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GCC(1)				   GNU Tools				GCC(1)

NAME
       gcc, g++	- GNU project C	and C++	Compiler (gcc-2.95.3)

SYNOPSIS
       gcc [ option | filename ]...
       g++ [ option | filename ]...

WARNING
       The information in this man page	is an extract from the full documenta-
       tion  of	 the  GNU C compiler, and is limited to	the meaning of the op-
       tions.

       This man	page is	not kept up to date except  when  volunteers  want  to
       maintain	 it.   If  you find a discrepancy between the man page and the
       software, please	check the Info file, which is the authoritative	 docu-
       mentation.

       If  we find that	the things in this man page that are out of date cause
       significant confusion or	complaints, we will stop distributing the  man
       page.   The  alternative, updating the man page when we update the Info
       file, is	impossible because the rest of the work	of maintaining GNU  CC
       leaves us no time for that.  The	GNU project regards man	pages as obso-
       lete and	should not let them take time away from	other things.

       For complete and	current	documentation, refer to	the Info file `gcc' or
       the  manual  Using and Porting GNU CC (for version 2.0).	 Both are made
       from the	Texinfo	source file gcc.texinfo.

DESCRIPTION
       The C and C++ compilers	are  integrated.   Both	 process  input	 files
       through	one or more of four stages: preprocessing, compilation,	assem-
       bly, and	linking.  Source filename suffixes identify  the  source  lan-
       guage,  but which name you use for the compiler governs default assump-
       tions:

       gcc    assumes preprocessed (.i)	files are C and	assumes	C style	 link-
	      ing.

       g++    assumes  preprocessed  (.i)  files are C++ and assumes C++ style
	      linking.

       Suffixes	of source file names indicate the language and	kind  of  pro-
       cessing to be done:

       .c    C source; preprocess, compile, assemble
       .C    C++ source; preprocess, compile, assemble
       .cc   C++ source; preprocess, compile, assemble
       .cxx  C++ source; preprocess, compile, assemble
       .m    Objective-C source; preprocess, compile, assemble
       .i    preprocessed C; compile, assemble
       .ii   preprocessed C++; compile,	assemble
       .s    Assembler source; assemble
       .S    Assembler source; preprocess, assemble
       .h    Preprocessor file;	not usually named on command line

       Files  with  other suffixes are passed to the linker.  Common cases in-
       clude:

       .o    Object file
       .a    Archive file

       Linking is always the last stage	unless you use one of the -c,  -S,  or
       -E  options  to	avoid  it (or unless compilation errors	stop the whole
       process).  For the link stage, all .o  files  corresponding  to	source
       files,  -l libraries, unrecognized filenames (including named .o	object
       files and .a archives) are passed to the	linker in command-line order.

OPTIONS
       Options must be separate: `-dr' is quite	different from `-d -r '.

       Most `-f'  and  `-W'  options  have  two	 contrary  forms:  -fname  and
       -fno-name  (or  -Wname  and -Wno-name).	Only the non-default forms are
       shown here.

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

       Overall Options
	      -c -S -E -o file -pipe -v	-x language

       Language	Options
	      -ansi   -fall-virtual  -fcond-mismatch  -fdollars-in-identifiers
	      -fenum-int-equiv	-fexternal-templates   -fno-asm	  -fno-builtin
	      -fhosted	   -fno-hosted	   -ffreestanding    -fno-freestanding
	      -fno-strict-prototype	 -fsigned-bitfields	 -fsigned-char
	      -fthis-is-variable      -funsigned-bitfields     -funsigned-char
	      -fwritable-strings -traditional -traditional-cpp -trigraphs

       Warning Options
	      -fsyntax-only   -pedantic	  -pedantic-errors   -w	   -W	 -Wall
	      -Waggregate-return   -Wcast-align	 -Wcast-qual  -Wchar-subscript
	      -Wcomment	   -Wconversion	   -Wenum-clash	   -Werror    -Wformat
	      -Wid-clash-len		 -Wimplicit		-Wimplicit-int
	      -Wimplicit-function-declaration  -Winline	  -Wlong-long	-Wmain
	      -Wmissing-prototypes   -Wmissing-declarations   -Wnested-externs
	      -Wno-import  -Wparentheses   -Wpointer-arith   -Wredundant-decls
	      -Wreturn-type	 -Wshadow     -Wstrict-prototypes     -Wswitch
	      -Wtemplate-debugging -Wtraditional  -Wtrigraphs  -Wuninitialized
	      -Wunused -Wwrite-strings

       Debugging Options
	      -a  -dletters -fpretend-float -g -glevel -gcoff -gxcoff -gxcoff+
	      -gdwarf -gdwarf+	-gstabs	 -gstabs+  -ggdb  -p  -pg  -save-temps
	      -print-file-name=library		       -print-libgcc-file-name
	      -print-prog-name=program

       Optimization Options
	      -fcaller-saves	   -fcse-follow-jumps	     -fcse-skip-blocks
	      -fdelayed-branch	-felide-constructors -fexpensive-optimizations
	      -ffast-math     -ffloat-store	 -fforce-addr	   -fforce-mem
	      -finline-functions   -fkeep-inline-functions   -fmemoize-lookups
	      -fno-default-inline -fno-defer-pop -fno-function-cse -fno-inline
	      -fno-peephole    -fomit-frame-pointer	-frerun-cse-after-loop
	      -fschedule-insns	     -fschedule-insns2	     -fstrength-reduce
	      -fthread-jumps -funroll-all-loops	-funroll-loops -O -O2 -O3  -O0
	      -Os

       Preprocessor Options
	      -Aassertion  -C  -dD -dM -dN -Dmacro[=defn] -E -H	-idirafter dir
	      -include file -imacros file -iprefix file	 -iwithprefix  dir  -M
	      -MD -MM -MMD -nostdinc -P	-Umacro	-undef

       Assembler Option
	      -Wa,option

       Linker Options
	      -llibrary	 -nostartfiles	-nostdlib  -static  -shared  -symbolic
	      -Xlinker option -Wl,option -u symbol

       Directory Options
	      -Bprefix -Idir -I- -Ldir

       Target Options
	      -b  machine -V version

       Configuration Dependent Options
	      M680x0 Options
	      -m68000 -m68020 -m68020-40 -m68030  -m68040  -m68881  -mbitfield
	      -mc68000 -mc68020	-mfpa -mnobitfield -mrtd -mshort -msoft-float

	      VAX Options
	      -mg -mgnu	-munix

	      SPARC Options
	      -mepilogue    -mfpu    -mhard-float    -mno-fpu	 -mno-epilogue
	      -msoft-float -msparclite -mv8 -msupersparc -mcypress

	      Convex Options
	      -margcount -mc1 -mc2 -mnoargcount

	      AMD29K Options
	      -m29000  -m29050	-mbw  -mdw  -mkernel-registers	-mlarge	 -mnbw
	      -mnodw -msmall -mstack-check -muser-registers

	      M88K Options
	      -m88000	 -m88100   -m88110   -mbig-pic	 -mcheck-zero-division
	      -mhandle-large-shift			   -midentify-revision
	      -mno-check-zero-division			   -mno-ocs-debug-info
	      -mno-ocs-frame-position			-mno-optimize-arg-area
	      -mno-serialize-volatile	  -mno-underscores    -mocs-debug-info
	      -mocs-frame-position  -moptimize-arg-area	  -mserialize-volatile
	      -mshort-data-num	    -msvr3	-msvr4	    -mtrap-large-shift
	      -muse-div-instruction -mversion-03.00 -mwarn-passed-structs

	      RS6000 Options
	      -mfp-in-toc -mno-fop-in-toc

	      RT Options
	      -mcall-lib-mul	   -mfp-arg-in-fpregs	     -mfp-arg-in-gregs
	      -mfull-fp-blocks	       -mhc-struct-return	 -min-line-mul
	      -mminimum-fp-blocks -mnohc-struct-return

	      MIPS Options
	      -mcpu=cpu	type  -mips2  -mips3  -mint64  -mlong64	 -mlonglong128
	      -mmips-as	 -mgas -mrnames	-mno-rnames -mgpopt -mno-gpopt -mstats
	      -mno-stats  -mmemcpy  -mno-memcpy	 -mno-mips-tfile  -mmips-tfile
	      -msoft-float  -mhard-float  -mabicalls  -mno-abicalls -mhalf-pic
	      -mno-half-pic -G num -nocpp

	      i386 Options
	      -m386  -m486  -mpentium  -mpentiumpro  -mno-486  -mcpu=cpu  type
	      -march=cpu   type	  -msoft-float	-mrtd  -mregparm  -msvr3-shlib
	      -mno-ieee-fp	   -mno-fp-ret-in-387	      -mfancy-math-387
	      -mno-wide-multiply  -mdebug-addr	-mno-move  -mprofiler-epilogue
	      -reg-alloc=LIST

	      HPPA Options
	      -mpa-risc-1-0	-mpa-risc-1-1	   -mkernel	 -mshared-libs
	      -mno-shared-libs		-mlong-calls	      -mdisable-fpregs
	      -mdisable-indexing -mtrailing-colon

	      i960 Options
	      -mcpu-type     -mnumerics	    -msoft-float     -mleaf-procedures
	      -mno-leaf-procedures  -mtail-call	 -mno-tail-call	-mcomplex-addr
	      -mno-complex-addr	  -mcode-align	 -mno-code-align   -mic-compat
	      -mic2.0-compat	 -mic3.0-compat	   -masm-compat	   -mintel-asm
	      -mstrict-align -mno-strict-align -mold-align -mno-old-align

	      DEC Alpha	Options
	      -mfp-regs	-mno-fp-regs -mno-soft-float -msoft-float

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

       Code Generation Options
	      -fcall-saved-reg		 -fcall-used-reg	   -ffixed-reg
	      -finhibit-size-directive	    -fnonnull-objects	   -fno-common
	      -fno-ident  -fno-gnu-linker  -fpcc-struct-return	 -fpic	 -fPIC
	      -freg-struct-return  -fshared-data  -fshort-enums	-fshort-double
	      -fvolatile -fvolatile-global -fverbose-asm

FreeBSD	SPECIFIC OPTIONS
       -pthread
	      Link a user-threaded process against libc_r instead of libc. Ob-
	      jects linked into	user-threaded  processes  should  be  compiled
	      with -D_THREAD_SAFE.

