter (e.g. v). Single-letter extensions can appear
	       consecutively, but multi-letter extensions must be separated by
	       underscores.

	   "An underscore can appear anywhere after the base ISA. It has no
	   specific"
	       effect but is used to improve readability and can act as a
	       separator.

	   "Extension names may include an optional version number, following
	   the"
	       syntax <major>p<minor> or <major>, (e.g. m2p1 or m2).

	   Supported extension are listed below:

	   Extension Name : Supported Version : Description
	   i   @tab 2.0, 2.1 @tab Base integer extension.

	   e   @tab 2.0 @tab Reduced base integer extension.

	   g   @tab - @tab General-purpose computing base extension, g will
	       expand to i, m, a, f, d, zicsr and zifencei.

	   m   @tab 2.0 @tab Integer multiplication and division extension.

	   a   @tab 2.0, 2.1 @tab Atomic extension.

	   f   @tab 2.0, 2.2 @tab Single-precision floating-point extension.

	   d   @tab 2.0, 2.2 @tab Double-precision floating-point extension.

	   c   @tab 2.0 @tab Compressed extension.

	   h   @tab 1.0 @tab Hypervisor extension.

	   v   @tab 1.0 @tab Vector extension.

	   zicsr
	       @tab 2.0 @tab Control and status register access extension.

	   zifencei
	       @tab 2.0 @tab Instruction-fetch fence extension.

	   zicond
	       @tab 1.0 @tab Integer conditional operations extension.

	   za64rs
	       @tab 1.0 @tab Reservation set size of 64 bytes.

	   za128rs
	       @tab 1.0 @tab Reservation set size of 128 bytes.

	   zawrs
	       @tab 1.0 @tab Wait-on-reservation-set extension.

	   zba @tab 1.0 @tab Address calculation extension.

	   zbb @tab 1.0 @tab Basic bit manipulation extension.

	   zbc @tab 1.0 @tab Carry-less multiplication extension.

	   zbs @tab 1.0 @tab Single-bit operation extension.

	   zfinx
	       @tab 1.0 @tab Single-precision floating-point in integer
	       registers extension.

	   zdinx
	       @tab 1.0 @tab Double-precision floating-point in integer
	       registers extension.

	   zhinx
	       @tab 1.0 @tab Half-precision floating-point in integer
	       registers extension.

	   zhinxmin
	       @tab 1.0 @tab Minimal half-precision floating-point in integer
	       registers extension.

	   zbkb
	       @tab 1.0 @tab Cryptography bit-manipulation extension.

	   zbkc
	       @tab 1.0 @tab Cryptography carry-less multiply extension.

	   zbkx
	       @tab 1.0 @tab Cryptography crossbar permutation extension.

	   zkne
	       @tab 1.0 @tab AES Encryption extension.

	   zknd
	       @tab 1.0 @tab AES Decryption extension.

	   zknh
	       @tab 1.0 @tab Hash function extension.

	   zkr @tab 1.0 @tab Entropy source extension.

	   zksed
	       @tab 1.0 @tab SM4 block cipher extension.

	   zksh
	       @tab 1.0 @tab SM3 hash function extension.

	   zkt @tab 1.0 @tab Data independent execution latency extension.

	   zk  @tab 1.0 @tab Standard scalar cryptography extension.

	   zkn @tab 1.0 @tab NIST algorithm suite extension.

	   zks @tab 1.0 @tab ShangMi algorithm suite extension.

	   zihintntl
	       @tab 1.0 @tab Non-temporal locality hints extension.

	   zihintpause
	       @tab 1.0 @tab Pause hint extension.

	   zicboz
	       @tab 1.0 @tab Cache-block zero extension.

	   zicbom
	       @tab 1.0 @tab Cache-block management extension.

	   zicbop
	       @tab 1.0 @tab Cache-block prefetch extension.

	   zic64b
	       @tab 1.0 @tab Cache block size isf 64 bytes.

	   ziccamoa
	       @tab 1.0 @tab Main memory supports all atomics in A.

	   ziccif
	       @tab 1.0 @tab Main memory supports instruction fetch with
	       atomicity requirement.

	   zicclsm
	       @tab 1.0 @tab Main memory supports misaligned loads/stores.

	   ziccrse
	       @tab 1.0 @tab Main memory supports forward progress on LR/SC
	       sequences.

	   zicntr
	       @tab 2.0 @tab Standard extension for base counters and timers.

	   zihpm
	       @tab 2.0 @tab Standard extension for hardware performance
	       counters.

	   ztso
	       @tab 1.0 @tab Total store ordering extension.

	   zve32x
	       @tab 1.0 @tab Vector extensions for embedded processors.

	   zve32f
	       @tab 1.0 @tab Vector extensions for embedded processors.

	   zve64x
	       @tab 1.0 @tab Vector extensions for embedded processors.

	   zve64f
	       @tab 1.0 @tab Vector extensions for embedded processors.

	   zve64d
	       @tab 1.0 @tab Vector extensions for embedded processors.

	   zvl32b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvl64b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvl128b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvl256b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvl512b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvl1024b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvl2048b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvl4096b
	       @tab 1.0 @tab Minimum vector length standard extensions

	   zvbb
	       @tab 1.0 @tab Vector basic bit-manipulation extension.

	   zvbc
	       @tab 1.0 @tab Vector carryless multiplication extension.

	   zvkb
	       @tab 1.0 @tab Vector cryptography bit-manipulation extension.

	   zvkg
	       @tab 1.0 @tab Vector GCM/GMAC extension.

	   zvkned
	       @tab 1.0 @tab Vector AES block cipher extension.

	   zvknha
	       @tab 1.0 @tab Vector SHA-2 secure hash extension.

	   zvknhb
	       @tab 1.0 @tab Vector SHA-2 secure hash extension.

	   zvksed
	       @tab 1.0 @tab Vector SM4 Block Cipher extension.

	   zvksh
	       @tab 1.0 @tab Vector SM3 Secure Hash extension.

	   zvkn
	       @tab 1.0 @tab Vector NIST Algorithm Suite extension, zvkn will
	       expand to zvkned, zvknhb, zvkb and zvkt.

	   zvknc
	       @tab 1.0 @tab Vector NIST Algorithm Suite with carryless
	       multiply extension, zvknc will expand to zvkn and zvbc.

	   zvkng
	       @tab 1.0 @tab Vector NIST Algorithm Suite with GCM extension,
	       zvkng will expand to zvkn and zvkg.

	   zvks
	       @tab 1.0 @tab Vector ShangMi algorithm suite extension, zvks
	       will expand to zvksed, zvksh, zvkb and zvkt.

	   zvksc
	       @tab 1.0 @tab Vector ShangMi algorithm suite with carryless
	       multiplication extension, zvksc will expand to zvks and zvbc.

	   zvksg
	       @tab 1.0 @tab Vector ShangMi algorithm suite with GCM
	       extension, zvksg will expand to zvks and zvkg.

	   zvkt
	       @tab 1.0 @tab Vector data independent execution latency
	       extension.

	   zfh @tab 1.0 @tab Half-precision floating-point extension.

	   zfhmin
	       @tab 1.0 @tab Minimal half-precision floating-point extension.

	   zvfh
	       @tab 1.0 @tab Vector half-precision floating-point extension.

	   zvfhmin
	       @tab 1.0 @tab Vector minimal half-precision floating-point
	       extension.

	   zvfbfmin
	       @tab 1.0 @tab Vector BF16 converts extension.

	   zfa @tab 1.0 @tab Additional floating-point extension.

	   zmmul
	       @tab 1.0 @tab Integer multiplication extension.

	   zca @tab 1.0 @tab Integer compressed instruction extension.

	   zcf @tab 1.0 @tab Compressed single-precision floating point loads
	       and stores extension.

	   zcd @tab 1.0 @tab Compressed double-precision floating point loads
	       and stores extension.

	   zcb @tab 1.0 @tab Simple compressed instruction extension.

	   zce @tab 1.0 @tab Compressed instruction extensions for embedded
	       processors.

	   zcmp
	       @tab 1.0 @tab Compressed push pop extension.

	   zcmt
	       @tab 1.0 @tab Table jump instruction extension.

	   smaia
	       @tab 1.0 @tab Advanced interrupt architecture extension.

	   smepmp
	       @tab 1.0 @tab PMP Enhancements for memory access and execution
	       prevention on Machine mode.

	   smstateen
	       @tab 1.0 @tab State enable extension.

	   ssaia
	       @tab 1.0 @tab Advanced interrupt architecture extension for
	       supervisor-mode.

	   sscofpmf
	       @tab 1.0 @tab Count overflow & filtering extension.

	   ssstateen
	       @tab 1.0 @tab State-enable extension for supervisor-mode.

	   sstc
	       @tab 1.0 @tab Supervisor-mode timer interrupts extension.

	   svinval
	       @tab 1.0 @tab Fine-grained address-translation cache
	       invalidation extension.

	   svnapot
	       @tab 1.0 @tab NAPOT translation contiguity extension.

	   svpbmt
	       @tab 1.0 @tab Page-based memory types extension.

	   xcvmac
	       @tab 1.0 @tab Core-V multiply-accumulate extension.

	   xcvalu
	       @tab 1.0 @tab Core-V miscellaneous ALU extension.

	   xcvelw
	       @tab 1.0 @tab Core-V event load word extension.

	   xtheadba
	       @tab 1.0 @tab T-head address calculation extension.

	   xtheadbb
	       @tab 1.0 @tab T-head basic bit-manipulation extension.

	   xtheadbs
	       @tab 1.0 @tab T-head single-bit instructions extension.

	   xtheadcmo
	       @tab 1.0 @tab T-head cache management operations extension.

	   xtheadcondmov
	       @tab 1.0 @tab T-head conditional move extension.

	   xtheadfmemidx
	       @tab 1.0 @tab T-head indexed memory operations for floating-
	       point registers extension.

	   xtheadfmv
	       @tab 1.0 @tab T-head double floating-point high-bit data
	       transmission extension.

	   xtheadint
	       @tab 1.0 @tab T-head acceleration interruption extension.

	   xtheadmac
	       @tab 1.0 @tab T-head multiply-accumulate extension.

	   xtheadmemidx
	       @tab 1.0 @tab T-head indexed memory operation extension.

	   xtheadmempair
	       @tab 1.0 @tab T-head two-GPR memory operation extension.

	   xtheadsync
	       @tab 1.0 @tab T-head multi-core synchronization extension.

	   xventanacondops
	       @tab 1.0 @tab Ventana integer conditional operations extension.

	   When -march= is not specified, use the setting from -mcpu.

	   If both -march and -mcpu= are not specified, the default for this
	   argument is system dependent, users who want a specific
	   architecture extensions should specify one explicitly.

       -mcpu=processor-string
	   Use architecture of and optimize the output for the given
	   processor, specified by particular CPU name.	 Permissible values
	   for this option are: sifive-e20, sifive-e21, sifive-e24,
	   sifive-e31, sifive-e34, sifive-e76, sifive-s21, sifive-s51,
	   sifive-s54, sifive-s76, sifive-u54, sifive-u74, sifive-x280,
	   sifive-xp450, sifive-x670.

	   Note that -mcpu does not override -march or -mtune.

       -mtune=processor-string
	   Optimize the output for the given processor, specified by
	   microarchitecture or particular CPU name.  Permissible values for
	   this option are: rocket, sifive-3-series, sifive-5-series,
	   sifive-7-series, thead-c906, size, sifive-p400-series,
	   sifive-p600-series, and all valid options for -mcpu=.

	   When -mtune= is not specified, use the setting from -mcpu, the
	   default is rocket if both are not specified.

	   The size choice is not intended for use by end-users.  This is used
	   when -Os is specified.  It overrides the instruction cost info
	   provided by -mtune=, but does not override the pipeline info.  This
	   helps reduce code size while still giving good performance.

       -mpreferred-stack-boundary=num
	   Attempt to keep the stack boundary aligned to a 2 raised to num
	   byte boundary.  If -mpreferred-stack-boundary is not specified, the
	   default is 4 (16 bytes or 128-bits).

	   Warning: If you use this switch, then you must build all modules
	   with the same value, including any libraries.  This includes the
	   system libraries and startup modules.

       -msmall-data-limit=n
	   Put global and static data smaller than n bytes into a special
	   section (on some targets).

       -msave-restore
       -mno-save-restore
	   Do or don't use smaller but slower prologue and epilogue code that
	   uses library function calls.	 The default is to use fast inline
	   prologues and epilogues.

       -mmovcc
       -mno-movcc
	   Do or don't produce branchless conditional-move code sequences even
	   with targets that do not have specific instructions for conditional
	   operations.	If enabled, sequences of ALU operations are produced
	   using base integer ISA instructions where profitable.

       -minline-atomics
       -mno-inline-atomics
	   Do or don't use smaller but slower subword atomic emulation code
	   that uses libatomic function calls.	The default is to use fast
	   inline subword atomics that do not require libatomic.

       -minline-strlen
       -mno-inline-strlen
	   Do or do not attempt to inline strlen calls if possible.  Inlining
	   will only be done if the string is properly aligned and
	   instructions for accelerated processing are available.  The default
	   is to not inline strlen calls.

       -minline-strcmp
       -mno-inline-strcmp
	   Do or do not attempt to inline strcmp calls if possible.  Inlining
	   will only be done if the strings are properly aligned and
	   instructions for accelerated processing are available.  The default
	   is to not inline strcmp calls.

	   The --param riscv-strcmp-inline-limit=n parameter controls the
	   maximum number of bytes compared by the inlined code.  The default
	   value is 64.

       -minline-strncmp
       -mno-inline-strncmp
	   Do or do not attempt to inline strncmp calls if possible.  Inlining
	   will only be done if the strings are properly aligned and
	   instructions for accelerated processing are available.  The default
	   is to not inline strncmp calls.

	   The --param riscv-strcmp-inline-limit=n parameter controls the
	   maximum number of bytes compared by the inlined code.  The default
	   value is 64.

       -mshorten-memrefs
       -mno-shorten-memrefs
	   Do or do not attempt to make more use of compressed load/store
	   instructions by replacing a load/store of 'base register + large
	   offset' with a new load/store of 'new base + small offset'.	If the
	   new base gets stored in a compressed register, then the new
	   load/store can be compressed.  Currently targets 32-bit integer
	   load/stores only.

       -mstrict-align
       -mno-strict-align
	   Do not or do generate unaligned memory accesses.  The default is
	   set depending on whether the processor we are optimizing for
	   supports fast unaligned access or not.

       -mcmodel=medlow
	   Generate code for the medium-low code model. The program and its
	   statically defined symbols must lie within a single 2 GiB address
	   range and must lie between absolute addresses -2 GiB and +2 GiB.
	   Programs can be statically or dynamically linked. This is the
	   default code model.

       -mcmodel=medany
	   Generate code for the medium-any code model. The program and its
	   statically defined symbols must be within any single 2 GiB address
	   range. Programs can be statically or dynamically linked.

	   The code generated by the medium-any code model is position-
	   independent, but is not guaranteed to function correctly when
	   linked into position-independent executables or libraries.

       -mexplicit-relocs
       -mno-exlicit-relocs
	   Use or do not use assembler relocation operators when dealing with
	   symbolic addresses.	The alternative is to use assembler macros
	   instead, which may limit optimization.

       -mrelax
       -mno-relax
	   Take advantage of linker relaxations to reduce the number of
	   instructions required to materialize symbol addresses. The default
	   is to take advantage of linker relaxations.

       -mriscv-attribute
       -mno-riscv-attribute
	   Emit (do not emit) RISC-V attribute to record extra information
	   into ELF objects.  This feature requires at least binutils 2.32.

       -mcsr-check
       -mno-csr-check
	   Enables or disables the CSR checking.

       -malign-data=type
	   Control how GCC aligns variables and constants of array, structure,
	   or union types.  Supported values for type are xlen which uses x
	   register width as the alignment value, and natural which uses
	   natural alignment.  xlen is the default.

       -mbig-endian
	   Generate big-endian code.  This is the default when GCC is
	   configured for a riscv64be-*-* or riscv32be-*-* target.

       -mlittle-endian
	   Generate little-endian code.	 This is the default when GCC is
	   configured for a riscv64-*-* or riscv32-*-* but not a riscv64be-*-*
	   or riscv32be-*-* target.

       -mstack-protector-guard=guard
       -mstack-protector-guard-reg=reg
       -mstack-protector-guard-offset=offset
	   Generate stack protection code using canary at guard.  Supported
	   locations are global for a global canary or tls for per-thread
	   canary in the TLS block.

	   With the latter choice the options -mstack-protector-guard-reg=reg
	   and -mstack-protector-guard-offset=offset furthermore specify which
	   register to use as base register for reading the canary, and from
	   what offset from that base register. There is no default register
	   or offset as this is entirely for use within the Linux kernel.

       -mtls-dialect=desc
	   Use TLS descriptors as the thread-local storage mechanism for
	   dynamic accesses of TLS variables.

       -mtls-dialect=trad
	   Use traditional TLS as the thread-local storage mechanism for
	   dynamic accesses of TLS variables.  This is the default.

       RL78 Options

       -msim
	   Links in additional target libraries to support operation within a
	   simulator.

       -mmul=none
       -mmul=g10
       -mmul=g13
       -mmul=g14
       -mmul=rl78
	   Specifies the type of hardware multiplication and division support
	   to be used.	The simplest is "none", which uses software for both
	   multiplication and division.	 This is the default.  The "g13" value
	   is for the hardware multiply/divide peripheral found on the
	   RL78/G13 (S2 core) targets.	The "g14" value selects the use of the
	   multiplication and division instructions supported by the RL78/G14
	   (S3 core) parts.  The value "rl78" is an alias for "g14" and the
	   value "mg10" is an alias for "none".

	   In addition a C preprocessor macro is defined, based upon the
	   setting of this option.  Possible values are: "__RL78_MUL_NONE__",
	   "__RL78_MUL_G13__" or "__RL78_MUL_G14__".

       -mcpu=g10
       -mcpu=g13
       -mcpu=g14
       -mcpu=rl78
	   Specifies the RL78 core to target.  The default is the G14 core,
	   also known as an S3 core or just RL78.  The G13 or S2 core does not
	   have multiply or divide instructions, instead it uses a hardware
	   peripheral for these operations.  The G10 or S1 core does not have
	   register banks, so it uses a different calling convention.

	   If this option is set it also selects the type of hardware multiply
	   support to use, unless this is overridden by an explicit -mmul=none
	   option on the command line.	Thus specifying -mcpu=g13 enables the
	   use of the G13 hardware multiply peripheral and specifying
	   -mcpu=g10 disables the use of hardware multiplications altogether.

	   Note, although the RL78/G14 core is the default target, specifying
	   -mcpu=g14 or -mcpu=rl78 on the command line does change the
	   behavior of the toolchain since it also enables G14 hardware
	   multiply support.  If these options are not specified on the
	   command line then software multiplication routines will be used
	   even though the code targets the RL78 core.	This is for backwards
	   compatibility with older toolchains which did not have hardware
	   multiply and divide support.

	   In addition a C preprocessor macro is defined, based upon the
	   setting of this option.  Possible values are: "__RL78_G10__",
	   "__RL78_G13__" or "__RL78_G14__".

       -mg10
       -mg13
       -mg14
       -mrl78
	   These are aliases for the corresponding -mcpu= option.  They are
	   provided for backwards compatibility.

       -mallregs
	   Allow the compiler to use all of the available registers.  By
	   default registers "r24..r31" are reserved for use in interrupt
	   handlers.  With this option enabled these registers can be used in
	   ordinary functions as well.

       -m64bit-doubles
       -m32bit-doubles
	   Make the "double" data type be 64 bits (-m64bit-doubles) or 32 bits
	   (-m32bit-doubles) in size.  The default is -m32bit-doubles.

       -msave-mduc-in-interrupts
       -mno-save-mduc-in-interrupts
	   Specifies that interrupt handler functions should preserve the MDUC
	   registers.  This is only necessary if normal code might use the
	   MDUC registers, for example because it performs multiplication and
	   division operations.	 The default is to ignore the MDUC registers
	   as this makes the interrupt handlers faster.	 The target option
	   -mg13 needs to be passed for this to work as this feature is only
	   available on the G13 target (S2 core).  The MDUC registers will
	   only be saved if the interrupt handler performs a multiplication or
	   division operation or it calls another function.

       IBM RS/6000 and PowerPC Options

       These -m options are defined for the IBM RS/6000 and PowerPC:

       -mpowerpc-gpopt
       -mno-powerpc-gpopt
       -mpowerpc-gfxopt
       -mno-powerpc-gfxopt
       -mpowerpc64
       -mno-powerpc64
       -mmfcrf
       -mno-mfcrf
       -mpopcntb
       -mno-popcntb
       -mpopcntd
       -mno-popcntd
       -mfprnd
       -mno-fprnd
       -mcmpb
       -mno-cmpb
       -mhard-dfp
       -mno-hard-dfp
	   You use these options to specify which instructions are available
	   on the processor you are using.  The default value of these options
	   is determined when configuring GCC.	Specifying the -mcpu=cpu_type
	   overrides the specification of these options.  We recommend you use
	   the -mcpu=cpu_type option rather than the options listed above.

	   Specifying -mpowerpc-gpopt allows GCC to use the optional PowerPC
	   architecture instructions in the General Purpose group, including
	   floating-point square root.	Specifying -mpowerpc-gfxopt allows GCC
	   to use the optional PowerPC architecture instructions in the
	   Graphics group, including floating-point select.

	   The -mmfcrf option allows GCC to generate the move from condition
	   register field instruction implemented on the POWER4 processor and
	   other processors that support the PowerPC V2.01 architecture.  The
	   -mpopcntb option allows GCC to generate the popcount and double-
	   precision FP reciprocal estimate instruction implemented on the
	   POWER5 processor and other processors that support the PowerPC
	   V2.02 architecture.	The -mpopcntd option allows GCC to generate
	   the popcount instruction implemented on the POWER7 processor and
	   other processors that support the PowerPC V2.06 architecture.  The
	   -mfprnd option allows GCC to generate the FP round to integer
	   instructions implemented on the POWER5+ processor and other
	   processors that support the PowerPC V2.03 architecture.  The -mcmpb
	   option allows GCC to generate the compare bytes instruction
	   implemented on the POWER6 processor and other processors that
	   support the PowerPC V2.05 architecture.  The -mhard-dfp option
	   allows GCC to generate the decimal floating-point instructions
	   implemented on some POWER processors.

	   The -mpowerpc64 option allows GCC to generate the additional 64-bit
	   instructions that are found in the full PowerPC64 architecture and
	   to treat GPRs as 64-bit, doubleword quantities.  GCC defaults to
	   -mno-powerpc64.

       -mcpu=cpu_type
	   Set architecture type, register usage, and instruction scheduling
	   parameters for machine type cpu_type.  Supported values for
	   cpu_type are 401, 403, 405, 405fp, 440, 440fp, 464, 464fp, 476,
	   476fp, 505, 601, 602, 603, 603e, 604, 604e, 620, 630, 740, 7400,
	   7450, 750, 801, 821, 823, 860, 970, 8540, a2, e300c2, e300c3,
	   e500mc, e500mc64, e5500, e6500, ec603e, G3, G4, G5, titan, power3,
	   power4, power5, power5+, power6, power6x, power7, power8, power9,
	   power10, powerpc, powerpc64, powerpc64le, rs64, and native.

	   -mcpu=powerpc, -mcpu=powerpc64, and -mcpu=powerpc64le specify pure
	   32-bit PowerPC (either endian), 64-bit big endian PowerPC and
	   64-bit little endian PowerPC architecture machine types, with an
	   appropriate, generic processor model assumed for scheduling
	   purposes.

	   Specifying native as cpu type detects and selects the architecture
	   option that corresponds to the host processor of the system
	   performing the compilation.	-mcpu=native has no effect if GCC does
	   not recognize the processor.

	   The other options specify a specific processor.  Code generated
	   under those options runs best on that processor, and may not run at
	   all on others.

	   The -mcpu options automatically enable or disable the following
	   options:

	   -maltivec  -mfprnd  -mhard-float  -mmfcrf  -mmultiple -mpopcntb
	   -mpopcntd  -mpowerpc64 -mpowerpc-gpopt  -mpowerpc-gfxopt -mmulhw
	   -mdlmzb  -mmfpgpr  -mvsx -mcrypto  -mhtm  -mpower8-fusion
	   -mquad-memory  -mquad-memory-atomic	-mfloat128 -mfloat128-hardware
	   -mprefixed -mpcrel -mmma -mrop-protect

	   The particular options set for any particular CPU varies between
	   compiler versions, depending on what setting seems to produce
	   optimal code for that CPU; it doesn't necessarily reflect the
	   actual hardware's capabilities.  If you wish to set an individual
	   option to a particular value, you may specify it after the -mcpu
	   option, like -mcpu=970 -mno-altivec.

	   On AIX, the -maltivec and -mpowerpc64 options are not enabled or
	   disabled by the -mcpu option at present because AIX does not have
	   full support for these options.  You may still enable or disable
	   them individually if you're sure it'll work in your environment.

       -mtune=cpu_type
	   Set the instruction scheduling parameters for machine type
	   cpu_type, but do not set the architecture type or register usage,
	   as -mcpu=cpu_type does.  The same values for cpu_type are used for
	   -mtune as for -mcpu.	 If both are specified, the code generated
	   uses the architecture and registers set by -mcpu, but the
	   scheduling parameters set by -mtune.

       -mcmodel=small
	   Generate PowerPC64 code for the small model: The TOC is limited to
	   64k.

       -mcmodel=medium
	   Generate PowerPC64 code for the medium model: The TOC and other
	   static data may be up to a total of 4G in size.  This is the
	   default for 64-bit Linux.

       -mcmodel=large
	   Generate PowerPC64 code for the large model: The TOC may be up to
	   4G in size.	Other data and code is only limited by the 64-bit
	   address space.

       -maltivec
       -mno-altivec
	   Generate code that uses (does not use) AltiVec instructions, and
	   also enable the use of built-in functions that allow more direct
	   access to the AltiVec instruction set.  You may also need to set
	   -mabi=altivec to adjust the current ABI with AltiVec ABI
	   enhancements.

	   When -maltivec is used, the element order for AltiVec intrinsics
	   such as "vec_splat", "vec_extract", and "vec_insert" match array
	   element order corresponding to the endianness of the target.	 That
	   is, element zero identifies the leftmost element in a vector
	   register when targeting a big-endian platform, and identifies the
	   rightmost element in a vector register when targeting a little-
	   endian platform.

       -mvrsave
       -mno-vrsave
	   Generate VRSAVE instructions when generating AltiVec code.

       -msecure-plt
	   Generate code that allows ld and ld.so to build executables and
	   shared libraries with non-executable ".plt" and ".got" sections.
	   This is a PowerPC 32-bit SYSV ABI option.

       -mbss-plt
	   Generate code that uses a BSS ".plt" section that ld.so fills in,
	   and requires ".plt" and ".got" sections that are both writable and
	   executable.	This is a PowerPC 32-bit SYSV ABI option.

       -misel
       -mno-isel
	   This switch enables or disables the generation of ISEL
	   instructions.

       -mvsx
       -mno-vsx
	   Generate code that uses (does not use) vector/scalar (VSX)
	   instructions, and also enable the use of built-in functions that
	   allow more direct access to the VSX instruction set.

       -mcrypto
       -mno-crypto
	   Enable the use (disable) of the built-in functions that allow
	   direct access to the cryptographic instructions that were added in
	   version 2.07 of the PowerPC ISA.

       -mhtm
       -mno-htm
	   Enable (disable) the use of the built-in functions that allow
	   direct access to the Hardware Transactional Memory (HTM)
	   instructions that were added in version 2.07 of the PowerPC ISA.

       -mpower8-fusion
       -mno-power8-fusion
	   Generate code that keeps (does not keeps) some integer operations
	   adjacent so that the instructions can be fused together on power8
	   and later processors.

       -mquad-memory
       -mno-quad-memory
	   Generate code that uses (does not use) the non-atomic quad word
	   memory instructions.	 The -mquad-memory option requires use of
	   64-bit mode.

       -mquad-memory-atomic
       -mno-quad-memory-atomic
	   Generate code that uses (does not use) the atomic quad word memory
	   instructions.  The -mquad-memory-atomic option requires use of
	   64-bit mode.

       -mfloat128
       -mno-float128
	   Enable/disable the __float128 keyword for IEEE 128-bit floating
	   point and use either software emulation for IEEE 128-bit floating
	   point or hardware instructions.

	   The VSX instruction set (-mvsx) must be enabled to use the IEEE
	   128-bit floating point support.  The IEEE 128-bit floating point is
	   only supported on Linux.

	   The default for -mfloat128 is enabled on PowerPC Linux systems
	   using the VSX instruction set, and disabled on other systems.

	   If you use the ISA 3.0 instruction set (-mcpu=power9) on a 64-bit
	   system, the IEEE 128-bit floating point support will also enable
	   the generation of ISA 3.0 IEEE 128-bit floating point instructions.
	   Otherwise, if you do not specify to generate ISA 3.0 instructions
	   or you are targeting a 32-bit big endian system, IEEE 128-bit
	   floating point will be done with software emulation.

       -mfloat128-hardware
       -mno-float128-hardware
	   Enable/disable using ISA 3.0 hardware instructions to support the
	   __float128 data type.

	   The default for -mfloat128-hardware is enabled on PowerPC Linux
	   systems using the ISA 3.0 instruction set, and disabled on other
	   systems.

       -m32
       -m64
	   Generate code for 32-bit or 64-bit environments of Darwin and SVR4
	   targets (including GNU/Linux).  The 32-bit environment sets int,
	   long and pointer to 32 bits and generates code that runs on any
	   PowerPC variant.  The 64-bit environment sets int to 32 bits and
	   long and pointer to 64 bits, and generates code for PowerPC64, as
	   for -mpowerpc64.

       -mfull-toc
       -mno-fp-in-toc
       -mno-sum-in-toc
       -mminimal-toc
	   Modify generation of the TOC (Table Of Contents), which is created
	   for every executable file.  The -mfull-toc option is selected by
	   default.  In that case, GCC allocates at least one TOC entry for
	   each unique non-automatic variable reference in your program.  GCC
	   also places floating-point constants in the TOC.  However, only
	   16,384 entries are available in the TOC.

	   If you receive a linker error message that saying you have
	   overflowed the available TOC space, you can reduce the amount of
	   TOC space used with the -mno-fp-in-toc and -mno-sum-in-toc options.
	   -mno-fp-in-toc prevents GCC from putting floating-point constants
	   in the TOC and -mno-sum-in-toc forces GCC to generate code to
	   calculate the sum of an address and a constant at run time instead
	   of putting that sum into the TOC.  You may specify one or both of
	   these options.  Each causes GCC to produce very slightly slower and
	   larger code at the expense of conserving TOC space.

	   If you still run out of space in the TOC even when you specify both
	   of these options, specify -mminimal-toc instead.  This option
	   causes GCC to make only one TOC entry for every file.  When you
	   specify this option, GCC produces code that is slower and larger
	   but which uses extremely little TOC space.  You may wish to use
	   this option only on files that contain less frequently-executed
	   code.

       -maix64
       -maix32
	   Enable 64-bit AIX ABI and calling convention: 64-bit pointers,
	   64-bit "long" type, and the infrastructure needed to support them.
	   Specifying -maix64 implies -mpowerpc64, while -maix32 disables the
	   64-bit ABI and implies -mno-powerpc64.  GCC defaults to -maix32.

       -mxl-compat
       -mno-xl-compat
	   Produce code that conforms more closely to IBM XL compiler
	   semantics when using AIX-compatible ABI.  Pass floating-point
	   arguments to prototyped functions beyond the register save area
	   (RSA) on the stack in addition to argument FPRs.  Do not assume
	   that most significant double in 128-bit long double value is
	   properly rounded when comparing values and converting to double.
	   Use XL symbol names for long double support routines.

	   The AIX calling convention was extended but not initially
	   documented to handle an obscure K&R C case of calling a function
	   that takes the address of its arguments with fewer arguments than
	   declared.  IBM XL compilers access floating-point arguments that do
	   not fit in the RSA from the stack when a subroutine is compiled
	   without optimization.  Because always storing floating-point
	   arguments on the stack is inefficient and rarely needed, this
	   option is not enabled by default and only is necessary when calling
	   subroutines compiled by IBM XL compilers without optimization.

       -mpe
	   Support IBM RS/6000 SP Parallel Environment (PE).  Link an
	   application written to use message passing with special startup
	   code to enable the application to run.  The system must have PE
	   installed in the standard location (/usr/lpp/ppe.poe/), or the
	   specs file must be overridden with the -specs= option to specify
	   the appropriate directory location.	The Parallel Environment does
	   not support threads, so the -mpe option and the -pthread option are
	   incompatible.

       -malign-natural
       -malign-power
	   On AIX, 32-bit Darwin, and 64-bit PowerPC GNU/Linux, the option
	   -malign-natural overrides the ABI-defined alignment of larger
	   types, such as floating-point doubles, on their natural size-based
	   boundary.  The option -malign-power instructs GCC to follow the
	   ABI-specified alignment rules.  GCC defaults to the standard
	   alignment defined in the ABI.

	   On 64-bit Darwin, natural alignment is the default, and
	   -malign-power is not supported.

       -msoft-float
       -mhard-float
	   Generate code that does not use (uses) the floating-point register
	   set.	 Software floating-point emulation is provided if you use the
	   -msoft-float option, and pass the option to GCC when linking.

       -mmultiple
       -mno-multiple
	   Generate code that uses (does not use) the load multiple word
	   instructions and the store multiple word instructions.  These
	   instructions are generated by default on POWER systems, and not
	   generated on PowerPC systems.  Do not use -mmultiple on little-
	   endian PowerPC systems, since those instructions do not work when
	   the processor is in little-endian mode.  The exceptions are PPC740
	   and PPC750 which permit these instructions in little-endian mode.

       -mupdate
       -mno-update
	   Generate code that uses (does not use) the load or store
	   instructions that update the base register to the address of the
	   calculated memory location.	These instructions are generated by
	   default.  If you use -mno-update, there is a small window between
	   the time that the stack pointer is updated and the address of the
	   previous frame is stored, which means code that walks the stack
	   frame across interrupts or signals may get corrupted data.

       -mavoid-indexed-addresses
       -mno-avoid-indexed-addresses
	   Generate code that tries to avoid (not avoid) the use of indexed
	   load or store instructions. These instructions can incur a
	   performance penalty on Power6 processors in certain situations,
	   such as when stepping through large arrays that cross a 16M
	   boundary.  This option is enabled by default when targeting Power6
	   and disabled otherwise.

       -mfused-madd
       -mno-fused-madd
	   Generate code that uses (does not use) the floating-point multiply
	   and accumulate instructions.	 These instructions are generated by
	   default if hardware floating point is used.	The machine-dependent
	   -mfused-madd option is now mapped to the machine-independent
	   -ffp-contract=fast option, and -mno-fused-madd is mapped to
	   -ffp-contract=off.