OVERALL	OPTIONS
       -x language
	      Specify  explicitly  the	language for the following input files
	      (rather than choosing a default based on the file	name suffix) .
	      This option applies to all following input files until the  next
	      `-x'  option.   Possible	values	of  language  are `c', `objec-
	      tive-c', `c-header', `c++', `cpp-output',	`assembler', and  `as-
	      sembler-with-cpp'.

       -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 want only	some of	the four stages	(preprocess,  compile,	assem-
       ble,  link),  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 com-
	      piler output is an object	 file  corresponding  to  each	source
	      file.

	      By  default, GCC makes the object	file name for a	source file by
	      replacing	the suffix `.c', `.i', `.s', etc., with	`.o'.  Use  -o
	      to select	another	name.

	      GCC  ignores any unrecognized input files	(those that do not re-
	      quire compilation	or assembly) with the -c option.

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

	      By default, GCC makes the	assembler file name for	a source  file
	      by  replacing the	suffix `.c', `.i', etc., with `.s'.  Use -o to
	      select another name.

	      GCC ignores any input files that don't require compilation.

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

	      GCC ignores input	files which don't require preprocessing.

       -o file
	      Place output in file file.  This applies regardless to  whatever
	      sort  of	output	GCC  is	producing, whether it be an executable
	      file, an object file, an assembler file or preprocessed C	code.

	      Since only one output file can be	specified, it  does  not  make
	      sense  to	 use `-o' when compiling more than one input file, un-
	      less you are producing an	executable file	as output.

	      If you do	not specify `-o', 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',	and  all  pre-
	      processed	C source on standard output.

       -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.

       -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 cannot read from a pipe; but the GNU
	      assembler	has no trouble.

LANGUAGE OPTIONS
       The following options control the dialect of C that  the	 compiler  ac-
       cepts:

       -ansi  Support all ANSI standard	C programs.

	      This  turns  off certain features	of GNU C that are incompatible
	      with ANSI	C, such	as the asm, inline 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 ANSI trigraph	feature, and disallows `$' as part  of
	      identifiers.

	      The  alternate  keywords	__asm__, __extension__,	__inline__ and
	      __typeof__ continue to work despite `-ansi'.  You	would not want
	      to use them in an	ANSI 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-ANSI programs to	be re-
	      jected gratuitously.  For	that, `-pedantic' is required in addi-
	      tion to `-ansi'.

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

       -fno-asm
	      Do not recognize asm, inline or  typeof  as  a  keyword.	 These
	      words  may  then	be  used as identifiers.  You can use __asm__,
	      __inline__ and __typeof__	instead.  `-ansi' implies `-fno-asm'.

       -fno-builtin
	      Don't recognize built-in functions that do not  begin  with  two
	      leading  underscores.  Currently,	the functions affected include
	      _exit, abort, abs, alloca, cos, exit, fabs, labs,	 memcmp,  mem-
	      cpy, sin,	sqrt, strcmp, strcpy, and strlen.

	      The  `-ansi' option prevents alloca and _exit from being builtin
	      functions.

       -fhosted
	      Compile for a hosted environment;	this implies  the  `-fbuiltin'
	      option,  and implies that	suspicious declarations	of main	should
	      be warned	about.

       -ffreestanding
	      Compile for a freestanding environment; this implies the	`-fno-
	      builtin'	option,	 and implies that main has no special require-
	      ments.

       -fno-strict-prototype
	      Treat a function declaration with	no arguments, such as `int foo
	      ();', as C would treat it--as saying nothing about the number of
	      arguments	or their types (C++ only).  Normally, such a  declara-
	      tion in C++ means	that the function foo takes no arguments.

       -trigraphs
	      Support  ANSI  C	trigraphs.   The `-ansi' option	implies	`-tri-
	      graphs'.

       -traditional
	      Attempt to support some aspects of traditional C compilers.  For
	      details, see the GNU C Manual; the duplicate list	here has  been
	      deleted so that we won't get complaints when it is out of	date.

	      But  one	note  about C++	programs only (not C).	`-traditional'
	      has one additional effect	for C++: assignment to this is permit-
	      ted.  This is the	same as	the effect of `-fthis-is-variable'.

       -traditional-cpp
	      Attempt to support some aspects of traditional C	preprocessors.
	      This includes the	items that specifically	mention	the preproces-
	      sor above, but none of the other effects of `-traditional'.

       -fdollars-in-identifiers
	      Permit  the  use of `$' in identifiers (C++ only).  You can also
	      use `-fno-dollars-in-identifiers'	to explicitly prohibit use  of
	      `$'.   (GNU C++ allows `$' by default on some target systems but
	      not others.)

       -fenum-int-equiv
	      Permit implicit conversion of int	to enumeration types (C++  on-
	      ly).  Normally GNU C++ allows conversion of enum to int, but not
	      the other	way around.

       -fexternal-templates
	      Produce  smaller	code  for template declarations, by generating
	      only a single copy of each template function where it is defined
	      (C++ only).  To use this option successfully, you	must also mark
	      all files	that use templates with	 either	 `#pragma  implementa-
	      tion' (the definition) or	`#pragma interface' (declarations).

	      When your	code is	compiled with `-fexternal-templates', all tem-
	      plate  instantiations  are  external.   You must arrange for all
	      necessary	instantiations to appear in the	 implementation	 file;
	      you  can	do this	with a typedef that references each instantia-
	      tion needed.  Conversely,	when you compile using the default op-
	      tion `-fno-external-templates', all template instantiations  are
	      explicitly internal.

       -fall-virtual
	      Treat all	possible member	functions as virtual, implicitly.  All
	      member  functions	 (except  for constructor functions and	new or
	      delete member operators) are treated as virtual functions	of the
	      class where they appear.

	      This does	not mean that all calls	to these member	functions will
	      be made through the internal table of virtual functions.	 Under
	      some  circumstances, the compiler	can determine that a call to a
	      given virtual function can be made directly; in these cases  the
	      calls are	direct in any case.

       -fcond-mismatch
	      Allow  conditional expressions with mismatched types in the sec-
	      ond and third arguments.	The value of  such  an	expression  is
	      void.

       -fthis-is-variable
	      Permit  assignment  to  this  (C++  only).  The incorporation of
	      user-defined free	store management into C++ has made  assignment
	      to  `this'  an anachronism.  Therefore, by default it is invalid
	      to assign	to this	within a class member function.	 However,  for
	      backwards	 compatibility,	you can	make it	valid with `-fthis-is-
	      variable'.

       -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 un-
	      signed 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 ma-
	      chines 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
	      and unsigned char, even though its behavior is always just  like
	      one of those two.

       -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,
	      `-fno-signed-char' is equivalent to `-funsigned-char'.

       -fsigned-bitfields

       -funsigned-bitfields

       -fno-signed-bitfields

       -fno-unsigned-bitfields
	      These  options control whether a bitfield	is signed or unsigned,
	      when declared with no explicit `signed' or `unsigned' qualifier.
	      By default, such a bitfield is signed, because this  is  consis-
	      tent: the	basic integer types such as int	are signed types.

	      However,	when you specify `-traditional', bitfields are all un-
	      signed no	matter what.

       -fwritable-strings
	      Store string constants in	the writable data  segment  and	 don't
	      uniquize	them.	This  is  for  compatibility with old programs
	      which assume they	can write into string constants.  `-tradition-
	      al' also has this	effect.

	      Writing into string constants is a very  bad  idea;  "constants"
	      should be	constant.

PREPROCESSOR OPTIONS
       These options control the C preprocessor, which is run on each C	source
       file before actual compilation.

       If  you	use  the  `-E'	option,	GCC does nothing except	preprocessing.
       Some of these options make sense	only together with `-E'	 because  they
       cause the preprocessor output to	be unsuitable for actual compilation.

       -include	file
	      Process  file as input before processing the regular input file.
	      In effect, the contents of file are compiled  first.   Any  `-D'
	      and `-U' options on the command line are always processed	before
	      `-include	file', regardless of the order in which	they are writ-
	      ten.  All	the `-include' and `-imacros' options are processed in
	      the order	in which they are written.