       -mmulhw
       -mno-mulhw
	   Generate code that uses (does not use) the half-word multiply and
	   multiply-accumulate instructions on the IBM 405, 440, 464 and 476
	   processors.	These instructions are generated by default when
	   targeting those processors.

       -mdlmzb
       -mno-dlmzb
	   Generate code that uses (does not use) the string-search dlmzb
	   instruction on the IBM 405, 440, 464 and 476 processors.  This
	   instruction is generated by default when targeting those
	   processors.

       -mno-bit-align
       -mbit-align
	   On System V.4 and embedded PowerPC systems do not (do) force
	   structures and unions that contain bit-fields to be aligned to the
	   base type of the bit-field.

	   For example, by default a structure containing nothing but 8
	   "unsigned" bit-fields of length 1 is aligned to a 4-byte boundary
	   and has a size of 4 bytes.  By using -mno-bit-align, the structure
	   is aligned to a 1-byte boundary and is 1 byte in size.

       -mno-strict-align
       -mstrict-align
	   On System V.4 and embedded PowerPC systems do not (do) assume that
	   unaligned memory references are handled by the system.

       -mrelocatable
       -mno-relocatable
	   Generate code that allows (does not allow) a static executable to
	   be relocated to a different address at run time.  A simple embedded
	   PowerPC system loader should relocate the entire contents of
	   ".got2" and 4-byte locations listed in the ".fixup" section, a
	   table of 32-bit addresses generated by this option.	For this to
	   work, all objects linked together must be compiled with
	   -mrelocatable or -mrelocatable-lib.	-mrelocatable code aligns the
	   stack to an 8-byte boundary.

       -mrelocatable-lib
       -mno-relocatable-lib
	   Like -mrelocatable, -mrelocatable-lib generates a ".fixup" section
	   to allow static executables to be relocated at run time, but
	   -mrelocatable-lib does not use the smaller stack alignment of
	   -mrelocatable.  Objects compiled with -mrelocatable-lib may be
	   linked with objects compiled with any combination of the
	   -mrelocatable options.

       -mno-toc
       -mtoc
	   On System V.4 and embedded PowerPC systems do not (do) assume that
	   register 2 contains a pointer to a global area pointing to the
	   addresses used in the program.

       -mlittle
       -mlittle-endian
	   On System V.4 and embedded PowerPC systems compile code for the
	   processor in little-endian mode.  The -mlittle-endian option is the
	   same as -mlittle.

       -mbig
       -mbig-endian
	   On System V.4 and embedded PowerPC systems compile code for the
	   processor in big-endian mode.  The -mbig-endian option is the same
	   as -mbig.

       -mdynamic-no-pic
	   On Darwin / macOS systems, compile code so that it is not
	   relocatable, but that its external references are relocatable.  The
	   resulting code is suitable for applications, but not shared
	   libraries.

       -msingle-pic-base
	   Treat the register used for PIC addressing as read-only, rather
	   than loading it in the prologue for each function.  The runtime
	   system is responsible for initializing this register with an
	   appropriate value before execution begins.

       -mprioritize-restricted-insns=priority
	   This option controls the priority that is assigned to dispatch-slot
	   restricted instructions during the second scheduling pass.  The
	   argument priority takes the value 0, 1, or 2 to assign no, highest,
	   or second-highest (respectively) priority to dispatch-slot
	   restricted instructions.

       -msched-costly-dep=dependence_type
	   This option controls which dependences are considered costly by the
	   target during instruction scheduling.  The argument dependence_type
	   takes one of the following values:

	   no  No dependence is costly.

	   all All dependences are costly.

	   true_store_to_load
	       A true dependence from store to load is costly.

	   store_to_load
	       Any dependence from store to load is costly.

	   number
	       Any dependence for which the latency is greater than or equal
	       to number is costly.

       -minsert-sched-nops=scheme
	   This option controls which NOP insertion scheme is used during the
	   second scheduling pass.  The argument scheme takes one of the
	   following values:

	   no  Don't insert NOPs.

	   pad Pad with NOPs any dispatch group that has vacant issue slots,
	       according to the scheduler's grouping.

	   regroup_exact
	       Insert NOPs to force costly dependent insns into separate
	       groups.	Insert exactly as many NOPs as needed to force an insn
	       to a new group, according to the estimated processor grouping.

	   number
	       Insert NOPs to force costly dependent insns into separate
	       groups.	Insert number NOPs to force an insn to a new group.

       -mcall-sysv
	   On System V.4 and embedded PowerPC systems compile code using
	   calling conventions that adhere to the March 1995 draft of the
	   System V Application Binary Interface, PowerPC processor
	   supplement.	This is the default unless you configured GCC using
	   powerpc-*-eabiaix.

       -mcall-sysv-eabi
       -mcall-eabi
	   Specify both -mcall-sysv and -meabi options.

       -mcall-sysv-noeabi
	   Specify both -mcall-sysv and -mno-eabi options.

       -mcall-aixdesc
	   On System V.4 and embedded PowerPC systems compile code for the AIX
	   operating system.

       -mcall-linux
	   On System V.4 and embedded PowerPC systems compile code for the
	   Linux-based GNU system.

       -mcall-freebsd
	   On System V.4 and embedded PowerPC systems compile code for the
	   FreeBSD operating system.

       -mcall-netbsd
	   On System V.4 and embedded PowerPC systems compile code for the
	   NetBSD operating system.

       -mcall-openbsd
	   On System V.4 and embedded PowerPC systems compile code for the
	   OpenBSD operating system.

       -mtraceback=traceback_type
	   Select the type of traceback table. Valid values for traceback_type
	   are full, part, and no.

       -maix-struct-return
	   Return all structures in memory (as specified by the AIX ABI).

       -msvr4-struct-return
	   Return structures smaller than 8 bytes in registers (as specified
	   by the SVR4 ABI).

       -mabi=abi-type
	   Extend the current ABI with a particular extension, or remove such
	   extension.  Valid values are: altivec, no-altivec, ibmlongdouble,
	   ieeelongdouble, elfv1, elfv2, and for AIX: vec-extabi, vec-default.

       -mabi=ibmlongdouble
	   Change the current ABI to use IBM extended-precision long double.
	   This is not likely to work if your system defaults to using IEEE
	   extended-precision long double.  If you change the long double type
	   from IEEE extended-precision, the compiler will issue a warning
	   unless you use the -Wno-psabi option.  Requires -mlong-double-128
	   to be enabled.

       -mabi=ieeelongdouble
	   Change the current ABI to use IEEE extended-precision long double.
	   This is not likely to work if your system defaults to using IBM
	   extended-precision long double.  If you change the long double type
	   from IBM extended-precision, the compiler will issue a warning
	   unless you use the -Wno-psabi option.  Requires -mlong-double-128
	   to be enabled.

       -mabi=elfv1
	   Change the current ABI to use the ELFv1 ABI.	 This is the default
	   ABI for big-endian PowerPC 64-bit Linux.  Overriding the default
	   ABI requires special system support and is likely to fail in
	   spectacular ways.

       -mabi=elfv2
	   Change the current ABI to use the ELFv2 ABI.	 This is the default
	   ABI for little-endian PowerPC 64-bit Linux.	Overriding the default
	   ABI requires special system support and is likely to fail in
	   spectacular ways.

       -mgnu-attribute
       -mno-gnu-attribute
	   Emit .gnu_attribute assembly directives to set tag/value pairs in a
	   .gnu.attributes section that specify ABI variations in function
	   parameters or return values.

       -mprototype
       -mno-prototype
	   On System V.4 and embedded PowerPC systems assume that all calls to
	   variable argument functions are properly prototyped.	 Otherwise,
	   the compiler must insert an instruction before every non-prototyped
	   call to set or clear bit 6 of the condition code register ("CR") to
	   indicate whether floating-point values are passed in the floating-
	   point registers in case the function takes variable arguments.
	   With -mprototype, only calls to prototyped variable argument
	   functions set or clear the bit.

       -msim
	   On embedded PowerPC systems, assume that the startup module is
	   called sim-crt0.o and that the standard C libraries are libsim.a
	   and libc.a.	This is the default for powerpc-*-eabisim
	   configurations.

       -mmvme
	   On embedded PowerPC systems, assume that the startup module is
	   called crt0.o and the standard C libraries are libmvme.a and
	   libc.a.

       -mads
	   On embedded PowerPC systems, assume that the startup module is
	   called crt0.o and the standard C libraries are libads.a and libc.a.

       -myellowknife
	   On embedded PowerPC systems, assume that the startup module is
	   called crt0.o and the standard C libraries are libyk.a and libc.a.

       -mvxworks
	   On System V.4 and embedded PowerPC systems, specify that you are
	   compiling for a VxWorks system.

       -memb
	   On embedded PowerPC systems, set the "PPC_EMB" bit in the ELF flags
	   header to indicate that eabi extended relocations are used.

       -meabi
       -mno-eabi
	   On System V.4 and embedded PowerPC systems do (do not) adhere to
	   the Embedded Applications Binary Interface (EABI), which is a set
	   of modifications to the System V.4 specifications.  Selecting
	   -meabi means that the stack is aligned to an 8-byte boundary, a
	   function "__eabi" is called from "main" to set up the EABI
	   environment, and the -msdata option can use both "r2" and "r13" to
	   point to two separate small data areas.  Selecting -mno-eabi means
	   that the stack is aligned to a 16-byte boundary, no EABI
	   initialization function is called from "main", and the -msdata
	   option only uses "r13" to point to a single small data area.	 The
	   -meabi option is on by default if you configured GCC using one of
	   the powerpc*-*-eabi* options.

       -msdata=eabi
	   On System V.4 and embedded PowerPC systems, put small initialized
	   "const" global and static data in the ".sdata2" section, which is
	   pointed to by register "r2".	 Put small initialized non-"const"
	   global and static data in the ".sdata" section, which is pointed to
	   by register "r13".  Put small uninitialized global and static data
	   in the ".sbss" section, which is adjacent to the ".sdata" section.
	   The -msdata=eabi option is incompatible with the -mrelocatable
	   option.  The -msdata=eabi option also sets the -memb option.

       -msdata=sysv
	   On System V.4 and embedded PowerPC systems, put small global and
	   static data in the ".sdata" section, which is pointed to by
	   register "r13".  Put small uninitialized global and static data in
	   the ".sbss" section, which is adjacent to the ".sdata" section.
	   The -msdata=sysv option is incompatible with the -mrelocatable
	   option.

       -msdata=default
       -msdata
	   On System V.4 and embedded PowerPC systems, if -meabi is used,
	   compile code the same as -msdata=eabi, otherwise compile code the
	   same as -msdata=sysv.

       -msdata=data
	   On System V.4 and embedded PowerPC systems, put small global data
	   in the ".sdata" section.  Put small uninitialized global data in
	   the ".sbss" section.	 Do not use register "r13" to address small
	   data however.  This is the default behavior unless other -msdata
	   options are used.

       -msdata=none
       -mno-sdata
	   On embedded PowerPC systems, put all initialized global and static
	   data in the ".data" section, and all uninitialized data in the
	   ".bss" section.

       -mreadonly-in-sdata
	   Put read-only objects in the ".sdata" section as well.  This is the
	   default.

       -mblock-move-inline-limit=num
	   Inline all block moves (such as calls to "memcpy" or structure
	   copies) less than or equal to num bytes.  The minimum value for num
	   is 32 bytes on 32-bit targets and 64 bytes on 64-bit targets.  The
	   default value is target-specific.

       -mblock-compare-inline-limit=num
	   Generate non-looping inline code for all block compares (such as
	   calls to "memcmp" or structure compares) less than or equal to num
	   bytes. If num is 0, all inline expansion (non-loop and loop) of
	   block compare is disabled. The default value is target-specific.

       -mblock-compare-inline-loop-limit=num
	   Generate an inline expansion using loop code for all block compares
	   that are less than or equal to num bytes, but greater than the
	   limit for non-loop inline block compare expansion. If the block
	   length is not constant, at most num bytes will be compared before
	   "memcmp" is called to compare the remainder of the block. The
	   default value is target-specific.

       -mstring-compare-inline-limit=num
	   Compare at most num string bytes with inline code.  If the
	   difference or end of string is not found at the end of the inline
	   compare a call to "strcmp" or "strncmp" will take care of the rest
	   of the comparison. The default is 64 bytes.

       -G num
	   On embedded PowerPC systems, put global and static items less than
	   or equal to num bytes into the small data or BSS sections instead
	   of the normal data or BSS section.  By default, num is 8.  The -G
	   num switch is also passed to the linker.  All modules should be
	   compiled with the same -G num value.

       -mregnames
       -mno-regnames
	   On System V.4 and embedded PowerPC systems do (do not) emit
	   register names in the assembly language output using symbolic
	   forms.

       -mlongcall
       -mno-longcall
	   By default assume that all calls are far away so that a longer and
	   more expensive calling sequence is required.	 This is required for
	   calls farther than 32 megabytes (33,554,432 bytes) from the current
	   location.  A short call is generated if the compiler knows the call
	   cannot be that far away.  This setting can be overridden by the
	   "shortcall" function attribute, or by #pragma longcall(0).

	   Some linkers are capable of detecting out-of-range calls and
	   generating glue code on the fly.  On these systems, long calls are
	   unnecessary and generate slower code.  As of this writing, the AIX
	   linker can do this, as can the GNU linker for PowerPC/64.  It is
	   planned to add this feature to the GNU linker for 32-bit PowerPC
	   systems as well.

	   On PowerPC64 ELFv2 and 32-bit PowerPC systems with newer GNU
	   linkers, GCC can generate long calls using an inline PLT call
	   sequence (see -mpltseq).  PowerPC with -mbss-plt and PowerPC64
	   ELFv1 (big-endian) do not support inline PLT calls.

	   On Darwin/PPC systems, "#pragma longcall" generates "jbsr callee,
	   L42", plus a branch island (glue code).  The two target addresses
	   represent the callee and the branch island.	The Darwin/PPC linker
	   prefers the first address and generates a "bl callee" if the PPC
	   "bl" instruction reaches the callee directly; otherwise, the linker
	   generates "bl L42" to call the branch island.  The branch island is
	   appended to the body of the calling function; it computes the full
	   32-bit address of the callee and jumps to it.

	   On Mach-O (Darwin) systems, this option directs the compiler emit
	   to the glue for every direct call, and the Darwin linker decides
	   whether to use or discard it.

	   In the future, GCC may ignore all longcall specifications when the
	   linker is known to generate glue.

       -mpltseq
       -mno-pltseq
	   Implement (do not implement) -fno-plt and long calls using an
	   inline PLT call sequence that supports lazy linking and long calls
	   to functions in dlopen'd shared libraries.  Inline PLT calls are
	   only supported on PowerPC64 ELFv2 and 32-bit PowerPC systems with
	   newer GNU linkers, and are enabled by default if the support is
	   detected when configuring GCC, and, in the case of 32-bit PowerPC,
	   if GCC is configured with --enable-secureplt.  -mpltseq code and
	   -mbss-plt 32-bit PowerPC relocatable objects may not be linked
	   together.

       -mtls-markers
       -mno-tls-markers
	   Mark (do not mark) calls to "__tls_get_addr" with a relocation
	   specifying the function argument.  The relocation allows the linker
	   to reliably associate function call with argument setup
	   instructions for TLS optimization, which in turn allows GCC to
	   better schedule the sequence.

       -mrecip
       -mno-recip
	   This option enables use of the reciprocal estimate and reciprocal
	   square root estimate instructions with additional Newton-Raphson
	   steps to increase precision instead of doing a divide or square
	   root and divide for floating-point arguments.  You should use the
	   -ffast-math option when using -mrecip (or at least
	   -funsafe-math-optimizations, -ffinite-math-only, -freciprocal-math
	   and -fno-trapping-math).  Note that while the throughput of the
	   sequence is generally higher than the throughput of the non-
	   reciprocal instruction, the precision of the sequence can be
	   decreased by up to 2 ulp (i.e. the inverse of 1.0 equals
	   0.99999994) for reciprocal square roots.

       -mrecip=opt
	   This option controls which reciprocal estimate instructions may be
	   used.  opt is a comma-separated list of options, which may be
	   preceded by a "!" to invert the option:

	   all Enable all estimate instructions.

	   default
	       Enable the default instructions, equivalent to -mrecip.

	   none
	       Disable all estimate instructions, equivalent to -mno-recip.

	   div Enable the reciprocal approximation instructions for both
	       single and double precision.

	   divf
	       Enable the single-precision reciprocal approximation
	       instructions.

	   divd
	       Enable the double-precision reciprocal approximation
	       instructions.

	   rsqrt
	       Enable the reciprocal square root approximation instructions
	       for both single and double precision.

	   rsqrtf
	       Enable the single-precision reciprocal square root
	       approximation instructions.

	   rsqrtd
	       Enable the double-precision reciprocal square root
	       approximation instructions.

	   So, for example, -mrecip=all,!rsqrtd enables all of the reciprocal
	   estimate instructions, except for the "FRSQRTE", "XSRSQRTEDP", and
	   "XVRSQRTEDP" instructions which handle the double-precision
	   reciprocal square root calculations.

       -mrecip-precision
       -mno-recip-precision
	   Assume (do not assume) that the reciprocal estimate instructions
	   provide higher-precision estimates than is mandated by the PowerPC
	   ABI.	 Selecting -mcpu=power6, -mcpu=power7 or -mcpu=power8
	   automatically selects -mrecip-precision.  The double-precision
	   square root estimate instructions are not generated by default on
	   low-precision machines, since they do not provide an estimate that
	   converges after three steps.

       -mveclibabi=type
	   Specifies the ABI type to use for vectorizing intrinsics using an
	   external library.  The only type supported at present is mass,
	   which specifies to use IBM's Mathematical Acceleration Subsystem
	   (MASS) libraries for vectorizing intrinsics using external
	   libraries.  GCC currently emits calls to "acosd2", "acosf4",
	   "acoshd2", "acoshf4", "asind2", "asinf4", "asinhd2", "asinhf4",
	   "atan2d2", "atan2f4", "atand2", "atanf4", "atanhd2", "atanhf4",
	   "cbrtd2", "cbrtf4", "cosd2", "cosf4", "coshd2", "coshf4", "erfcd2",
	   "erfcf4", "erfd2", "erff4", "exp2d2", "exp2f4", "expd2", "expf4",
	   "expm1d2", "expm1f4", "hypotd2", "hypotf4", "lgammad2", "lgammaf4",
	   "log10d2", "log10f4", "log1pd2", "log1pf4", "log2d2", "log2f4",
	   "logd2", "logf4", "powd2", "powf4", "sind2", "sinf4", "sinhd2",
	   "sinhf4", "sqrtd2", "sqrtf4", "tand2", "tanf4", "tanhd2", and
	   "tanhf4" when generating code for power7.  Both -ftree-vectorize
	   and -funsafe-math-optimizations must also be enabled.  The MASS
	   libraries must be specified at link time.

       -mfriz
       -mno-friz
	   Generate (do not generate) the "friz" instruction when the
	   -funsafe-math-optimizations option is used to optimize rounding of
	   floating-point values to 64-bit integer and back to floating point.
	   The "friz" instruction does not return the same value if the
	   floating-point number is too large to fit in an integer.

       -mpointers-to-nested-functions
       -mno-pointers-to-nested-functions
	   Generate (do not generate) code to load up the static chain
	   register ("r11") when calling through a pointer on AIX and 64-bit
	   Linux systems where a function pointer points to a 3-word
	   descriptor giving the function address, TOC value to be loaded in
	   register "r2", and static chain value to be loaded in register
	   "r11".  The -mpointers-to-nested-functions is on by default.	 You
	   cannot call through pointers to nested functions or pointers to
	   functions compiled in other languages that use the static chain if
	   you use -mno-pointers-to-nested-functions.

       -msave-toc-indirect
       -mno-save-toc-indirect
	   Generate (do not generate) code to save the TOC value in the
	   reserved stack location in the function prologue if the function
	   calls through a pointer on AIX and 64-bit Linux systems.  If the
	   TOC value is not saved in the prologue, it is saved just before the
	   call through the pointer.  The -mno-save-toc-indirect option is the
	   default.

       -mcompat-align-parm
       -mno-compat-align-parm
	   Generate (do not generate) code to pass structure parameters with a
	   maximum alignment of 64 bits, for compatibility with older versions
	   of GCC.

	   Older versions of GCC (prior to 4.9.0) incorrectly did not align a
	   structure parameter on a 128-bit boundary when that structure
	   contained a member requiring 128-bit alignment.  This is corrected
	   in more recent versions of GCC.  This option may be used to
	   generate code that is compatible with functions compiled with older
	   versions of GCC.

	   The -mno-compat-align-parm option is the default.

       -mstack-protector-guard=guard
       -mstack-protector-guard-reg=reg
       -mstack-protector-guard-offset=offset
       -mstack-protector-guard-symbol=symbol
	   Generate stack protection code using canary at guard.  Supported
	   locations are global for global canary or tls for per-thread canary
	   in the TLS block (the default with GNU libc version 2.4 or later).

	   With the latter choice the options -mstack-protector-guard-reg=reg
	   and -mstack-protector-guard-offset=offset furthermore specify which
	   register to use as base register for reading the canary, and from
	   what offset from that base register. The default for those is as
	   specified in the relevant ABI.
	   -mstack-protector-guard-symbol=symbol overrides the offset with a
	   symbol reference to a canary in the TLS block.

       -mpcrel
       -mno-pcrel
	   Generate (do not generate) pc-relative addressing.  The -mpcrel
	   option requires that the medium code model (-mcmodel=medium) and
	   prefixed addressing (-mprefixed) options are enabled.

       -mprefixed
       -mno-prefixed
	   Generate (do not generate) addressing modes using prefixed load and
	   store instructions.	The -mprefixed option requires that the option
	   -mcpu=power10 (or later) is enabled.

       -mmma
       -mno-mma
	   Generate (do not generate) the MMA instructions.  The -mma option
	   requires that the option -mcpu=power10 (or later) is enabled.

       -mrop-protect
       -mno-rop-protect
	   Generate (do not generate) ROP protection instructions when the
	   target processor supports them.  Currently this option disables the
	   shrink-wrap optimization (-fshrink-wrap).

       -mprivileged
       -mno-privileged
	   Generate (do not generate) code that will run in privileged state.

       -mblock-ops-unaligned-vsx
       -mno-block-ops-unaligned-vsx
	   Generate (do not generate) unaligned vsx loads and stores for
	   inline expansion of "memcpy" and "memmove".

       --param rs6000-vect-unroll-limit=
	   The vectorizer will check with target information to determine
	   whether it would be beneficial to unroll the main vectorized loop
	   and by how much.  This parameter sets the upper bound of how much
	   the vectorizer will unroll the main loop.  The default value is
	   four.

       RX Options

       These command-line options are defined for RX targets:

       -m64bit-doubles
       -m32bit-doubles
	   Make the "double" data type be 64 bits (-m64bit-doubles) or 32 bits
	   (-m32bit-doubles) in size.  The default is -m32bit-doubles.	Note
	   RX floating-point hardware only works on 32-bit values, which is
	   why the default is -m32bit-doubles.

       -fpu
       -nofpu
	   Enables (-fpu) or disables (-nofpu) the use of RX floating-point
	   hardware.  The default is enabled for the RX600 series and disabled
	   for the RX200 series.

	   Floating-point instructions are only generated for 32-bit floating-
	   point values, however, so the FPU hardware is not used for doubles
	   if the -m64bit-doubles option is used.

	   Note If the -fpu option is enabled then -funsafe-math-optimizations
	   is also enabled automatically.  This is because the RX FPU
	   instructions are themselves unsafe.

       -mcpu=name
	   Selects the type of RX CPU to be targeted.  Currently three types
	   are supported, the generic RX600 and RX200 series hardware and the
	   specific RX610 CPU.	The default is RX600.

	   The only difference between RX600 and RX610 is that the RX610 does
	   not support the "MVTIPL" instruction.

	   The RX200 series does not have a hardware floating-point unit and
	   so -nofpu is enabled by default when this type is selected.

       -mbig-endian-data
       -mlittle-endian-data
	   Store data (but not code) in the big-endian format.	The default is
	   -mlittle-endian-data, i.e. to store data in the little-endian
	   format.

       -msmall-data-limit=N
	   Specifies the maximum size in bytes of global and static variables
	   which can be placed into the small data area.  Using the small data
	   area can lead to smaller and faster code, but the size of area is
	   limited and it is up to the programmer to ensure that the area does
	   not overflow.  Also when the small data area is used one of the
	   RX's registers (usually "r13") is reserved for use pointing to this
	   area, so it is no longer available for use by the compiler.	This
	   could result in slower and/or larger code if variables are pushed
	   onto the stack instead of being held in this register.

	   Note, common variables (variables that have not been initialized)
	   and constants are not placed into the small data area as they are
	   assigned to other sections in the output executable.

	   The default value is zero, which disables this feature.  Note, this
	   feature is not enabled by default with higher optimization levels
	   (-O2 etc) because of the potentially detrimental effects of
	   reserving a register.  It is up to the programmer to experiment and
	   discover whether this feature is of benefit to their program.  See
	   the description of the -mpid option for a description of how the
	   actual register to hold the small data area pointer is chosen.

       -msim
       -mno-sim
	   Use the simulator runtime.  The default is to use the libgloss
	   board-specific runtime.

       -mas100-syntax
       -mno-as100-syntax
	   When generating assembler output use a syntax that is compatible
	   with Renesas's AS100 assembler.  This syntax can also be handled by
	   the GAS assembler, but it has some restrictions so it is not
	   generated by default.

       -mmax-constant-size=N
	   Specifies the maximum size, in bytes, of a constant that can be
	   used as an operand in a RX instruction.  Although the RX
	   instruction set does allow constants of up to 4 bytes in length to
	   be used in instructions, a longer value equates to a longer
	   instruction.	 Thus in some circumstances it can be beneficial to
	   restrict the size of constants that are used in instructions.
	   Constants that are too big are instead placed into a constant pool
	   and referenced via register indirection.

	   The value N can be between 0 and 4.	A value of 0 (the default) or
	   4 means that constants of any size are allowed.

       -mrelax
	   Enable linker relaxation.  Linker relaxation is a process whereby
	   the linker attempts to reduce the size of a program by finding
	   shorter versions of various instructions.  Disabled by default.

       -mint-register=N
	   Specify the number of registers to reserve for fast interrupt
	   handler functions.  The value N can be between 0 and 4.  A value of
	   1 means that register "r13" is reserved for the exclusive use of
	   fast interrupt handlers.  A value of 2 reserves "r13" and "r12".  A
	   value of 3 reserves "r13", "r12" and "r11", and a value of 4
	   reserves "r13" through "r10".  A value of 0, the default, does not
	   reserve any registers.

       -msave-acc-in-interrupts
	   Specifies that interrupt handler functions should preserve the
	   accumulator register.  This is only necessary if normal code might
	   use the accumulator register, for example because it performs
	   64-bit multiplications.  The default is to ignore the accumulator
	   as this makes the interrupt handlers faster.

       -mpid
       -mno-pid
	   Enables the generation of position independent data.	 When enabled
	   any access to constant data is done via an offset from a base
	   address held in a register.	This allows the location of constant
	   data to be determined at run time without requiring the executable
	   to be relocated, which is a benefit to embedded applications with
	   tight memory constraints.  Data that can be modified is not
	   affected by this option.

	   Note, using this feature reserves a register, usually "r13", for
	   the constant data base address.  This can result in slower and/or
	   larger code, especially in complicated functions.

	   The actual register chosen to hold the constant data base address
	   depends upon whether the -msmall-data-limit and/or the
	   -mint-register command-line options are enabled.  Starting with
	   register "r13" and proceeding downwards, registers are allocated
	   first to satisfy the requirements of -mint-register, then -mpid and
	   finally -msmall-data-limit.	Thus it is possible for the small data
	   area register to be "r8" if both -mint-register=4 and -mpid are
	   specified on the command line.

	   By default this feature is not enabled.  The default can be
	   restored via the -mno-pid command-line option.

       -mno-warn-multiple-fast-interrupts
       -mwarn-multiple-fast-interrupts
	   Prevents GCC from issuing a warning message if it finds more than
	   one fast interrupt handler when it is compiling a file.  The
	   default is to issue a warning for each extra fast interrupt handler
	   found, as the RX only supports one such interrupt.

       -mallow-string-insns
       -mno-allow-string-insns
	   Enables or disables the use of the string manipulation instructions
	   "SMOVF", "SCMPU", "SMOVB", "SMOVU", "SUNTIL" "SWHILE" and also the
	   "RMPA" instruction.	These instructions may prefetch data, which is
	   not safe to do if accessing an I/O register.	 (See section 12.2.7
	   of the RX62N Group User's Manual for more information).

	   The default is to allow these instructions, but it is not possible
	   for GCC to reliably detect all circumstances where a string
	   instruction might be used to access an I/O register, so their use
	   cannot be disabled automatically.  Instead it is reliant upon the
	   programmer to use the -mno-allow-string-insns option if their
	   program accesses I/O space.

	   When the instructions are enabled GCC defines the C preprocessor
	   symbol "__RX_ALLOW_STRING_INSNS__", otherwise it defines the symbol
	   "__RX_DISALLOW_STRING_INSNS__".

       -mjsr
       -mno-jsr
	   Use only (or not only) "JSR" instructions to access functions.
	   This option can be used when code size exceeds the range of "BSR"
	   instructions.  Note that -mno-jsr does not mean to not use "JSR"
	   but instead means that any type of branch may be used.

       Note: The generic GCC command-line option -ffixed-reg has special
       significance to the RX port when used with the "interrupt" function
       attribute.  This attribute indicates a function intended to process
       fast interrupts.	 GCC ensures that it only uses the registers "r10",
       "r11", "r12" and/or "r13" and only provided that the normal use of the
       corresponding registers have been restricted via the -ffixed-reg or
       -mint-register command-line options.

       S/390 and zSeries Options

       These are the -m options defined for the S/390 and zSeries
       architecture.

       -mhard-float
       -msoft-float
	   Use (do not use) the hardware floating-point instructions and
	   registers for floating-point operations.  When -msoft-float is
	   specified, functions in libgcc.a are used to perform floating-point
	   operations.	When -mhard-float is specified, the compiler generates
	   IEEE floating-point instructions.  This is the default.

       -mhard-dfp
       -mno-hard-dfp
	   Use (do not use) the hardware decimal-floating-point instructions
	   for decimal-floating-point operations.  When -mno-hard-dfp is
	   specified, functions in libgcc.a are used to perform decimal-
	   floating-point operations.  When -mhard-dfp is specified, the
	   compiler generates decimal-floating-point hardware instructions.
	   This is the default for -march=z9-ec or higher.

       -mlong-double-64
       -mlong-double-128
	   These switches control the size of "long double" type. A size of 64
	   bits makes the "long double" type equivalent to the "double" type.
	   This is the default.

       -mbackchain
       -mno-backchain
	   Store (do not store) the address of the caller's frame as backchain
	   pointer into the callee's stack frame.  A backchain may be needed
	   to allow debugging using tools that do not understand DWARF call
	   frame information.  When -mno-packed-stack is in effect, the
	   backchain pointer is stored at the bottom of the stack frame; when
	   -mpacked-stack is in effect, the backchain is placed into the
	   topmost word of the 96/160 byte register save area.

	   In general, code compiled with -mbackchain is call-compatible with
	   code compiled with -mno-backchain; however, use of the backchain
	   for debugging purposes usually requires that the whole binary is
	   built with -mbackchain.  Note that the combination of -mbackchain,
	   -mpacked-stack and -mhard-float is not supported.  In order to
	   build a linux kernel use -msoft-float.

	   The default is to not maintain the backchain.

       -mpacked-stack
       -mno-packed-stack
	   Use (do not use) the packed stack layout.  When -mno-packed-stack
	   is specified, the compiler uses the all fields of the 96/160 byte
	   register save area only for their default purpose; unused fields
	   still take up stack space.  When -mpacked-stack is specified,
	   register save slots are densely packed at the top of the register
	   save area; unused space is reused for other purposes, allowing for
	   more efficient use of the available stack space.  However, when
	   -mbackchain is also in effect, the topmost word of the save area is
	   always used to store the backchain, and the return address register
	   is always saved two words below the backchain.

	   As long as the stack frame backchain is not used, code generated
	   with -mpacked-stack is call-compatible with code generated with
	   -mno-packed-stack.  Note that some non-FSF releases of GCC 2.95 for
	   S/390 or zSeries generated code that uses the stack frame backchain
	   at run time, not just for debugging purposes.  Such code is not
	   call-compatible with code compiled with -mpacked-stack.  Also, note
	   that the combination of -mbackchain, -mpacked-stack and
	   -mhard-float is not supported.  In order to build a linux kernel
	   use -msoft-float.

	   The default is to not use the packed stack layout.

       -msmall-exec
       -mno-small-exec
	   Generate (or do not generate) code using the "bras" instruction to
	   do subroutine calls.	 This only works reliably if the total
	   executable size does not exceed 64k.	 The default is to use the
	   "basr" instruction instead, which does not have this limitation.

       -m64
       -m31
	   When -m31 is specified, generate code compliant to the GNU/Linux
	   for S/390 ABI.  When -m64 is specified, generate code compliant to
	   the GNU/Linux for zSeries ABI.  This allows GCC in particular to
	   generate 64-bit instructions.  For the s390 targets, the default is
	   -m31, while the s390x targets default to -m64.

       -mzarch
       -mesa
	   When -mzarch is specified, generate code using the instructions
	   available on z/Architecture.	 When -mesa is specified, generate
	   code using the instructions available on ESA/390.  Note that -mesa
	   is not possible with -m64.  When generating code compliant to the
	   GNU/Linux for S/390 ABI, the default is -mesa.  When generating
	   code compliant to the GNU/Linux for zSeries ABI, the default is
	   -mzarch.

       -mhtm
       -mno-htm
	   The -mhtm option enables a set of builtins making use of
	   instructions available with the transactional execution facility
	   introduced with the IBM zEnterprise EC12 machine generation S/390
	   System z Built-in Functions.	 -mhtm is enabled by default when
	   using -march=zEC12.

       -mvx
       -mno-vx
	   When -mvx is specified, generate code using the instructions
	   available with the vector extension facility introduced with the
	   IBM z13 machine generation.	This option changes the ABI for some
	   vector type values with regard to alignment and calling
	   conventions.	 In case vector type values are being used in an ABI-
	   relevant context a GAS .gnu_attribute command will be added to mark
	   the resulting binary with the ABI used.  -mvx is enabled by default
	   when using -march=z13.

       -mzvector
       -mno-zvector
	   The -mzvector option enables vector language extensions and
	   builtins using instructions available with the vector extension
	   facility introduced with the IBM z13 machine generation.  This
	   option adds support for vector to be used as a keyword to define
	   vector type variables and arguments.	 vector is only available when
	   GNU extensions are enabled.	It will not be expanded when
	   requesting strict standard compliance e.g. with -std=c99.  In
	   addition to the GCC low-level builtins -mzvector enables a set of
	   builtins added for compatibility with AltiVec-style implementations
	   like Power and Cell.	 In order to make use of these builtins the
	   header file vecintrin.h needs to be included.  -mzvector is
	   disabled by default.