       -imacros	file
	      Process  file  as	input, discarding the resulting	output,	before
	      processing the regular input file.  Because the output generated
	      from file	is discarded, the only effect of `-imacros file' is to
	      make the macros defined in file available	for use	 in  the  main
	      input.   The preprocessor	evaluates any `-D' and `-U' options on
	      the command line before processing `-imacrosfile', regardless of
	      the order	in which they are written.   All  the  `-include'  and
	      `-imacros'  options are processed	in the order in	which they are
	      written.

       -idirafter dir
	      Add the directory	dir to the second include path.	 The  directo-
	      ries  on the second include path are searched when a header file
	      is not found in any of the directories in	the main include  path
	      (the one that `-I' adds to).

       -iprefix	prefix
	      Specify  prefix  as the prefix for subsequent `-iwithprefix' op-
	      tions.

       -iwithprefix dir
	      Add a directory to the second  include  path.   The  directory's
	      name  is	made by	concatenating prefix and dir, where prefix was
	      specified	previously with	`-iprefix'.

       -nostdinc
	      Do not search the	standard system	directories for	header	files.
	      Only  the	 directories you have specified	with `-I' options (and
	      the current directory, if	appropriate) are searched.

	      By using both `-nostdinc'	and `-I-', you can limit the  include-
	      file search file to only those directories you specify explicit-
	      ly.

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

       -undef Do  not  predefine any nonstandard macros.  (Including architec-
	      ture flags).

       -E     Run only the C preprocessor.  Preprocess all the C source	 files
	      specified	 and  output  the results to standard output or	to the
	      specified	output file.

       -C     Tell the preprocessor not	to discard comments.   Used  with  the
	      `-E' option.

       -P     Tell  the	 preprocessor  not to generate `#line' commands.  Used
	      with the `-E' option.

       -M  [ -MG ]
	      Tell the preprocessor to output a	rule  suitable	for  make  de-
	      scribing	the dependencies of each object	file.  For each	source
	      file, the	preprocessor outputs one make-rule whose target	is the
	      object file name for that	source file and	whose dependencies are
	      all the files `#include'd	in it.	This rule may be a single line
	      or may be	continued with `\'-newline if it is long.  The list of
	      rules is printed on standard output instead of the  preprocessed
	      C	program.

	      `-M' implies `-E'.

	      `-MG'  says to treat missing header files	as generated files and
	      assume they live in the same directory as	the source  file.   It
	      must be specified	in addition to `-M'.

       -MM  [ -MG ]
	      Like `-M'	but the	output mentions	only the user header files in-
	      cluded  with  `#include  "file"'.	  System header	files included
	      with `#include <file>' are omitted.

       -MD    Like `-M'	but the	dependency information	is  written  to	 files
	      with  names  made	 by replacing `.o' with	`.d' at	the end	of the
	      output file names.  This is in addition to compiling the file as
	      specified--`-MD' does not	inhibit	ordinary compilation  the  way
	      `-M' does.

	      The Mach utility `md' can	be used	to merge the `.d' files	into a
	      single  dependency  file suitable	for using with the `make' com-
	      mand.

       -MMD   Like `-MD' except	mention	only user  header  files,  not	system
	      header files.

       -H     Print  the  name	of each	header file used, in addition to other
	      normal activities.

       -Aquestion(answer)
	      Assert the answer	answer for question, in	case it	is tested with
	      a	preprocessor  conditional  such	 as  `#if  #question(answer)'.
	      `-A-'  disables  the  standard assertions	that normally describe
	      the target machine.

       -Aquestion(answer
	      )	Assert the answer answer for question, in case	it  is	tested
	      with a preprocessor conditional such as `#if #question(answer)'.
	      `-A-'  disables  the  standard assertions	that normally describe
	      the target machine.

       -Dmacro
	      Define macro macro with the string `1' as	its definition.

       -Dmacro=defn
	      Define macro macro as defn.    All instances of `-D' on the com-
	      mand line	are processed before any `-U' options.

       -Umacro
	      Undefine macro macro.  `-U' options are evaluated	after all `-D'
	      options, but before any `-include' and `-imacros'	options.

       -dM    Tell the preprocessor to output only a list of the macro defini-
	      tions that are in	effect at the end of preprocessing.  Used with
	      the `-E' option.

       -dD    Tell the preprocessor to pass all	 macro	definitions  into  the
	      output, in their proper sequence in the rest of the output.

       -dN    Like  `-dD'  except  that	 the  macro arguments and contents are
	      omitted.	Only `#define name' is included	in the output.

ASSEMBLER OPTION
       -Wa,option
	      Pass option as an	option to the assembler.  If  option  contains
	      commas, it is split into multiple	options	at the commas.

LINKER OPTIONS
       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 GCC does a	link step, these object	files are used
	      as input to the linker.

       -llibrary
	      Use the library named library when linking.

	      The  linker  searches a standard list of directories for the li-
	      brary, which is actually a file named `liblibrary.a'.  The link-
	      er then uses this	file as	if it had been specified precisely  by
	      name.

	      The  directories searched	include	several	standard system	direc-
	      tories plus any that you specify with `-L'.

	      Normally the files found this  way  are  library	files--archive
	      files  whose  members  are  object files.	 The linker handles an
	      archive file by scanning through it  for	members	 which	define
	      symbols  that have so far	been referenced	but not	defined.  How-
	      ever, if the linker finds	an ordinary object file	rather than  a
	      library,	the  object  file is linked in the usual fashion.  The
	      only difference between using an `-l' option  and	 specifying  a
	      file name	is that	`-l' surrounds library with `lib' and `.a' and
	      searches several directories.

       -lobjc You  need	this special case of the -l option in order to link an
	      Objective	C program.

       -nostartfiles
	      Do not use the standard system startup files when	linking.   The
	      standard libraries are used normally.

       -nostdlib
	      Don't  use  the standard system libraries	and startup files when
	      linking.	Only the files you specify will	be passed to the link-
	      er.

       -static
	      On systems that support dynamic linking, this  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 ob-
	      jects to form an executable.  Only a few	systems	 support  this
	      option.

       -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.

       -Xlinker	option
	      Pass  option  as	an  option to the linker.  You can use this to
	      supply system-specific linker options which GNU CC does not know
	      how to recognize.

	      If you want to pass an option that takes an argument,  you  must
	      use `-Xlinker' twice, once for the option	and once for the argu-
	      ment.   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.

       -Wl,option
	      Pass option as an	option to the linker.  If option contains com-
	      mas, it is split into multiple options at	the commas.

       -u symbol
	      Pretend the symbol symbol	is undefined, to force linking of  li-
	      brary  modules  to  define  it.  You can use `-u'	multiple times
	      with different symbols to	force loading  of  additional  library
	      modules.

DIRECTORY OPTIONS
       These  options  specify directories to search for header	files, for li-
       braries and for parts of	the compiler:

       -Idir  Append directory dir to the list of directories searched for in-
	      clude files.

       -I-    Any directories you specify with `-I' options before  the	 `-I-'
	      option are searched only for the case of `#include "file"'; they
	      are not searched for `#include <file>'.

	      If  additional directories are specified with `-I' options after
	      the `-I-', these directories are searched	for all	`#include' di-
	      rectives.	 (Ordinarily all `-I' directories are used this	way.)

	      In addition, the `-I-' option inhibits the use  of  the  current
	      directory	 (where	the current input file came from) as the first
	      search directory for `#include "file"'.	There  is  no  way  to
	      override	this  effect  of  `-I-'.   With	 `-I.' you can specify
	      searching	the directory which was	current	when the compiler  was
	      invoked.	 That is not exactly the same as what the preprocessor
	      does by default, but it is often satisfactory.

	      `-I-' does not inhibit the use of	the standard  system  directo-
	      ries for header files.  Thus, `-I-' and `-nostdinc' are indepen-
	      dent.

       -Ldir  Add  directory dir to the	list of	directories to be searched for
	      `-l'.

       -Bprefix
	      This option specifies where to find the  executables,  libraries
	      and data files of	the compiler itself.

	      The  compiler driver program runs	one or more of the subprograms
	      `cpp', `cc1' (or,	for C++, `cc1plus'), `as' and `ld'.  It	 tries
	      prefix  as  a prefix for each program it tries to	run, both with
	      and without `machine/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'
	      was not specified, the driver tries two standard prefixes, which
	      are `/usr/lib/gcc/' and `/usr/local/lib/gcc-lib/'.   If  neither
	      of those results in a file name that is found, the compiler dri-
	      ver searches for the unmodified program name, using the directo-
	      ries specified in	your `PATH' environment	variable.

	      The  run-time support file `libgcc.a' is also 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.  Most of
	      the  time,  on  most machines, `libgcc.a'	is not actually	neces-
	      sary.

	      You can get a  similar  result  from  the	 environment  variable
	      GCC_EXEC_PREFIX; if it is	defined, its value is used as a	prefix
	      in  the same way.	 If both the `-B' option and the GCC_EXEC_PRE-
	      FIX variable are present,	the `-B' option	is used	first and  the
	      environment variable value second.

WARNING	OPTIONS
       Warnings	 are  diagnostic  messages that	report constructions which are
       not inherently erroneous	but which are risky or suggest there may  have
       been an error.

       These  options control the amount and kinds of warnings produced	by GNU
       CC:

       -fsyntax-only
	      Check the	code for syntax	errors,	but don't emit any output.

       -w     Inhibit all warning messages.

       -Wno-import
	      Inhibit warning messages about the use of	#import.

       -pedantic
	      Issue all	the warnings demanded by strict	ANSI standard  C;  re-
	      ject all programs	that use forbidden extensions.