       -mmvcle
       -mno-mvcle
	   Generate (or do not generate) code using the "mvcle" instruction to
	   perform block moves.	 When -mno-mvcle is specified, use a "mvc"
	   loop instead.  This is the default unless optimizing for size.

       -mdebug
       -mno-debug
	   Print (or do not print) additional debug information when
	   compiling.  The default is to not print debug information.

       -march=cpu-type
	   Generate code that runs on cpu-type, which is the name of a system
	   representing a certain processor type.  Possible values for cpu-
	   type are z900/arch5, z990/arch6, z9-109, z9-ec/arch7, z10/arch8,
	   z196/arch9, zEC12, z13/arch11, z14/arch12, z15/arch13, z16/arch14,
	   and native.

	   The default is -march=z900.

	   Specifying native as cpu type can be used to select the best
	   architecture option for the host processor.	-march=native has no
	   effect if GCC does not recognize the processor.

       -mtune=cpu-type
	   Tune to cpu-type everything applicable about the generated code,
	   except for the ABI and the set of available instructions.  The list
	   of cpu-type values is the same as for -march.  The default is the
	   value used for -march.

       -mtpf-trace
       -mno-tpf-trace
	   Generate code that adds (does not add) in TPF OS specific branches
	   to trace routines in the operating system.  This option is off by
	   default, even when compiling for the TPF OS.

       -mtpf-trace-skip
       -mno-tpf-trace-skip
	   Generate code that changes (does not change) the default branch
	   targets enabled by -mtpf-trace to point to specialized trace
	   routines providing the ability of selectively skipping function
	   trace entries for the TPF OS.  This option is off by default, even
	   when compiling for the TPF OS and specifying -mtpf-trace.

       -mfused-madd
       -mno-fused-madd
	   Generate code that uses (does not use) the floating-point multiply
	   and accumulate instructions.	 These instructions are generated by
	   default if hardware floating point is used.

       -mwarn-framesize=framesize
	   Emit a warning if the current function exceeds the given frame
	   size.  Because this is a compile-time check it doesn't need to be a
	   real problem when the program runs.	It is intended to identify
	   functions that most probably cause a stack overflow.	 It is useful
	   to be used in an environment with limited stack size e.g. the linux
	   kernel.

       -mwarn-dynamicstack
	   Emit a warning if the function calls "alloca" or uses dynamically-
	   sized arrays.  This is generally a bad idea with a limited stack
	   size.

       -mstack-guard=stack-guard
       -mstack-size=stack-size
	   If these options are provided the S/390 back end emits additional
	   instructions in the function prologue that trigger a trap if the
	   stack size is stack-guard bytes above the stack-size (remember that
	   the stack on S/390 grows downward).	If the stack-guard option is
	   omitted the smallest power of 2 larger than the frame size of the
	   compiled function is chosen.	 These options are intended to be used
	   to help debugging stack overflow problems.  The additionally
	   emitted code causes only little overhead and hence can also be used
	   in production-like systems without greater performance degradation.
	   The given values have to be exact powers of 2 and stack-size has to
	   be greater than stack-guard without exceeding 64k.  In order to be
	   efficient the extra code makes the assumption that the stack starts
	   at an address aligned to the value given by stack-size.  The stack-
	   guard option can only be used in conjunction with stack-size.

       -mhotpatch=pre-halfwords,post-halfwords
	   If the hotpatch option is enabled, a "hot-patching" function
	   prologue is generated for all functions in the compilation unit.
	   The funtion label is prepended with the given number of two-byte
	   NOP instructions (pre-halfwords, maximum 1000000).  After the
	   label, 2 * post-halfwords bytes are appended, using the largest NOP
	   like instructions the architecture allows (maximum 1000000).

	   If both arguments are zero, hotpatching is disabled.

	   This option can be overridden for individual functions with the
	   "hotpatch" attribute.

       SH Options

       These -m options are defined for the SH implementations:

       -m1 Generate code for the SH1.

       -m2 Generate code for the SH2.

       -m2e
	   Generate code for the SH2e.

       -m2a-nofpu
	   Generate code for the SH2a without FPU, or for a SH2a-FPU in such a
	   way that the floating-point unit is not used.

       -m2a-single-only
	   Generate code for the SH2a-FPU, in such a way that no double-
	   precision floating-point operations are used.

       -m2a-single
	   Generate code for the SH2a-FPU assuming the floating-point unit is
	   in single-precision mode by default.

       -m2a
	   Generate code for the SH2a-FPU assuming the floating-point unit is
	   in double-precision mode by default.

       -m3 Generate code for the SH3.

       -m3e
	   Generate code for the SH3e.

       -m4-nofpu
	   Generate code for the SH4 without a floating-point unit.

       -m4-single-only
	   Generate code for the SH4 with a floating-point unit that only
	   supports single-precision arithmetic.

       -m4-single
	   Generate code for the SH4 assuming the floating-point unit is in
	   single-precision mode by default.

       -m4 Generate code for the SH4.

       -m4-100
	   Generate code for SH4-100.

       -m4-100-nofpu
	   Generate code for SH4-100 in such a way that the floating-point
	   unit is not used.

       -m4-100-single
	   Generate code for SH4-100 assuming the floating-point unit is in
	   single-precision mode by default.

       -m4-100-single-only
	   Generate code for SH4-100 in such a way that no double-precision
	   floating-point operations are used.

       -m4-200
	   Generate code for SH4-200.

       -m4-200-nofpu
	   Generate code for SH4-200 without in such a way that the floating-
	   point unit is not used.

       -m4-200-single
	   Generate code for SH4-200 assuming the floating-point unit is in
	   single-precision mode by default.

       -m4-200-single-only
	   Generate code for SH4-200 in such a way that no double-precision
	   floating-point operations are used.

       -m4-300
	   Generate code for SH4-300.

       -m4-300-nofpu
	   Generate code for SH4-300 without in such a way that the floating-
	   point unit is not used.

       -m4-300-single
	   Generate code for SH4-300 in such a way that no double-precision
	   floating-point operations are used.

       -m4-300-single-only
	   Generate code for SH4-300 in such a way that no double-precision
	   floating-point operations are used.

       -m4-340
	   Generate code for SH4-340 (no MMU, no FPU).

       -m4-500
	   Generate code for SH4-500 (no FPU).	Passes -isa=sh4-nofpu to the
	   assembler.

       -m4a-nofpu
	   Generate code for the SH4al-dsp, or for a SH4a in such a way that
	   the floating-point unit is not used.

       -m4a-single-only
	   Generate code for the SH4a, in such a way that no double-precision
	   floating-point operations are used.

       -m4a-single
	   Generate code for the SH4a assuming the floating-point unit is in
	   single-precision mode by default.

       -m4a
	   Generate code for the SH4a.

       -m4al
	   Same as -m4a-nofpu, except that it implicitly passes -dsp to the
	   assembler.  GCC doesn't generate any DSP instructions at the
	   moment.

       -mb Compile code for the processor in big-endian mode.

       -ml Compile code for the processor in little-endian mode.

       -mdalign
	   Align doubles at 64-bit boundaries.	Note that this changes the
	   calling conventions, and thus some functions from the standard C
	   library do not work unless you recompile it first with -mdalign.

       -mrelax
	   Shorten some address references at link time, when possible; uses
	   the linker option -relax.

       -mbigtable
	   Use 32-bit offsets in "switch" tables.  The default is to use
	   16-bit offsets.

       -mbitops
	   Enable the use of bit manipulation instructions on SH2A.

       -mfmovd
	   Enable the use of the instruction "fmovd".  Check -mdalign for
	   alignment constraints.

       -mrenesas
	   Comply with the calling conventions defined by Renesas.

       -mno-renesas
	   Comply with the calling conventions defined for GCC before the
	   Renesas conventions were available.	This option is the default for
	   all targets of the SH toolchain.

       -mnomacsave
	   Mark the "MAC" register as call-clobbered, even if -mrenesas is
	   given.

       -mieee
       -mno-ieee
	   Control the IEEE compliance of floating-point comparisons, which
	   affects the handling of cases where the result of a comparison is
	   unordered.  By default -mieee is implicitly enabled.	 If
	   -ffinite-math-only is enabled -mno-ieee is implicitly set, which
	   results in faster floating-point greater-equal and less-equal
	   comparisons.	 The implicit settings can be overridden by specifying
	   either -mieee or -mno-ieee.

       -minline-ic_invalidate
	   Inline code to invalidate instruction cache entries after setting
	   up nested function trampolines.  This option has no effect if
	   -musermode is in effect and the selected code generation option
	   (e.g. -m4) does not allow the use of the "icbi" instruction.	 If
	   the selected code generation option does not allow the use of the
	   "icbi" instruction, and -musermode is not in effect, the inlined
	   code manipulates the instruction cache address array directly with
	   an associative write.  This not only requires privileged mode at
	   run time, but it also fails if the cache line had been mapped via
	   the TLB and has become unmapped.

       -misize
	   Dump instruction size and location in the assembly code.

       -mpadstruct
	   This option is deprecated.  It pads structures to multiple of 4
	   bytes, which is incompatible with the SH ABI.

       -matomic-model=model
	   Sets the model of atomic operations and additional parameters as a
	   comma separated list.  For details on the atomic built-in functions
	   see __atomic Builtins.  The following models and parameters are
	   supported:

	   none
	       Disable compiler generated atomic sequences and emit library
	       calls for atomic operations.  This is the default if the target
	       is not "sh*-*-linux*".

	   soft-gusa
	       Generate GNU/Linux compatible gUSA software atomic sequences
	       for the atomic built-in functions.  The generated atomic
	       sequences require additional support from the
	       interrupt/exception handling code of the system and are only
	       suitable for SH3* and SH4* single-core systems.	This option is
	       enabled by default when the target is "sh*-*-linux*" and SH3*
	       or SH4*.	 When the target is SH4A, this option also partially
	       utilizes the hardware atomic instructions "movli.l" and
	       "movco.l" to create more efficient code, unless strict is
	       specified.

	   soft-tcb
	       Generate software atomic sequences that use a variable in the
	       thread control block.  This is a variation of the gUSA
	       sequences which can also be used on SH1* and SH2* targets.  The
	       generated atomic sequences require additional support from the
	       interrupt/exception handling code of the system and are only
	       suitable for single-core systems.  When using this model, the
	       gbr-offset= parameter has to be specified as well.

	   soft-imask
	       Generate software atomic sequences that temporarily disable
	       interrupts by setting "SR.IMASK = 1111".	 This model works only
	       when the program runs in privileged mode and is only suitable
	       for single-core systems.	 Additional support from the
	       interrupt/exception handling code of the system is not
	       required.  This model is enabled by default when the target is
	       "sh*-*-linux*" and SH1* or SH2*.

	   hard-llcs
	       Generate hardware atomic sequences using the "movli.l" and
	       "movco.l" instructions only.  This is only available on SH4A
	       and is suitable for multi-core systems.	Since the hardware
	       instructions support only 32 bit atomic variables access to 8
	       or 16 bit variables is emulated with 32 bit accesses.  Code
	       compiled with this option is also compatible with other
	       software atomic model interrupt/exception handling systems if
	       executed on an SH4A system.  Additional support from the
	       interrupt/exception handling code of the system is not required
	       for this model.

	   gbr-offset=
	       This parameter specifies the offset in bytes of the variable in
	       the thread control block structure that should be used by the
	       generated atomic sequences when the soft-tcb model has been
	       selected.  For other models this parameter is ignored.  The
	       specified value must be an integer multiple of four and in the
	       range 0-1020.

	   strict
	       This parameter prevents mixed usage of multiple atomic models,
	       even if they are compatible, and makes the compiler generate
	       atomic sequences of the specified model only.

       -mtas
	   Generate the "tas.b" opcode for "__atomic_test_and_set".  Notice
	   that depending on the particular hardware and software
	   configuration this can degrade overall performance due to the
	   operand cache line flushes that are implied by the "tas.b"
	   instruction.	 On multi-core SH4A processors the "tas.b" instruction
	   must be used with caution since it can result in data corruption
	   for certain cache configurations.

       -mprefergot
	   When generating position-independent code, emit function calls
	   using the Global Offset Table instead of the Procedure Linkage
	   Table.

       -musermode
       -mno-usermode
	   Don't allow (allow) the compiler generating privileged mode code.
	   Specifying -musermode also implies -mno-inline-ic_invalidate if the
	   inlined code would not work in user mode.  -musermode is the
	   default when the target is "sh*-*-linux*".  If the target is SH1*
	   or SH2* -musermode has no effect, since there is no user mode.

       -multcost=number
	   Set the cost to assume for a multiply insn.

       -mdiv=strategy
	   Set the division strategy to be used for integer division
	   operations.	strategy can be one of:

	   call-div1
	       Calls a library function that uses the single-step division
	       instruction "div1" to perform the operation.  Division by zero
	       calculates an unspecified result and does not trap.  This is
	       the default except for SH4, SH2A and SHcompact.

	   call-fp
	       Calls a library function that performs the operation in double
	       precision floating point.  Division by zero causes a floating-
	       point exception.	 This is the default for SHcompact with FPU.
	       Specifying this for targets that do not have a double precision
	       FPU defaults to "call-div1".

	   call-table
	       Calls a library function that uses a lookup table for small
	       divisors and the "div1" instruction with case distinction for
	       larger divisors.	 Division by zero calculates an unspecified
	       result and does not trap.  This is the default for SH4.
	       Specifying this for targets that do not have dynamic shift
	       instructions defaults to "call-div1".

	   When a division strategy has not been specified the default
	   strategy is selected based on the current target.  For SH2A the
	   default strategy is to use the "divs" and "divu" instructions
	   instead of library function calls.

       -maccumulate-outgoing-args
	   Reserve space once for outgoing arguments in the function prologue
	   rather than around each call.  Generally beneficial for performance
	   and size.  Also needed for unwinding to avoid changing the stack
	   frame around conditional code.

       -mdivsi3_libfunc=name
	   Set the name of the library function used for 32-bit signed
	   division to name.  This only affects the name used in the call
	   division strategies, and the compiler still expects the same sets
	   of input/output/clobbered registers as if this option were not
	   present.

       -mfixed-range=register-range
	   Generate code treating the given register range as fixed registers.
	   A fixed register is one that the register allocator cannot use.
	   This is useful when compiling kernel code.  A register range is
	   specified as two registers separated by a dash.  Multiple register
	   ranges can be specified separated by a comma.

       -mbranch-cost=num
	   Assume num to be the cost for a branch instruction.	Higher numbers
	   make the compiler try to generate more branch-free code if
	   possible.  If not specified the value is selected depending on the
	   processor type that is being compiled for.

       -mzdcbranch
       -mno-zdcbranch
	   Assume (do not assume) that zero displacement conditional branch
	   instructions "bt" and "bf" are fast.	 If -mzdcbranch is specified,
	   the compiler prefers zero displacement branch code sequences.  This
	   is enabled by default when generating code for SH4 and SH4A.	 It
	   can be explicitly disabled by specifying -mno-zdcbranch.

       -mcbranch-force-delay-slot
	   Force the usage of delay slots for conditional branches, which
	   stuffs the delay slot with a "nop" if a suitable instruction cannot
	   be found.  By default this option is disabled.  It can be enabled
	   to work around hardware bugs as found in the original SH7055.

       -mfused-madd
       -mno-fused-madd
	   Generate code that uses (does not use) the floating-point multiply
	   and accumulate instructions.	 These instructions are generated by
	   default if hardware floating point is used.	The machine-dependent
	   -mfused-madd option is now mapped to the machine-independent
	   -ffp-contract=fast option, and -mno-fused-madd is mapped to
	   -ffp-contract=off.

       -mfsca
       -mno-fsca
	   Allow or disallow the compiler to emit the "fsca" instruction for
	   sine and cosine approximations.  The option -mfsca must be used in
	   combination with -funsafe-math-optimizations.  It is enabled by
	   default when generating code for SH4A.  Using -mno-fsca disables
	   sine and cosine approximations even if -funsafe-math-optimizations
	   is in effect.

       -mfsrra
       -mno-fsrra
	   Allow or disallow the compiler to emit the "fsrra" instruction for
	   reciprocal square root approximations.  The option -mfsrra must be
	   used in combination with -funsafe-math-optimizations and
	   -ffinite-math-only.	It is enabled by default when generating code
	   for SH4A.  Using -mno-fsrra disables reciprocal square root
	   approximations even if -funsafe-math-optimizations and
	   -ffinite-math-only are in effect.

       -mpretend-cmove
	   Prefer zero-displacement conditional branches for conditional move
	   instruction patterns.  This can result in faster code on the SH4
	   processor.

       -mfdpic
	   Generate code using the FDPIC ABI.

       Solaris 2 Options

       These -m options are supported on Solaris 2:

       -mclear-hwcap
	   -mclear-hwcap tells the compiler to remove the hardware
	   capabilities generated by the Solaris assembler.  This is only
	   necessary when object files use ISA extensions not supported by the
	   current machine, but check at runtime whether or not to use them.

       -mimpure-text
	   -mimpure-text, used in addition to -shared, tells the compiler to
	   not pass -z text to the linker when linking a shared object.	 Using
	   this option, you can link position-dependent code into a shared
	   object.

	   -mimpure-text suppresses the "relocations remain against
	   allocatable but non-writable sections" linker error message.
	   However, the necessary relocations trigger copy-on-write, and the
	   shared object is not actually shared across processes.  Instead of
	   using -mimpure-text, you should compile all source code with -fpic
	   or -fPIC.

       These switches are supported in addition to the above on Solaris 2:

       -pthreads
	   This is a synonym for -pthread.

       SPARC Options

       These -m options are supported on the SPARC:

       -mno-app-regs
       -mapp-regs
	   Specify -mapp-regs to generate output using the global registers 2
	   through 4, which the SPARC SVR4 ABI reserves for applications.
	   Like the global register 1, each global register 2 through 4 is
	   then treated as an allocable register that is clobbered by function
	   calls.  This is the default.

	   To be fully SVR4 ABI-compliant at the cost of some performance
	   loss, specify -mno-app-regs.	 You should compile libraries and
	   system software with this option.

       -mflat
       -mno-flat
	   With -mflat, the compiler does not generate save/restore
	   instructions and uses a "flat" or single register window model.
	   This model is compatible with the regular register window model.
	   The local registers and the input registers (0--5) are still
	   treated as "call-saved" registers and are saved on the stack as
	   needed.

	   With -mno-flat (the default), the compiler generates save/restore
	   instructions (except for leaf functions).  This is the normal
	   operating mode.

       -mfpu
       -mhard-float
	   Generate output containing floating-point instructions.  This is
	   the default.

       -mno-fpu
       -msoft-float
	   Generate output containing library calls for floating point.
	   Warning: the requisite libraries are not available for all SPARC
	   targets.  Normally the facilities of the machine's usual C compiler
	   are used, but this cannot be done directly in cross-compilation.
	   You must make your own arrangements to provide suitable library
	   functions for cross-compilation.  The embedded targets sparc-*-aout
	   and sparclite-*-* do provide software floating-point support.

	   -msoft-float changes the calling convention in the output file;
	   therefore, it is only useful if you compile all of a program with
	   this option.	 In particular, you need to compile libgcc.a, the
	   library that comes with GCC, with -msoft-float in order for this to
	   work.

       -mhard-quad-float
	   Generate output containing quad-word (long double) floating-point
	   instructions.

       -msoft-quad-float
	   Generate output containing library calls for quad-word (long
	   double) floating-point instructions.	 The functions called are
	   those specified in the SPARC ABI.  This is the default.

	   As of this writing, there are no SPARC implementations that have
	   hardware support for the quad-word floating-point instructions.
	   They all invoke a trap handler for one of these instructions, and
	   then the trap handler emulates the effect of the instruction.
	   Because of the trap handler overhead, this is much slower than
	   calling the ABI library routines.  Thus the -msoft-quad-float
	   option is the default.

       -mno-unaligned-doubles
       -munaligned-doubles
	   Assume that doubles have 8-byte alignment.  This is the default.

	   With -munaligned-doubles, GCC assumes that doubles have 8-byte
	   alignment only if they are contained in another type, or if they
	   have an absolute address.  Otherwise, it assumes they have 4-byte
	   alignment.  Specifying this option avoids some rare compatibility
	   problems with code generated by other compilers.  It is not the
	   default because it results in a performance loss, especially for
	   floating-point code.

       -muser-mode
       -mno-user-mode
	   Do not generate code that can only run in supervisor mode.  This is
	   relevant only for the "casa" instruction emitted for the LEON3
	   processor.  This is the default.

       -mfaster-structs
       -mno-faster-structs
	   With -mfaster-structs, the compiler assumes that structures should
	   have 8-byte alignment.  This enables the use of pairs of "ldd" and
	   "std" instructions for copies in structure assignment, in place of
	   twice as many "ld" and "st" pairs.  However, the use of this
	   changed alignment directly violates the SPARC ABI.  Thus, it's
	   intended only for use on targets where the developer acknowledges
	   that their resulting code is not directly in line with the rules of
	   the ABI.

       -mstd-struct-return
       -mno-std-struct-return
	   With -mstd-struct-return, the compiler generates checking code in
	   functions returning structures or unions to detect size mismatches
	   between the two sides of function calls, as per the 32-bit ABI.

	   The default is -mno-std-struct-return.  This option has no effect
	   in 64-bit mode.

       -mlra
       -mno-lra
	   Enable Local Register Allocation.  This is the default for SPARC
	   since GCC 7 so -mno-lra needs to be passed to get old Reload.

       -mcpu=cpu_type
	   Set the instruction set, register set, and instruction scheduling
	   parameters for machine type cpu_type.  Supported values for
	   cpu_type are v7, cypress, v8, supersparc, hypersparc, leon, leon3,
	   leon3v7, leon5, sparclite, f930, f934, sparclite86x, sparclet,
	   tsc701, v9, ultrasparc, ultrasparc3, niagara, niagara2, niagara3,
	   niagara4, niagara7 and m8.

	   Native Solaris and GNU/Linux toolchains also support the value
	   native, which selects the best architecture option for the host
	   processor.  -mcpu=native has no effect if GCC does not recognize
	   the processor.

	   Default instruction scheduling parameters are used for values that
	   select an architecture and not an implementation.  These are v7,
	   v8, sparclite, sparclet, v9.

	   Here is a list of each supported architecture and their supported
	   implementations.

	   v7  cypress, leon3v7

	   v8  supersparc, hypersparc, leon, leon3, leon5

	   sparclite
	       f930, f934, sparclite86x

	   sparclet
	       tsc701

	   v9  ultrasparc, ultrasparc3, niagara, niagara2, niagara3, niagara4,
	       niagara7, m8

	   By default (unless configured otherwise), GCC generates code for
	   the V7 variant of the SPARC architecture.  With -mcpu=cypress, the
	   compiler additionally optimizes it for the Cypress CY7C602 chip, as
	   used in the SPARCStation/SPARCServer 3xx series.  This is also
	   appropriate for the older SPARCStation 1, 2, IPX etc.

	   With -mcpu=v8, GCC generates code for the V8 variant of the SPARC
	   architecture.  The only difference from V7 code is that the
	   compiler emits the integer multiply and integer divide instructions
	   which exist in SPARC-V8 but not in SPARC-V7.	 With
	   -mcpu=supersparc, the compiler additionally optimizes it for the
	   SuperSPARC chip, as used in the SPARCStation 10, 1000 and 2000
	   series.

	   With -mcpu=sparclite, GCC generates code for the SPARClite variant
	   of the SPARC architecture.  This adds the integer multiply, integer
	   divide step and scan ("ffs") instructions which exist in SPARClite
	   but not in SPARC-V7.	 With -mcpu=f930, the compiler additionally
	   optimizes it for the Fujitsu MB86930 chip, which is the original
	   SPARClite, with no FPU.  With -mcpu=f934, the compiler additionally
	   optimizes it for the Fujitsu MB86934 chip, which is the more recent
	   SPARClite with FPU.

	   With -mcpu=sparclet, GCC generates code for the SPARClet variant of
	   the SPARC architecture.  This adds the integer multiply,
	   multiply/accumulate, integer divide step and scan ("ffs")
	   instructions which exist in SPARClet but not in SPARC-V7.  With
	   -mcpu=tsc701, the compiler additionally optimizes it for the TEMIC
	   SPARClet chip.

	   With -mcpu=v9, GCC generates code for the V9 variant of the SPARC
	   architecture.  This adds 64-bit integer and floating-point move
	   instructions, 3 additional floating-point condition code registers
	   and conditional move instructions.  With -mcpu=ultrasparc, the
	   compiler additionally optimizes it for the Sun UltraSPARC I/II/IIi
	   chips.  With -mcpu=ultrasparc3, the compiler additionally optimizes
	   it for the Sun UltraSPARC III/III+/IIIi/IIIi+/IV/IV+ chips.	With
	   -mcpu=niagara, the compiler additionally optimizes it for Sun
	   UltraSPARC T1 chips.	 With -mcpu=niagara2, the compiler
	   additionally optimizes it for Sun UltraSPARC T2 chips. With
	   -mcpu=niagara3, the compiler additionally optimizes it for Sun
	   UltraSPARC T3 chips.	 With -mcpu=niagara4, the compiler
	   additionally optimizes it for Sun UltraSPARC T4 chips.  With
	   -mcpu=niagara7, the compiler additionally optimizes it for Oracle
	   SPARC M7 chips.  With -mcpu=m8, the compiler additionally optimizes
	   it for Oracle M8 chips.

       -mtune=cpu_type
	   Set the instruction scheduling parameters for machine type
	   cpu_type, but do not set the instruction set or register set that
	   the option -mcpu=cpu_type does.

	   The same values for -mcpu=cpu_type can be used for -mtune=cpu_type,
	   but the only useful values are those that select a particular CPU
	   implementation.  Those are cypress, supersparc, hypersparc, leon,
	   leon3, leon3v7, leon5, f930, f934, sparclite86x, tsc701,
	   ultrasparc, ultrasparc3, niagara, niagara2, niagara3, niagara4,
	   niagara7 and m8.  With native Solaris and GNU/Linux toolchains,
	   native can also be used.

       -mv8plus
       -mno-v8plus
	   With -mv8plus, GCC generates code for the SPARC-V8+ ABI.  The
	   difference from the V8 ABI is that the global and out registers are
	   considered 64 bits wide.  This is enabled by default on Solaris in
	   32-bit mode for all SPARC-V9 processors.

       -mvis
       -mno-vis
	   With -mvis, GCC generates code that takes advantage of the
	   UltraSPARC Visual Instruction Set extensions.  The default is
	   -mno-vis.

       -mvis2
       -mno-vis2
	   With -mvis2, GCC generates code that takes advantage of version 2.0
	   of the UltraSPARC Visual Instruction Set extensions.	 The default
	   is -mvis2 when targeting a cpu that supports such instructions,
	   such as UltraSPARC-III and later.  Setting -mvis2 also sets -mvis.

       -mvis3
       -mno-vis3
	   With -mvis3, GCC generates code that takes advantage of version 3.0
	   of the UltraSPARC Visual Instruction Set extensions.	 The default
	   is -mvis3 when targeting a cpu that supports such instructions,
	   such as niagara-3 and later.	 Setting -mvis3 also sets -mvis2 and
	   -mvis.

       -mvis4
       -mno-vis4
	   With -mvis4, GCC generates code that takes advantage of version 4.0
	   of the UltraSPARC Visual Instruction Set extensions.	 The default
	   is -mvis4 when targeting a cpu that supports such instructions,
	   such as niagara-7 and later.	 Setting -mvis4 also sets -mvis3,
	   -mvis2 and -mvis.

       -mvis4b
       -mno-vis4b
	   With -mvis4b, GCC generates code that takes advantage of version
	   4.0 of the UltraSPARC Visual Instruction Set extensions, plus the
	   additional VIS instructions introduced in the Oracle SPARC
	   Architecture 2017.  The default is -mvis4b when targeting a cpu
	   that supports such instructions, such as m8 and later.  Setting
	   -mvis4b also sets -mvis4, -mvis3, -mvis2 and -mvis.

       -mcbcond
       -mno-cbcond
	   With -mcbcond, GCC generates code that takes advantage of the
	   UltraSPARC Compare-and-Branch-on-Condition instructions.  The
	   default is -mcbcond when targeting a CPU that supports such
	   instructions, such as Niagara-4 and later.

       -mfmaf
       -mno-fmaf
	   With -mfmaf, GCC generates code that takes advantage of the
	   UltraSPARC Fused Multiply-Add Floating-point instructions.  The
	   default is -mfmaf when targeting a CPU that supports such
	   instructions, such as Niagara-3 and later.

       -mfsmuld
       -mno-fsmuld
	   With -mfsmuld, GCC generates code that takes advantage of the
	   Floating-point Multiply Single to Double (FsMULd) instruction.  The
	   default is -mfsmuld when targeting a CPU supporting the
	   architecture versions V8 or V9 with FPU except -mcpu=leon.

       -mpopc
       -mno-popc
	   With -mpopc, GCC generates code that takes advantage of the
	   UltraSPARC Population Count instruction.  The default is -mpopc
	   when targeting a CPU that supports such an instruction, such as
	   Niagara-2 and later.

       -msubxc
       -mno-subxc
	   With -msubxc, GCC generates code that takes advantage of the
	   UltraSPARC Subtract-Extended-with-Carry instruction.	 The default
	   is -msubxc when targeting a CPU that supports such an instruction,
	   such as Niagara-7 and later.

       -mfix-at697f
	   Enable the documented workaround for the single erratum of the
	   Atmel AT697F processor (which corresponds to erratum #13 of the
	   AT697E processor).

       -mfix-ut699
	   Enable the documented workarounds for the floating-point errata and
	   the data cache nullify errata of the UT699 processor.

       -mfix-ut700
	   Enable the documented workaround for the back-to-back store errata
	   of the UT699E/UT700 processor.

       -mfix-gr712rc
	   Enable the documented workaround for the back-to-back store errata
	   of the GR712RC processor.

       These -m options are supported in addition to the above on SPARC-V9
       processors in 64-bit environments:

       -m32
       -m64
	   Generate code for a 32-bit or 64-bit environment.  The 32-bit
	   environment sets int, long and pointer to 32 bits.  The 64-bit
	   environment sets int to 32 bits and long and pointer to 64 bits.

       -mcmodel=which
	   Set the code model to one of

	   medlow
	       The Medium/Low code model: 64-bit addresses, programs must be
	       linked in the low 32 bits of memory.  Programs can be
	       statically or dynamically linked.

	   medmid
	       The Medium/Middle code model: 64-bit addresses, programs must
	       be linked in the low 44 bits of memory, the text and data
	       segments must be less than 2GB in size and the data segment
	       must be located within 2GB of the text segment.

	   medany
	       The Medium/Anywhere code model: 64-bit addresses, programs may
	       be linked anywhere in memory, the text and data segments must
	       be less than 2GB in size and the data segment must be located
	       within 2GB of the text segment.

	   embmedany
	       The Medium/Anywhere code model for embedded systems: 64-bit
	       addresses, the text and data segments must be less than 2GB in
	       size, both starting anywhere in memory (determined at link
	       time).  The global register %g4 points to the base of the data
	       segment.	 Programs are statically linked and PIC is not
	       supported.

       -mmemory-model=mem-model
	   Set the memory model in force on the processor to one of

	   default
	       The default memory model for the processor and operating
	       system.

	   rmo Relaxed Memory Order

	   pso Partial Store Order

	   tso Total Store Order

	   sc  Sequential Consistency

	   These memory models are formally defined in Appendix D of the
	   SPARC-V9 architecture manual, as set in the processor's "PSTATE.MM"
	   field.

       -mstack-bias
       -mno-stack-bias
	   With -mstack-bias, GCC assumes that the stack pointer, and frame
	   pointer if present, are offset by -2047 which must be added back
	   when making stack frame references.	This is the default in 64-bit
	   mode.  Otherwise, assume no such offset is present.

       Options for System V

       These additional options are available on System V Release 4 for
       compatibility with other compilers on those systems:

       -G  Create a shared object.  It is recommended that -symbolic or
	   -shared be used instead.

       -Qy Identify the versions of each tool used by the compiler, in a
	   ".ident" assembler directive in the output.

       -Qn Refrain from adding ".ident" directives to the output file (this is
	   the default).

       -YP,dirs
	   Search the directories dirs, and no others, for libraries specified
	   with -l.

       -Ym,dir
	   Look in the directory dir to find the M4 preprocessor.  The
	   assembler uses this option.

       V850 Options

       These -m options are defined for V850 implementations:

       -mlong-calls
       -mno-long-calls
	   Treat all calls as being far away (near).  If calls are assumed to
	   be far away, the compiler always loads the function's address into
	   a register, and calls indirect through the pointer.

       -mno-ep
       -mep
	   Do not optimize (do optimize) basic blocks that use the same index
	   pointer 4 or more times to copy pointer into the "ep" register, and
	   use the shorter "sld" and "sst" instructions.  The -mep option is
	   on by default if you optimize.

       -mno-prolog-function
       -mprolog-function
	   Do not use (do use) external functions to save and restore
	   registers at the prologue and epilogue of a function.  The external
	   functions are slower, but use less code space if more than one
	   function saves the same number of registers.	 The -mprolog-function
	   option is on by default if you optimize.

       -mspace
	   Try to make the code as small as possible.  At present, this just
	   turns on the -mep and -mprolog-function options.

       -mtda=n
	   Put static or global variables whose size is n bytes or less into
	   the tiny data area that register "ep" points to.  The tiny data
	   area can hold up to 256 bytes in total (128 bytes for byte
	   references).

       -msda=n
	   Put static or global variables whose size is n bytes or less into
	   the small data area that register "gp" points to.  The small data
	   area can hold up to 64 kilobytes.

       -mzda=n
	   Put static or global variables whose size is n bytes or less into
	   the first 32 kilobytes of memory.

       -mv850
	   Specify that the target processor is the V850.

       -mv850e3v5
	   Specify that the target processor is the V850E3V5.  The
	   preprocessor constant "__v850e3v5__" is defined if this option is
	   used.

       -mv850e2v4
	   Specify that the target processor is the V850E3V5.  This is an
	   alias for the -mv850e3v5 option.

       -mv850e2v3
	   Specify that the target processor is the V850E2V3.  The
	   preprocessor constant "__v850e2v3__" is defined if this option is
	   used.

       -mv850e2
	   Specify that the target processor is the V850E2.  The preprocessor
	   constant "__v850e2__" is defined if this option is used.

       -mv850e1
	   Specify that the target processor is the V850E1.  The preprocessor
	   constants "__v850e1__" and "__v850e__" are defined if this option
	   is used.

       -mv850es
	   Specify that the target processor is the V850ES.  This is an alias
	   for the -mv850e1 option.

       -mv850e
	   Specify that the target processor is the V850E.  The preprocessor
	   constant "__v850e__" is defined if this option is used.