	      Valid  ANSI  standard C programs should compile properly with or
	      without this option (though a rare few  will  require  `-ansi').
	      However,	without	this option, certain GNU extensions and	tradi-
	      tional C features	are supported as well.	With this option, they
	      are rejected.  There is no reason	to use this option; it	exists
	      only to satisfy pedants.

	      `-pedantic'  does	 not cause warning messages for	use of the al-
	      ternate keywords whose names begin and end with `__'.   Pedantic
	      warnings	are also disabled in the expression that follows __ex-
	      tension__.  However, only	system header files should  use	 these
	      escape routes; application programs should avoid them.

       -pedantic-errors
	      Like  `-pedantic',  except  that errors are produced rather than
	      warnings.

       -W     Print extra warning messages for these events:

	  •   A	nonvolatile automatic variable might be	changed	by a  call  to
	      longjmp.	 These warnings	are possible only in optimizing	compi-
	      lation.

	      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 which would	cause a	 prob-
	      lem.

	  •   A	 function can return either with or without a value.  (Falling
	      off the end of the function body is considered returning without
	      a	value.)	 For example, this function would evoke	such  a	 warn-
	      ing:

	      foo (a)
	      {
		if (a >	0)
		  return a;
	      }

	      Spurious warnings	can occur because GNU CC does not realize that
	      certain  functions  (including abort and longjmp)	will never re-
	      turn.

	  •   An expression-statement or the left-hand side of a comma expres-
	      sion contains no side effects.  To suppress  the	warning,  cast
	      the  unused expression to	void.  For example, an expression such
	      as `x[i,j]' will cause a warning,	but `x[(void)i,j]' will	not.

	  •   An unsigned value	is compared against zero with `>' or `<='.

       -Wimplicit-int
	      Warn whenever a declaration does not specify a type.

       -Wimplicit-function-declaration
	      Warn whenever a function is used before being declared.

       -Wimplicit
	      Same as -Wimplicit-int and -Wimplicit-function-declaration.

       -Wmain Warn if the main function	is declared or defined with  a	suspi-
	      cious  type.  Typically, it is a function	with external linkage,
	      returning	int, and taking	zero or	two arguments.

       -Wreturn-type
	      Warn whenever a function is defined with a return-type that  de-
	      faults to	int.  Also warn	about any return statement with	no re-
	      turn-value in a function whose return-type is not	void.

       -Wunused
	      Warn whenever a local variable is	unused aside from its declara-
	      tion,  whenever a	function is declared static but	never defined,
	      and whenever a statement computes	a result  that	is  explicitly
	      not used.

       -Wswitch
	      Warn  whenever  a	switch statement has an	index of enumeral type
	      and lacks	a case for one or more of the named codes of that enu-
	      meration.	 (The presence of a default label prevents this	 warn-
	      ing.)   case  labels  outside the	enumeration range also provoke
	      warnings when this option	is used.

       -Wcomment
	      Warn whenever a comment-start sequence `/*' appears  in  a  com-
	      ment.

       -Wtrigraphs
	      Warn  if	any  trigraphs	are encountered	(assuming they are en-
	      abled).

       -Wformat
	      Check calls to printf and	scanf, etc., to	make sure that the ar-
	      guments supplied have types appropriate  to  the	format	string
	      specified.

       -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.

       -Wuninitialized
	      An automatic variable is used without first being	initialized.

	      These  warnings are possible only	in optimizing compilation, be-
	      cause they require data flow information that is	computed  only
	      when  optimizing.	  If  you don't	specify	`-O', you simply won't
	      get these	warnings.

	      These warnings occur only	for variables that are candidates  for
	      register	allocation.   Therefore, they do not occur for a vari-
	      able that	is declared volatile, or whose address	is  taken,  or
	      whose  size is other than	1, 2, 4	or 8 bytes.  Also, they	do not
	      occur for	structures, unions or arrays, even when	 they  are  in
	      registers.

	      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.

	      These warnings are made optional because GNU  CC	is  not	 smart
	      enough  to see all the reasons why the code might	be correct de-
	      spite 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 initial-
	      ized,  but  GNU  CC  doesn't  know this.	Here is	another	common
	      case:

	      {
		int save_y;
		if (change_y) save_y = y, y = new_y;
		...
		if (change_y) y	= save_y;
	      }

	      This has no bug because save_y is	used only if it	is set.

	      Some spurious warnings can be avoided if you declare as volatile
	      all the functions	you use	that never return.

       -Wparentheses
	      Warn if parentheses are omitted in certain contexts.

       -Wtemplate-debugging
	      When using templates in a	C++ program, warn if debugging is  not
	      yet fully	available (C++ only).

       -Wall  All  of  the above `-W' options combined.	 These are all the op-
	      tions which pertain to usage that	we recommend avoiding and that
	      we believe is easy to avoid, even	in conjunction with macros.

       The remaining `-W...' options are not implied by	`-Wall'	 because  they
       warn  about  constructions that we consider reasonable to use, on occa-
       sion, in	clean programs.

       -Wtraditional
	      Warn about certain constructs that behave	differently in	tradi-
	      tional and ANSI C.

	  •   Macro  arguments	occurring within string	constants in the macro
	      body.  These would substitute the	argument in traditional	C, but
	      are part of the constant in ANSI C.

	  •   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.

       -Wshadow
	      Warn whenever a local variable shadows another local variable.

       -Wid-clash-len
	      Warn  whenever  two  distinct identifiers	match in the first len
	      characters.  This	may help you prepare a program that will  com-
	      pile with	certain	obsolete, brain-damaged	compilers.

       -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.

       -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 *.

       -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.

       -Wwrite-strings
	      Give  string constants the type const char[length] so that copy-
	      ing the address of one into a non-const char * pointer will  get
	      a	 warning.   These  warnings will 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 will just be a nuisance; this	is why
	      we did not make `-Wall' request these warnings.

       -Wconversion
	      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.

       -Waggregate-return
	      Warn  if	any functions that return structures or	unions are de-
	      fined or called.	(In languages where you	can return  an	array,
	      this also	elicits	a warning.)

       -Wstrict-prototypes
	      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  which  specifies
	      the argument types.)

       -Wmissing-prototypes
	      Warn  if	a global function is defined without a previous	proto-
	      type declaration.	 This warning is issued	even if	the definition
	      itself provides a	prototype.  The	aim is to detect global	 func-
	      tions that fail to be declared in	header files.

       -Wmissing-declarations
	      Warn if a	global function	is defined without a previous declara-
	      tion.  Do	so even	if the definition itself provides a prototype.
	      Use this option to detect	global functions that are not declared
	      in header	files.

       -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.

       -Wnested-externs
	      Warn if an extern	declaration is encountered within a function.

       -Wenum-clash
	      Warn  about  conversion between different	enumeration types (C++
	      only).

       -Wlong-long
	      Warn if long long	type is	used.  This is	default.   To  inhibit
	      the   warning   messages,	  use  flag  `-Wno-long-long'.	 Flags
	      `-W-long-long' and `-Wno-long-long' are taken into account  only
	      when flag	`-pedantic' is used.

       -Woverloaded-virtual
	      (C++  only.)   In	 a  derived  class, the	definitions of virtual
	      functions	must match the type signature of  a  virtual  function
	      declared in the base class.  Use this option to request warnings
	      when  a  derived	class declares a function that may be an erro-
	      neous attempt to define a	virtual	function: that is, warn	when a
	      function with the	same name as a virtual function	 in  the  base
	      class,  but with a type signature	that doesn't match any virtual
	      functions	from the base class.

       -Winline
	      Warn if a	function can not be inlined, and  either  it  was  de-
	      clared as	inline,	or else	the -finline-functions option was giv-
	      en.

       -Werror
	      Treat warnings as	errors;	abort compilation after	any warning.

DEBUGGING OPTIONS
       GNU  CC	has various special options that are used for debugging	either
       your program or GCC:

       -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 informa-
	      tion makes debugging work	better in GDB but will	probably  make
	      other  debuggers	crash  or  refuse to read the program.	If you
	      want to control for certain whether to generate the extra	infor-
	      mation,  use  `-gstabs+',	 `-gstabs',   `-gxcoff+',   `-gxcoff',
	      `-gdwarf+', or `-gdwarf' (see below).

	      Unlike  most  other  C  compilers, GNU CC	allows you to use `-g'
	      with `-O'.  The shortcuts	taken by optimized code	may  occasion-
	      ally produce surprising results: 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 were already  at	 hand;
	      some  statements	may  execute  in different places because they
	      were moved out of	loops.

	      Nevertheless it proves possible to debug optimized output.  This
	      makes it reasonable to use the optimizer for programs that might
	      have bugs.

       The following options are useful	when GNU CC is generated with the  ca-
       pability	for more than one debugging format.

       -ggdb  Produce  debugging  information in the native format (if that is
	      supported), including GDB	extensions if at all possible.

       -gstabs
	      Produce debugging	information in stabs format (if	that  is  sup-
	      ported), without GDB extensions.	This is	the format used	by DBX
	      on most BSD systems.

       -gstabs+
	      Produce  debugging  information in stabs format (if that is sup-
	      ported), using GNU extensions understood only by the GNU	debug-
	      ger  (GDB).  The use of these extensions is likely to make other
	      debuggers	crash or refuse	to read	the program.

       -gcoff Produce debugging	information in COFF format (if	that  is  sup-
	      ported).	 This  is the format used by SDB on most System	V sys-
	      tems prior to System V Release 4.

       -gxcoff
	      Produce debugging	information in XCOFF format (if	that  is  sup-
	      ported).	 This  is  the	format used by the DBX debugger	on IBM
	      RS/6000 systems.

       -gxcoff+
	      Produce debugging	information in XCOFF format (if	that  is  sup-
	      ported),	using GNU extensions understood	only by	the GNU	debug-
	      ger (GDB).  The use of these extensions is likely	to make	 other
	      debuggers	crash or refuse	to read	the program.

       -gdwarf
	      Produce  debugging  information in DWARF format (if that is sup-
	      ported).	This is	the format used	by SDB on most	System	V  Re-
	      lease 4 systems.

       -gdwarf+
	      Produce  debugging  information in DWARF format (if that is sup-
	      ported), using GNU extensions understood only by the GNU	debug-
	      ger  (GDB).  The use of these extensions is likely to make other
	      debuggers	crash or refuse	to read	the program.

       -glevel
       -ggdblevel
       -gstabslevel
       -gcofflevel -gxcofflevel

       -gdwarflevel
	      Request debugging	information and	also use level to specify  how
	      much information.	 The default level is 2.

	      Level  1	produces  minimal information, enough for making back-
	      traces in	parts of the program that you  don't  plan  to	debug.
	      This  includes descriptions of functions and external variables,
	      but no information about local variables and no line numbers.

	      Level 3 includes extra information, such as all the macro	defin-
	      itions present in	the program.  Some debuggers support macro ex-
	      pansion when you use `-g3'.

       -p     Generate extra code to write profile  information	 suitable  for
	      the analysis program prof.

       -pg    Generate	extra  code  to	write profile information suitable for
	      the analysis program gprof.

       -a     Generate extra code  to  write  profile  information  for	 basic
	      blocks,  which  will record the number of	times each basic block
	      is executed.  This data could be	analyzed  by  a	 program  like
	      tcov.   Note,  however,  that the	format of the data is not what
	      tcov expects.   Eventually  GNU  gprof  should  be  extended  to
	      process this data.

       -ax    Generate	extra  code  to	 read basic block profiling parameters
	      from file	`bb.in'	and write profiling results to file  `bb.out'.
	      `bb.in' contains a list of functions. Whenever a function	on the
	      list  is entered,	profiling is turned on.	When the outmost func-
	      tion is left, profiling is turned	off. If	 a  function  name  is
	      prefixed	with `-' the function is excluded from profiling. If a
	      function name is not unique it can be disambiguated  by  writing
	      `/path/filename.d:functionname'.	`bb.out' will list some	avail-
	      able filenames.  Four function names  have  a  special  meaning:
	      `__bb_jumps__'  will  cause  jump	 frequencies  to be written to
	      `bb.out'.	 `__bb_trace__'	 will  cause  the  sequence  of	 basic
	      blocks to	be piped into `gzip' and written to file `bbtrace.gz'.
	      `__bb_hidecall__'	 will  cause  call instructions	to be excluded
	      from the trace.  `__bb_showret__'	will cause return instructions
	      to be included in	the trace.

       -dletters
	      Says to make debugging dumps during compilation at times	speci-
	      fied  by letters.	 This is used for debugging the	compiler.  The
	      file names for most of the dumps are made	by appending a word to
	      the source file name (e.g.  `foo.c.rtl' or `foo.c.jump').

       -dM    Dump all macro definitions, at the  end  of  preprocessing,  and
	      write no output.

       -dN    Dump all macro names, at the end of preprocessing.

       -dD    Dump  all	macro definitions, at the end of preprocessing,	in ad-
	      dition to	normal output.

       -dy    Dump debugging information during	parsing, to standard error.

       -dr    Dump after RTL generation, to `file.rtl'.

       -dx    Just generate RTL	for a function instead of compiling it.	  Usu-
	      ally used	with `r'.

       -dj    Dump after first jump optimization, to `file.jump'.

       -ds    Dump  after  CSE (including the jump optimization	that sometimes
	      follows CSE), to `file.cse'.

       -dL    Dump after loop optimization, to `file.loop'.

       -dt    Dump after the second CSE	pass (including	the jump  optimization
	      that sometimes follows CSE), to `file.cse2'.

       -df    Dump after flow analysis,	to `file.flow'.

       -dc    Dump after instruction combination, to `file.combine'.

       -dS    Dump   after   the   first   instruction	 scheduling  pass,  to
	      `file.sched'.

       -dl    Dump after local register	allocation, to `file.lreg'.

       -dg    Dump after global	register allocation, to	`file.greg'.

       -dR    Dump  after  the	second	 instruction   scheduling   pass,   to
	      `file.sched2'.

       -dJ    Dump after last jump optimization, to `file.jump2'.

       -dd    Dump after delayed branch	scheduling, to `file.dbr'.

       -dk    Dump after conversion from registers to stack, to	`file.stack'.

       -da    Produce all the dumps listed above.

       -dm    Print  statistics	 on  memory  usage,  at	the end	of the run, to
	      standard error.

       -dp    Annotate the assembler output with a  comment  indicating	 which
	      pattern and alternative was used.

       -fpretend-float
	      When  running  a cross-compiler, pretend that the	target machine
	      uses the same floating point format as the host  machine.	  This
	      causes  incorrect	 output	 of the	actual floating	constants, but
	      the actual instruction sequence will probably be the same	as GNU
	      CC would make when running on the	target machine.

       -save-temps
	      Store the	 usual	"temporary"  intermediate  files  permanently;
	      place  them  in the current directory and	name them based	on the
	      source file.  Thus,  compiling  `foo.c'  with  `-c  -save-temps'
	      would produce files `foo.cpp' and	`foo.s', as well as `foo.o'.

       -print-file-name=library
	      Print  the  full absolute	name of	the library file library  that
	      would be used when linking--and do not do	anything  else.	  With
	      this  option,  GNU CC does not compile or	link anything; it just
	      prints the file name.

       -print-libgcc-file-name
	      Same as `-print-file-name=libgcc.a'.

       -print-prog-name=program
	      Like `-print-file-name', but searches  for  a  program  such  as
	      `cpp'.

OPTIMIZATION OPTIONS
       These options control various sorts of optimizations:

       -O

       -O1    Optimize.	  Optimizing compilation takes somewhat	more time, and
	      a	lot more memory	for a large function.

	      Without `-O', the	compiler's goal	is to reduce the cost of  com-
	      pilation	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 would
	      expect from the source code.

	      Without `-O', only variables declared register are allocated  in
	      registers.   The	resulting compiled code	is a little worse than
	      produced by PCC without `-O'.

	      With `-O', the compiler tries to reduce code size	and  execution
	      time.

	      When  you	 specify  `-O',	 the  two options `-fthread-jumps' and
	      `-fdefer-pop' are	turned on.  On machines	that have delay	slots,
	      the `-fdelayed-branch' option is turned on.  For those  machines
	      that  can	 support  debugging  even without a frame pointer, the
	      `-fomit-frame-pointer' option is turned on.   On	some  machines
	      other flags may also be turned on.

       -O2    Optimize	even more.  Nearly all supported optimizations that do
	      not involve a space-speed	 tradeoff  are	performed.   Loop  un-
	      rolling  and  function  inlining	are not	done, for example.  As
	      compared to -O, this option increases both compilation time  and
	      the performance of the generated code.

       -O3    Optimize yet more. This turns on everything -O2 does, along with
	      also turning on -finline-functions.

       -Os    Optimize	for  size.  This enables all -O2 optimizations that do
	      not typically increase code size.	 It also performs further  op-
	      timizations designed to reduce code size.

       -O0    Do not optimize.

	      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' would be	`-fno-foo'.  The following list	shows only one	form--
       the one which is	not the	default.  You can figure out the other form by
       either removing `no-' or	adding it.

       -ffloat-store
	      Do  not  store floating point variables in registers.  This pre-
	      vents 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.

	      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.

       -fmemoize-lookups

       -fsave-memoized
	      Use  heuristics  to compile faster (C++ only).  These heuristics
	      are not enabled by default, since	they are  only	effective  for
	      certain input files.  Other input	files compile more slowly.

	      The  first time the compiler must	build a	call to	a member func-
	      tion (or reference to a data  member),  it  must	(1)  determine
	      whether  the class implements member functions of	that name; (2)
	      resolve which member function to call (which  involves  figuring
	      out  what	 sorts	of  type conversions need to be	made); and (3)
	      check the	visibility of the member function to the caller.   All
	      of  this	adds  up  to slower compilation.  Normally, the	second
	      time a call is made to that member  function  (or	 reference  to
	      that  data  member), it must go through the same lengthy process
	      again.  This means that code like	this

		cout <<	"This "	<< p <<	" has "	<< n <<	" legs.\n";

	      makes six	passes through all three steps.	 By using  a  software
	      cache,  a	"hit" significantly reduces this cost.	Unfortunately,
	      using the	cache introduces another  layer	 of  mechanisms	 which
	      must  be	implemented, and so incurs its own overhead.  `-fmemo-
	      ize-lookups' enables the software	cache.