	   If neither -mv850 nor -mv850e nor -mv850e1 nor -mv850e2 nor
	   -mv850e2v3 nor -mv850e3v5 are defined then a default target
	   processor is chosen and the relevant __v850*__ preprocessor
	   constant is defined.

	   The preprocessor constants "__v850" and "__v851__" are always
	   defined, regardless of which processor variant is the target.

       -mdisable-callt
       -mno-disable-callt
	   This option suppresses generation of the "CALLT" instruction for
	   the v850e, v850e1, v850e2, v850e2v3 and v850e3v5 flavors of the
	   v850 architecture.

	   This option is enabled by default when the RH850 ABI is in use (see
	   -mrh850-abi), and disabled by default when the GCC ABI is in use.
	   If "CALLT" instructions are being generated then the C preprocessor
	   symbol "__V850_CALLT__" is defined.

       -mrelax
       -mno-relax
	   Pass on (or do not pass on) the -mrelax command-line option to the
	   assembler.

       -mlong-jumps
       -mno-long-jumps
	   Disable (or re-enable) the generation of PC-relative jump
	   instructions.

       -msoft-float
       -mhard-float
	   Disable (or re-enable) the generation of hardware floating point
	   instructions.  This option is only significant when the target
	   architecture is V850E2V3 or higher.	If hardware floating point
	   instructions are being generated then the C preprocessor symbol
	   "__FPU_OK__" is defined, otherwise the symbol "__NO_FPU__" is
	   defined.

       -mloop
	   Enables the use of the e3v5 LOOP instruction.  The use of this
	   instruction is not enabled by default when the e3v5 architecture is
	   selected because its use is still experimental.

       -mrh850-abi
       -mghs
	   Enables support for the RH850 version of the V850 ABI.  This is the
	   default.  With this version of the ABI the following rules apply:

	   *   Integer sized structures and unions are returned via a memory
	       pointer rather than a register.

	   *   Large structures and unions (more than 8 bytes in size) are
	       passed by value.

	   *   Functions are aligned to 16-bit boundaries.

	   *   The -m8byte-align command-line option is supported.

	   *   The -mdisable-callt command-line option is enabled by default.
	       The -mno-disable-callt command-line option is not supported.

	   When this version of the ABI is enabled the C preprocessor symbol
	   "__V850_RH850_ABI__" is defined.

       -mgcc-abi
	   Enables support for the old GCC version of the V850 ABI.  With this
	   version of the ABI the following rules apply:

	   *   Integer sized structures and unions are returned in register
	       "r10".

	   *   Large structures and unions (more than 8 bytes in size) are
	       passed by reference.

	   *   Functions are aligned to 32-bit boundaries, unless optimizing
	       for size.

	   *   The -m8byte-align command-line option is not supported.

	   *   The -mdisable-callt command-line option is supported but not
	       enabled by default.

	   When this version of the ABI is enabled the C preprocessor symbol
	   "__V850_GCC_ABI__" is defined.

       -m8byte-align
       -mno-8byte-align
	   Enables support for "double" and "long long" types to be aligned on
	   8-byte boundaries.  The default is to restrict the alignment of all
	   objects to at most 4-bytes.	When -m8byte-align is in effect the C
	   preprocessor symbol "__V850_8BYTE_ALIGN__" is defined.

       -mbig-switch
	   Generate code suitable for big switch tables.  Use this option only
	   if the assembler/linker complain about out of range branches within
	   a switch table.

       -mapp-regs
	   This option causes r2 and r5 to be used in the code generated by
	   the compiler.  This setting is the default.

       -mno-app-regs
	   This option causes r2 and r5 to be treated as fixed registers.

       VAX Options

       These -m options are defined for the VAX:

       -munix
	   Do not output certain jump instructions ("aobleq" and so on) that
	   the Unix assembler for the VAX cannot handle across long ranges.

       -mgnu
	   Do output those jump instructions, on the assumption that the GNU
	   assembler is being used.

       -mg Output code for G-format floating-point numbers instead of
	   D-format.

       -mlra
       -mno-lra
	   Enable Local Register Allocation.  This is still experimental for
	   the VAX, so by default the compiler uses standard reload.

       Visium Options

       -mdebug
	   A program which performs file I/O and is destined to run on an MCM
	   target should be linked with this option.  It causes the libraries
	   libc.a and libdebug.a to be linked.	The program should be run on
	   the target under the control of the GDB remote debugging stub.

       -msim
	   A program which performs file I/O and is destined to run on the
	   simulator should be linked with option.  This causes libraries
	   libc.a and libsim.a to be linked.

       -mfpu
       -mhard-float
	   Generate code containing floating-point instructions.  This is the
	   default.

       -mno-fpu
       -msoft-float
	   Generate code containing library calls for floating-point.

	   -msoft-float changes the calling convention in the output file;
	   therefore, it is only useful if you compile all of a program with
	   this option.	 In particular, you need to compile libgcc.a, the
	   library that comes with GCC, with -msoft-float in order for this to
	   work.

       -mcpu=cpu_type
	   Set the instruction set, register set, and instruction scheduling
	   parameters for machine type cpu_type.  Supported values for
	   cpu_type are mcm, gr5 and gr6.

	   mcm is a synonym of gr5 present for backward compatibility.

	   By default (unless configured otherwise), GCC generates code for
	   the GR5 variant of the Visium architecture.

	   With -mcpu=gr6, GCC generates code for the GR6 variant of the
	   Visium architecture.	 The only difference from GR5 code is that the
	   compiler will generate block move instructions.

       -mtune=cpu_type
	   Set the instruction scheduling parameters for machine type
	   cpu_type, but do not set the instruction set or register set that
	   the option -mcpu=cpu_type would.

       -msv-mode
	   Generate code for the supervisor mode, where there are no
	   restrictions on the access to general registers.  This is the
	   default.

       -muser-mode
	   Generate code for the user mode, where the access to some general
	   registers is forbidden: on the GR5, registers r24 to r31 cannot be
	   accessed in this mode; on the GR6, only registers r29 to r31 are
	   affected.

       VMS Options

       These -m options are defined for the VMS implementations:

       -mvms-return-codes
	   Return VMS condition codes from "main". The default is to return
	   POSIX-style condition (e.g. error) codes.

       -mdebug-main=prefix
	   Flag the first routine whose name starts with prefix as the main
	   routine for the debugger.

       -mmalloc64
	   Default to 64-bit memory allocation routines.

       -mpointer-size=size
	   Set the default size of pointers. Possible options for size are 32
	   or short for 32 bit pointers, 64 or long for 64 bit pointers, and
	   no for supporting only 32 bit pointers.  The later option disables
	   "pragma pointer_size".

       VxWorks Options

       The options in this section are defined for all VxWorks targets.
       Options specific to the target hardware are listed with the other
       options for that target.

       -mrtp
	   GCC can generate code for both VxWorks kernels and real time
	   processes (RTPs).  This option switches from the former to the
	   latter.  It also defines the preprocessor macro "__RTP__".

       -msmp
	   Select SMP runtimes for linking.  Not available on architectures
	   other than PowerPC, nor on VxWorks version 7 or later, in which the
	   selection is part of the VxWorks build configuration and the
	   library paths are the same for either choice.

       -non-static
	   Link an RTP executable against shared libraries rather than static
	   libraries.  The options -static and -shared can also be used for
	   RTPs; -static is the default.

       -Bstatic
       -Bdynamic
	   These options are passed down to the linker.	 They are defined for
	   compatibility with Diab.

       -Xbind-lazy
	   Enable lazy binding of function calls.  This option is equivalent
	   to -Wl,-z,now and is defined for compatibility with Diab.

       -Xbind-now
	   Disable lazy binding of function calls.  This option is the default
	   and is defined for compatibility with Diab.

       x86 Options

       These -m options are defined for the x86 family of computers.

       -march=cpu-type
	   Generate instructions for the machine type cpu-type.	 In contrast
	   to -mtune=cpu-type, which merely tunes the generated code for the
	   specified cpu-type, -march=cpu-type allows GCC to generate code
	   that may not run at all on processors other than the one indicated.
	   Specifying -march=cpu-type implies -mtune=cpu-type, except where
	   noted otherwise.

	   The choices for cpu-type are:

	   native
	       This selects the CPU to generate code for at compilation time
	       by determining the processor type of the compiling machine.
	       Using -march=native enables all instruction subsets supported
	       by the local machine (hence the result might not run on
	       different machines).  Using -mtune=native produces code
	       optimized for the local machine under the constraints of the
	       selected instruction set.

	   x86-64
	       A generic CPU with 64-bit extensions.

	   x86-64-v2
	   x86-64-v3
	   x86-64-v4
	       These choices for cpu-type select the corresponding micro-
	       architecture level from the x86-64 psABI.  On ABIs other than
	       the x86-64 psABI they select the same CPU features as the
	       x86-64 psABI documents for the particular micro-architecture
	       level.

	       Since these cpu-type values do not have a corresponding -mtune
	       setting, using -march with these values enables generic tuning.
	       Specific tuning can be enabled using the -mtune=other-cpu-type
	       option with an appropriate other-cpu-type value.

	   i386
	       Original Intel i386 CPU.

	   i486
	       Intel i486 CPU.	(No scheduling is implemented for this chip.)

	   i586
	   pentium
	       Intel Pentium CPU with no MMX support.

	   lakemont
	       Intel Lakemont MCU, based on Intel Pentium CPU.

	   pentium-mmx
	       Intel Pentium MMX CPU, based on Pentium core with MMX
	       instruction set support.

	   pentiumpro
	       Intel Pentium Pro CPU.

	   i686
	       When used with -march, the Pentium Pro instruction set is used,
	       so the code runs on all i686 family chips.  When used with
	       -mtune, it has the same meaning as generic.

	   pentium2
	       Intel Pentium II CPU, based on Pentium Pro core with MMX and
	       FXSR instruction set support.

	   pentium3
	   pentium3m
	       Intel Pentium III CPU, based on Pentium Pro core with MMX, FXSR
	       and SSE instruction set support.

	   pentium-m
	       Intel Pentium M; low-power version of Intel Pentium III CPU
	       with MMX, SSE, SSE2 and FXSR instruction set support.  Used by
	       Centrino notebooks.

	   pentium4
	   pentium4m
	       Intel Pentium 4 CPU with MMX, SSE, SSE2 and FXSR instruction
	       set support.

	   prescott
	       Improved version of Intel Pentium 4 CPU with MMX, SSE, SSE2,
	       SSE3 and FXSR instruction set support.

	   nocona
	       Improved version of Intel Pentium 4 CPU with 64-bit extensions,
	       MMX, SSE, SSE2, SSE3 and FXSR instruction set support.

	   core2
	       Intel Core 2 CPU with 64-bit extensions, MMX, SSE, SSE2, SSE3,
	       SSSE3, CX16, SAHF and FXSR instruction set support.

	   nehalem
	       Intel Nehalem CPU with 64-bit extensions, MMX, SSE, SSE2, SSE3,
	       SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF and FXSR instruction
	       set support.

	   westmere
	       Intel Westmere CPU with 64-bit extensions, MMX, SSE, SSE2,
	       SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR and
	       PCLMUL instruction set support.

	   sandybridge
	       Intel Sandy Bridge CPU with 64-bit extensions, MMX, SSE, SSE2,
	       SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR, AVX,
	       XSAVE and PCLMUL instruction set support.

	   ivybridge
	       Intel Ivy Bridge CPU with 64-bit extensions, MMX, SSE, SSE2,
	       SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR, AVX,
	       XSAVE, PCLMUL, FSGSBASE, RDRND and F16C instruction set
	       support.

	   haswell
	       Intel Haswell CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE and HLE instruction set support.

	   broadwell
	       Intel Broadwell CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX and PREFETCHW instruction
	       set support.

	   skylake
	       Intel Skylake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES and SGX instruction set support.

	   bonnell
	       Intel Bonnell CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3 and SSSE3 instruction set support.

	   silvermont
	       Intel Silvermont CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       PCLMUL, PREFETCHW and RDRND instruction set support.

	   goldmont
	       Intel Goldmont CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       PCLMUL, PREFETCHW, RDRND, AES, SHA, RDSEED, XSAVE, XSAVEC,
	       XSAVES, XSAVEOPT, CLFLUSHOPT and FSGSBASE instruction set
	       support.

	   goldmont-plus
	       Intel Goldmont Plus CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, PCLMUL, PREFETCHW, RDRND, AES, SHA, RDSEED, XSAVE,
	       XSAVEC, XSAVES, XSAVEOPT, CLFLUSHOPT, FSGSBASE, PTWRITE, RDPID
	       and SGX instruction set support.

	   tremont
	       Intel Tremont CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       PCLMUL, PREFETCHW, RDRND, AES, SHA, RDSEED, XSAVE, XSAVEC,
	       XSAVES, XSAVEOPT, CLFLUSHOPT, FSGSBASE, PTWRITE, RDPID, SGX,
	       CLWB, GFNI-SSE, MOVDIRI, MOVDIR64B, CLDEMOTE and WAITPKG
	       instruction set support.

	   sierraforest
	       Intel Sierra Forest CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PREFETCHW,
	       PCLMUL, RDRND, XSAVE, XSAVEC, XSAVES, XSAVEOPT, FSGSBASE,
	       PTWRITE, RDPID, SGX, GFNI-SSE, CLWB, MOVDIRI, MOVDIR64B,
	       CLDEMOTE, WAITPKG, ADCX, AVX, AVX2, BMI, BMI2, F16C, FMA,
	       LZCNT, PCONFIG, PKU, VAES, VPCLMULQDQ, SERIALIZE, HRESET, KL,
	       WIDEKL, AVX-VNNI, AVXIFMA, AVXVNNIINT8, AVXNECONVERT,
	       CMPCCXADD, ENQCMD and UINTR instruction set support.

	   grandridge
	       Intel Grand Ridge CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PREFETCHW,
	       PCLMUL, RDRND, XSAVE, XSAVEC, XSAVES, XSAVEOPT, FSGSBASE,
	       PTWRITE, RDPID, SGX, GFNI-SSE, CLWB, MOVDIRI, MOVDIR64B,
	       CLDEMOTE, WAITPKG, ADCX, AVX, AVX2, BMI, BMI2, F16C, FMA,
	       LZCNT, PCONFIG, PKU, VAES, VPCLMULQDQ, SERIALIZE, HRESET, KL,
	       WIDEKL, AVX-VNNI, AVXIFMA, AVXVNNIINT8, AVXNECONVERT,
	       CMPCCXADD, ENQCMD and UINTR instruction set support.

	   clearwaterforest
	       Intel Clearwater Forest CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PREFETCHW,
	       PCLMUL, RDRND, XSAVE, XSAVEC, XSAVES, XSAVEOPT, FSGSBASE,
	       PTWRITE, RDPID, SGX, GFNI-SSE, CLWB, MOVDIRI, MOVDIR64B,
	       CLDEMOTE, WAITPKG, ADCX, AVX, AVX2, BMI, BMI2, F16C, FMA,
	       LZCNT, PCONFIG, PKU, VAES, VPCLMULQDQ, SERIALIZE, HRESET, KL,
	       WIDEKL, AVX-VNNI, ENQCMD, UINTR, AVXIFMA, AVXVNNIINT8,
	       AVXNECONVERT, CMPCCXADD, AVXVNNIINT16, SHA512, SM3, SM4,
	       USER_MSR and PREFETCHI instruction set support.

	   knl Intel Knight's Landing CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW,
	       AVX512PF, AVX512ER, AVX512F, AVX512CD and PREFETCHWT1
	       instruction set support.

	   knm Intel Knights Mill CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AVX512PF,
	       AVX512ER, AVX512F, AVX512CD and PREFETCHWT1, AVX5124VNNIW,
	       AVX5124FMAPS and AVX512VPOPCNTDQ instruction set support.

	   skylake-avx512
	       Intel Skylake Server CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, CLWB, AVX512VL,
	       AVX512BW, AVX512DQ and AVX512CD instruction set support.

	   cannonlake
	       Intel Cannonlake Server CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD, PKU, AVX512VBMI, AVX512IFMA and SHA
	       instruction set support.

	   icelake-client
	       Intel Icelake Client CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD, PKU, AVX512VBMI, AVX512IFMA, SHA,
	       AVX512VNNI, GFNI, VAES, AVX512VBMI2 , VPCLMULQDQ, AVX512BITALG,
	       RDPID and AVX512VPOPCNTDQ instruction set support.

	   icelake-server
	       Intel Icelake Server CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD, PKU, AVX512VBMI, AVX512IFMA, SHA,
	       AVX512VNNI, GFNI, VAES, AVX512VBMI2 , VPCLMULQDQ, AVX512BITALG,
	       RDPID, AVX512VPOPCNTDQ, PCONFIG, WBNOINVD and CLWB instruction
	       set support.

	   cascadelake
	       Intel Cascadelake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, CLWB, AVX512VL,
	       AVX512BW, AVX512DQ, AVX512CD and AVX512VNNI instruction set
	       support.

	   cooperlake
	       Intel cooperlake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, CLWB, AVX512VL,
	       AVX512BW, AVX512DQ, AVX512CD, AVX512VNNI and AVX512BF16
	       instruction set support.

	   tigerlake
	       Intel Tigerlake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD PKU, AVX512VBMI, AVX512IFMA, SHA,
	       AVX512VNNI, GFNI, VAES, AVX512VBMI2, VPCLMULQDQ, AVX512BITALG,
	       RDPID, AVX512VPOPCNTDQ, MOVDIRI, MOVDIR64B, CLWB,
	       AVX512VP2INTERSECT and KEYLOCKER instruction set support.

	   sapphirerapids
	       Intel sapphirerapids CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD, PKU, AVX512VBMI, AVX512IFMA, SHA,
	       AVX512VNNI, GFNI, VAES, AVX512VBMI2, VPCLMULQDQ, AVX512BITALG,
	       RDPID, AVX512VPOPCNTDQ, PCONFIG, WBNOINVD, CLWB, MOVDIRI,
	       MOVDIR64B, ENQCMD, CLDEMOTE, PTWRITE, WAITPKG, SERIALIZE,
	       TSXLDTRK, UINTR, AMX-BF16, AMX-TILE, AMX-INT8, AVX-VNNI,
	       AVX512-FP16 and AVX512BF16 instruction set support.

	   alderlake
	       Intel Alderlake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PREFETCHW,
	       PCLMUL, RDRND, XSAVE, XSAVEC, XSAVES, XSAVEOPT, FSGSBASE,
	       PTWRITE, RDPID, SGX, GFNI-SSE, CLWB, MOVDIRI, MOVDIR64B,
	       CLDEMOTE, WAITPKG, ADCX, AVX, AVX2, BMI, BMI2, F16C, FMA,
	       LZCNT, PCONFIG, PKU, VAES, VPCLMULQDQ, SERIALIZE, HRESET, KL,
	       WIDEKL and AVX-VNNI instruction set support.

	   rocketlake
	       Intel Rocketlake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3 , SSE4.1, SSE4.2, POPCNT, CX16, SAHF, FXSR,
	       AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI, BMI2,
	       LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD PKU, AVX512VBMI, AVX512IFMA, SHA,
	       AVX512VNNI, GFNI, VAES, AVX512VBMI2, VPCLMULQDQ, AVX512BITALG,
	       RDPID and AVX512VPOPCNTDQ instruction set support.

	   graniterapids
	       Intel graniterapids CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD, PKU, AVX512VBMI, AVX512IFMA, SHA,
	       AVX512VNNI, GFNI, VAES, AVX512VBMI2, VPCLMULQDQ, AVX512BITALG,
	       RDPID, AVX512VPOPCNTDQ, PCONFIG, WBNOINVD, CLWB, MOVDIRI,
	       MOVDIR64B, ENQCMD, CLDEMOTE, PTWRITE, WAITPKG, SERIALIZE,
	       TSXLDTRK, UINTR, AMX-BF16, AMX-TILE, AMX-INT8, AVX-VNNI,
	       AVX512-FP16, AVX512BF16, AMX-FP16 and PREFETCHI instruction set
	       support.

	   graniterapids-d
	       Intel graniterapids D CPU with 64-bit extensions, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, CX16, SAHF,
	       FXSR, AVX, XSAVE, PCLMUL, FSGSBASE, RDRND, F16C, AVX2, BMI,
	       BMI2, LZCNT, FMA, MOVBE, HLE, RDSEED, ADCX, PREFETCHW, AES,
	       CLFLUSHOPT, XSAVEC, XSAVES, SGX, AVX512F, AVX512VL, AVX512BW,
	       AVX512DQ, AVX512CD, PKU, AVX512VBMI, AVX512IFMA, SHA,
	       AVX512VNNI, GFNI, VAES, AVX512VBMI2, VPCLMULQDQ, AVX512BITALG,
	       RDPID, AVX512VPOPCNTDQ, PCONFIG, WBNOINVD, CLWB, MOVDIRI,
	       MOVDIR64B, ENQCMD, CLDEMOTE, PTWRITE, WAITPKG, SERIALIZE,
	       TSXLDTRK, UINTR, AMX-BF16, AMX-TILE, AMX-INT8, AVX-VNNI,
	       AVX512FP16, AVX512BF16, AMX-FP16, PREFETCHI and AMX-COMPLEX
	       instruction set support.

	   arrowlake
	       Intel Arrow Lake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PREFETCHW,
	       PCLMUL, RDRND, XSAVE, XSAVEC, XSAVES, XSAVEOPT, FSGSBASE,
	       PTWRITE, RDPID, SGX, GFNI-SSE, CLWB, MOVDIRI, MOVDIR64B,
	       CLDEMOTE, WAITPKG, ADCX, AVX, AVX2, BMI, BMI2, F16C, FMA,
	       LZCNT, PCONFIG, PKU, VAES, VPCLMULQDQ, SERIALIZE, HRESET, KL,
	       WIDEKL, AVX-VNNI, UINTR, AVXIFMA, AVXVNNIINT8, AVXNECONVERT and
	       CMPCCXADD instruction set support.

	   arrowlake-s
	       Intel Arrow Lake S CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PREFETCHW,
	       PCLMUL, RDRND, XSAVE, XSAVEC, XSAVES, XSAVEOPT, FSGSBASE,
	       PTWRITE, RDPID, SGX, GFNI-SSE, CLWB, MOVDIRI, MOVDIR64B,
	       CLDEMOTE, WAITPKG, ADCX, AVX, AVX2, BMI, BMI2, F16C, FMA,
	       LZCNT, PCONFIG, PKU, VAES, VPCLMULQDQ, SERIALIZE, HRESET, KL,
	       WIDEKL, AVX-VNNI, UINTR, AVXIFMA, AVXVNNIINT8, AVXNECONVERT,
	       CMPCCXADD, AVXVNNIINT16, SHA512, SM3 and SM4 instruction set
	       support.

	   pantherlake
	       Intel Panther Lake CPU with 64-bit extensions, MOVBE, MMX, SSE,
	       SSE2, SSE3, SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PREFETCHW,
	       PCLMUL, RDRND, XSAVE, XSAVEC, XSAVES, XSAVEOPT, FSGSBASE,
	       PTWRITE, RDPID, SGX, GFNI-SSE, CLWB, MOVDIRI, MOVDIR64B,
	       CLDEMOTE, WAITPKG, ADCX, AVX, AVX2, BMI, BMI2, F16C, FMA,
	       LZCNT, PCONFIG, PKU, VAES, VPCLMULQDQ, SERIALIZE, HRESET, KL,
	       WIDEKL, AVX-VNNI, UINTR, AVXIFMA, AVXVNNIINT8, AVXNECONVERT,
	       CMPCCXADD, AVXVNNIINT16, SHA512, SM3, SM4 and PREFETCHI
	       instruction set support.

	   k6  AMD K6 CPU with MMX instruction set support.

	   k6-2
	   k6-3
	       Improved versions of AMD K6 CPU with MMX and 3DNow! instruction
	       set support.

	   athlon
	   athlon-tbird
	       AMD Athlon CPU with MMX, 3dNOW!, enhanced 3DNow! and SSE
	       prefetch instructions support.

	   athlon-4
	   athlon-xp
	   athlon-mp
	       Improved AMD Athlon CPU with MMX, 3DNow!, enhanced 3DNow! and
	       full SSE instruction set support.

	   k8
	   opteron
	   athlon64
	   athlon-fx
	       Processors based on the AMD K8 core with x86-64 instruction set
	       support, including the AMD Opteron, Athlon 64, and Athlon 64 FX
	       processors.  (This supersets MMX, SSE, SSE2, 3DNow!, enhanced
	       3DNow! and 64-bit instruction set extensions.)

	   k8-sse3
	   opteron-sse3
	   athlon64-sse3
	       Improved versions of AMD K8 cores with SSE3 instruction set
	       support.

	   amdfam10
	   barcelona
	       CPUs based on AMD Family 10h cores with x86-64 instruction set
	       support.	 (This supersets MMX, SSE, SSE2, SSE3, SSE4A, 3DNow!,
	       enhanced 3DNow!, ABM and 64-bit instruction set extensions.)

	   bdver1
	       CPUs based on AMD Family 15h cores with x86-64 instruction set
	       support.	 (This supersets FMA4, AVX, XOP, LWP, AES, PCLMUL,
	       CX16, MMX, SSE, SSE2, SSE3, SSE4A, SSSE3, SSE4.1, SSE4.2, ABM
	       and 64-bit instruction set extensions.)

	   bdver2
	       AMD Family 15h core based CPUs with x86-64 instruction set
	       support.	 (This supersets BMI, TBM, F16C, FMA, FMA4, AVX, XOP,
	       LWP, AES, PCLMUL, CX16, MMX, SSE, SSE2, SSE3, SSE4A, SSSE3,
	       SSE4.1, SSE4.2, ABM and 64-bit instruction set extensions.)

	   bdver3
	       AMD Family 15h core based CPUs with x86-64 instruction set
	       support.	 (This supersets BMI, TBM, F16C, FMA, FMA4, FSGSBASE,
	       AVX, XOP, LWP, AES, PCLMUL, CX16, MMX, SSE, SSE2, SSE3, SSE4A,
	       SSSE3, SSE4.1, SSE4.2, ABM and 64-bit instruction set
	       extensions.)

	   bdver4
	       AMD Family 15h core based CPUs with x86-64 instruction set
	       support.	 (This supersets BMI, BMI2, TBM, F16C, FMA, FMA4,
	       FSGSBASE, AVX, AVX2, XOP, LWP, AES, PCLMUL, CX16, MOVBE, MMX,
	       SSE, SSE2, SSE3, SSE4A, SSSE3, SSE4.1, SSE4.2, ABM and 64-bit
	       instruction set extensions.)

	   znver1
	       AMD Family 17h core based CPUs with x86-64 instruction set
	       support.	 (This supersets BMI, BMI2, F16C, FMA, FSGSBASE, AVX,
	       AVX2, ADCX, RDSEED, MWAITX, SHA, CLZERO, AES, PCLMUL, CX16,
	       MOVBE, MMX, SSE, SSE2, SSE3, SSE4A, SSSE3, SSE4.1, SSE4.2, ABM,
	       XSAVEC, XSAVES, CLFLUSHOPT, POPCNT, and 64-bit instruction set
	       extensions.)

	   znver2
	       AMD Family 17h core based CPUs with x86-64 instruction set
	       support. (This supersets BMI, BMI2, CLWB, F16C, FMA, FSGSBASE,
	       AVX, AVX2, ADCX, RDSEED, MWAITX, SHA, CLZERO, AES, PCLMUL,
	       CX16, MOVBE, MMX, SSE, SSE2, SSE3, SSE4A, SSSE3, SSE4.1,
	       SSE4.2, ABM, XSAVEC, XSAVES, CLFLUSHOPT, POPCNT, RDPID,
	       WBNOINVD, and 64-bit instruction set extensions.)

	   znver3
	       AMD Family 19h core based CPUs with x86-64 instruction set
	       support. (This supersets BMI, BMI2, CLWB, F16C, FMA, FSGSBASE,
	       AVX, AVX2, ADCX, RDSEED, MWAITX, SHA, CLZERO, AES, PCLMUL,
	       CX16, MOVBE, MMX, SSE, SSE2, SSE3, SSE4A, SSSE3, SSE4.1,
	       SSE4.2, ABM, XSAVEC, XSAVES, CLFLUSHOPT, POPCNT, RDPID,
	       WBNOINVD, PKU, VPCLMULQDQ, VAES, and 64-bit instruction set
	       extensions.)

	   znver4
	       AMD Family 19h core based CPUs with x86-64 instruction set
	       support. (This supersets BMI, BMI2, CLWB, F16C, FMA, FSGSBASE,
	       AVX, AVX2, ADCX, RDSEED, MWAITX, SHA, CLZERO, AES, PCLMUL,
	       CX16, MOVBE, MMX, SSE, SSE2, SSE3, SSE4A, SSSE3, SSE4.1,
	       SSE4.2, ABM, XSAVEC, XSAVES, CLFLUSHOPT, POPCNT, RDPID,
	       WBNOINVD, PKU, VPCLMULQDQ, VAES, AVX512F, AVX512DQ, AVX512IFMA,
	       AVX512CD, AVX512BW, AVX512VL, AVX512BF16, AVX512VBMI,
	       AVX512VBMI2, AVX512VNNI, AVX512BITALG, AVX512VPOPCNTDQ, GFNI
	       and 64-bit instruction set extensions.)

	   znver5
	       AMD Family 1ah core based CPUs with x86-64 instruction set
	       support. (This supersets BMI, BMI2, CLWB, F16C, FMA, FSGSBASE,
	       AVX, AVX2, ADCX, RDSEED, MWAITX, SHA, CLZERO, AES, PCLMUL,
	       CX16, MOVBE, MMX, SSE, SSE2, SSE3, SSE4A, SSSE3, SSE4.1,
	       SSE4.2, ABM, XSAVEC, XSAVES, CLFLUSHOPT, POPCNT, RDPID,
	       WBNOINVD, PKU, VPCLMULQDQ, VAES, AVX512F, AVX512DQ, AVX512IFMA,
	       AVX512CD, AVX512BW, AVX512VL, AVX512BF16, AVX512VBMI,
	       AVX512VBMI2, AVX512VNNI, AVX512BITALG, AVX512VPOPCNTDQ, GFNI,
	       AVXVNNI, MOVDIRI, MOVDIR64B, AVX512VP2INTERSECT, PREFETCHI and
	       64-bit instruction set extensions.)

	   btver1
	       CPUs based on AMD Family 14h cores with x86-64 instruction set
	       support.	 (This supersets MMX, SSE, SSE2, SSE3, SSSE3, SSE4A,
	       CX16, ABM and 64-bit instruction set extensions.)

	   btver2
	       CPUs based on AMD Family 16h cores with x86-64 instruction set
	       support. This includes MOVBE, F16C, BMI, AVX, PCLMUL, AES,
	       SSE4.2, SSE4.1, CX16, ABM, SSE4A, SSSE3, SSE3, SSE2, SSE, MMX
	       and 64-bit instruction set extensions.

	   winchip-c6
	       IDT WinChip C6 CPU, dealt in same way as i486 with additional
	       MMX instruction set support.

	   winchip2
	       IDT WinChip 2 CPU, dealt in same way as i486 with additional
	       MMX and 3DNow!  instruction set support.

	   c3  VIA C3 CPU with MMX and 3DNow! instruction set support.	(No
	       scheduling is implemented for this chip.)

	   c3-2
	       VIA C3-2 (Nehemiah/C5XL) CPU with MMX and SSE instruction set
	       support.	 (No scheduling is implemented for this chip.)

	   c7  VIA C7 (Esther) CPU with MMX, SSE, SSE2 and SSE3 instruction
	       set support.  (No scheduling is implemented for this chip.)

	   samuel-2
	       VIA Eden Samuel 2 CPU with MMX and 3DNow! instruction set
	       support.	 (No scheduling is implemented for this chip.)

	   nehemiah
	       VIA Eden Nehemiah CPU with MMX and SSE instruction set support.
	       (No scheduling is implemented for this chip.)

	   esther
	       VIA Eden Esther CPU with MMX, SSE, SSE2 and SSE3 instruction
	       set support.  (No scheduling is implemented for this chip.)

	   eden-x2
	       VIA Eden X2 CPU with x86-64, MMX, SSE, SSE2 and SSE3
	       instruction set support.	 (No scheduling is implemented for
	       this chip.)

	   eden-x4
	       VIA Eden X4 CPU with x86-64, MMX, SSE, SSE2, SSE3, SSSE3,
	       SSE4.1, SSE4.2, AVX and AVX2 instruction set support.  (No
	       scheduling is implemented for this chip.)

	   nano
	       Generic VIA Nano CPU with x86-64, MMX, SSE, SSE2, SSE3 and
	       SSSE3 instruction set support.  (No scheduling is implemented
	       for this chip.)

	   nano-1000
	       VIA Nano 1xxx CPU with x86-64, MMX, SSE, SSE2, SSE3 and SSSE3
	       instruction set support.	 (No scheduling is implemented for
	       this chip.)

	   nano-2000
	       VIA Nano 2xxx CPU with x86-64, MMX, SSE, SSE2, SSE3 and SSSE3
	       instruction set support.	 (No scheduling is implemented for
	       this chip.)

	   nano-3000
	       VIA Nano 3xxx CPU with x86-64, MMX, SSE, SSE2, SSE3, SSSE3 and
	       SSE4.1 instruction set support.	(No scheduling is implemented
	       for this chip.)

	   nano-x2
	       VIA Nano Dual Core CPU with x86-64, MMX, SSE, SSE2, SSE3, SSSE3
	       and SSE4.1 instruction set support.  (No scheduling is
	       implemented for this chip.)

	   nano-x4
	       VIA Nano Quad Core CPU with x86-64, MMX, SSE, SSE2, SSE3, SSSE3
	       and SSE4.1 instruction set support.  (No scheduling is
	       implemented for this chip.)

	   lujiazui
	       ZHAOXIN lujiazui CPU with x86-64, MOVBE, MMX, SSE, SSE2, SSE3,
	       SSSE3, SSE4.1, SSE4.2, POPCNT, AES, PCLMUL, RDRND, XSAVE,
	       XSAVEOPT, FSGSBASE, CX16, ABM, BMI, BMI2, FXSR, RDSEED
	       instruction set support.	 While the CPUs do support AVX and
	       F16C, these aren't enabled by "-march=lujiazui" for performance
	       reasons.

	   yongfeng
	       ZHAOXIN yongfeng CPU with x86-64, MOVBE, MMX, SSE, SSE2, SSE3,
	       SSSE3, SSE4.1, SSE4.2, AVX, POPCNT, AES, PCLMUL, RDRND, XSAVE,
	       XSAVEOPT, FSGSBASE, CX16, ABM, BMI, BMI2, F16C, FXSR, RDSEED,
	       AVX2, FMA, SHA, LZCNT instruction set support.

	   geode
	       AMD Geode embedded processor with MMX and 3DNow! instruction
	       set support.