	      Because access privileges	(visibility)  to  members  and	member
	      functions	 may differ from one function context to the next, g++
	      may need to flush	the cache.  With the `-fmemoize-lookups' flag,
	      the cache	is flushed after every function	that is	compiled.  The
	      `-fsave-memoized'	flag enables the same software cache, but when
	      the compiler determines that the context of  the	last  function
	      compiled	would  yield  the  same	 access	privileges of the next
	      function to compile, it preserves	the cache.  This is most help-
	      ful when defining	many member functions for the same class: with
	      the exception of member functions	which  are  friends  of	 other
	      classes, each member function has	exactly	the same access	privi-
	      leges as every other, and	the cache need not be flushed.

       -fno-default-inline
	      Don't  make  member  functions  inline by	default	merely because
	      they are defined inside the class	scope (C++ only).

       -fno-defer-pop
	      Always pop the arguments to each function	call as	soon  as  that
	      function returns.	 For machines which must pop arguments after a
	      function	call,  the compiler normally lets arguments accumulate
	      on the stack for several function	calls and  pops	 them  all  at
	      once.

       -fforce-mem
	      Force  memory  operands to be copied into	registers before doing
	      arithmetic on them.  This	may produce better code	by making  all
	      memory  references  potential  common subexpressions.  When they
	      are not common subexpressions,  instruction  combination	should
	      eliminate	 the separate register-load.  I	am interested in hear-
	      ing about	the difference this makes.

       -fforce-addr
	      Force memory address constants to	be copied into	registers  be-
	      fore  doing  arithmetic  on  them.  This may produce better code
	      just as `-fforce-mem' may.  I am interested in hearing about the
	      difference this makes.

       -fomit-frame-pointer
	      Don't keep the frame pointer in a	register  for  functions  that
	      don't  need  one.	  This avoids the instructions to save,	set up
	      and restore frame	pointers; it  also  makes  an  extra  register
	      available	in many	functions.  It also makes debugging impossible
	      on most machines.

	      On  some machines, such as the Vax, this flag has	no effect, be-
	      cause the	standard calling sequence  automatically  handles  the
	      frame  pointer and nothing is saved by pretending	it doesn't ex-
	      ist.  The	machine-description macro FRAME_POINTER_REQUIRED  con-
	      trols whether a target machine supports this flag.

       -finline-functions
	      Integrate	all simple functions into their	callers.  The compiler
	      heuristically  decides  which  functions are simple enough to be
	      worth integrating	in this	way.

	      If all calls to a	given function are integrated, and  the	 func-
	      tion  is	declared static, then GCC normally does	not output the
	      function as assembler code in its	own right.

       -fcaller-saves
	      Enable values to be allocated in registers that  will  be	 clob-
	      bered  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 than would oth-
	      erwise be	produced.

	      This option is enabled by	default	on certain  machines,  usually
	      those which have no call-preserved registers to use instead.

       -fkeep-inline-functions
	      Even  if	all  calls to a	given function are integrated, and the
	      function is declared static, nevertheless	output a separate run-
	      time callable version of the function.

       -fno-function-cse
	      Do not put function addresses in registers; make	each  instruc-
	      tion  that  calls	a constant function contain the	function's ad-
	      dress explicitly.

	      This option results in less efficient  code,  but	 some  strange
	      hacks that alter the assembler output may	be confused by the op-
	      timizations performed when this option is	not used.

       -fno-peephole
	      Disable any machine-specific peephole optimizations.

       -ffast-math
	      This option allows GCC to	violate	some ANSI or IEEE rules/speci-
	      fications	in the interest	of optimizing code for speed.  For ex-
	      ample,  it  allows  the compiler to assume arguments to the sqrt
	      function are non-negative	numbers.

	      This option should never be turned on by any `-O'	 option	 since
	      it  can  result in incorrect output for programs which depend on
	      an exact implementation of IEEE or ANSI rules/specifications for
	      math functions.

       The following options control specific optimizations.  The `-O2'	option
       turns on	all of these optimizations except `-funroll-loops' and	`-fun-
       roll-all-loops'.

       The  `-O'  option  usually  turns  on  the  `-fthread-jumps' and	`-fde-
       layed-branch' options, but specific machines may	change the default op-
       timizations.

       You can use the following flags in the rare cases when "fine-tuning" of
       optimizations to	be performed is	desired.

       -fstrength-reduce
	      Perform the optimizations	of loop	strength reduction and	elimi-
	      nation of	iteration variables.

       -fthread-jumps
	      Perform  optimizations  where we 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 des-
	      tination	of  the	second branch or a point immediately following
	      it, depending on whether the condition is	known to  be  true  or
	      false.

       -funroll-loops
	      Perform  the  optimization of loop unrolling.  This is only done
	      for loops	whose number of	iterations can be determined  at  com-
	      pile time	or run time.

       -funroll-all-loops
	      Perform  the  optimization  of loop unrolling.  This is done for
	      all loops.  This usually makes programs run more slowly.

       -fcse-follow-jumps
	      In common	subexpression elimination, scan	through	jump  instruc-
	      tions  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	will follow the	jump when the condition	tested
	      is false.

       -fcse-skip-blocks
	      This is similar to `-fcse-follow-jumps', but causes CSE to  fol-
	      low  jumps  which	 conditionally skip over blocks.  When CSE en-
	      counters	a  simple  if	statement   with   no	else   clause,
	      `-fcse-skip-blocks'  causes  CSE	to  follow the jump around the
	      body of the if.

       -frerun-cse-after-loop
	      Re-run common subexpression elimination after loop optimizations
	      has been performed.

       -felide-constructors
	      Elide constructors when this seems plausible (C++	 only).	  With
	      this  flag,  GNU C++ initializes y directly from the call	to foo
	      without going through a temporary	in the following code:

	      A	foo ();	A y = foo ();

	      Without this option, GNU C++ first initializes y by calling  the
	      appropriate  constructor	for type A; then assigns the result of
	      foo to a temporary; and, finally,	replaces the initial value  of
	      `y' with the temporary.

	      The default behavior (`-fno-elide-constructors') is specified by
	      the  draft  ANSI	C++  standard.	If your	program's constructors
	      have side	effects, using `-felide-constructors'  can  make  your
	      program  act  differently,  since	 some constructor calls	may be
	      omitted.

       -fexpensive-optimizations
	      Perform a	number of minor	optimizations that are relatively  ex-
	      pensive.

       -fdelayed-branch
	      If supported for the target machine, attempt to reorder instruc-
	      tions  to	 exploit  instruction  slots  available	 after delayed
	      branch instructions.

       -fschedule-insns
	      If supported for the target machine, attempt to reorder instruc-
	      tions 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  instruc-
	      tion is required.

       -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.

TARGET OPTIONS
       By  default, GNU	CC compiles code for the same type of machine that you
       are using.  However, it can also	be installed as	a  cross-compiler,  to
       compile	for  some  other  type of machine.  In fact, several different
       configurations of GNU CC, for different target  machines,  can  be  in-
       stalled	side by	side.  Then you	specify	which one to use with the `-b'
       option.

       In addition, older and newer versions of	GNU CC can be  installed  side
       by  side.   One	of them	(probably the newest) will be the default, but
       you may sometimes wish to use another.

       -b machine
	      The argument machine specifies the target	machine	 for  compila-
	      tion.  This is useful when you have installed GNU	CC as a	cross-
	      compiler.

	      The value	to use for machine is the same as was specified	as the
	      machine  type  when configuring GNU CC as	a cross-compiler.  For
	      example, if a  cross-compiler  was  configured  with  `configure
	      i386v',  meaning	to compile for an 80386	running	System V, then
	      you would	specify	`-b i386v' to run that cross compiler.

	      When you do not specify `-b', it normally	means to  compile  for
	      the same type of machine that you	are using.

       -V version
	      The  argument  version specifies which version of	GNU CC to run.
	      This is useful when multiple versions are	installed.  For	 exam-
	      ple, version might be `2.0', meaning to run GNU CC version 2.0.

	      The default version, when	you do not specify `-V', is controlled
	      by  the way GNU CC is installed.	Normally, it will be a version
	      that is recommended for general use.

MACHINE	DEPENDENT OPTIONS
       Each of the target machine types	can  have  its	own  special  options,
       starting	with `-m', to choose among various hardware models or configu-
       rations--for  example, 68010 vs 68020, floating coprocessor or none.  A
       single installed	version	of the compiler	can compile for	any  model  or
       configuration, according	to the options specified.

       Some configurations of the compiler also	support	additional special op-
       tions,  usually	for command-line compatibility with other compilers on
       the same	platform.

       These are the `-m' options defined for the 68000	series:

       -m68000

       -mc68000
	      Generate output for a 68000.  This is the	default	when the  com-
	      piler is configured for 68000-based systems.

       -m68020

       -mc68020
	      Generate	output for a 68020 (rather than	a 68000).  This	is the
	      default when the compiler	is configured for 68020-based systems.

       -m68881
	      Generate	output	containing  68881  instructions	 for  floating
	      point.   This is the default for most 68020-based	systems	unless
	      -nfp was specified when the compiler was configured.

       -m68030
	      Generate output for a 68030.  This is the	default	when the  com-
	      piler is configured for 68030-based systems.

       -m68040
	      Generate	output for a 68040.  This is the default when the com-
	      piler is configured for 68040-based systems.

       -m68020-40
	      Generate output for a 68040, without using any of	 the  new  in-
	      structions.  This	results	in code	which can run relatively effi-
	      ciently on either	a 68020/68881 or a 68030 or a 68040.

       -mfpa  Generate	output	containing  Sun	 FPA instructions for floating
	      point.

       -msoft-float
	      Generate output containing library  calls	 for  floating	point.
	      WARNING:	the  requisite libraries are not part of GNU CC.  Nor-
	      mally the	facilities of the machine's usual C compiler are used,
	      but this can't be	done directly in cross-compilation.  You  must
	      make your	own arrangements to provide suitable library functions
	      for cross-compilation.

       -mshort
	      Consider type int	to be 16 bits wide, like short int.

       -mnobitfield
	      Do not use the bit-field instructions.  `-m68000'	implies	`-mno-
	      bitfield'.

       -mbitfield
	      Do  use  the  bit-field instructions.  `-m68020' implies `-mbit-
	      field'.  This is the default if you use the unmodified sources.

       -mrtd  Use a different function-calling convention, in which  functions
	      that  take  a  fixed number of arguments return with the rtd in-
	      struction, 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); oth-
	      erwise incorrect code will be generated for calls	to those func-
	      tions.

	      In addition, seriously incorrect code will result	if you call  a
	      function	with  too  many	arguments.  (Normally, extra arguments
	      are harmlessly ignored.)

	      The rtd instruction is supported by the 68010 and	68020  proces-
	      sors, but	not by the 68000.

       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  you
	      will assemble with the GNU assembler.

       -mg    Output  code  for	 g-format floating point numbers instead of d-
	      format.

       These `-m' switches are supported on the	SPARC:

       -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: there is	no GNU floating-point library for SPARC.  Nor-
	      mally 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.

       -mno-epilogue

       -mepilogue
	      With  -mepilogue	(the  default),	the compiler always emits code
	      for function exit	at the end of each function.  Any function ex-
	      it in the	middle of the function (such as	a return statement  in
	      C) will generate a jump to the exit code at the end of the func-
	      tion.

	      With  -mno-epilogue, the compiler	tries to emit exit code	inline
	      at every function	exit.

       -mno-v8

       -mv8

       -msparclite
	      These three options select variations on the SPARC architecture.

	      By default (unless specifically configured for the Fujitsu SPAR-
	      Clite), GCC generates code for the v7 variant of the  SPARC  ar-
	      chitecture.

	      -mv8  will  give you SPARC v8 code.  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.

	      -msparclite will give you	SPARClite code.	 This adds the integer
	      multiply,	integer	divide step and	scan (ffs) instructions	 which
	      exist in SPARClite but not in SPARC v7.

       -mcypress

       -msupersparc
	      These two	options	select the processor for which the code	is op-
	      timized.

	      With  -mcypress  (the  default), the compiler optimizes code for
	      the Cypress CY7C602 chip,	as used	in the SparcStation/SparcServ-
	      er 3xx series. This is also appropriate for the older  SparcSta-
	      tion 1, 2, IPX etc.

	      With -msupersparc	the compiler optimizes code for	the SuperSparc
	      cpu,  as used in the SparcStation	10, 1000 and 2000 series. This
	      flag also	enables	use of the full	SPARC v8 instruction set.

       These `-m' options are defined for the Convex:

       -mc1   Generate output for a C1.	 This is the default when the compiler
	      is configured for	a C1.

       -mc2   Generate output for a C2.	 This is the default when the compiler
	      is configured for	a C2.

       -margcount
	      Generate code which puts an argument count in the	word preceding
	      each argument list.  Some	nonportable Convex  and	 Vax  programs
	      need  this  word.	  (Debuggers  don't, except for	functions with
	      variable-length argument lists; this info	is in the  symbol  ta-
	      ble.)

       -mnoargcount
	      Omit  the	 argument  count word.	This is	the default if you use
	      the unmodified sources.

       These `-m' options are defined for the AMD Am29000:

       -mdw   Generate code that assumes the DW	bit is set,  i.e.,  that  byte
	      and  halfword operations are directly supported by the hardware.
	      This is the default.

       -mnodw Generate code that assumes the DW	bit is not set.

       -mbw   Generate code that assumes the system supports byte and halfword
	      write operations.	 This is the default.

       -mnbw  Generate code that assumes the systems does not support byte and
	      halfword write operations.  This implies `-mnodw'.

       -msmall
	      Use a small memory model that assumes that all function address-
	      es are either within a single 256	KB segment or at  an  absolute
	      address  of less than 256K.  This	allows the call	instruction to
	      be used instead of a const, consth, calli	sequence.

       -mlarge
	      Do not assume that the call instruction can be used; this	is the
	      default.

       -m29050
	      Generate code for	the Am29050.

       -m29000
	      Generate code for	the Am29000.  This is the default.

       -mkernel-registers
	      Generate	references   to	  registers   gr64-gr95	  instead   of
	      gr96-gr127.   This option	can be used when compiling kernel code
	      that wants a set of global registers disjoint from that used  by
	      user-mode	code.

	      Note that	when this option is used, register names in `-f' flags
	      must use the normal, user-mode, names.

       -muser-registers
	      Use the normal set of global registers, gr96-gr127.  This	is the
	      default.

       -mstack-check
	      Insert  a	call to	__msp_check after each stack adjustment.  This
	      is often used for	kernel code.

       These `-m' options are defined for Motorola 88K architectures:

       -m88000
	      Generate code that works well on both the	m88100 and the m88110.

       -m88100
	      Generate code that works best for	the m88100, but	that also runs
	      on the m88110.

       -m88110
	      Generate code that works best for	the m88110, and	may not	run on
	      the m88100.

       -midentify-revision
	      Include an ident directive in the	assembler output recording the
	      source file name,	compiler name and version, timestamp, and com-
	      pilation flags used.

       -mno-underscores
	      In assembler output, emit	symbol names without adding an	under-
	      score  character	at the beginning of each name.	The default is
	      to use an	underscore as prefix on	each name.

       -mno-check-zero-division

       -mcheck-zero-division
	      Early models of the 88K architecture had problems	with  division
	      by zero; in particular, many of them didn't trap.	 Use these op-
	      tions  to	 avoid including (or to	include	explicitly) additional
	      code to detect division by zero and signal  an  exception.   All
	      GCC  configurations  for	the 88K	use `-mcheck-zero-division' by
	      default.

       -mocs-debug-info

       -mno-ocs-debug-info
	      Include (or omit)	additional debugging information (about	regis-
	      ters used	in each	stack frame) as	specified in the 88Open	Object
	      Compatibility Standard, "OCS".  This extra  information  is  not
	      needed by	GDB.  The default for DG/UX, SVr4, and Delta 88	SVr3.2
	      is  to  include  this information; other 88k configurations omit
	      this information by default.

       -mocs-frame-position

       -mno-ocs-frame-position
	      Force (or	do not require)	register values	to be stored in	a par-
	      ticular place in stack frames, as	specified in OCS.  The	DG/UX,
	      Delta88  SVr3.2,	and  BCS configurations	use `-mocs-frame-posi-
	      tion';   other   88k    configurations	have	the    default
	      `-mno-ocs-frame-position'.

       -moptimize-arg-area

       -mno-optimize-arg-area
	      Control how to store function arguments in stack frames.	`-mop-
	      timize-arg-area'	saves space, but may break some	debuggers (not
	      GDB).  `-mno-optimize-arg-area' conforms	better	to  standards.
	      By default GCC does not optimize the argument area.

       -mshort-data-num
	      num  Generate smaller data references by making them relative to
	      r0, which	allows loading a  value	 using	a  single  instruction
	      (rather  than the	usual two).  You control which data references
	      are affected by specifying num with this option.	 For  example,
	      if  you specify `-mshort-data-512', then the data	references af-
	      fected are those involving displacements of less than 512	bytes.
	      `-mshort-data-num' is not	effective for num greater than 64K.

       -mserialize-volatile

       -mno-serialize-volatile
	      Do, or do	not, generate code to guarantee	sequential consistency
	      of volatile memory references.

	      GNU CC always guarantees consistency by default,	for  the  pre-
	      ferred processor submodel.  How this is done depends on the sub-
	      model.

	      The  m88100  processor does not reorder memory references	and so
	      always provides sequential consistency.  If you  use  `-m88100',
	      GNU CC does not generate any special instructions	for sequential
	      consistency.

	      The order	of memory references made by the m88110	processor does
	      not  always match	the order of the instructions requesting those
	      references.  In particular, a load instruction may  execute  be-
	      fore  a  preceding  store	instruction.  Such reordering violates
	      sequential consistency of	volatile memory	references, when there
	      are multiple processors.	When you use `-m88000'	or  `-m88110',
	      GNU CC generates special instructions when appropriate, to force
	      execution	in the proper order.

	      The extra	code generated to guarantee consistency	may affect the
	      performance of your application.	If you know that you can safe-
	      ly forgo this guarantee, you may use the option `-mno-serialize-
	      volatile'.

	      If  you  use the `-m88100' option	but require sequential consis-
	      tency when running on  the  m88110  processor,  you  should  use
	      `-mserialize-volatile'.

       -msvr4

       -msvr3 Turn on (`-msvr4') or off	(`-msvr3') compiler extensions related
	      to System	V release 4 (SVr4).  This controls the following:

	  •   Which variant of the assembler syntax to emit (which you can se-
	      lect independently using `-mversion-03.00').