       -mtune=cpu-type
	   Tune to cpu-type everything applicable about the generated code,
	   except for the ABI and the set of available instructions.  While
	   picking a specific cpu-type schedules things appropriately for that
	   particular chip, the compiler does not generate any code that
	   cannot run on the default machine type unless you use a -march=cpu-
	   type option.	 For example, if GCC is configured for
	   i686-pc-linux-gnu then -mtune=pentium4 generates code that is tuned
	   for Pentium 4 but still runs on i686 machines.

	   The choices for cpu-type are the same as for -march.	 In addition,
	   -mtune supports 2 extra choices for cpu-type:

	   generic
	       Produce code optimized for the most common IA32/AMD64/EM64T
	       processors.  If you know the CPU on which your code will run,
	       then you should use the corresponding -mtune or -march option
	       instead of -mtune=generic.  But, if you do not know exactly
	       what CPU users of your application will have, then you should
	       use this option.

	       As new processors are deployed in the marketplace, the behavior
	       of this option will change.  Therefore, if you upgrade to a
	       newer version of GCC, code generation controlled by this option
	       will change to reflect the processors that are most common at
	       the time that version of GCC is released.

	       There is no -march=generic option because -march indicates the
	       instruction set the compiler can use, and there is no generic
	       instruction set applicable to all processors.  In contrast,
	       -mtune indicates the processor (or, in this case, collection of
	       processors) for which the code is optimized.

	   intel
	       Produce code optimized for the most current Intel processors,
	       which are Haswell and Silvermont for this version of GCC.  If
	       you know the CPU on which your code will run, then you should
	       use the corresponding -mtune or -march option instead of
	       -mtune=intel.  But, if you want your application performs
	       better on both Haswell and Silvermont, then you should use this
	       option.

	       As new Intel processors are deployed in the marketplace, the
	       behavior of this option will change.  Therefore, if you upgrade
	       to a newer version of GCC, code generation controlled by this
	       option will change to reflect the most current Intel processors
	       at the time that version of GCC is released.

	       There is no -march=intel option because -march indicates the
	       instruction set the compiler can use, and there is no common
	       instruction set applicable to all processors.  In contrast,
	       -mtune indicates the processor (or, in this case, collection of
	       processors) for which the code is optimized.

       -mcpu=cpu-type
	   A deprecated synonym for -mtune.

       -mfpmath=unit
	   Generate floating-point arithmetic for selected unit unit.  The
	   choices for unit are:

	   387 Use the standard 387 floating-point coprocessor present on the
	       majority of chips and emulated otherwise.  Code compiled with
	       this option runs almost everywhere.  The temporary results are
	       computed in 80-bit precision instead of the precision specified
	       by the type, resulting in slightly different results compared
	       to most of other chips.	See -ffloat-store for more detailed
	       description.

	       This is the default choice for non-Darwin x86-32 targets.

	   sse Use scalar floating-point instructions present in the SSE
	       instruction set.	 This instruction set is supported by Pentium
	       III and newer chips, and in the AMD line by Athlon-4, Athlon XP
	       and Athlon MP chips.  The earlier version of the SSE
	       instruction set supports only single-precision arithmetic, thus
	       the double and extended-precision arithmetic are still done
	       using 387.  A later version, present only in Pentium 4 and AMD
	       x86-64 chips, supports double-precision arithmetic too.

	       For the x86-32 compiler, you must use -march=cpu-type, -msse or
	       -msse2 switches to enable SSE extensions and make this option
	       effective.  For the x86-64 compiler, these extensions are
	       enabled by default.

	       The resulting code should be considerably faster in the
	       majority of cases and avoid the numerical instability problems
	       of 387 code, but may break some existing code that expects
	       temporaries to be 80 bits.

	       This is the default choice for the x86-64 compiler, Darwin
	       x86-32 targets, and the default choice for x86-32 targets with
	       the SSE2 instruction set when -ffast-math is enabled.

	   sse,387
	   sse+387
	   both
	       Attempt to utilize both instruction sets at once.  This
	       effectively doubles the amount of available registers, and on
	       chips with separate execution units for 387 and SSE the
	       execution resources too.	 Use this option with care, as it is
	       still experimental, because the GCC register allocator does not
	       model separate functional units well, resulting in unstable
	       performance.

       -masm=dialect
	   Output assembly instructions using selected dialect.	 Also affects
	   which dialect is used for basic "asm" and extended "asm". Supported
	   choices (in dialect order) are att or intel. The default is att.
	   Darwin does not support intel.

       -mieee-fp
       -mno-ieee-fp
	   Control whether or not the compiler uses IEEE floating-point
	   comparisons.	 These correctly handle the case where the result of a
	   comparison is unordered.

       -m80387
       -mhard-float
	   Generate output containing 80387 instructions for floating point.

       -mno-80387
       -msoft-float
	   Generate output containing library calls for floating point.

	   Warning: the requisite libraries are not part of GCC.  Normally the
	   facilities of the machine's usual C compiler are used, but this
	   cannot be done directly in cross-compilation.  You must make your
	   own arrangements to provide suitable library functions for cross-
	   compilation.

	   On machines where a function returns floating-point results in the
	   80387 register stack, some floating-point opcodes may be emitted
	   even if -msoft-float is used.

       -mno-fp-ret-in-387
	   Do not use the FPU registers for return values of functions.

	   The usual calling convention has functions return values of types
	   "float" and "double" in an FPU register, even if there is no FPU.
	   The idea is that the operating system should emulate an FPU.

	   The option -mno-fp-ret-in-387 causes such values to be returned in
	   ordinary CPU registers instead.

       -mno-fancy-math-387
	   Some 387 emulators do not support the "sin", "cos" and "sqrt"
	   instructions for the 387.  Specify this option to avoid generating
	   those instructions.	This option is overridden when -march
	   indicates that the target CPU always has an FPU and so the
	   instruction does not need emulation.	 These instructions are not
	   generated unless you also use the -funsafe-math-optimizations
	   switch.

       -malign-double
       -mno-align-double
	   Control whether GCC aligns "double", "long double", and "long long"
	   variables on a two-word boundary or a one-word boundary.  Aligning
	   "double" variables on a two-word boundary produces code that runs
	   somewhat faster on a Pentium at the expense of more memory.

	   On x86-64, -malign-double is enabled by default.

	   Warning: if you use the -malign-double switch, structures
	   containing the above types are aligned differently than the
	   published application binary interface specifications for the
	   x86-32 and are not binary compatible with structures in code
	   compiled without that switch.

       -m96bit-long-double
       -m128bit-long-double
	   These switches control the size of "long double" type.  The x86-32
	   application binary interface specifies the size to be 96 bits, so
	   -m96bit-long-double is the default in 32-bit mode.

	   Modern architectures (Pentium and newer) prefer "long double" to be
	   aligned to an 8- or 16-byte boundary.  In arrays or structures
	   conforming to the ABI, this is not possible.	 So specifying
	   -m128bit-long-double aligns "long double" to a 16-byte boundary by
	   padding the "long double" with an additional 32-bit zero.

	   In the x86-64 compiler, -m128bit-long-double is the default choice
	   as its ABI specifies that "long double" is aligned on 16-byte
	   boundary.

	   Notice that neither of these options enable any extra precision
	   over the x87 standard of 80 bits for a "long double".

	   Warning: if you override the default value for your target ABI,
	   this changes the size of structures and arrays containing "long
	   double" variables, as well as modifying the function calling
	   convention for functions taking "long double".  Hence they are not
	   binary-compatible with code compiled without that switch.

       -mlong-double-64
       -mlong-double-80
       -mlong-double-128
	   These switches control the size of "long double" type. A size of 64
	   bits makes the "long double" type equivalent to the "double" type.
	   This is the default for 32-bit Bionic C library.  A size of 128
	   bits makes the "long double" type equivalent to the "__float128"
	   type. This is the default for 64-bit Bionic C library.

	   Warning: if you override the default value for your target ABI,
	   this changes the size of structures and arrays containing "long
	   double" variables, as well as modifying the function calling
	   convention for functions taking "long double".  Hence they are not
	   binary-compatible with code compiled without that switch.

       -malign-data=type
	   Control how GCC aligns variables.  Supported values for type are
	   compat uses increased alignment value compatible uses GCC 4.8 and
	   earlier, abi uses alignment value as specified by the psABI, and
	   cacheline uses increased alignment value to match the cache line
	   size.  compat is the default.

       -mlarge-data-threshold=threshold
	   When -mcmodel=medium or -mcmodel=large is specified, data objects
	   larger than threshold are placed in large data sections.  The
	   default is 65535.

       -mrtd
	   Use a different function-calling convention, in which functions
	   that take a fixed number of arguments return with the "ret num"
	   instruction, which pops their arguments while returning.  This
	   saves one instruction in the caller since there is no need to pop
	   the arguments there.

	   You can specify that an individual function is called with this
	   calling sequence with the function attribute "stdcall".  You can
	   also override the -mrtd option by using the function attribute
	   "cdecl".

	   Warning: this calling convention is incompatible with the one
	   normally used on Unix, so you cannot use it if you need to call
	   libraries compiled with the Unix compiler.

	   Also, you must provide function prototypes for all functions that
	   take variable numbers of arguments (including "printf"); otherwise
	   incorrect code is generated for calls to those functions.

	   In addition, seriously incorrect code results if you call a
	   function with too many arguments.  (Normally, extra arguments are
	   harmlessly ignored.)

       -mregparm=num
	   Control how many registers are used to pass integer arguments.  By
	   default, no registers are used to pass arguments, and at most 3
	   registers can be used.  You can control this behavior for a
	   specific function by using the function attribute "regparm".

	   Warning: if you use this switch, and num is nonzero, then you must
	   build all modules with the same value, including any libraries.
	   This includes the system libraries and startup modules.

       -msseregparm
	   Use SSE register passing conventions for float and double arguments
	   and return values.  You can control this behavior for a specific
	   function by using the function attribute "sseregparm".

	   Warning: if you use this switch then you must build all modules
	   with the same value, including any libraries.  This includes the
	   system libraries and startup modules.

       -mvect8-ret-in-mem
	   Return 8-byte vectors in memory instead of MMX registers.  This is
	   the default on VxWorks to match the ABI of the Sun Studio compilers
	   until version 12.  Only use this option if you need to remain
	   compatible with existing code produced by those previous compiler
	   versions or older versions of GCC.

       -mpc32
       -mpc64
       -mpc80
	   Set 80387 floating-point precision to 32, 64 or 80 bits.  When
	   -mpc32 is specified, the significands of results of floating-point
	   operations are rounded to 24 bits (single precision); -mpc64 rounds
	   the significands of results of floating-point operations to 53 bits
	   (double precision) and -mpc80 rounds the significands of results of
	   floating-point operations to 64 bits (extended double precision),
	   which is the default.  When this option is used, floating-point
	   operations in higher precisions are not available to the programmer
	   without setting the FPU control word explicitly.

	   Setting the rounding of floating-point operations to less than the
	   default 80 bits can speed some programs by 2% or more.  Note that
	   some mathematical libraries assume that extended-precision (80-bit)
	   floating-point operations are enabled by default; routines in such
	   libraries could suffer significant loss of accuracy, typically
	   through so-called "catastrophic cancellation", when this option is
	   used to set the precision to less than extended precision.

       -mdaz-ftz
	   The flush-to-zero (FTZ) and denormals-are-zero (DAZ) flags in the
	   MXCSR register are used to control floating-point calculations.SSE
	   and AVX instructions including scalar and vector instructions could
	   benefit from enabling the FTZ and DAZ flags when -mdaz-ftz is
	   specified. Don't set FTZ/DAZ flags when -mno-daz-ftz or -shared is
	   specified, -mdaz-ftz will set FTZ/DAZ flags even with -shared.

       -mstackrealign
	   Realign the stack at entry.	On the x86, the -mstackrealign option
	   generates an alternate prologue and epilogue that realigns the run-
	   time stack if necessary.  This supports mixing legacy codes that
	   keep 4-byte stack alignment with modern codes that keep 16-byte
	   stack alignment for SSE compatibility.  See also the attribute
	   "force_align_arg_pointer", applicable to individual functions.

       -mpreferred-stack-boundary=num
	   Attempt to keep the stack boundary aligned to a 2 raised to num
	   byte boundary.  If -mpreferred-stack-boundary is not specified, the
	   default is 4 (16 bytes or 128 bits).

	   Warning: When generating code for the x86-64 architecture with SSE
	   extensions disabled, -mpreferred-stack-boundary=3 can be used to
	   keep the stack boundary aligned to 8 byte boundary.	Since x86-64
	   ABI require 16 byte stack alignment, this is ABI incompatible and
	   intended to be used in controlled environment where stack space is
	   important limitation.  This option leads to wrong code when
	   functions compiled with 16 byte stack alignment (such as functions
	   from a standard library) are called with misaligned stack.  In this
	   case, SSE instructions may lead to misaligned memory access traps.
	   In addition, variable arguments are handled incorrectly for 16 byte
	   aligned objects (including x87 long double and __int128), leading
	   to wrong results.  You must build all modules with
	   -mpreferred-stack-boundary=3, including any libraries.  This
	   includes the system libraries and startup modules.

       -mincoming-stack-boundary=num
	   Assume the incoming stack is aligned to a 2 raised to num byte
	   boundary.  If -mincoming-stack-boundary is not specified, the one
	   specified by -mpreferred-stack-boundary is used.

	   On Pentium and Pentium Pro, "double" and "long double" values
	   should be aligned to an 8-byte boundary (see -malign-double) or
	   suffer significant run time performance penalties.  On Pentium III,
	   the Streaming SIMD Extension (SSE) data type "__m128" may not work
	   properly if it is not 16-byte aligned.

	   To ensure proper alignment of this values on the stack, the stack
	   boundary must be as aligned as that required by any value stored on
	   the stack.  Further, every function must be generated such that it
	   keeps the stack aligned.  Thus calling a function compiled with a
	   higher preferred stack boundary from a function compiled with a
	   lower preferred stack boundary most likely misaligns the stack.  It
	   is recommended that libraries that use callbacks always use the
	   default setting.

	   This extra alignment does consume extra stack space, and generally
	   increases code size.	 Code that is sensitive to stack space usage,
	   such as embedded systems and operating system kernels, may want to
	   reduce the preferred alignment to -mpreferred-stack-boundary=2.

       -mmmx
       -msse
       -msse2
       -msse3
       -mssse3
       -msse4
       -msse4a
       -msse4.1
       -msse4.2
       -mavx
       -mavx2
       -mavx512f
       -mavx512pf
       -mavx512er
       -mavx512cd
       -mavx512vl
       -mavx512bw
       -mavx512dq
       -mavx512ifma
       -mavx512vbmi
       -msha
       -maes
       -mpclmul
       -mclflushopt
       -mclwb
       -mfsgsbase
       -mptwrite
       -mrdrnd
       -mf16c
       -mfma
       -mpconfig
       -mwbnoinvd
       -mfma4
       -mprfchw
       -mrdpid
       -mprefetchwt1
       -mrdseed
       -msgx
       -mxop
       -mlwp
       -m3dnow
       -m3dnowa
       -mpopcnt
       -mabm
       -madx
       -mbmi
       -mbmi2
       -mlzcnt
       -mfxsr
       -mxsave
       -mxsaveopt
       -mxsavec
       -mxsaves
       -mrtm
       -mhle
       -mtbm
       -mmwaitx
       -mclzero
       -mpku
       -mavx512vbmi2
       -mavx512bf16
       -mavx512fp16
       -mgfni
       -mvaes
       -mwaitpkg
       -mvpclmulqdq
       -mavx512bitalg
       -mmovdiri
       -mmovdir64b
       -menqcmd
       -muintr
       -mtsxldtrk
       -mavx512vpopcntdq
       -mavx512vp2intersect
       -mavx5124fmaps
       -mavx512vnni
       -mavxvnni
       -mavx5124vnniw
       -mcldemote
       -mserialize
       -mamx-tile
       -mamx-int8
       -mamx-bf16
       -mhreset
       -mkl
       -mwidekl
       -mavxifma
       -mavxvnniint8
       -mavxneconvert
       -mcmpccxadd
       -mamx-fp16
       -mprefetchi
       -mraoint
       -mamx-complex
       -mavxvnniint16
       -msm3
       -msha512
       -msm4
       -mapxf
       -musermsr
       -mavx10.1
       -mavx10.1-256
       -mavx10.1-512
	   These switches enable the use of instructions in the MMX, SSE,
	   AVX512ER, AVX512CD, AVX512VL, AVX512BW, AVX512DQ, AVX512IFMA,
	   AVX512VBMI, SHA, AES, PCLMUL, CLFLUSHOPT, CLWB, FSGSBASE, PTWRITE,
	   RDRND, F16C, FMA, PCONFIG, WBNOINVD, FMA4, PREFETCHW, RDPID,
	   PREFETCHWT1, RDSEED, SGX, XOP, LWP, 3DNow!, enhanced 3DNow!,
	   POPCNT, ABM, ADX, BMI, BMI2, LZCNT, FXSR, XSAVE, XSAVEOPT, XSAVEC,
	   XSAVES, RTM, HLE, TBM, MWAITX, CLZERO, PKU, AVX512VBMI2, GFNI,
	   VAES, WAITPKG, VPCLMULQDQ, AVX512BITALG, MOVDIRI, MOVDIR64B,
	   AVX512BF16, ENQCMD, AVX512VPOPCNTDQ, AVX5124FMAPS, AVX512VNNI,
	   AVX5124VNNIW, SERIALIZE, UINTR, HRESET, AMXTILE, AMXINT8, AMXBF16,
	   KL, WIDEKL, AVXVNNI, AVX512-FP16, AVXIFMA, AVXVNNIINT8,
	   AVXNECONVERT, CMPCCXADD, AMX-FP16, PREFETCHI, RAOINT, AMX-COMPLEX,
	   AVXVNNIINT16, SM3, SHA512, SM4, APX_F, USER_MSR, AVX10.1 or
	   CLDEMOTE extended instruction sets.	Each has a corresponding -mno-
	   option to disable use of these instructions.

	   These extensions are also available as built-in functions: see x86
	   Built-in Functions, for details of the functions enabled and
	   disabled by these switches.

	   To generate SSE/SSE2 instructions automatically from floating-point
	   code (as opposed to 387 instructions), see -mfpmath=sse.

	   GCC depresses SSEx instructions when -mavx is used. Instead, it
	   generates new AVX instructions or AVX equivalence for all SSEx
	   instructions when needed.

	   These options enable GCC to use these extended instructions in
	   generated code, even without -mfpmath=sse.  Applications that
	   perform run-time CPU detection must compile separate files for each
	   supported architecture, using the appropriate flags.	 In
	   particular, the file containing the CPU detection code should be
	   compiled without these options.

       -mdump-tune-features
	   This option instructs GCC to dump the names of the x86 performance
	   tuning features and default settings. The names can be used in
	   -mtune-ctrl=feature-list.

       -mtune-ctrl=feature-list
	   This option is used to do fine grain control of x86 code generation
	   features.  feature-list is a comma separated list of feature names.
	   See also -mdump-tune-features. When specified, the feature is
	   turned on if it is not preceded with ^, otherwise, it is turned
	   off.	 -mtune-ctrl=feature-list is intended to be used by GCC
	   developers. Using it may lead to code paths not covered by testing
	   and can potentially result in compiler ICEs or runtime errors.

       -mno-default
	   This option instructs GCC to turn off all tunable features. See
	   also -mtune-ctrl=feature-list and -mdump-tune-features.

       -mcld
	   This option instructs GCC to emit a "cld" instruction in the
	   prologue of functions that use string instructions.	String
	   instructions depend on the DF flag to select between autoincrement
	   or autodecrement mode.  While the ABI specifies the DF flag to be
	   cleared on function entry, some operating systems violate this
	   specification by not clearing the DF flag in their exception
	   dispatchers.	 The exception handler can be invoked with the DF flag
	   set, which leads to wrong direction mode when string instructions
	   are used.  This option can be enabled by default on 32-bit x86
	   targets by configuring GCC with the --enable-cld configure option.
	   Generation of "cld" instructions can be suppressed with the
	   -mno-cld compiler option in this case.

       -mvzeroupper
	   This option instructs GCC to emit a "vzeroupper" instruction before
	   a transfer of control flow out of the function to minimize the AVX
	   to SSE transition penalty as well as remove unnecessary "zeroupper"
	   intrinsics.

       -mprefer-avx128
	   This option instructs GCC to use 128-bit AVX instructions instead
	   of 256-bit AVX instructions in the auto-vectorizer.

       -mprefer-vector-width=opt
	   This option instructs GCC to use opt-bit vector width in
	   instructions instead of default on the selected platform.

       -mpartial-vector-fp-math
	   This option enables GCC to generate floating-point operations that
	   might affect the set of floating-point status flags on partial
	   vectors, where vector elements reside in the low part of the
	   128-bit SSE register.  Unless -fno-trapping-math is specified, the
	   compiler guarantees correct behavior by sanitizing all input
	   operands to have zeroes in the unused upper part of the vector
	   register.  Note that by using built-in functions or inline assembly
	   with partial vector arguments, NaNs, denormal or invalid values can
	   leak into the upper part of the vector, causing possible
	   performance issues when -fno-trapping-math is in effect.  These
	   issues can be mitigated by manually sanitizing the upper part of
	   the partial vector argument register or by using -mdaz-ftz to set
	   denormals-are-zero (DAZ) flag in the MXCSR register.

	   This option is enabled by default.

       -mmove-max=bits
	   This option instructs GCC to set the maximum number of bits can be
	   moved from memory to memory efficiently to bits.  The valid bits
	   are 128, 256 and 512.

       -mstore-max=bits
	   This option instructs GCC to set the maximum number of bits can be
	   stored to memory efficiently to bits.  The valid bits are 128, 256
	   and 512.

	   none
	       No extra limitations applied to GCC other than defined by the
	       selected platform.

	   128 Prefer 128-bit vector width for instructions.

	   256 Prefer 256-bit vector width for instructions.

	   512 Prefer 512-bit vector width for instructions.

       -mnoreturn-no-callee-saved-registers
	   This option optimizes functions with "noreturn" attribute or
	   "_Noreturn" specifier by not saving in the function prologue
	   callee-saved registers which are used in the function (except for
	   the "BP" register).	This option can interfere with debugging of
	   the caller of the "noreturn" function or any function further up in
	   the call stack, so it is not enabled by default.

       -mcx16
	   This option enables GCC to generate "CMPXCHG16B" instructions in
	   64-bit code to implement compare-and-exchange operations on 16-byte
	   aligned 128-bit objects.  This is useful for atomic updates of data
	   structures exceeding one machine word in size.  The compiler uses
	   this instruction to implement __sync Builtins.  However, for
	   __atomic Builtins operating on 128-bit integers, a library call is
	   always used.

       -msahf
	   This option enables generation of "SAHF" instructions in 64-bit
	   code.  Early Intel Pentium 4 CPUs with Intel 64 support, prior to
	   the introduction of Pentium 4 G1 step in December 2005, lacked the
	   "LAHF" and "SAHF" instructions which are supported by AMD64.	 These
	   are load and store instructions, respectively, for certain status
	   flags.  In 64-bit mode, the "SAHF" instruction is used to optimize
	   "fmod", "drem", and "remainder" built-in functions; see Other
	   Builtins for details.

       -mmovbe
	   This option enables use of the "movbe" instruction to optimize byte
	   swapping of four and eight byte entities.

       -mshstk
	   The -mshstk option enables shadow stack built-in functions from x86
	   Control-flow Enforcement Technology (CET).

       -mcrc32
	   This option enables built-in functions "__builtin_ia32_crc32qi",
	   "__builtin_ia32_crc32hi", "__builtin_ia32_crc32si" and
	   "__builtin_ia32_crc32di" to generate the "crc32" machine
	   instruction.

       -mmwait
	   This option enables built-in functions "__builtin_ia32_monitor",
	   and "__builtin_ia32_mwait" to generate the "monitor" and "mwait"
	   machine instructions.

       -mrecip
	   This option enables use of "RCPSS" and "RSQRTSS" instructions (and
	   their vectorized variants "RCPPS" and "RSQRTPS") with an additional
	   Newton-Raphson step to increase precision instead of "DIVSS" and
	   "SQRTSS" (and their vectorized variants) for single-precision
	   floating-point arguments.  These instructions are generated only
	   when -funsafe-math-optimizations is enabled together with
	   -ffinite-math-only and -fno-trapping-math.  Note that while the
	   throughput of the sequence is higher than the throughput of the
	   non-reciprocal instruction, the precision of the sequence can be
	   decreased by up to 2 ulp (i.e. the inverse of 1.0 equals
	   0.99999994).

	   Note that GCC implements "1.0f/sqrtf(x)" in terms of "RSQRTSS" (or
	   "RSQRTPS") already with -ffast-math (or the above option
	   combination), and doesn't need -mrecip.

	   Also note that GCC emits the above sequence with additional Newton-
	   Raphson step for vectorized single-float division and vectorized
	   sqrtf(x) already with -ffast-math (or the above option
	   combination), and doesn't need -mrecip.

       -mrecip=opt
	   This option controls which reciprocal estimate instructions may be
	   used.  opt is a comma-separated list of options, which may be
	   preceded by a ! to invert the option:

	   all Enable all estimate instructions.

	   default
	       Enable the default instructions, equivalent to -mrecip.

	   none
	       Disable all estimate instructions, equivalent to -mno-recip.

	   div Enable the approximation for scalar division.

	   vec-div
	       Enable the approximation for vectorized division.

	   sqrt
	       Enable the approximation for scalar square root.

	   vec-sqrt
	       Enable the approximation for vectorized square root.

	   So, for example, -mrecip=all,!sqrt enables all of the reciprocal
	   approximations, except for square root.

       -mveclibabi=type
	   Specifies the ABI type to use for vectorizing intrinsics using an
	   external library.  Supported values for type are svml for the Intel
	   short vector math library and acml for the AMD math core library.
	   To use this option, both -ftree-vectorize and
	   -funsafe-math-optimizations have to be enabled, and an SVML or ACML
	   ABI-compatible library must be specified at link time.

	   GCC currently emits calls to "vmldExp2", "vmldLn2", "vmldLog102",
	   "vmldPow2", "vmldTanh2", "vmldTan2", "vmldAtan2", "vmldAtanh2",
	   "vmldCbrt2", "vmldSinh2", "vmldSin2", "vmldAsinh2", "vmldAsin2",
	   "vmldCosh2", "vmldCos2", "vmldAcosh2", "vmldAcos2", "vmlsExp4",
	   "vmlsLn4", "vmlsLog104", "vmlsPow4", "vmlsTanh4", "vmlsTan4",
	   "vmlsAtan4", "vmlsAtanh4", "vmlsCbrt4", "vmlsSinh4", "vmlsSin4",
	   "vmlsAsinh4", "vmlsAsin4", "vmlsCosh4", "vmlsCos4", "vmlsAcosh4"
	   and "vmlsAcos4" for corresponding function type when
	   -mveclibabi=svml is used, and "__vrd2_sin", "__vrd2_cos",
	   "__vrd2_exp", "__vrd2_log", "__vrd2_log2", "__vrd2_log10",
	   "__vrs4_sinf", "__vrs4_cosf", "__vrs4_expf", "__vrs4_logf",
	   "__vrs4_log2f", "__vrs4_log10f" and "__vrs4_powf" for the
	   corresponding function type when -mveclibabi=acml is used.

       -mabi=name
	   Generate code for the specified calling convention.	Permissible
	   values are sysv for the ABI used on GNU/Linux and other systems,
	   and ms for the Microsoft ABI.  The default is to use the Microsoft
	   ABI when targeting Microsoft Windows and the SysV ABI on all other
	   systems.  You can control this behavior for specific functions by
	   using the function attributes "ms_abi" and "sysv_abi".

       -mforce-indirect-call
	   Force all calls to functions to be indirect. This is useful when
	   using Intel Processor Trace where it generates more precise timing
	   information for function calls.

       -mmanual-endbr
	   Insert ENDBR instruction at function entry only via the "cf_check"
	   function attribute. This is useful when used with the option
	   -fcf-protection=branch to control ENDBR insertion at the function
	   entry.

       -mcet-switch
	   By default, CET instrumentation is turned off on switch statements
	   that use a jump table and indirect branch track is disabled.	 Since
	   jump tables are stored in read-only memory, this does not result in
	   a direct loss of hardening.	But if the jump table index is
	   attacker-controlled, the indirect jump may not be constrained by
	   CET.	 This option turns on CET instrumentation to enable indirect
	   branch track for switch statements with jump tables which leads to
	   the jump targets reachable via any indirect jumps.

       -mcall-ms2sysv-xlogues
	   Due to differences in 64-bit ABIs, any Microsoft ABI function that
	   calls a System V ABI function must consider RSI, RDI and XMM6-15 as
	   clobbered.  By default, the code for saving and restoring these
	   registers is emitted inline, resulting in fairly lengthy prologues
	   and epilogues.  Using -mcall-ms2sysv-xlogues emits prologues and
	   epilogues that use stubs in the static portion of libgcc to perform
	   these saves and restores, thus reducing function size at the cost
	   of a few extra instructions.

       -mtls-dialect=type
	   Generate code to access thread-local storage using the gnu or gnu2
	   conventions.	 gnu is the conservative default; gnu2 is more
	   efficient, but it may add compile- and run-time requirements that
	   cannot be satisfied on all systems.

       -mpush-args
       -mno-push-args
	   Use PUSH operations to store outgoing parameters.  This method is
	   shorter and usually equally fast as method using SUB/MOV operations
	   and is enabled by default.  In some cases disabling it may improve
	   performance because of improved scheduling and reduced
	   dependencies.

       -maccumulate-outgoing-args
	   If enabled, the maximum amount of space required for outgoing
	   arguments is computed in the function prologue.  This is faster on
	   most modern CPUs because of reduced dependencies, improved
	   scheduling and reduced stack usage when the preferred stack
	   boundary is not equal to 2.	The drawback is a notable increase in
	   code size.  This switch implies -mno-push-args.

       -mthreads
	   Support thread-safe exception handling on MinGW.  Programs that
	   rely on thread-safe exception handling must compile and link all
	   code with the -mthreads option.  When compiling, -mthreads defines
	   -D_MT; when linking, it links in a special thread helper library
	   -lmingwthrd which cleans up per-thread exception-handling data.

       -mms-bitfields
       -mno-ms-bitfields
	   Enable/disable bit-field layout compatible with the native
	   Microsoft Windows compiler.

	   If "packed" is used on a structure, or if bit-fields are used, it
	   may be that the Microsoft ABI lays out the structure differently
	   than the way GCC normally does.  Particularly when moving packed
	   data between functions compiled with GCC and the native Microsoft
	   compiler (either via function call or as data in a file), it may be
	   necessary to access either format.

	   This option is enabled by default for Microsoft Windows targets.
	   This behavior can also be controlled locally by use of variable or
	   type attributes.  For more information, see x86 Variable Attributes
	   and x86 Type Attributes.

	   The Microsoft structure layout algorithm is fairly simple with the
	   exception of the bit-field packing.	The padding and alignment of
	   members of structures and whether a bit-field can straddle a
	   storage-unit boundary are determine by these rules:

	   1. Structure members are stored sequentially in the order in which
	   they are
	       declared: the first member has the lowest memory address and
	       the last member the highest.

	   2. Every data object has an alignment requirement.  The alignment
	   requirement
	       for all data except structures, unions, and arrays is either
	       the size of the object or the current packing size (specified
	       with either the "aligned" attribute or the "pack" pragma),
	       whichever is less.  For structures, unions, and arrays, the
	       alignment requirement is the largest alignment requirement of
	       its members.  Every object is allocated an offset so that:

		       offset % alignment_requirement == 0

	   3. Adjacent bit-fields are packed into the same 1-, 2-, or 4-byte
	   allocation
	       unit if the integral types are the same size and if the next
	       bit-field fits into the current allocation unit without
	       crossing the boundary imposed by the common alignment
	       requirements of the bit-fields.

	   MSVC interprets zero-length bit-fields in the following ways:

	   1. If a zero-length bit-field is inserted between two bit-fields
	   that
	       are normally coalesced, the bit-fields are not coalesced.

	       For example:

		       struct
			{
			  unsigned long bf_1 : 12;
			  unsigned long : 0;
			  unsigned long bf_2 : 12;
			} t1;

	       The size of "t1" is 8 bytes with the zero-length bit-field.  If
	       the zero-length bit-field were removed, "t1"'s size would be 4
	       bytes.

	   2. If a zero-length bit-field is inserted after a bit-field, "foo",
	   and the
	       alignment of the zero-length bit-field is greater than the
	       member that follows it, "bar", "bar" is aligned as the type of
	       the zero-length bit-field.

	       For example:

		       struct
			{
			  char foo : 4;
			  short : 0;
			  char bar;
			} t2;

		       struct
			{
			  char foo : 4;
			  short : 0;
			  double bar;
			} t3;

	       For "t2", "bar" is placed at offset 2, rather than offset 1.
	       Accordingly, the size of "t2" is 4.  For "t3", the zero-length
	       bit-field does not affect the alignment of "bar" or, as a
	       result, the size of the structure.

	       Taking this into account, it is important to note the
	       following:

	       1. If a zero-length bit-field follows a normal bit-field, the
	       type of the
		   zero-length bit-field may affect the alignment of the
		   structure as whole. For example, "t2" has a size of 4
		   bytes, since the zero-length bit-field follows a normal
		   bit-field, and is of type short.

	       2. Even if a zero-length bit-field is not followed by a normal
	       bit-field, it may
		   still affect the alignment of the structure:

			   struct
			    {
			      char foo : 6;
			      long : 0;
			    } t4;

		   Here, "t4" takes up 4 bytes.

	   3. Zero-length bit-fields following non-bit-field members are
	   ignored:
		       struct
			{
			  char foo;
			  long : 0;
			  char bar;
			} t5;

	       Here, "t5" takes up 2 bytes.

       -mno-align-stringops
	   Do not align the destination of inlined string operations.  This
	   switch reduces code size and improves performance in case the
	   destination is already aligned, but GCC doesn't know about it.

       -minline-all-stringops
	   By default GCC inlines string operations only when the destination
	   is known to be aligned to least a 4-byte boundary.  This enables
	   more inlining and increases code size, but may improve performance
	   of code that depends on fast "memcpy" and "memset" for short
	   lengths.  The option enables inline expansion of "strlen" for all
	   pointer alignments.

       -minline-stringops-dynamically
	   For string operations of unknown size, use run-time checks with
	   inline code for small blocks and a library call for large blocks.

       -mstringop-strategy=alg
	   Override the internal decision heuristic for the particular
	   algorithm to use for inlining string operations.  The allowed
	   values for alg are:

	   rep_byte
	   rep_4byte
	   rep_8byte
	       Expand using i386 "rep" prefix of the specified size.

	   byte_loop
	   loop
	   unrolled_loop
	       Expand into an inline loop.

	   libcall
	       Always use a library call.

       -mmemcpy-strategy=strategy
	   Override the internal decision heuristic to decide if
	   "__builtin_memcpy" should be inlined and what inline algorithm to
	   use when the expected size of the copy operation is known. strategy
	   is a comma-separated list of alg:max_size:dest_align triplets.  alg
	   is specified in -mstringop-strategy, max_size specifies the max
	   byte size with which inline algorithm alg is allowed.  For the last
	   triplet, the max_size must be -1. The max_size of the triplets in
	   the list must be specified in increasing order.  The minimal byte
	   size for alg is 0 for the first triplet and "max_size + 1" of the
	   preceding range.

       -mmemset-strategy=strategy
	   The option is similar to -mmemcpy-strategy= except that it is to
	   control "__builtin_memset" expansion.

       -momit-leaf-frame-pointer
	   Don't keep the frame pointer in a register for leaf functions.
	   This avoids the instructions to save, set up, and restore frame
	   pointers and makes an extra register available in leaf functions.
	   The option -fomit-leaf-frame-pointer removes the frame pointer for
	   leaf functions, which might make debugging harder.

       -mtls-direct-seg-refs
       -mno-tls-direct-seg-refs
	   Controls whether TLS variables may be accessed with offsets from
	   the TLS segment register (%gs for 32-bit, %fs for 64-bit), or
	   whether the thread base pointer must be added.  Whether or not this
	   is valid depends on the operating system, and whether it maps the
	   segment to cover the entire TLS area.

	   For systems that use the GNU C Library, the default is on.

       -msse2avx
       -mno-sse2avx
	   Specify that the assembler should encode SSE instructions with VEX
	   prefix.  The option -mavx turns this on by default.

       -mfentry
       -mno-fentry
	   If profiling is active (-pg), put the profiling counter call before
	   the prologue.  Note: On x86 architectures the attribute
	   "ms_hook_prologue" isn't possible at the moment for -mfentry and
	   -pg.

       -mrecord-mcount
       -mno-record-mcount
	   If profiling is active (-pg), generate a __mcount_loc section that
	   contains pointers to each profiling call. This is useful for
	   automatically patching and out calls.

       -mnop-mcount
       -mno-nop-mcount
	   If profiling is active (-pg), generate the calls to the profiling
	   functions as NOPs. This is useful when they should be patched in
	   later dynamically. This is likely only useful together with
	   -mrecord-mcount.

       -minstrument-return=type
	   Instrument function exit in -pg -mfentry instrumented functions
	   with call to specified function. This only instruments true returns
	   ending with ret, but not sibling calls ending with jump. Valid
	   types are none to not instrument, call to generate a call to
	   __return__, or nop5 to generate a 5 byte nop.

       -mrecord-return
       -mno-record-return
	   Generate a __return_loc section pointing to all return
	   instrumentation code.

       -mfentry-name=name
	   Set name of __fentry__ symbol called at function entry for -pg
	   -mfentry functions.

       -mfentry-section=name
	   Set name of section to record -mrecord-mcount calls (default
	   __mcount_loc).

       -mskip-rax-setup
       -mno-skip-rax-setup
	   When generating code for the x86-64 architecture with SSE
	   extensions disabled, -mskip-rax-setup can be used to skip setting
	   up RAX register when there are no variable arguments passed in
	   vector registers.

	   Warning: Since RAX register is used to avoid unnecessarily saving
	   vector registers on stack when passing variable arguments, the
	   impacts of this option are callees may waste some stack space,
	   misbehave or jump to a random location.  GCC 4.4 or newer don't
	   have those issues, regardless the RAX register value.

       -m8bit-idiv
       -mno-8bit-idiv
	   On some processors, like Intel Atom, 8-bit unsigned integer divide
	   is much faster than 32-bit/64-bit integer divide.  This option
	   generates a run-time check.	If both dividend and divisor are
	   within range of 0 to 255, 8-bit unsigned integer divide is used
	   instead of 32-bit/64-bit integer divide.

       -mavx256-split-unaligned-load
       -mavx256-split-unaligned-store
	   Split 32-byte AVX unaligned load and store.

       -mstack-protector-guard=guard
       -mstack-protector-guard-reg=reg
       -mstack-protector-guard-offset=offset
	   Generate stack protection code using canary at guard.  Supported
	   locations are global for global canary or tls for per-thread canary
	   in the TLS block (the default).  This option has effect only when
	   -fstack-protector or -fstack-protector-all is specified.

	   With the latter choice the options -mstack-protector-guard-reg=reg
	   and -mstack-protector-guard-offset=offset furthermore specify which
	   segment register (%fs or %gs) to use as base register for reading
	   the canary, and from what offset from that base register.  The
	   default for those is as specified in the relevant ABI.

       -mgeneral-regs-only
	   Generate code that uses only the general-purpose registers.	This
	   prevents the compiler from using floating-point, vector, mask and
	   bound registers.

       -mrelax-cmpxchg-loop
	   When emitting a compare-and-swap loop for __sync Builtins and
	   __atomic Builtins lacking a native instruction, optimize for the
	   highly contended case by issuing an atomic load before the
	   "CMPXCHG" instruction, and using the "PAUSE" instruction to save
	   CPU power when restarting the loop.

       -mindirect-branch=choice
	   Convert indirect call and jump with choice.	The default is keep,
	   which keeps indirect call and jump unmodified.  thunk converts
	   indirect call and jump to call and return thunk.  thunk-inline
	   converts indirect call and jump to inlined call and return thunk.
	   thunk-extern converts indirect call and jump to external call and
	   return thunk provided in a separate object file.  You can control
	   this behavior for a specific function by using the function
	   attribute "indirect_branch".

	   Note that -mcmodel=large is incompatible with
	   -mindirect-branch=thunk and -mindirect-branch=thunk-extern since
	   the thunk function may not be reachable in the large code model.

	   Note that -mindirect-branch=thunk-extern is compatible with
	   -fcf-protection=branch since the external thunk can be made to
	   enable control-flow check.

       -mfunction-return=choice
	   Convert function return with choice.	 The default is keep, which
	   keeps function return unmodified.  thunk converts function return
	   to call and return thunk.  thunk-inline converts function return to
	   inlined call and return thunk.  thunk-extern converts function
	   return to external call and return thunk provided in a separate
	   object file.	 You can control this behavior for a specific function
	   by using the function attribute "function_return".

	   Note that -mindirect-return=thunk-extern is compatible with
	   -fcf-protection=branch since the external thunk can be made to
	   enable control-flow check.

	   Note that -mcmodel=large is incompatible with
	   -mfunction-return=thunk and -mfunction-return=thunk-extern since
	   the thunk function may not be reachable in the large code model.

       -mindirect-branch-register
	   Force indirect call and jump via register.

       -mharden-sls=choice
	   Generate code to mitigate against straight line speculation (SLS)
	   with choice.	 The default is none which disables all SLS hardening.
	   return enables SLS hardening for function returns.  indirect-jmp
	   enables SLS hardening for indirect jumps.  all enables all SLS
	   hardening.

       -mindirect-branch-cs-prefix
	   Add CS prefix to call and jmp to indirect thunk with branch target
	   in r8-r15 registers so that the call and jmp instruction length is
	   6 bytes to allow them to be replaced with lfence; call *%r8-r15 or
	   lfence; jmp *%r8-r15 at run-time.

       -mapx-inline-asm-use-gpr32
	   For inline asm support with APX, by default the EGPR feature was
	   disabled to prevent potential illegal instruction with EGPR occurs.
	   To invoke egpr usage in inline asm, use new compiler option
	   -mapx-inline-asm-use-gpr32 and user should ensure the instruction
	   supports EGPR.

       -mevex512
       -mno-evex512
	   Enables/disables 512-bit vector. It will be default on if AVX512F
	   is enabled.

       These -m switches are supported in addition to the above on x86-64
       processors in 64-bit environments.

       -m32
       -m64
       -mx32
       -m16
       -miamcu
	   Generate code for a 16-bit, 32-bit or 64-bit environment.  The -m32
	   option sets "int", "long", and pointer types to 32 bits, and
	   generates code that runs in 32-bit mode.

	   The -m64 option sets "int" to 32 bits and "long" and pointer types
	   to 64 bits, and generates code for the x86-64 architecture.	For
	   Darwin only the -m64 option also turns off the -fno-pic and
	   -mdynamic-no-pic options.

	   The -mx32 option sets "int", "long", and pointer types to 32 bits,
	   and generates code for the x86-64 architecture.

	   The -m16 option is the same as -m32, except for that it outputs the
	   ".code16gcc" assembly directive at the beginning of the assembly
	   output so that the binary can run in 16-bit mode.

	   The -miamcu option generates code which conforms to Intel MCU
	   psABI.  It requires the -m32 option to be turned on.

       -mno-red-zone
	   Do not use a so-called "red zone" for x86-64 code.  The red zone is
	   mandated by the x86-64 ABI; it is a 128-byte area beyond the
	   location of the stack pointer that is not modified by signal or
	   interrupt handlers and therefore can be used for temporary data
	   without adjusting the stack pointer.	 The flag -mno-red-zone
	   disables this red zone.

       -mcmodel=small
	   Generate code for the small code model: the program and its symbols
	   must be linked in the lower 2 GB of the address space.  Pointers
	   are 64 bits.	 Programs can be statically or dynamically linked.
	   This is the default code model.

       -mcmodel=kernel
	   Generate code for the kernel code model.  The kernel runs in the
	   negative 2 GB of the address space.	This model has to be used for
	   Linux kernel code.

       -mcmodel=medium
	   Generate code for the medium model: the program is linked in the
	   lower 2 GB of the address space.  Small symbols are also placed
	   there.  Symbols with sizes larger than -mlarge-data-threshold are
	   put into large data or BSS sections and can be located above 2GB.
	   Programs can be statically or dynamically linked.

       -mcmodel=large
	   Generate code for the large model.  This model makes no assumptions
	   about addresses and sizes of sections.

       -maddress-mode=long
	   Generate code for long address mode.	 This is only supported for
	   64-bit and x32 environments.	 It is the default address mode for
	   64-bit environments.

       -maddress-mode=short
	   Generate code for short address mode.  This is only supported for
	   32-bit and x32 environments.	 It is the default address mode for
	   32-bit and x32 environments.

       -mneeded
       -mno-needed
	   Emit GNU_PROPERTY_X86_ISA_1_NEEDED GNU property for Linux target to
	   indicate the micro-architecture ISA level required to execute the
	   binary.

       -mno-direct-extern-access
	   Without -fpic nor -fPIC, always use the GOT pointer to access
	   external symbols.  With -fpic or -fPIC, treat access to protected
	   symbols as local symbols.  The default is -mdirect-extern-access.

	   Warning: shared libraries compiled with -mno-direct-extern-access
	   and executable compiled with -mdirect-extern-access may not be
	   binary compatible if protected symbols are used in shared libraries
	   and executable.

       -munroll-only-small-loops
	   Controls conservative small loop unrolling. It is default enabled
	   by O2, and unrolls loop with less than 4 insns by 1 time. Explicit
	   -f[no-]unroll-[all-]loops would disable this flag to avoid any
	   unintended unrolling behavior that user does not want.

       -mlam=choice
	   LAM(linear-address masking) allows special bits in the pointer to
	   be used for metadata. The default is none. With u48, pointer bits
	   in positions 62:48 can be used for metadata; With u57, pointer bits
	   in positions 62:57 can be used for metadata.

       x86 Windows Options

       These additional options are available for Microsoft Windows targets:

       -mconsole
	   This option specifies that a console application is to be
	   generated, by instructing the linker to set the PE header subsystem
	   type required for console applications.  This option is available
	   for Cygwin and MinGW targets and is enabled by default on those
	   targets.

       -mcrtdll=library
	   Preprocess, compile or link with specified C RunTime DLL library.
	   This option adjust predefined macros "__CRTDLL__", "__MSVCRT__",
	   "_UCRT" and "__MSVCRT_VERSION__" for specified CRT library, choose
	   start file for CRT library and link with CRT library.  Recognized
	   CRT library names for proprocessor are: "crtdll*", "msvcrt10*",
	   "msvcrt20*", "msvcrt40*", "msvcr40*", "msvcrtd*", "msvcrt-os*",
	   "msvcr70*", "msvcr71*", "msvcr80*", "msvcr90*", "msvcr100*",
	   "msvcr110*", "msvcr120*" and "ucrt*".  If this options is not
	   specified then the default MinGW import library "msvcrt" is used
	   for linking and no other adjustment for preprocessor is done. MinGW
	   import library "msvcrt" is just a symlink to (or a copy of) another
	   MinGW CRT import library chosen during MinGW compilation. MinGW
	   import library "msvcrt-os" is for Windows system CRT DLL library
	   "msvcrt.dll" and in most cases is the default MinGW import library.
	   Generally speaking, changing the CRT DLL requires recompiling the
	   entire MinGW CRT. This option is for experimental and testing
	   purposes only.  This option is available for MinGW targets.

       -mdll
	   This option is available for Cygwin and MinGW targets.  It
	   specifies that a DLL---a dynamic link library---is to be generated,
	   enabling the selection of the required runtime startup object and
	   entry point.

       -mnop-fun-dllimport
	   This option is available for Cygwin and MinGW targets.  It
	   specifies that the "dllimport" attribute should be ignored.

       -mthreads
	   This option is available for MinGW targets. It specifies that
	   MinGW-specific thread support is to be used.

       -municode
	   This option is available for MinGW-w64 targets.  It causes the
	   "UNICODE" preprocessor macro to be predefined, and chooses Unicode-
	   capable runtime startup code.

       -mwin32
	   This option is available for Cygwin and MinGW targets.  It
	   specifies that the typical Microsoft Windows predefined macros are
	   to be set in the pre-processor, but does not influence the choice
	   of runtime library/startup code.

       -mwindows
	   This option is available for Cygwin and MinGW targets.  It
	   specifies that a GUI application is to be generated by instructing
	   the linker to set the PE header subsystem type appropriately.

       -fno-set-stack-executable
	   This option is available for MinGW targets. It specifies that the
	   executable flag for the stack used by nested functions isn't set.
	   This is necessary for binaries running in kernel mode of Microsoft
	   Windows, as there the User32 API, which is used to set executable
	   privileges, isn't available.

       -fwritable-relocated-rdata
	   This option is available for MinGW and Cygwin targets.  It
	   specifies that relocated-data in read-only section is put into the
	   ".data" section.  This is a necessary for older runtimes not
	   supporting modification of ".rdata" sections for pseudo-relocation.

       -mpe-aligned-commons
	   This option is available for Cygwin and MinGW targets.  It
	   specifies that the GNU extension to the PE file format that permits
	   the correct alignment of COMMON variables should be used when
	   generating code.  It is enabled by default if GCC detects that the
	   target assembler found during configuration supports the feature.

       See also under x86 Options for standard options.

       Xstormy16 Options

       These options are defined for Xstormy16:

       -msim
	   Choose startup files and linker script suitable for the simulator.

       Xtensa Options

       These options are supported for Xtensa targets:

       -mconst16
       -mno-const16
	   Enable or disable use of "CONST16" instructions for loading
	   constant values.  The "CONST16" instruction is currently not a
	   standard option from Tensilica.  When enabled, "CONST16"
	   instructions are always used in place of the standard "L32R"
	   instructions.  The use of "CONST16" is enabled by default only if
	   the "L32R" instruction is not available.

       -mfused-madd
       -mno-fused-madd
	   Enable or disable use of fused multiply/add and multiply/subtract
	   instructions in the floating-point option.  This has no effect if
	   the floating-point option is not also enabled.  Disabling fused
	   multiply/add and multiply/subtract instructions forces the compiler
	   to use separate instructions for the multiply and add/subtract
	   operations.	This may be desirable in some cases where strict IEEE
	   754-compliant results are required: the fused multiply add/subtract
	   instructions do not round the intermediate result, thereby
	   producing results with more bits of precision than specified by the
	   IEEE standard.  Disabling fused multiply add/subtract instructions
	   also ensures that the program output is not sensitive to the
	   compiler's ability to combine multiply and add/subtract operations.

       -mserialize-volatile
       -mno-serialize-volatile
	   When this option is enabled, GCC inserts "MEMW" instructions before
	   "volatile" memory references to guarantee sequential consistency.
	   The default is -mserialize-volatile.	 Use -mno-serialize-volatile
	   to omit the "MEMW" instructions.

       -mforce-no-pic
	   For targets, like GNU/Linux, where all user-mode Xtensa code must
	   be position-independent code (PIC), this option disables PIC for
	   compiling kernel code.

       -mtext-section-literals
       -mno-text-section-literals
	   These options control the treatment of literal pools.  The default
	   is -mno-text-section-literals, which places literals in a separate
	   section in the output file.	This allows the literal pool to be
	   placed in a data RAM/ROM, and it also allows the linker to combine
	   literal pools from separate object files to remove redundant
	   literals and improve code size.  With -mtext-section-literals, the
	   literals are interspersed in the text section in order to keep them
	   as close as possible to their references.  This may be necessary
	   for large assembly files.  Literals for each function are placed
	   right before that function.

       -mauto-litpools
       -mno-auto-litpools
	   These options control the treatment of literal pools.  The default
	   is -mno-auto-litpools, which places literals in a separate section
	   in the output file unless -mtext-section-literals is used.  With
	   -mauto-litpools the literals are interspersed in the text section
	   by the assembler.  Compiler does not produce explicit ".literal"
	   directives and loads literals into registers with "MOVI"
	   instructions instead of "L32R" to let the assembler do relaxation
	   and place literals as necessary.  This option allows assembler to
	   create several literal pools per function and assemble very big
	   functions, which may not be possible with -mtext-section-literals.

       -mtarget-align
       -mno-target-align
	   When this option is enabled, GCC instructs the assembler to
	   automatically align instructions to reduce branch penalties at the
	   expense of some code density.  The assembler attempts to widen
	   density instructions to align branch targets and the instructions
	   following call instructions.	 If there are not enough preceding
	   safe density instructions to align a target, no widening is
	   performed.  The default is -mtarget-align.  These options do not
	   affect the treatment of auto-aligned instructions like "LOOP",
	   which the assembler always aligns, either by widening density
	   instructions or by inserting NOP instructions.

       -mlongcalls
       -mno-longcalls
	   When this option is enabled, GCC instructs the assembler to
	   translate direct calls to indirect calls unless it can determine
	   that the target of a direct call is in the range allowed by the
	   call instruction.  This translation typically occurs for calls to
	   functions in other source files.  Specifically, the assembler
	   translates a direct "CALL" instruction into an "L32R" followed by a
	   "CALLX" instruction.	 The default is -mno-longcalls.	 This option
	   should be used in programs where the call target can potentially be
	   out of range.  This option is implemented in the assembler, not the
	   compiler, so the assembly code generated by GCC still shows direct
	   call instructions---look at the disassembled object code to see the
	   actual instructions.	 Note that the assembler uses an indirect call
	   for every cross-file call, not just those that really are out of
	   range.

       -mabi=name
	   Generate code for the specified ABI.	 Permissible values are:
	   call0, windowed.  Default ABI is chosen by the Xtensa core
	   configuration.

       -mabi=call0
	   When this option is enabled function parameters are passed in
	   registers "a2" through "a7", registers "a12" through "a15" are
	   caller-saved, and register "a15" may be used as a frame pointer.
	   When this version of the ABI is enabled the C preprocessor symbol
	   "__XTENSA_CALL0_ABI__" is defined.

       -mabi=windowed
	   When this option is enabled function parameters are passed in
	   registers "a10" through "a15", and called function rotates register
	   window by 8 registers on entry so that its arguments are found in
	   registers "a2" through "a7".	 Register "a7" may be used as a frame
	   pointer.  Register window is rotated 8 registers back upon return.
	   When this version of the ABI is enabled the C preprocessor symbol
	   "__XTENSA_WINDOWED_ABI__" is defined.

       -mextra-l32r-costs=n
	   Specify an extra cost of instruction RAM/ROM access for "L32R"
	   instructions, in clock cycles.  This affects, when optimizing for
	   speed, whether loading a constant from literal pool using "L32R" or
	   synthesizing the constant from a small one with a couple of
	   arithmetic instructions.  The default value is 0.

       -mstrict-align
       -mno-strict-align
	   Avoid or allow generating memory accesses that may not be aligned
	   on a natural object boundary as described in the architecture
	   specification.  The default is -mno-strict-align for cores that
	   support both unaligned loads and stores in hardware and
	   -mstrict-align for all other cores.

       zSeries Options

       These are listed under

ENVIRONMENT
       This section describes several environment variables that affect how
       GCC operates.  Some of them work by specifying directories or prefixes
       to use when searching for various kinds of files.  Some are used to
       specify other aspects of the compilation environment.

       Note that you can also specify places to search using options such as
       -B, -I and -L.  These take precedence over places specified using
       environment variables, which in turn take precedence over those
       specified by the configuration of GCC.

       LANG
       LC_CTYPE
       LC_MESSAGES
       LC_ALL
	   These environment variables control the way that GCC uses
	   localization information which allows GCC to work with different
	   national conventions.  GCC inspects the locale categories LC_CTYPE
	   and LC_MESSAGES if it has been configured to do so.	These locale
	   categories can be set to any value supported by your installation.
	   A typical value is en_GB.UTF-8 for English in the United Kingdom
	   encoded in UTF-8.

	   The LC_CTYPE environment variable specifies character
	   classification.  GCC uses it to determine the character boundaries
	   in a string; this is needed for some multibyte encodings that
	   contain quote and escape characters that are otherwise interpreted
	   as a string end or escape.

	   The LC_MESSAGES environment variable specifies the language to use
	   in diagnostic messages.

	   If the LC_ALL environment variable is set, it overrides the value
	   of LC_CTYPE and LC_MESSAGES; otherwise, LC_CTYPE and LC_MESSAGES
	   default to the value of the LANG environment variable.  If none of
	   these variables are set, GCC defaults to traditional C English
	   behavior.

       TMPDIR
	   If TMPDIR is set, it specifies the directory to use for temporary
	   files.  GCC uses temporary files to hold the output of one stage of
	   compilation which is to be used as input to the next stage: for
	   example, the output of the preprocessor, which is the input to the
	   compiler proper.

       GCC_COMPARE_DEBUG
	   Setting GCC_COMPARE_DEBUG is nearly equivalent to passing
	   -fcompare-debug to the compiler driver.  See the documentation of
	   this option for more details.

       GCC_EXEC_PREFIX
	   If GCC_EXEC_PREFIX is set, it specifies a prefix to use in the
	   names of the subprograms executed by the compiler.  No slash is
	   added when this prefix is combined with the name of a subprogram,
	   but you can specify a prefix that ends with a slash if you wish.

	   If GCC_EXEC_PREFIX is not set, GCC attempts to figure out an
	   appropriate prefix to use based on the pathname it is invoked with.

	   If GCC cannot find the subprogram using the specified prefix, it
	   tries looking in the usual places for the subprogram.

	   The default value of GCC_EXEC_PREFIX is prefix/lib/gcc/ where
	   prefix is the prefix to the installed compiler. In many cases
	   prefix is the value of "prefix" when you ran the configure script.

	   Other prefixes specified with -B take precedence over this prefix.

	   This prefix is also used for finding files such as crt0.o that are
	   used for linking.

	   In addition, the prefix is used in an unusual way in finding the
	   directories to search for header files.  For each of the standard
	   directories whose name normally begins with /usr/local/lib/gcc
	   (more precisely, with the value of GCC_INCLUDE_DIR), GCC tries
	   replacing that beginning with the specified prefix to produce an
	   alternate directory name.  Thus, with -Bfoo/, GCC searches foo/bar
	   just before it searches the standard directory /usr/local/lib/bar.
	   If a standard directory begins with the configured prefix then the
	   value of prefix is replaced by GCC_EXEC_PREFIX when looking for
	   header files.

       COMPILER_PATH
	   The value of COMPILER_PATH is a colon-separated list of
	   directories, much like PATH.	 GCC tries the directories thus
	   specified when searching for subprograms, if it cannot find the
	   subprograms using GCC_EXEC_PREFIX.

       LIBRARY_PATH
	   The value of LIBRARY_PATH is a colon-separated list of directories,
	   much like PATH.  When configured as a native compiler, GCC tries
	   the directories thus specified when searching for special linker
	   files, if it cannot find them using GCC_EXEC_PREFIX.	 Linking using
	   GCC also uses these directories when searching for ordinary
	   libraries for the -l option (but directories specified with -L come
	   first).

       LANG
	   This variable is used to pass locale information to the compiler.
	   One way in which this information is used is to determine the
	   character set to be used when character literals, string literals
	   and comments are parsed in C and C++.  When the compiler is
	   configured to allow multibyte characters, the following values for
	   LANG are recognized:

	   C-JIS
	       Recognize JIS characters.

	   C-SJIS
	       Recognize SJIS characters.

	   C-EUCJP
	       Recognize EUCJP characters.

	   If LANG is not defined, or if it has some other value, then the
	   compiler uses "mblen" and "mbtowc" as defined by the default locale
	   to recognize and translate multibyte characters.

       GCC_EXTRA_DIAGNOSTIC_OUTPUT
	   If GCC_EXTRA_DIAGNOSTIC_OUTPUT is set to one of the following
	   values, then additional text will be emitted to stderr when fix-it
	   hints are emitted.  -fdiagnostics-parseable-fixits and
	   -fno-diagnostics-parseable-fixits take precedence over this
	   environment variable.

	   fixits-v1
	       Emit parseable fix-it hints, equivalent to
	       -fdiagnostics-parseable-fixits.	In particular, columns are
	       expressed as a count of bytes, starting at byte 1 for the
	       initial column.

	   fixits-v2
	       As "fixits-v1", but columns are expressed as display columns,
	       as per -fdiagnostics-column-unit=display.

       Some additional environment variables affect the behavior of the
       preprocessor.

       CPATH
       C_INCLUDE_PATH
       CPLUS_INCLUDE_PATH
       OBJC_INCLUDE_PATH
	   Each variable's value is a list of directories separated by a
	   special character, much like PATH, in which to look for header
	   files.  The special character, "PATH_SEPARATOR", is target-
	   dependent and determined at GCC build time.	For Microsoft Windows-
	   based targets it is a semicolon, and for almost all other targets
	   it is a colon.

	   CPATH specifies a list of directories to be searched as if
	   specified with -I, but after any paths given with -I options on the
	   command line.  This environment variable is used regardless of
	   which language is being preprocessed.

	   The remaining environment variables apply only when preprocessing
	   the particular language indicated.  Each specifies a list of
	   directories to be searched as if specified with -isystem, but after
	   any paths given with -isystem options on the command line.

	   In all these variables, an empty element instructs the compiler to
	   search its current working directory.  Empty elements can appear at
	   the beginning or end of a path.  For instance, if the value of
	   CPATH is ":/special/include", that has the same effect as
	   -I. -I/special/include.

       DEPENDENCIES_OUTPUT
	   If this variable is set, its value specifies how to output
	   dependencies for Make based on the non-system header files
	   processed by the compiler.  System header files are ignored in the
	   dependency output.

	   The value of DEPENDENCIES_OUTPUT can be just a file name, in which
	   case the Make rules are written to that file, guessing the target
	   name from the source file name.  Or the value can have the form
	   file target, in which case the rules are written to file file using
	   target as the target name.

	   In other words, this environment variable is equivalent to
	   combining the options -MM and -MF, with an optional -MT switch too.

       SUNPRO_DEPENDENCIES
	   This variable is the same as DEPENDENCIES_OUTPUT (see above),
	   except that system header files are not ignored, so it implies -M
	   rather than -MM.  However, the dependence on the main input file is
	   omitted.

       SOURCE_DATE_EPOCH
	   If this variable is set, its value specifies a UNIX timestamp to be
	   used in replacement of the current date and time in the "__DATE__"
	   and "__TIME__" macros, so that the embedded timestamps become
	   reproducible.

	   The value of SOURCE_DATE_EPOCH must be a UNIX timestamp, defined as
	   the number of seconds (excluding leap seconds) since 01 Jan 1970
	   00:00:00 represented in ASCII; identical to the output of "date
	   +%s" on GNU/Linux and other systems that support the %s extension
	   in the "date" command.

	   The value should be a known timestamp such as the last modification
	   time of the source or package and it should be set by the build
	   process.

BUGS
       For instructions on reporting bugs, see <https://gcc.gnu.org/bugs/>.

FOOTNOTES
       1.  On some systems, gcc -shared needs to build supplementary stub code
	   for constructors to work.  On multi-libbed systems, gcc -shared
	   must select the correct support libraries to link against.  Failing
	   to supply the correct flags may lead to subtle defects.  Supplying
	   them in cases where they are not necessary is innocuous.  -shared
	   suppresses the addition of startup code to alter the floating-point
	   environment as done with -ffast-math, -Ofast or
	   -funsafe-math-optimizations on some targets.

SEE ALSO
       gpl(7), gfdl(7), fsf-funding(7), cpp(1), gcov(1), as(1), ld(1), gdb(1)
       and the Info entries for gcc, cpp, as, ld, binutils and gdb.

AUTHOR
       See the Info entry for gcc, or
       <https://gcc.gnu.org/onlinedocs/gcc/Contributors.html>, for
       contributors to GCC.

COPYRIGHT
       Copyright (c) 1988-2024 Free Software Foundation, Inc.

       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.3 or
       any later version published by the Free Software Foundation; with the
       Invariant Sections being "GNU General Public License" and "Funding Free
       Software", the Front-Cover texts being (a) (see below), and with the
       Back-Cover Texts being (b) (see below).	A copy of the license is
       included in the gfdl(7) man page.

       (a) The FSF's Front-Cover Text is:

	    A GNU Manual

       (b) The FSF's Back-Cover Text is:

	    You have freedom to copy and modify this GNU Manual, like GNU
	    software.  Copies published by the Free Software Foundation raise
	    funds for GNU development.



gcc-14.2.0			  2024-08-01				GCC(1)

GCOV(1)				      GNU			       GCOV(1)



NAME
       gcov - coverage testing tool

SYNOPSIS
       gcov [-v|--version] [-h|--help]
	    [-a|--all-blocks]
	    [-b|--branch-probabilities]
	    [-c|--branch-counts]
	    [-g|--conditions]
	    [-d|--display-progress]
	    [-f|--function-summaries]
	    [-j|--json-format]
	    [-H|--human-readable]
	    [-k|--use-colors]
	    [-l|--long-file-names]
	    [-m|--demangled-names]
	    [-n|--no-output]
	    [-o|--object-directory directory|file]
	    [-p|--preserve-paths]
	    [-q|--use-hotness-colors]
	    [-r|--relative-only]
	    [-s|--source-prefix directory]
	    [-t|--stdout]
	    [-u|--unconditional-branches]
	    [-x|--hash-filenames]
	    files

DESCRIPTION
       gcov is a test coverage program.	 Use it in concert with GCC to analyze
       your programs to help create more efficient, faster running code and to
       discover untested parts of your program.	 You can use gcov as a
       profiling tool to help discover where your optimization efforts will
       best affect your code.  You can also use gcov along with the other
       profiling tool, gprof, to assess which parts of your code use the
       greatest amount of computing time.

       Profiling tools help you analyze your code's performance.  Using a
       profiler such as gcov or gprof, you can find out some basic performance
       statistics, such as:

       *   how often each line of code executes

       *   what lines of code are actually executed

       *   how much computing time each section of code uses

       Once you know these things about how your code works when compiled, you
       can look at each module to see which modules should be optimized.  gcov
       helps you determine where to work on optimization.

       Software developers also use coverage testing in concert with
       testsuites, to make sure software is actually good enough for a
       release.	 Testsuites can verify that a program works as expected; a
       coverage program tests to see how much of the program is exercised by
       the testsuite.  Developers can then determine what kinds of test cases
       need to be added to the testsuites to create both better testing and a
       better final product.

       You should compile your code without optimization if you plan to use
       gcov because the optimization, by combining some lines of code into one
       function, may not give you as much information as you need to look for
       `hot spots' where the code is using a great deal of computer time.
       Likewise, because gcov accumulates statistics by line (at the lowest
       resolution), it works best with a programming style that places only
       one statement on each line.  If you use complicated macros that expand
       to loops or to other control structures, the statistics are less
       helpful---they only report on the line where the macro call appears.
       If your complex macros behave like functions, you can replace them with
       inline functions to solve this problem.

       gcov creates a logfile called sourcefile.gcov which indicates how many
       times each line of a source file sourcefile.c has executed.  You can
       use these logfiles along with gprof to aid in fine-tuning the
       performance of your programs.  gprof gives timing information you can
       use along with the information you get from gcov.

       gcov works only on code compiled with GCC.  It is not compatible with
       any other profiling or test coverage mechanism.

OPTIONS
       -a
       --all-blocks
	   Write individual execution counts for every basic block.  Normally
	   gcov outputs execution counts only for the main blocks of a line.
	   With this option you can determine if blocks within a single line
	   are not being executed.

       -b
       --branch-probabilities
	   Write branch frequencies to the output file, and write branch
	   summary info to the standard output.	 This option allows you to see
	   how often each branch in your program was taken.  Unconditional
	   branches will not be shown, unless the -u option is given.

       -c
       --branch-counts
	   Write branch frequencies as the number of branches taken, rather
	   than the percentage of branches taken.

       -g
       --conditions
	   Write condition coverage to the output file, and write condition
	   summary info to the standard output.	 This option allows you to see
	   if the conditions in your program at least once had an independent
	   effect on the outcome of the boolean expression (modified
	   condition/decision coverage).  This requires you to compile the
	   source with -fcondition-coverage.

       -d
       --display-progress
	   Display the progress on the standard output.

       -f
       --function-summaries
	   Output summaries for each function in addition to the file level
	   summary.

       -h
       --help
	   Display help about using gcov (on the standard output), and exit
	   without doing any further processing.

       -j
       --json-format
	   Output gcov file in an easy-to-parse JSON intermediate format which
	   does not require source code for generation.	 The JSON file is
	   compressed with gzip compression algorithm and the files have
	   .gcov.json.gz extension.

	   Structure of the JSON is following:

		   {
		     "current_working_directory": "foo/bar",
		     "data_file": "a.out",
		     "format_version": "2",
		     "gcc_version": "11.1.1 20210510"
		     "files": ["$file"]
		   }

	   Fields of the root element have following semantics:

	   *   current_working_directory: working directory where a
	       compilation unit was compiled

	   *   data_file: name of the data file (GCDA)

	   *   format_version: semantic version of the format

	       Changes in version 2:

	       *   calls: information about function calls is added

	   *   gcc_version: version of the GCC compiler

	   Each file has the following form:

		   {
		     "file": "a.c",
		     "functions": ["$function"],
		     "lines": ["$line"]
		   }

	   Fields of the file element have following semantics:

	   *   file_name: name of the source file

	   Each function has the following form:

		   {
		     "blocks": 2,
		     "blocks_executed": 2,
		     "demangled_name": "foo",
		     "end_column": 1,
		     "end_line": 4,
		     "execution_count": 1,
		     "name": "foo",
		     "start_column": 5,
		     "start_line": 1
		   }

	   Fields of the function element have following semantics:

	   *   blocks: number of blocks that are in the function

	   *   blocks_executed: number of executed blocks of the function

	   *   demangled_name: demangled name of the function

	   *   end_column: column in the source file where the function ends

	   *   end_line: line in the source file where the function ends

	   *   execution_count: number of executions of the function

	   *   name: name of the function

	   *   start_column: column in the source file where the function
	       begins

	   *   start_line: line in the source file where the function begins

	   Note that line numbers and column numbers number from 1.  In the
	   current implementation, start_line and start_column do not include
	   any template parameters and the leading return type but that this
	   is likely to be fixed in the future.

	   Each line has the following form:

		   {
		     "block_ids": ["$block_id"],
		     "branches": ["$branch"],
		     "calls": ["$call"],
		     "count": 2,
		     "conditions": ["$condition"],
		     "line_number": 15,
		     "unexecuted_block": false,
		     "function_name": "foo",
		   }

	   Branches and calls are present only with -b option.	Fields of the
	   line element have following semantics:

	   *   block_ids: IDs of basic blocks that belong to the line

	   *   count: number of executions of the line

	   *   line_number: line number

	   *   unexecuted_block: flag whether the line contains an unexecuted
	       block (not all statements on the line are executed)

	   *   function_name: a name of a function this line belongs to (for a
	       line with an inlined statements can be not set)

	   Each branch has the following form:

		   {
		     "count": 11,
		     "destination_block_id": 17,
		     "fallthrough": true,
		     "source_block_id": 13,
		     "throw": false
		   }

	   Fields of the branch element have following semantics:

	   *   count: number of executions of the branch

	   *   fallthrough: true when the branch is a fall through branch

	   *   throw: true when the branch is an exceptional branch

	   *   isource_block_id: ID of the basic block where this branch
	       happens

	   *   destination_block_id: ID of the basic block this branch jumps
	       to

	   Each call has the following form:

		   {
		     "destination_block_id": 1,
		     "returned": 11,
		     "source_block_id": 13
		   }

	   Fields of the call element have following semantics:

	   *   returned: number of times a function call returned (call count
	       is equal to line::count)

	   *   isource_block_id: ID of the basic block where this call happens

	   *   destination_block_id: ID of the basic block this calls
	       continues after return

	   Each condition has the following form:

		   {
		     "count": 4,
		     "covered": 2,
		     "not_covered_false": [],
		     "not_covered_true": [0, 1],
		   }

	   Fields of the condition element have following semantics:

	   *   count: number of condition outcomes in this expression

	   *   covered: number of covered condition outcomes in this
	       expression

	   *   not_covered_true: terms, by index, not seen as true in this
	       expression

	   *   not_covered_false: terms, by index, not seen as false in this
	       expression

       -H
       --human-readable
	   Write counts in human readable format (like 24.6k).

       -k
       --use-colors
	   Use colors for lines of code that have zero coverage.  We use red
	   color for non-exceptional lines and cyan for exceptional.  Same
	   colors are used for basic blocks with -a option.

       -l
       --long-file-names
	   Create long file names for included source files.  For example, if
	   the header file x.h contains code, and was included in the file
	   a.c, then running gcov on the file a.c will produce an output file
	   called a.c##x.h.gcov instead of x.h.gcov.  This can be useful if
	   x.h is included in multiple source files and you want to see the
	   individual contributions.  If you use the -p option, both the
	   including and included file names will be complete path names.

       -m
       --demangled-names
	   Display demangled function names in output. The default is to show
	   mangled function names.

       -n
       --no-output
	   Do not create the gcov output file.

       -o directory|file
       --object-directory directory
       --object-file file
	   Specify either the directory containing the gcov data files, or the
	   object path name.  The .gcno, and .gcda data files are searched for
	   using this option.  If a directory is specified, the data files are
	   in that directory and named after the input file name, without its
	   extension.  If a file is specified here, the data files are named
	   after that file, without its extension.

       -p
       --preserve-paths
	   Preserve complete path information in the names of generated .gcov
	   files.  Without this option, just the filename component is used.
	   With this option, all directories are used, with / characters
	   translated to # characters, . directory components removed and
	   unremoveable ..  components renamed to ^.  This is useful if
	   sourcefiles are in several different directories.

       -q
       --use-hotness-colors
	   Emit perf-like colored output for hot lines.	 Legend of the color
	   scale is printed at the very beginning of the output file.

       -r
       --relative-only
	   Only output information about source files with a relative pathname
	   (after source prefix elision).  Absolute paths are usually system
	   header files and coverage of any inline functions therein is
	   normally uninteresting.

       -s directory
       --source-prefix directory
	   A prefix for source file names to remove when generating the output
	   coverage files.  This option is useful when building in a separate
	   directory, and the pathname to the source directory is not wanted
	   when determining the output file names.  Note that this prefix
	   detection is applied before determining whether the source file is
	   absolute.

       -t
       --stdout
	   Output to standard output instead of output files.

       -u
       --unconditional-branches
	   When branch probabilities are given, include those of unconditional
	   branches.  Unconditional branches are normally not interesting.

       -v
       --version
	   Display the gcov version number (on the standard output), and exit
	   without doing any further processing.

       -w
       --verbose
	   Print verbose informations related to basic blocks and arcs.

       -x
       --hash-filenames
	   When using --preserve-paths, gcov uses the full pathname of the
	   source files to create an output filename.  This can lead to long
	   filenames that can overflow filesystem limits.  This option creates
	   names of the form source-file##md5.gcov, where the source-file
	   component is the final filename part and the md5 component is
	   calculated from the full mangled name that would have been used
	   otherwise.  The option is an alternative to the --preserve-paths on
	   systems which have a filesystem limit.

       gcov should be run with the current directory the same as that when you
       invoked the compiler.  Otherwise it will not be able to locate the
       source files.  gcov produces files called mangledname.gcov in the
       current directory.  These contain the coverage information of the
       source file they correspond to.	One .gcov file is produced for each
       source (or header) file containing code, which was compiled to produce
       the data files.	The mangledname part of the output file name is
       usually simply the source file name, but can be something more
       complicated if the -l or -p options are given.  Refer to those options
       for details.

       If you invoke gcov with multiple input files, the contributions from
       each input file are summed.  Typically you would invoke it with the
       same list of files as the final link of your executable.

       The .gcov files contain the : separated fields along with program
       source code.  The format is

	       <execution_count>:<line_number>:<source line text>

       Additional block information may succeed each line, when requested by
       command line option.  The execution_count is - for lines containing no
       code.  Unexecuted lines are marked ##### or =====, depending on whether
       they are reachable by non-exceptional paths or only exceptional paths
       such as C++ exception handlers, respectively. Given the -a option,
       unexecuted blocks are marked $$$$$ or %%%%%, depending on whether a
       basic block is reachable via non-exceptional or exceptional paths.
       Executed basic blocks having a statement with zero execution_count end
       with * character and are colored with magenta color with the -k option.
       This functionality is not supported in Ada.

       Note that GCC can completely remove the bodies of functions that are
       not needed -- for instance if they are inlined everywhere.  Such
       functions are marked with -, which can be confusing.  Use the
       -fkeep-inline-functions and -fkeep-static-functions options to retain
       these functions and allow gcov to properly show their execution_count.

       Some lines of information at the start have line_number of zero.	 These
       preamble lines are of the form

	       -:0:<tag>:<value>

       The ordering and number of these preamble lines will be augmented as
       gcov development progresses --- do not rely on them remaining
       unchanged.  Use tag to locate a particular preamble line.

       The additional block information is of the form

	       <tag> <information>

       The information is human readable, but designed to be simple enough for
       machine parsing too.

       When printing percentages, 0% and 100% are only printed when the values
       are exactly 0% and 100% respectively.  Other values which would
       conventionally be rounded to 0% or 100% are instead printed as the
       nearest non-boundary value.

       When using gcov, you must first compile your program with a special GCC
       option --coverage.  This tells the compiler to generate additional
       information needed by gcov (basically a flow graph of the program) and
       also includes additional code in the object files for generating the
       extra profiling information needed by gcov.  These additional files are
       placed in the directory where the object file is located.

       Running the program will cause profile output to be generated.  For
       each source file compiled with -fprofile-arcs, an accompanying .gcda
       file will be placed in the object file directory.

       Running gcov with your program's source file names as arguments will
       now produce a listing of the code along with frequency of execution for
       each line.  For example, if your program is called tmp.cpp, this is
       what you see when you use the basic gcov facility:

	       $ g++ --coverage tmp.cpp -c
	       $ g++ --coverage tmp.o
	       $ a.out
	       $ gcov tmp.cpp -m
	       File 'tmp.cpp'
	       Lines executed:92.86% of 14
	       Creating 'tmp.cpp.gcov'

       The file tmp.cpp.gcov contains output from gcov.	 Here is a sample:

		       -:    0:Source:tmp.cpp
		       -:    0:Working directory:/home/gcc/testcase
		       -:    0:Graph:tmp.gcno
		       -:    0:Data:tmp.gcda
		       -:    0:Runs:1
		       -:    0:Programs:1
		       -:    1:#include <stdio.h>
		       -:    2:
		       -:    3:template<class T>
		       -:    4:class Foo
		       -:    5:{
		       -:    6:	 public:
		      1*:    7:	 Foo(): b (1000) {}
	       ------------------
	       Foo<char>::Foo():
		   #####:    7:	 Foo(): b (1000) {}
	       ------------------
	       Foo<int>::Foo():
		       1:    7:	 Foo(): b (1000) {}
	       ------------------
		      2*:    8:	 void inc () { b++; }
	       ------------------
	       Foo<char>::inc():
		   #####:    8:	 void inc () { b++; }
	       ------------------
	       Foo<int>::inc():
		       2:    8:	 void inc () { b++; }
	       ------------------
		       -:    9:
		       -:   10:	 private:
		       -:   11:	 int b;
		       -:   12:};
		       -:   13:
		       -:   14:template class Foo<int>;
		       -:   15:template class Foo<char>;
		       -:   16:
		       -:   17:int
		       1:   18:main (void)
		       -:   19:{
		       -:   20:	 int i, total;
		       1:   21:	 Foo<int> counter;
		       -:   22:
		       1:   23:	 counter.inc();
		       1:   24:	 counter.inc();
		       1:   25:	 total = 0;
		       -:   26:
		      11:   27:	 for (i = 0; i < 10; i++)
		      10:   28:	   total += i;
		       -:   29:
		      1*:   30:	 int v = total > 100 ? 1 : 2;
		       -:   31:
		       1:   32:	 if (total != 45)
		   #####:   33:	   printf ("Failure\n");
		       -:   34:	 else
		       1:   35:	   printf ("Success\n");
		       1:   36:	 return 0;
		       -:   37:}

       Note that line 7 is shown in the report multiple times.	First
       occurrence presents total number of execution of the line and the next
       two belong to instances of class Foo constructors.  As you can also
       see, line 30 contains some unexecuted basic blocks and thus execution
       count has asterisk symbol.

       When you use the -a option, you will get individual block counts, and
       the output looks like this:

		       -:    0:Source:tmp.cpp
		       -:    0:Working directory:/home/gcc/testcase
		       -:    0:Graph:tmp.gcno
		       -:    0:Data:tmp.gcda
		       -:    0:Runs:1
		       -:    0:Programs:1
		       -:    1:#include <stdio.h>
		       -:    2:
		       -:    3:template<class T>
		       -:    4:class Foo
		       -:    5:{
		       -:    6:	 public:
		      1*:    7:	 Foo(): b (1000) {}
	       ------------------
	       Foo<char>::Foo():
		   #####:    7:	 Foo(): b (1000) {}
	       ------------------
	       Foo<int>::Foo():
		       1:    7:	 Foo(): b (1000) {}
	       ------------------
		      2*:    8:	 void inc () { b++; }
	       ------------------
	       Foo<char>::inc():
		   #####:    8:	 void inc () { b++; }
	       ------------------
	       Foo<int>::inc():
		       2:    8:	 void inc () { b++; }
	       ------------------
		       -:    9:
		       -:   10:	 private:
		       -:   11:	 int b;
		       -:   12:};
		       -:   13:
		       -:   14:template class Foo<int>;
		       -:   15:template class Foo<char>;
		       -:   16:
		       -:   17:int
		       1:   18:main (void)
		       -:   19:{
		       -:   20:	 int i, total;
		       1:   21:	 Foo<int> counter;
		       1:   21-block  0
		       -:   22:
		       1:   23:	 counter.inc();
		       1:   23-block  0
		       1:   24:	 counter.inc();
		       1:   24-block  0
		       1:   25:	 total = 0;
		       -:   26:
		      11:   27:	 for (i = 0; i < 10; i++)
		       1:   27-block  0
		      11:   27-block  1
		      10:   28:	   total += i;
		      10:   28-block  0
		       -:   29:
		      1*:   30:	 int v = total > 100 ? 1 : 2;
		       1:   30-block  0
		   %%%%%:   30-block  1
		       1:   30-block  2
		       -:   31:
		       1:   32:	 if (total != 45)
		       1:   32-block  0
		   #####:   33:	   printf ("Failure\n");
		   %%%%%:   33-block  0
		       -:   34:	 else
		       1:   35:	   printf ("Success\n");
		       1:   35-block  0
		       1:   36:	 return 0;
		       1:   36-block  0
		       -:   37:}

       In this mode, each basic block is only shown on one line -- the last
       line of the block.  A multi-line block will only contribute to the
       execution count of that last line, and other lines will not be shown to
       contain code, unless previous blocks end on those lines.	 The total
       execution count of a line is shown and subsequent lines show the
       execution counts for individual blocks that end on that line.  After
       each block, the branch and call counts of the block will be shown, if
       the -b option is given.

       Because of the way GCC instruments calls, a call count can be shown
       after a line with no individual blocks.	As you can see, line 33
       contains a basic block that was not executed.

       When you use the -b option, your output looks like this:

		       -:    0:Source:tmp.cpp
		       -:    0:Working directory:/home/gcc/testcase
		       -:    0:Graph:tmp.gcno
		       -:    0:Data:tmp.gcda
		       -:    0:Runs:1
		       -:    0:Programs:1
		       -:    1:#include <stdio.h>
		       -:    2:
		       -:    3:template<class T>
		       -:    4:class Foo
		       -:    5:{
		       -:    6:	 public:
		      1*:    7:	 Foo(): b (1000) {}
	       ------------------
	       Foo<char>::Foo():
	       function Foo<char>::Foo() called 0 returned 0% blocks executed 0%
		   #####:    7:	 Foo(): b (1000) {}
	       ------------------
	       Foo<int>::Foo():
	       function Foo<int>::Foo() called 1 returned 100% blocks executed 100%
		       1:    7:	 Foo(): b (1000) {}
	       ------------------
		      2*:    8:	 void inc () { b++; }
	       ------------------
	       Foo<char>::inc():
	       function Foo<char>::inc() called 0 returned 0% blocks executed 0%
		   #####:    8:	 void inc () { b++; }
	       ------------------
	       Foo<int>::inc():
	       function Foo<int>::inc() called 2 returned 100% blocks executed 100%
		       2:    8:	 void inc () { b++; }
	       ------------------
		       -:    9:
		       -:   10:	 private:
		       -:   11:	 int b;
		       -:   12:};
		       -:   13:
		       -:   14:template class Foo<int>;
		       -:   15:template class Foo<char>;
		       -:   16:
		       -:   17:int
	       function main called 1 returned 100% blocks executed 81%
		       1:   18:main (void)
		       -:   19:{
		       -:   20:	 int i, total;
		       1:   21:	 Foo<int> counter;
	       call    0 returned 100%
	       branch  1 taken 100% (fallthrough)
	       branch  2 taken 0% (throw)
		       -:   22:
		       1:   23:	 counter.inc();
	       call    0 returned 100%
	       branch  1 taken 100% (fallthrough)
	       branch  2 taken 0% (throw)
		       1:   24:	 counter.inc();
	       call    0 returned 100%
	       branch  1 taken 100% (fallthrough)
	       branch  2 taken 0% (throw)
		       1:   25:	 total = 0;
		       -:   26:
		      11:   27:	 for (i = 0; i < 10; i++)
	       branch  0 taken 91% (fallthrough)
	       branch  1 taken 9%
		      10:   28:	   total += i;
		       -:   29:
		      1*:   30:	 int v = total > 100 ? 1 : 2;
	       branch  0 taken 0% (fallthrough)
	       branch  1 taken 100%
		       -:   31:
		       1:   32:	 if (total != 45)
	       branch  0 taken 0% (fallthrough)
	       branch  1 taken 100%
		   #####:   33:	   printf ("Failure\n");
	       call    0 never executed
	       branch  1 never executed
	       branch  2 never executed
		       -:   34:	 else
		       1:   35:	   printf ("Success\n");
	       call    0 returned 100%
	       branch  1 taken 100% (fallthrough)
	       branch  2 taken 0% (throw)
		       1:   36:	 return 0;
		       -:   37:}

       For each function, a line is printed showing how many times the
       function is called, how many times it returns and what percentage of
       the function's blocks were executed.

       For each basic block, a line is printed after the last line of the
       basic block describing the branch or call that ends the basic block.
       There can be multiple branches and calls listed for a single source
       line if there are multiple basic blocks that end on that line.  In this
       case, the branches and calls are each given a number.  There is no
       simple way to map these branches and calls back to source constructs.
       In general, though, the lowest numbered branch or call will correspond
       to the leftmost construct on the source line.

       For a branch, if it was executed at least once, then a percentage
       indicating the number of times the branch was taken divided by the
       number of times the branch was executed will be printed.	 Otherwise,
       the message "never executed" is printed.

       For a call, if it was executed at least once, then a percentage
       indicating the number of times the call returned divided by the number
       of times the call was executed will be printed.	This will usually be
       100%, but may be less for functions that call "exit" or "longjmp", and
       thus may not return every time they are called.

       The execution counts are cumulative.  If the example program were
       executed again without removing the .gcda file, the count for the
       number of times each line in the source was executed would be added to
       the results of the previous run(s).  This is potentially useful in
       several ways.  For example, it could be used to accumulate data over a
       number of program runs as part of a test verification suite, or to
       provide more accurate long-term information over a large number of
       program runs.

       The data in the .gcda files is saved immediately before the program
       exits.  For each source file compiled with -fprofile-arcs, the
       profiling code first attempts to read in an existing .gcda file; if the
       file doesn't match the executable (differing number of basic block
       counts) it will ignore the contents of the file.	 It then adds in the
       new execution counts and finally writes the data to the file.

   Using gcov with GCC Optimization
       If you plan to use gcov to help optimize your code, you must first
       compile your program with a special GCC option --coverage.  Aside from
       that, you can use any other GCC options; but if you want to prove that
       every single line in your program was executed, you should not compile
       with optimization at the same time.  On some machines the optimizer can
       eliminate some simple code lines by combining them with other lines.
       For example, code like this:

	       if (a != b)
		 c = 1;
	       else
		 c = 0;

       can be compiled into one instruction on some machines.  In this case,
       there is no way for gcov to calculate separate execution counts for
       each line because there isn't separate code for each line.  Hence the
       gcov output looks like this if you compiled the program with
       optimization:

		     100:   12:if (a != b)
		     100:   13:	 c = 1;
		     100:   14:else
		     100:   15:	 c = 0;

       The output shows that this block of code, combined by optimization,
       executed 100 times.  In one sense this result is correct, because there
       was only one instruction representing all four of these lines.
       However, the output does not indicate how many times the result was 0
       and how many times the result was 1.

       Inlineable functions can create unexpected line counts.	Line counts
       are shown for the source code of the inlineable function, but what is
       shown depends on where the function is inlined, or if it is not inlined
       at all.

       If the function is not inlined, the compiler must emit an out of line
       copy of the function, in any object file that needs it.	If fileA.o and
       fileB.o both contain out of line bodies of a particular inlineable
       function, they will also both contain coverage counts for that
       function.  When fileA.o and fileB.o are linked together, the linker
       will, on many systems, select one of those out of line bodies for all
       calls to that function, and remove or ignore the other.	Unfortunately,
       it will not remove the coverage counters for the unused function body.
       Hence when instrumented, all but one use of that function will show
       zero counts.

       If the function is inlined in several places, the block structure in
       each location might not be the same.  For instance, a condition might
       now be calculable at compile time in some instances.  Because the
       coverage of all the uses of the inline function will be shown for the
       same source lines, the line counts themselves might seem inconsistent.

       Long-running applications can use the "__gcov_reset" and "__gcov_dump"
       facilities to restrict profile collection to the program region of
       interest. Calling "__gcov_reset(void)" will clear all run-time profile
       counters to zero, and calling "__gcov_dump(void)" will cause the
       profile information collected at that point to be dumped to .gcda
       output files.  Instrumented applications use a static destructor with
       priority 99 to invoke the "__gcov_dump" function. Thus "__gcov_dump" is
       executed after all user defined static destructors, as well as handlers
       registered with "atexit".

       If an executable loads a dynamic shared object via dlopen
       functionality, -Wl,--dynamic-list-data is needed to dump all profile
       data.

       Profiling run-time library reports various errors related to profile
       manipulation and profile saving.	 Errors are printed into standard
       error output or GCOV_ERROR_FILE file, if environment variable is used.
       In order to terminate immediately after an errors occurs set
       GCOV_EXIT_AT_ERROR environment variable.	 That can help users to find
       profile clashing which leads to a misleading profile.

SEE ALSO
       gpl(7), gfdl(7), fsf-funding(7), gcc(1) and the Info entry for gcc.

COPYRIGHT
       Copyright (c) 1996-2024 Free Software Foundation, Inc.

       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.3 or
       any later version published by the Free Software Foundation; with the
       Invariant Sections being "GNU General Public License" and "Funding Free
       Software", the Front-Cover texts being (a) (see below), and with the
       Back-Cover Texts being (b) (see below).	A copy of the license is
       included in the gfdl(7) man page.

       (a) The FSF's Front-Cover Text is:

	    A GNU Manual

       (b) The FSF's Back-Cover Text is:

	    You have freedom to copy and modify this GNU Manual, like GNU
	    software.  Copies published by the Free Software Foundation raise
	    funds for GNU development.



gcc-14.2.0			  2024-08-01			       GCOV(1)

M2(1)				      GNU				 M2(1)



NAME
       gm2 - The GNU Modula-2 Compiler

SYNOPSIS
DESCRIPTION
OPTIONS
       For any given input file, the file name suffix determines what kind of
       compilation is done.  The following kinds of input file names are
       supported:

       file.mod
	   Modula-2 implementation or program source files.  See the -fmod=
	   option if you wish to compile a project which uses a different
	   source file extension.

       file.def
	   Modula-2 definition module source files.  Definition modules are
	   not compiled separately, in GNU Modula-2 definition modules are
	   parsed as required when program or implementation modules are
	   compiled.  See the -fdef= option if you wish to compile a project
	   which uses a different source file extension.

       You can specify more than one input file on the gm2 command line,

       "-g"
	   create debugging information so that debuggers such as gdb can
	   inspect and control executable.

       "-I"
	   used to specify the search path for definition and implementation
	   modules.  An example is:  "gm2 -g -c -I.:../../libs foo.mod".  If
	   this option is not specified then the default path is added which
	   consists of the current directory followed by the appropriate
	   language dialect library directories.

       "-fauto-init"
	   turns on auto initialization of pointers to NIL.  Whenever a block
	   is created all pointers declared within this scope will have their
	   addresses assigned to NIL.

       "-fbounds"
	   turns on run time subrange, array index and indirection via "NIL"
	   pointer checking.

       "-fcase"
	   turns on compile time checking to check whether a "CASE" statement
	   requires an "ELSE" clause when on was not specified.

       "-fcpp"
	   preprocess the source with cpp -lang-asm -traditional-cpp For
	   further details about these options If -fcpp is supplied then all
	   definition modules and implementation modules which are parsed will
	   be prepossessed by cpp.

       "-fdebug-builtins"
	   call a real function, rather than the builtin equivalent.  This can
	   be useful for debugging parameter values to a builtin function as
	   it allows users to single step code into an intrinsic function.

       "-fdef="
	   recognize the specified suffix as a definition module filename.
	   The default implementation and module filename suffix is .def.  If
	   this option is used GNU Modula-2 will still fall back to this
	   default if a requested definition module is not found.

       "-fdump-system-exports"
	   display all inbuilt system items.  This is an internal command line
	   option.

       "-fexceptions"
	   turn on exception handling code.  By default this option is on.
	   Exception handling can be disabled by -fno-exceptions and no
	   references are made to the run time exception libraries.

       "-fextended-opaque"
	   allows opaque types to be implemented as any type.  This is a GNU
	   Modula-2 extension and it requires that the implementation module
	   defining the opaque type is available so that it can be resolved
	   when compiling the module which imports the opaque type.

       "-ffloatvalue"
	   turns on run time checking to check whether a floating point number
	   is about to exceed range.

       "-fgen-module-list=filename"
	   attempt to find all modules when linking and generate a module
	   list.  If the filename is - then the contents are not written and
	   only used to force the linking of all module ctors.	This option
	   cannot be used if -fuse-list= is enabled.

       "-findex"
	   generate code to check whether array index values are out of
	   bounds.  Array index checking can be disabled via -fno-index.

       "-fiso"
	   turn on ISO standard features.  Currently this enables the ISO
	   "SYSTEM" module and alters the default library search path so that
	   the ISO libraries are searched before the PIM libraries.  It also
	   effects the behavior of "DIV" and "MOD" operators.

       "-flibs="
	   modifies the default library search path.  The libraries supplied
	   are: m2pim, m2iso, m2min, m2log and m2cor.  These map onto the
	   Programming in Modula-2 base libraries, ISO standard libraries,
	   minimal library support, Logitech compatible library and
	   Programming in Modula-2 with coroutines.  Multiple libraries can be
	   specified and are comma separated with precedence going to the
	   first in the list.  It is not necessary to use -flibs=m2pim or
	   -flibs=m2iso if you also specify -fpim, -fpim2, -fpim3, -fpim4 or
	   -fiso.  Unless you are using -flibs=m2min you should include m2pim
	   as the they provide the base modules which all other dialects
	   utilize.  The option -fno-libs=- disables the gm2 driver from
	   modifying the search and library paths.

       "-static-libgm2"
	   On systems that provide the m2 runtimes as both shared and static
	   libraries, this option forces the use of the static version.

       "-fm2-g"
	   improve the debugging experience for new programmers at the expense
	   of generating "nop" instructions if necessary to ensure single
	   stepping precision over all code related keywords.  An example of
	   this is in termination of a list of nested "IF" statements where
	   multiple "END" keywords are mapped onto a sequence of "nop"
	   instructions.

       "-fm2-lower-case"
	   render keywords in error messages using lower case.

       "-fm2-pathname="
	   specify the module mangled prefix name for all modules in the
	   following include paths.

       "-fm2-pathnameI"
	   for internal use only: used by the driver to copy the user facing
	   -I option.

       "-fm2-plugin"
	   insert plugin to identify run time errors at compile time (default
	   on).

       "-fm2-prefix="
	   specify the module mangled prefix name.  All exported symbols from
	   a definition module will have the prefix name.

       "-fm2-statistics"
	   generates quadruple information: number of quadruples generated,
	   number of quadruples remaining after optimization and number of
	   source lines compiled.

       "-fm2-strict-type"
	   experimental flag to turn on the new strict type checker.

       "-fm2-whole-program"
	   compile all implementation modules and program module at once.
	   Notice that you need to take care if you are compiling different
	   dialect modules (particularly with the negative operands to
	   modulus).  But this option, when coupled together with "-O3", can
	   deliver huge performance improvements.

       "-fmod="
	   recognize the specified suffix as implementation and module
	   filenames.  The default implementation and module filename suffix
	   is .mod.  If this option is used GNU Modula-2 will still fall back
	   to this default if it needs to read an implementation module and
	   the specified suffixed filename does not exist.

       "-fnil"
	   generate code to detect accessing data through a "NIL" value
	   pointer.  Dereferencing checking through a "NIL" pointer can be
	   disabled by -fno-nil.

       "-fpim"
	   turn on PIM standard features.  Currently this enables the PIM
	   "SYSTEM" module and determines which identifiers are pervasive
	   (declared in the base module).  If no other -fpim[234] switch is
	   used then division and modulus operators behave as defined in PIM4.

       "-fpim2"
	   turn on PIM-2 standard features.  Currently this removes "SIZE"
	   from being a pervasive identifier (declared in the base module).
	   It places "SIZE" in the "SYSTEM" module.  It also effects the
	   behavior of "DIV" and "MOD" operators.

       "-fpim3"
	   turn on PIM-3 standard features.  Currently this only effects the
	   behavior of "DIV" and "MOD" operators.

       "-fpim4"
	   turn on PIM-4 standard features.  Currently this only effects the
	   behavior of "DIV" and "MOD" operators.

       "-fpositive-mod-floor-div"
	   forces the "DIV" and "MOD" operators to behave as defined by PIM4.
	   All modulus results are positive and the results from the division
	   are rounded to the floor.

       "-fpthread"
	   link against the pthread library.  By default this option is on.
	   It can be disabled by -fno-pthread.	GNU Modula-2 uses the GCC
	   pthread libraries to implement coroutines (see the SYSTEM
	   implementation module).

       "-frange"
	   generate code to check the assignment range, return value range set
	   range and constructor range.	 Range checking can be disabled via
	   -fno-range.

       "-freturn"
	   generate code to check that functions always exit with a "RETURN"
	   and do not fall out at the end.  Return checking can be disabled
	   via -fno-return.

       "-fruntime-modules="
	   specify, using a comma separated list, the run time modules and
	   their order.	 These modules will initialized first before any other
	   modules in the application dependency.  By default the run time
	   modules list is set to "m2iso:RTentity,m2iso:Storage,m2iso:SYSTEM,"
	   "m2iso:M2RTS,m2iso:RTExceptions,m2iso:IOLink".  Note that these
	   modules will only be linked into your executable if they are
	   required.  Adding a long list of dependent modules will not effect
	   the size of the executable it merely states the initialization
	   order should they be required.

       "-fscaffold-dynamic"
	   the option ensures that gm2 will generate a dynamic scaffold
	   infrastructure when compiling implementation and program modules.
	   By default this option is on.  Use -fno-scaffold-dynamic to turn it
	   off or select -fno-scaffold-static.

       "-fscaffold-c"
	   generate a C source scaffold for the current module being compiled.

       "-fscaffold-c++"
	   generate a C++ source scaffold for the current module being
	   compiled.

       "-fscaffold-main"
	   force the generation of the main function.  This is not necessary
	   if the -c is omitted.

       "-fscaffold-static"
	   the option ensures that gm2 will generate a static scaffold within
	   the program module.	The static scaffold consists of sequences of
	   calls to all dependent module initialization and finalization
	   procedures.	The static scaffold is useful for debugging and single
	   stepping the initialization blocks of implementation modules.

       "-fshared"
	   generate a shared library from the module.

       "-fsoft-check-all"
	   turns on all run time checks.  This is the same as invoking GNU
	   Modula-2 using the command options "-fnil" "-frange" "-findex"
	   "-fwholevalue" "-fwholediv" "-fcase" "-freturn".

       "-fsources"
	   displays the path to the source of each module.  This option can be
	   used at compile time to check the correct definition module is
	   being used.

       "-fswig"
	   generate a swig interface file.

       "-funbounded-by-reference"
	   enable optimization of unbounded parameters by attempting to pass
	   non "VAR" unbounded parameters by reference.	 This optimization
	   avoids the implicit copy inside the callee procedure.  GNU Modula-2
	   will only allow unbounded parameters to be passed by reference if,
	   inside the callee procedure, they are not written to, no address is
	   calculated on the array and it is not passed as a "VAR" parameter.
	   Note that it is possible to write code to break this optimization,
	   therefore this option should be used carefully.  For example it
	   would be possible to take the address of an array, pass the address
	   and the array to a procedure, read from the array in the procedure
	   and write to the location using the address parameter.

	   Due to the dangerous nature of this option it is not enabled when
	   the -O option is specified.

       "-fuse-list=filename"
	   if -fscaffold-static is enabled then use the file filename for the
	   initialization order of modules.  Whereas if -fscaffold-dynamic is
	   enabled then use this file to force linking of all module ctors.
	   This option cannot be used if -fgen-module-list= is enabled.

       "-fwholediv"
	   generate code to detect whole number division by zero or modulus by
	   zero.

       "-fwholevalue"
	   generate code to detect whole number overflow and underflow.

       "-Wcase-enum"
	   generate a warning if a "CASE" statement selects on an enumerated
	   type expression and the statement is missing one or more "CASE"
	   labels.  No warning is issued if the "CASE" statement has a default
	   "ELSE" clause.  The option -Wall will turn on this flag.

       "-Wuninit-variable-checking"
	   issue a warning if a variable is used before it is initialized.
	   The checking only occurs in the first basic block in each
	   procedure.  It does not check parameters, array types or set types.

       "-Wuninit-variable-checking=all,known,cond"
	   issue a warning if a variable is used before it is initialized.
	   The checking will only occur in the first basic block in each
	   procedure if known is specified.  If cond or all is specified then
	   checking continues into conditional branches of the flow graph.
	   All checking will stop when a procedure call is invoked or the top
	   of a loop is encountered.  The option -Wall will turn on this flag
	   with -Wuninit-variable-checking=known.  The
	   -Wuninit-variable-checking=all will increase compile time.

SEE ALSO
       gpl(7), gfdl(7), fsf-funding(7), gcc(1) and the Info entries for gm2
       and gcc.

COPYRIGHT
       Copyright (c) 1999-2024 Free Software Foundation, Inc.

       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.3 or
       any later version published by the Free Software Foundation; with no
       Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts.  A
       copy of the license is included in the man page gfdl(7).



gcc-14.2.0			  2024-08-01				 M2(1)

LTO-DUMP(1)			      GNU			   LTO-DUMP(1)



NAME
       lto-dump - Tool for dumping LTO object files

SYNOPSIS
       lto-dump [-list]
	    [-demangle]
	    [-defined-only]
	    [-print-value]
	    [-name-sort]
	    [-size-sort]
	    [-reverse-sort]
	    [-no-sort]
	    [-symbol=]
	    [-objects]
	    [-type-stats]
	    [-tree-stats]
	    [-gimple-stats]
	    [-dump-level=]
	    [-dump-body=]
	    [-help] lto-dump

DESCRIPTION
       lto-dump is a tool you can use in conjunction with GCC to dump link
       time optimization object files.

OPTIONS
       -list
	   Dumps list of details of functions and variables.

       -demangle
	   Dump the demangled output.

       -defined-only
	   Dump only the defined symbols.

       -print-value
	   Dump initial values of the variables.

       -name-sort
	   Sort the symbols alphabetically.

       -size-sort
	   Sort the symbols according to size.

       -reverse-sort
	   Dump the symbols in reverse order.

       -no-sort
	   Dump the symbols in order of occurrence.

       -symbol=
	   Dump the details of specific symbol.

       -objects
	   Dump the details of LTO objects.

       -type-stats
	   Dump the statistics of tree types.

       -tree-stats
	   Dump the statistics of trees.

       -gimple-stats
	   Dump the statistics of gimple statements.

       -dump-level=
	   For deciding the optimization level of body.

       -dump-body=
	   Dump the specific gimple body.

       -help
	   Display the dump tool help.

COPYRIGHT
       Copyright (c) 2017-2024 Free Software Foundation, Inc.

       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.3 or
       any later version published by the Free Software Foundation; with the
       Invariant Sections being "GNU General Public License" and "Funding Free
       Software", the Front-Cover texts being (a) (see below), and with the
       Back-Cover Texts being (b) (see below).	A copy of the license is
       included in the gfdl(7) man page.

       (a) The FSF's Front-Cover Text is:

	    A GNU Manual

       (b) The FSF's Back-Cover Text is:

	    You have freedom to copy and modify this GNU Manual, like GNU
	    software.  Copies published by the Free Software Foundation raise
	    funds for GNU development.



gcc-14.2.0			  2024-08-01			   LTO-DUMP(1)

GCOV-DUMP(1)			      GNU			  GCOV-DUMP(1)



NAME
       gcov-dump - offline gcda and gcno profile dump tool

SYNOPSIS
       gcov-dump [-v|--version]
	    [-h|--help]
	    [-l|--long]
	    [-p|--positions]
	    [-r|--raw]
	    [-s|--stable]
	    gcovfiles

DESCRIPTION
       gcov-dump is a tool you can use in conjunction with GCC to dump content
       of gcda and gcno profile files offline.

OPTIONS
       -h
       --help
	   Display help about using gcov-dump (on the standard output), and
	   exit without doing any further processing.

       -l
       --long
	   Dump content of records.

       -p
       --positions
	   Dump positions of records.

       -r
       --raw
	   Print content records in raw format.

       -s
       --stable
	   Print content in stable format usable for comparison.

       -v
       --version
	   Display the gcov-dump version number (on the standard output), and
	   exit without doing any further processing.

COPYRIGHT
       Copyright (c) 2017-2024 Free Software Foundation, Inc.

       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.3 or
       any later version published by the Free Software Foundation; with the
       Invariant Sections being "GNU General Public License" and "Funding Free
       Software", the Front-Cover texts being (a) (see below), and with the
       Back-Cover Texts being (b) (see below).	A copy of the license is
       included in the gfdl(7) man page.

       (a) The FSF's Front-Cover Text is:

	    A GNU Manual

       (b) The FSF's Back-Cover Text is:

	    You have freedom to copy and modify this GNU Manual, like GNU
	    software.  Copies published by the Free Software Foundation raise
	    funds for GNU development.



gcc-14.2.0			  2024-08-01			  GCOV-DUMP(1)

CPP(1)				      GNU				CPP(1)



NAME
       cpp - The C Preprocessor

SYNOPSIS
       cpp [-Dmacro[=defn]...] [-Umacro]
	   [-Idir...] [-iquotedir...]
	   [-M|-MM] [-MG] [-MF filename]
	   [-MP] [-MQ target...]
	   [-MT target...]
	   infile [[-o] outfile]

       Only the most useful options are given above; see below for a more
       complete list of preprocessor-specific options.	In addition, cpp
       accepts most gcc driver options, which are not listed here.  Refer to
       the GCC documentation for details.

DESCRIPTION
       The C preprocessor, often known as cpp, is a macro processor that is
       used automatically by the C compiler to transform your program before
       compilation.  It is called a macro processor because it allows you to
       define macros, which are brief abbreviations for longer constructs.

       The C preprocessor is intended to be used only with C, C++, and
       Objective-C source code.	 In the past, it has been abused as a general
       text processor.	It will choke on input which does not obey C's lexical
       rules.  For example, apostrophes will be interpreted as the beginning
       of character constants, and cause errors.  Also, you cannot rely on it
       preserving characteristics of the input which are not significant to
       C-family languages.  If a Makefile is preprocessed, all the hard tabs
       will be removed, and the Makefile will not work.

       Having said that, you can often get away with using cpp on things which
       are not C.  Other Algol-ish programming languages are often safe (Ada,
       etc.) So is assembly, with caution.  -traditional-cpp mode preserves
       more white space, and is otherwise more permissive.  Many of the
       problems can be avoided by writing C or C++ style comments instead of
       native language comments, and keeping macros simple.

       Wherever possible, you should use a preprocessor geared to the language
       you are writing in.  Modern versions of the GNU assembler have macro
       facilities.  Most high level programming languages have their own
       conditional compilation and inclusion mechanism.	 If all else fails,
       try a true general text processor, such as GNU M4.

       C preprocessors vary in some details.  This manual discusses the GNU C
       preprocessor, which provides a small superset of the features of ISO
       Standard C.  In its default mode, the GNU C preprocessor does not do a
       few things required by the standard.  These are features which are
       rarely, if ever, used, and may cause surprising changes to the meaning
       of a program which does not expect them.	 To get strict ISO Standard C,
       you should use the -std=c90, -std=c99, -std=c11 or -std=c17 options,
       depending on which version of the standard you want.  To get all the
       mandatory diagnostics, you must also use -pedantic.

       This manual describes the behavior of the ISO preprocessor.  To
       minimize gratuitous differences, where the ISO preprocessor's behavior
       does not conflict with traditional semantics, the traditional
       preprocessor should behave the same way.	 The various differences that
       do exist are detailed in the section Traditional Mode.

       For clarity, unless noted otherwise, references to CPP in this manual
       refer to GNU CPP.

OPTIONS
       The cpp command expects two file names as arguments, infile and
       outfile.	 The preprocessor reads infile together with any other files
       it specifies with #include.  All the output generated by the combined
       input files is written in outfile.

       Either infile or outfile may be -, which as infile means to read from
       standard input and as outfile means to write to standard output.	 If
       either file is omitted, it means the same as if - had been specified
       for that file.  You can also use the -o outfile option to specify the
       output file.

       Unless otherwise noted, or the option ends in =, all options which take
       an argument may have that argument appear either immediately after the
       option, or with a space between option and argument: -Ifoo and -I foo
       have the same effect.

       Many options have multi-letter names; therefore multiple single-letter
       options may not be grouped: -dM is very different from -d -M.

       -D name
	   Predefine name as a macro, with definition 1.

       -D name=definition
	   The contents of definition are tokenized and processed as if they
	   appeared during translation phase three in a #define directive.  In
	   particular, the definition is truncated by embedded newline
	   characters.

	   If you are invoking the preprocessor from a shell or shell-like
	   program you may need to use the shell's quoting syntax to protect
	   characters such as spaces that have a meaning in the shell syntax.

	   If you wish to define a function-like macro on the command line,
	   write its argument list with surrounding parentheses before the
	   equals sign (if any).  Parentheses are meaningful to most shells,
	   so you should quote the option.  With sh and csh,
	   -D'name(args...)=definition' works.

	   -D and -U options are processed in the order they are given on the
	   command line.  All -imacros file and -include file options are
	   processed after all -D and -U options.

       -U name
	   Cancel any previous definition of name, either built in or provided
	   with a -D option.

       -include file
	   Process file as if "#include "file"" appeared as the first line of
	   the primary source file.  However, the first directory searched for
	   file is the preprocessor's working directory instead of the
	   directory containing the main source file.  If not found there, it
	   is searched for in the remainder of the "#include "..."" search
	   chain as normal.

	   If multiple -include options are given, the files are included in
	   the order they appear on the command line.

       -imacros file
	   Exactly like -include, except that any output produced by scanning
	   file is thrown away.	 Macros it defines remain defined.  This
	   allows you to acquire all the macros from a header without also
	   processing its declarations.

	   All files specified by -imacros are processed before all files
	   specified by -include.

       -undef
	   Do not predefine any system-specific or GCC-specific macros.	 The
	   standard predefined macros remain defined.

       -pthread
	   Define additional macros required for using the POSIX threads
	   library.  You should use this option consistently for both
	   compilation and linking.  This option is supported on GNU/Linux
	   targets, most other Unix derivatives, and also on x86 Cygwin and
	   MinGW targets.

       -M  Instead of outputting the result of preprocessing, output a rule
	   suitable for make describing the dependencies of the main source
	   file.  The preprocessor outputs one make rule containing the object
	   file name for that source file, a colon, and the names of all the
	   included files, including those coming from -include or -imacros
	   command-line options.

	   Unless specified explicitly (with -MT or -MQ), the object file name
	   consists of the name of the source file with any suffix replaced
	   with object file suffix and with any leading directory parts
	   removed.  If there are many included files then the rule is split
	   into several lines using \-newline.	The rule has no commands.

	   This option does not suppress the preprocessor's debug output, such
	   as -dM.  To avoid mixing such debug output with the dependency
	   rules you should explicitly specify the dependency output file with
	   -MF, or use an environment variable like DEPENDENCIES_OUTPUT.
	   Debug output is still sent to the regular output stream as normal.

	   Passing -M to the driver implies -E, and suppresses warnings with
	   an implicit -w.

       -MM Like -M but do not mention header files that are found in system
	   header directories, nor header files that are included, directly or
	   indirectly, from such a header.

	   This implies that the choice of angle brackets or double quotes in
	   an #include directive does not in itself determine whether that
	   header appears in -MM dependency output.

       -MF file
	   When used with -M or -MM, specifies a file to write the
	   dependencies to.  If no -MF switch is given the preprocessor sends
	   the rules to the same place it would send preprocessed output.

	   When used with the driver options -MD or -MMD, -MF overrides the
	   default dependency output file.

	   If file is -, then the dependencies are written to stdout.

       -MG In conjunction with an option such as -M requesting dependency
	   generation, -MG assumes missing header files are generated files
	   and adds them to the dependency list without raising an error.  The
	   dependency filename is taken directly from the "#include" directive
	   without prepending any path.	 -MG also suppresses preprocessed
	   output, as a missing header file renders this useless.

	   This feature is used in automatic updating of makefiles.

       -Mno-modules
	   Disable dependency generation for compiled module interfaces.

       -MP This option instructs CPP to add a phony target for each dependency
	   other than the main file, causing each to depend on nothing.	 These
	   dummy rules work around errors make gives if you remove header
	   files without updating the Makefile to match.

	   This is typical output:

		   test.o: test.c test.h

		   test.h:

       -MT target
	   Change the target of the rule emitted by dependency generation.  By
	   default CPP takes the name of the main input file, deletes any
	   directory components and any file suffix such as .c, and appends
	   the platform's usual object suffix.	The result is the target.

	   An -MT option sets the target to be exactly the string you specify.
	   If you want multiple targets, you can specify them as a single
	   argument to -MT, or use multiple -MT options.

	   For example, -MT '$(objpfx)foo.o' might give

		   $(objpfx)foo.o: foo.c

       -MQ target
	   Same as -MT, but it quotes any characters which are special to
	   Make.  -MQ '$(objpfx)foo.o' gives

		   $$(objpfx)foo.o: foo.c

	   The default target is automatically quoted, as if it were given
	   with -MQ.

       -MD -MD is equivalent to -M -MF file, except that -E is not implied.
	   The driver determines file based on whether an -o option is given.
	   If it is, the driver uses its argument but with a suffix of .d,
	   otherwise it takes the name of the input file, removes any
	   directory components and suffix, and applies a .d suffix.

	   If -MD is used in conjunction with -E, any -o switch is understood
	   to specify the dependency output file, but if used without -E, each
	   -o is understood to specify a target object file.

	   Since -E is not implied, -MD can be used to generate a dependency
	   output file as a side effect of the compilation process.

       -MMD
	   Like -MD except mention only user header files, not system header
	   files.

       -fpreprocessed
	   Indicate to the preprocessor that the input file has already been
	   preprocessed.  This suppresses things like macro expansion,
	   trigraph conversion, escaped newline splicing, and processing of
	   most directives.  The preprocessor still recognizes and removes
	   comments, so that you can pass a file preprocessed with -C to the
	   compiler without problems.  In this mode the integrated
	   preprocessor is little more than a tokenizer for the front ends.

	   -fpreprocessed is implicit if the input file has one of the
	   extensions .i, .ii or .mi.  These are the extensions that GCC uses
	   for preprocessed files created by -save-temps.

       -fdirectives-only
	   When preprocessing, handle directives, but do not expand macros.

	   The option's behavior depends on the -E and -fpreprocessed options.

	   With -E, preprocessing is limited to the handling of directives
	   such as "#define", "#ifdef", and "#error".  Other preprocessor
	   operations, such as macro expansion and trigraph conversion are not
	   performed.  In addition, the -dD option is implicitly enabled.

	   With -fpreprocessed, predefinition of command line and most builtin
	   macros is disabled.	Macros such as "__LINE__", which are
	   contextually dependent, are handled normally.  This enables
	   compilation of files previously preprocessed with "-E
	   -fdirectives-only".

	   With both -E and -fpreprocessed, the rules for -fpreprocessed take
	   precedence.	This enables full preprocessing of files previously
	   preprocessed with "-E -fdirectives-only".

       -fdollars-in-identifiers
	   Accept $ in identifiers.

       -fextended-identifiers
	   Accept universal character names and extended characters in
	   identifiers.	 This option is enabled by default for C99 (and later
	   C standard versions) and C++.

       -fno-canonical-system-headers
	   When preprocessing, do not shorten system header paths with
	   canonicalization.

       -fmax-include-depth=depth
	   Set the maximum depth of the nested #include. The default is 200.

       -ftabstop=width
	   Set the distance between tab stops.	This helps the preprocessor
	   report correct column numbers in warnings or errors, even if tabs
	   appear on the line.	If the value is less than 1 or greater than
	   100, the option is ignored.	The default is 8.

       -ftrack-macro-expansion[=level]
	   Track locations of tokens across macro expansions. This allows the
	   compiler to emit diagnostic about the current macro expansion stack
	   when a compilation error occurs in a macro expansion. Using this
	   option makes the preprocessor and the compiler consume more memory.
	   The level parameter can be used to choose the level of precision of
	   token location tracking thus decreasing the memory consumption if
	   necessary. Value 0 of level de-activates this option. Value 1
	   tracks tokens locations in a degraded mode for the sake of minimal
	   memory overhead. In this mode all tokens resulting from the
	   expansion of an argument of a function-like macro have the same
	   location. Value 2 tracks tokens locations completely. This value is
	   the most memory hungry.  When this option is given no argument, the
	   default parameter value is 2.

	   Note that "-ftrack-macro-expansion=2" is activated by default.

       -fmacro-prefix-map=old=new
	   When preprocessing files residing in directory old, expand the
	   "__FILE__" and "__BASE_FILE__" macros as if the files resided in
	   directory new instead.  This can be used to change an absolute path
	   to a relative path by using . for new which can result in more
	   reproducible builds that are location independent.  This option
	   also affects "__builtin_FILE()" during compilation.	See also
	   -ffile-prefix-map and -fcanon-prefix-map.

       -fexec-charset=charset
	   Set the execution character set, used for string and character
	   constants.  The default is UTF-8.  charset can be any encoding
	   supported by the system's "iconv" library routine.

       -fwide-exec-charset=charset
	   Set the wide execution character set, used for wide string and
	   character constants.	 The default is one of UTF-32BE, UTF-32LE,
	   UTF-16BE, or UTF-16LE, whichever corresponds to the width of
	   "wchar_t" and the big-endian or little-endian byte order being used
	   for code generation.	 As with -fexec-charset, charset can be any
	   encoding supported by the system's "iconv" library routine;
	   however, you will have problems with encodings that do not fit
	   exactly in "wchar_t".

       -finput-charset=charset
	   Set the input character set, used for translation from the
	   character set of the input file to the source character set used by
	   GCC.	 If the locale does not specify, or GCC cannot get this
	   information from the locale, the default is UTF-8.  This can be
	   overridden by either the locale or this command-line option.
	   Currently the command-line option takes precedence if there's a
	   conflict.  charset can be any encoding supported by the system's
	   "iconv" library routine.

       -fworking-directory
	   Enable generation of linemarkers in the preprocessor output that
	   let the compiler know the current working directory at the time of
	   preprocessing.  When this option is enabled, the preprocessor
	   emits, after the initial linemarker, a second linemarker with the
	   current working directory followed by two slashes.  GCC uses this
	   directory, when it's present in the preprocessed input, as the
	   directory emitted as the current working directory in some
	   debugging information formats.  This option is implicitly enabled
	   if debugging information is enabled, but this can be inhibited with
	   the negated form -fno-working-directory.  If the -P flag is present
	   in the command line, this option has no effect, since no "#line"
	   directives are emitted whatsoever.

       -A predicate=answer
	   Make an assertion with the predicate predicate and answer answer.
	   This form is preferred to the older form -A predicate(answer),
	   which is still supported, because it does not use shell special
	   characters.

       -A -predicate=answer
	   Cancel an assertion with the predicate predicate and answer answer.

       -C  Do not discard comments.  All comments are passed through to the
	   output file, except for comments in processed directives, which are
	   deleted along with the directive.

	   You should be prepared for side effects when using -C; it causes
	   the preprocessor to treat comments as tokens in their own right.
	   For example, comments appearing at the start of what would be a
	   directive line have the effect of turning that line into an
	   ordinary source line, since the first token on the line is no
	   longer a #.

       -CC Do not discard comments, including during macro expansion.  This is
	   like -C, except that comments contained within macros are also
	   passed through to the output file where the macro is expanded.

	   In addition to the side effects of the -C option, the -CC option
	   causes all C++-style comments inside a macro to be converted to
	   C-style comments.  This is to prevent later use of that macro from
	   inadvertently commenting out the remainder of the source line.

	   The -CC option is generally used to support lint comments.

       -P  Inhibit generation of linemarkers in the output from the
	   preprocessor.  This might be useful when running the preprocessor
	   on something that is not C code, and will be sent to a program
	   which might be confused by the linemarkers.

       -traditional
       -traditional-cpp
	   Try to imitate the behavior of pre-standard C preprocessors, as
	   opposed to ISO C preprocessors.

	   Note that GCC does not otherwise attempt to emulate a pre-standard
	   C compiler, and these options are only supported with the -E
	   switch, or when invoking CPP explicitly.

       -trigraphs
	   Support ISO C trigraphs.  These are three-character sequences, all
	   starting with ??, that are defined by ISO C to stand for single
	   characters.	For example, ??/ stands for \, so '??/n' is a
	   character constant for a newline.

	   By default, GCC ignores trigraphs, but in standard-conforming modes
	   it converts them.  See the -std and -ansi options.

       -remap
	   Enable special code to work around file systems which only permit
	   very short file names, such as MS-DOS.

       -H  Print the name of each header file used, in addition to other
	   normal activities.  Each name is indented to show how deep in the
	   #include stack it is.  Precompiled header files are also printed,
	   even if they are found to be invalid; an invalid precompiled header
	   file is printed with ...x and a valid one with ...! .

       -dletters
	   Says to make debugging dumps during compilation as specified by
	   letters.  The flags documented here are those relevant to the
	   preprocessor.  Other letters are interpreted by the compiler
	   proper, or reserved for future versions of GCC, and so are silently
	   ignored.  If you specify letters whose behavior conflicts, the
	   result is undefined.

	   -dM Instead of the normal output, generate a list of #define
	       directives for all the macros defined during the execution of
	       the preprocessor, including predefined macros.  This gives you
	       a way of finding out what is predefined in your version of the
	       preprocessor.  Assuming you have no file foo.h, the command

		       touch foo.h; cpp -dM foo.h

	       shows all the predefined macros.

	   -dD Like -dM except that it outputs both the #define directives and
	       the result of preprocessing.  Both kinds of output go to the
	       standard output file.

	   -dN Like -dD, but emit only the macro names, not their expansions.

	   -dI Output #include directives in addition to the result of
	       preprocessing.

	   -dU Like -dD except that only macros that are expanded, or whose
	       definedness is tested in preprocessor directives, are output;
	       the output is delayed until the use or test of the macro; and
	       #undef directives are also output for macros tested but
	       undefined at the time.

       -fdebug-cpp
	   This option is only useful for debugging GCC.  When used from CPP
	   or with -E, it dumps debugging information about location maps.
	   Every token in the output is preceded by the dump of the map its
	   location belongs to.

	   When used from GCC without -E, this option has no effect.

       -I dir
       -iquote dir
       -isystem dir
       -idirafter dir
	   Add the directory dir to the list of directories to be searched for
	   header files during preprocessing.

	   If dir begins with = or $SYSROOT, then the = or $SYSROOT is
	   replaced by the sysroot prefix; see --sysroot and -isysroot.

	   Directories specified with -iquote apply only to the quote form of
	   the directive, "#include "file"".  Directories specified with -I,
	   -isystem, or -idirafter apply to lookup for both the
	   "#include "file"" and "#include <file>" directives.

	   You can specify any number or combination of these options on the
	   command line to search for header files in several directories.
	   The lookup order is as follows:

	   1.  For the quote form of the include directive, the directory of
	       the current file is searched first.

	   2.  For the quote form of the include directive, the directories
	       specified by -iquote options are searched in left-to-right
	       order, as they appear on the command line.

	   3.  Directories specified with -I options are scanned in left-to-
	       right order.

	   4.  Directories specified with -isystem options are scanned in
	       left-to-right order.

	   5.  Standard system directories are scanned.

	   6.  Directories specified with -idirafter options are scanned in
	       left-to-right order.

	   You can use -I to override a system header file, substituting your
	   own version, since these directories are searched before the
	   standard system header file directories.  However, you should not
	   use this option to add directories that contain vendor-supplied
	   system header files; use -isystem for that.

	   The -isystem and -idirafter options also mark the directory as a
	   system directory, so that it gets the same special treatment that
	   is applied to the standard system directories.

	   If a standard system include directory, or a directory specified
	   with -isystem, is also specified with -I, the -I option is ignored.
	   The directory is still searched but as a system directory at its
	   normal position in the system include chain.	 This is to ensure
	   that GCC's procedure to fix buggy system headers and the ordering
	   for the "#include_next" directive are not inadvertently changed.
	   If you really need to change the search order for system
	   directories, use the -nostdinc and/or -isystem options.

       -I- Split the include path.  This option has been deprecated.  Please
	   use -iquote instead for -I directories before the -I- and remove
	   the -I- option.

	   Any directories specified with -I options before -I- are searched
	   only for headers requested with "#include "file""; they are not
	   searched for "#include <file>".  If additional directories are
	   specified with -I options after the -I-, those directories are
	   searched for all #include directives.

	   In addition, -I- inhibits the use of the directory of the current
	   file directory as the first search directory for "#include "file"".
	   There is no way to override this effect of -I-.

       -iprefix prefix
	   Specify prefix as the prefix for subsequent -iwithprefix options.
	   If the prefix represents a directory, you should include the final
	   /.

       -iwithprefix dir
       -iwithprefixbefore dir
	   Append dir to the prefix specified previously with -iprefix, and
	   add the resulting directory to the include search path.
	   -iwithprefixbefore puts it in the same place -I would; -iwithprefix
	   puts it where -idirafter would.

       -isysroot dir
	   This option is like the --sysroot option, but applies only to
	   header files (except for Darwin targets, where it applies to both
	   header files and libraries).	 See the --sysroot option for more
	   information.

       -imultilib dir
	   Use dir as a subdirectory of the directory containing target-
	   specific C++ headers.

       -nostdinc
	   Do not search the standard system directories for header files.
	   Only the directories explicitly specified with -I, -iquote,
	   -isystem, and/or -idirafter options (and the directory of the
	   current file, if appropriate) are searched.

       -nostdinc++
	   Do not search for header files in the C++-specific standard
	   directories, but do still search the other standard directories.
	   (This option is used when building the C++ library.)

       -Wcomment
       -Wcomments
	   Warn whenever a comment-start sequence /* appears in a /* comment,
	   or whenever a backslash-newline appears in a // comment.  This
	   warning is enabled by -Wall.

       -Wtrigraphs
	   Warn if any trigraphs are encountered that might change the meaning
	   of the program.  Trigraphs within comments are not warned about,
	   except those that would form escaped newlines.

	   This option is implied by -Wall.  If -Wall is not given, this
	   option is still enabled unless trigraphs are enabled.  To get
	   trigraph conversion without warnings, but get the other -Wall
	   warnings, use -trigraphs -Wall -Wno-trigraphs.

       -Wundef
	   Warn if an undefined identifier is evaluated in an "#if" directive.
	   Such identifiers are replaced with zero.

       -Wexpansion-to-defined
	   Warn whenever defined is encountered in the expansion of a macro
	   (including the case where the macro is expanded by an #if
	   directive).	Such usage is not portable.  This warning is also
	   enabled by -Wpedantic and -Wextra.

       -Wunused-macros
	   Warn about macros defined in the main file that are unused.	A
	   macro is used if it is expanded or tested for existence at least
	   once.  The preprocessor also warns if the macro has not been used
	   at the time it is redefined or undefined.

	   Built-in macros, macros defined on the command line, and macros
	   defined in include files are not warned about.

	   Note: If a macro is actually used, but only used in skipped
	   conditional blocks, then the preprocessor reports it as unused.  To
	   avoid the warning in such a case, you might improve the scope of
	   the macro's definition by, for example, moving it into the first
	   skipped block.  Alternatively, you could provide a dummy use with
	   something like:

		   #if defined the_macro_causing_the_warning
		   #endif

       -Wno-endif-labels
	   Do not warn whenever an "#else" or an "#endif" are followed by
	   text.  This sometimes happens in older programs with code of the
	   form

		   #if FOO
		   ...
		   #else FOO
		   ...
		   #endif FOO

	   The second and third "FOO" should be in comments.  This warning is
	   on by default.

ENVIRONMENT
       This section describes the environment variables that affect how CPP
       operates.  You can use them to specify directories or prefixes to use
       when searching for include files, or to control dependency output.

       Note that you can also specify places to search using options such as
       -I, and control dependency output with options like -M.	These take
       precedence over environment variables, which in turn take precedence
       over the configuration of GCC.

       CPATH
       C_INCLUDE_PATH
       CPLUS_INCLUDE_PATH
       OBJC_INCLUDE_PATH
	   Each variable's value is a list of directories separated by a
	   special character, much like PATH, in which to look for header
	   files.  The special character, "PATH_SEPARATOR", is target-
	   dependent and determined at GCC build time.	For Microsoft Windows-
	   based targets it is a semicolon, and for almost all other targets
	   it is a colon.

	   CPATH specifies a list of directories to be searched as if
	   specified with -I, but after any paths given with -I options on the
	   command line.  This environment variable is used regardless of
	   which language is being preprocessed.

	   The remaining environment variables apply only when preprocessing
	   the particular language indicated.  Each specifies a list of
	   directories to be searched as if specified with -isystem, but after
	   any paths given with -isystem options on the command line.

	   In all these variables, an empty element instructs the compiler to
	   search its current working directory.  Empty elements can appear at
	   the beginning or end of a path.  For instance, if the value of
	   CPATH is ":/special/include", that has the same effect as
	   -I. -I/special/include.

       DEPENDENCIES_OUTPUT
	   If this variable is set, its value specifies how to output
	   dependencies for Make based on the non-system header files
	   processed by the compiler.  System header files are ignored in the
	   dependency output.

	   The value of DEPENDENCIES_OUTPUT can be just a file name, in which
	   case the Make rules are written to that file, guessing the target
	   name from the source file name.  Or the value can have the form
	   file target, in which case the rules are written to file file using
	   target as the target name.

	   In other words, this environment variable is equivalent to
	   combining the options -MM and -MF, with an optional -MT switch too.

       SUNPRO_DEPENDENCIES
	   This variable is the same as DEPENDENCIES_OUTPUT (see above),
	   except that system header files are not ignored, so it implies -M
	   rather than -MM.  However, the dependence on the main input file is
	   omitted.

       SOURCE_DATE_EPOCH
	   If this variable is set, its value specifies a UNIX timestamp to be
	   used in replacement of the current date and time in the "__DATE__"
	   and "__TIME__" macros, so that the embedded timestamps become
	   reproducible.

	   The value of SOURCE_DATE_EPOCH must be a UNIX timestamp, defined as
	   the number of seconds (excluding leap seconds) since 01 Jan 1970
	   00:00:00 represented in ASCII; identical to the output of "date
	   +%s" on GNU/Linux and other systems that support the %s extension
	   in the "date" command.

	   The value should be a known timestamp such as the last modification
	   time of the source or package and it should be set by the build
	   process.

SEE ALSO
       gpl(7), gfdl(7), fsf-funding(7), gcc(1), and the Info entries for cpp
       and gcc.

COPYRIGHT
       Copyright (c) 1987-2024 Free Software Foundation, Inc.

       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.3 or
       any later version published by the Free Software Foundation.  A copy of
       the license is included in the man page gfdl(7).	 This manual contains
       no Invariant Sections.  The Front-Cover Texts are (a) (see below), and
       the Back-Cover Texts are (b) (see below).

       (a) The FSF's Front-Cover Text is:

	    A GNU Manual

       (b) The FSF's Back-Cover Text is:

	    You have freedom to copy and modify this GNU Manual, like GNU
	    software.  Copies published by the Free Software Foundation raise
	    funds for GNU development.



gcc-14.2.0			  2024-08-01				CPP(1)

GCOV-TOOL(1)			      GNU			  GCOV-TOOL(1)



NAME
       gcov-tool - offline gcda profile processing tool

SYNOPSIS
       gcov-tool [-v|--version] [-h|--help]

       gcov-tool merge [merge-options] directory1 directory2
	    [-o|--output directory]
	    [-v|--verbose]
	    [-w|--weight w1,w2]

       gcov-tool merge-stream [merge-stream-options] [file]
	    [-v|--verbose]
	    [-w|--weight w1,w2]

       gcov-tool rewrite [rewrite-options] directory
	    [-n|--normalize long_long_value]
	    [-o|--output directory]
	    [-s|--scale float_or_simple-frac_value]
	    [-v|--verbose]

       gcov-tool overlap [overlap-options] directory1 directory2
	    [-f|--function]
	    [-F|--fullname]
	    [-h|--hotonly]
	    [-o|--object]
	    [-t|--hot_threshold] float
	    [-v|--verbose]

DESCRIPTION
       gcov-tool is an offline tool to process gcc's gcda profile files.

       Current gcov-tool supports the following functionalities:

       *   merge two sets of profiles with weights.

       *   read a stream of profiles with associated filenames and merge it
	   with a set of profiles with weights.

       *   read one set of profile and rewrite profile contents. One can scale
	   or normalize the count values.

       Examples of the use cases for this tool are:

       *   Collect the profiles for different set of inputs, and use this tool
	   to merge them. One can specify the weight to factor in the relative
	   importance of each input.

       *   Collect profiles from target systems without a filesystem
	   (freestanding environments).	 Merge the collected profiles with
	   associated profiles present on the host system.  One can specify
	   the weight to factor in the relative importance of each input.

       *   Rewrite the profile after removing a subset of the gcda files,
	   while maintaining the consistency of the summary and the histogram.

       *   It can also be used to debug or libgcov code as the tools shares
	   the majority code as the runtime library.

       Note that for the merging operation, this profile generated offline may
       contain slight different values from the online merged profile. Here
       are a list of typical differences:

       *   histogram difference: This offline tool recomputes the histogram
	   after merging the counters. The resulting histogram, therefore, is
	   precise. The online merging does not have this capability -- the
	   histogram is merged from two histograms and the result is an
	   approximation.

       *   summary checksum difference: Summary checksum uses a CRC32
	   operation. The value depends on the link list order of gcov-info
	   objects. This order is different in gcov-tool from that in the
	   online merge. It's expected to have different summary checksums. It
	   does not really matter as the compiler does not use this checksum
	   anywhere.

       *   value profile counter values difference: Some counter values for
	   value profile are runtime dependent, like heap addresses. It's
	   normal to see some difference in these kind of counters.

OPTIONS
       -h
       --help
	   Display help about using gcov-tool (on the standard output), and
	   exit without doing any further processing.

       -v
       --version
	   Display the gcov-tool version number (on the standard output), and
	   exit without doing any further processing.

       merge
	   Merge two profile directories.

	   -o directory
	   --output directory
	       Set the output profile directory. Default output directory name
	       is merged_profile.

	   -v
	   --verbose
	       Set the verbose mode.

	   -w w1,w2
	   --weight w1,w2
	       Set the merge weights of the directory1 and directory2,
	       respectively. The default weights are 1 for both.

       merge-stream
	   Collect profiles with associated filenames from a gcfn and gcda
	   data stream.	 Read the stream from the file specified by file or
	   from stdin.	Merge the profiles with associated profiles in the
	   host filesystem.  Apply the optional weights while merging
	   profiles.

	   For the generation of a gcfn and gcda data stream on the target
	   system, please have a look at the "__gcov_filename_to_gcfn()" and
	   "__gcov_info_to_gcda()" functions declared in "#include <gcov.h>".

	   -v
	   --verbose
	       Set the verbose mode.

	   -w w1,w2
	   --weight w1,w2
	       Set the merge weights of the profiles from the gcfn and gcda
	       data stream and the associated profiles in the host filesystem,
	       respectively.  The default weights are 1 for both.

       rewrite
	   Read the specified profile directory and rewrite to a new
	   directory.

	   -n long_long_value
	   --normalize <long_long_value>
	       Normalize the profile. The specified value is the max counter
	       value in the new profile.

	   -o directory
	   --output directory
	       Set the output profile directory. Default output name is
	       rewrite_profile.

	   -s float_or_simple-frac_value
	   --scale float_or_simple-frac_value
	       Scale the profile counters. The specified value can be in
	       floating point value, or simple fraction value form, such 1, 2,
	       2/3, and 5/3.

	   -v
	   --verbose
	       Set the verbose mode.

       overlap
	   Compute the overlap score between the two specified profile
	   directories.	 The overlap score is computed based on the arc
	   profiles. It is defined as the sum of min (p1_counter[i] /
	   p1_sum_all, p2_counter[i] / p2_sum_all), for all arc counter i,
	   where p1_counter[i] and p2_counter[i] are two matched counters and
	   p1_sum_all and p2_sum_all are the sum of counter values in profile
	   1 and profile 2, respectively.

	   -f
	   --function
	       Print function level overlap score.

	   -F
	   --fullname
	       Print full gcda filename.

	   -h
	   --hotonly
	       Only print info for hot objects/functions.

	   -o
	   --object
	       Print object level overlap score.

	   -t float
	   --hot_threshold <float>
	       Set the threshold for hot counter value.

	   -v
	   --verbose
	       Set the verbose mode.

SEE ALSO
       gpl(7), gfdl(7), fsf-funding(7), gcc(1), gcov(1) and the Info entry for
       gcc.

COPYRIGHT
       Copyright (c) 2014-2024 Free Software Foundation, Inc.

       Permission is granted to copy, distribute and/or modify this document
       under the terms of the GNU Free Documentation License, Version 1.3 or
       any later version published by the Free Software Foundation; with the
       Invariant Sections being "GNU General Public License" and "Funding Free
       Software", the Front-Cover texts being (a) (see below), and with the
       Back-Cover Texts being (b) (see below).	A copy of the license is
       included in the gfdl(7) man page.

       (a) The FSF's Front-Cover Text is:

	    A GNU Manual

       (b) The FSF's Back-Cover Text is:

	    You have freedom to copy and modify this GNU Manual, like GNU
	    software.  Copies published by the Free Software Foundation raise
	    funds for GNU development.



gcc-14.2.0			  2024-08-01			  GCOV-TOOL(1)