	  •   `-msvr4' makes the C preprocessor	recognize `#pragma weak'

	  •   `-msvr4'	makes GCC issue	additional declaration directives used
	      in SVr4.

       `-msvr3'	is the default for all m88K  configurations  except  the  SVr4
       configuration.

       -mtrap-large-shift

       -mhandle-large-shift
	      Include  code to detect bit-shifts of more than 31 bits; respec-
	      tively, trap such	shifts or emit code to handle  them  properly.
	      By default GCC makes no special provision	for large bit shifts.

       -muse-div-instruction
	      Very  early  models of the 88K architecture didn't have a	divide
	      instruction, so GCC avoids that  instruction  by	default.   Use
	      this option to specify that it's safe to use the divide instruc-
	      tion.

       -mversion-03.00
	      In the DG/UX configuration, there	are two	flavors	of SVr4.  This
	      option  modifies -msvr4 to select	whether	the hybrid-COFF	or re-
	      al-ELF flavor is used.  All other	configurations ignore this op-
	      tion.

       -mwarn-passed-structs
	      Warn when	a function passes a struct as an argument  or  result.
	      Structure-passing	 conventions have changed during the evolution
	      of the C language, and are often the source of portability prob-
	      lems.  By	default, GCC issues no such warning.

       These options are defined for the IBM RS6000:

       -mfp-in-toc

       -mno-fp-in-toc
	      Control whether or not floating-point constants go in the	 Table
	      of  Contents  (TOC), a table of all global variable and function
	      addresses.  By default GCC puts floating-point constants	there;
	      if  the  TOC overflows, `-mno-fp-in-toc' will reduce the size of
	      the TOC, which may avoid the overflow.

       These `-m' options are defined for the IBM RT PC:

       -min-line-mul
	      Use an in-line code sequence for integer	multiplies.   This  is
	      the default.

       -mcall-lib-mul
	      Call lmul$$ for integer multiples.

       -mfull-fp-blocks
	      Generate	full-size  floating  point  data blocks, including the
	      minimum amount of	scratch	space recommended by IBM.  This	is the
	      default.

       -mminimum-fp-blocks
	      Do not include  extra  scratch  space  in	 floating  point  data
	      blocks.	This  results  in  smaller code, but slower execution,
	      since scratch space must be allocated dynamically.

       -mfp-arg-in-fpregs
	      Use a calling sequence incompatible with the IBM calling conven-
	      tion in which floating point arguments are  passed  in  floating
	      point  registers.	  Note	that  varargs.h	and stdargs.h will not
	      work with	floating point operands	if this	option is specified.

       -mfp-arg-in-gregs
	      Use the normal calling convention	for floating point  arguments.
	      This is the default.

       -mhc-struct-return
	      Return  structures  of more than one word	in memory, rather than
	      in a register.  This provides compatibility  with	 the  MetaWare
	      HighC (hc) compiler.  Use	`-fpcc-struct-return' for compatibili-
	      ty with the Portable C Compiler (pcc).

       -mnohc-struct-return
	      Return  some structures of more than one word in registers, when
	      convenient.  This	is the default.	 For  compatibility  with  the
	      IBM-supplied  compilers,	use  either  `-fpcc-struct-return'  or
	      `-mhc-struct-return'.

       These `-m' options are defined for the MIPS family of computers:

       -mcpu=cpu-type
	      Assume the defaults for the machine type cpu-type	when  schedul-
	      ing  instructions.  The default cpu-type is default, which picks
	      the longest cycles times for any of the machines,	in order  that
	      the  code	 run  at  reasonable  rates  on	all MIPS cpu's.	 Other
	      choices for cpu-type are r2000, r3000, r4000, and	r6000.	 While
	      picking  a  specific cpu-type will schedule things appropriately
	      for that particular chip,	the compiler  will  not	 generate  any
	      code that	does not meet level 1 of the MIPS ISA (instruction set
	      architecture) without the	-mips2 or -mips3 switches being	used.

       -mips2 Issue  instructions from level 2 of the MIPS ISA (branch likely,
	      square  root  instructions).   The  -mcpu=r4000  or  -mcpu=r6000
	      switch must be used in conjunction with -mips2.

       -mips3 Issue instructions from level 3 of the MIPS ISA (64 bit instruc-
	      tions).  The -mcpu=r4000 switch must be used in conjunction with
	      -mips2.

       -mint64

       -mlong64

       -mlonglong128
	      These options don't work at present.

       -mmips-as
	      Generate	code  for the MIPS assembler, and invoke mips-tfile to
	      add normal debug information.  This is the default for all plat-
	      forms  except  for  the  OSF/1  reference	 platform,  using  the
	      OSF/rose	object	format.	  If  any  of  the  -ggdb, -gstabs, or
	      -gstabs+ switches	are used, the mips-tfile program will encapsu-
	      late the stabs within MIPS ECOFF.

       -mgas  Generate code for	the GNU	assembler.  This is the	default	on the
	      OSF/1 reference platform,	using the OSF/rose object format.

       -mrnames

       -mno-rnames
	      The -mrnames switch says to output code using the	MIPS  software
	      names  for  the registers, instead of the	hardware names (ie, a0
	      instead of $4).  The GNU assembler does not support the -mrnames
	      switch, and the MIPS assembler will be  instructed  to  run  the
	      MIPS  C  preprocessor  over  the	source	file.  The -mno-rnames
	      switch is	default.

       -mgpopt

       -mno-gpopt
	      The -mgpopt switch says to write all of  the  data  declarations
	      before the instructions in the text section, to all the MIPS as-
	      sembler  to generate one word memory references instead of using
	      two words	for short global or static data	items.	This is	on  by
	      default if optimization is selected.

       -mstats

       -mno-stats
	      For each non-inline function processed, the -mstats switch caus-
	      es  the  compiler	to emit	one line to the	standard error file to
	      print statistics about the program (number of  registers	saved,
	      stack size, etc.).

       -mmemcpy

       -mno-memcpy
	      The  -mmemcpy  switch makes all block moves call the appropriate
	      string function (memcpy or bcopy)	instead	of possibly generating
	      inline code.

       -mmips-tfile

       -mno-mips-tfile
	      The -mno-mips-tfile switch causes	the compiler  not  postprocess
	      the  object file with the	mips-tfile program, after the MIPS as-
	      sembler has generated it to add debug support.  If mips-tfile is
	      not run, then no local variables will be available to the	debug-
	      ger.  In addition, stage2	and stage3 objects will	have the  tem-
	      porary file names	passed to the assembler	embedded in the	object
	      file, which means	the objects will not compare the same.

       -msoft-float
	      Generate	output	containing  library  calls for floating	point.
	      WARNING: the requisite libraries are not part of GNU  CC.	  Nor-
	      mally the	facilities of the machine's usual C compiler are used,
	      but  this	can't be done directly in cross-compilation.  You must
	      make your	own arrangements to provide suitable library functions
	      for cross-compilation.

       -mhard-float
	      Generate output containing floating point	instructions.  This is
	      the default if you use the unmodified sources.

       -mfp64 Assume that the FR bit in	the status word	is on, and that	 there
	      are  32  64-bit  floating	 point registers, instead of 32	32-bit
	      floating point registers.	 You must also specify the -mcpu=r4000
	      and -mips3 switches.

       -mfp32 Assume that there	are 32 32-bit floating point registers.	  This
	      is the default.

       -mabicalls

       -mno-abicalls
	      Emit  (or	 do  not  emit)	the .abicalls, .cpload,	and .cprestore
	      pseudo operations	that some System V.4 ports  use	 for  position
	      independent code.

       -mhalf-pic

       -mno-half-pic
	      The  -mhalf-pic switch says to put pointers to extern references
	      into the data section and	load them up, rather than put the ref-
	      erences in the text section.   This  option  does	 not  work  at
	      present.	 -Gnum	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.  This allows the assembler to emit
	      one word memory  reference  instructions	based  on  the	global
	      pointer  (gp  or $28), instead of	the normal two words used.  By
	      default, num is 8	when the MIPS assembler	is used,  and  0  when
	      the  GNU	assembler is used.  The	-Gnum switch is	also passed to
	      the assembler and	linker.	 All modules should be	compiled  with
	      the same -Gnum value.

       -nocpp Tell  the	 MIPS  assembler to not	run its	preprocessor over user
	      assembler	files (with a `.s' suffix) when	assembling them.

       These `-m' options are defined for the Intel 80386 family of computers:

       -m486

       -mno-486
	      Control whether or not code is optimized for a 486 instead of an
	      386.  Code generated for a 486 will run on a 386 and vice	versa.

       -mpentium
	      Synonym for -mcpu=pentium

       -mpentiumpro
	      Synonym for -mcpu=pentiumpro

       -mcpu=cpu type
	      Assume the defaults for the machine type CPU TYPE	when  schedul-
	      ing  instructions.   The	choices	 for CPU TYPE are: i386, i486,
	      i586 (pentium),  pentium,	 i686  (pentiumpro),  and  pentiumpro.
	      While picking a specific CPU TYPE	will schedule things appropri-
	      ately  for  that particular chip,	the compiler will not generate
	      any code that does not run on the	i386  without  the  -march=cpu
	      type option being	used.

       -march=cpu type
	      Generate instructions for	the machine type CPU TYPE.  The	choic-
	      es for CPU TYPE are: i386, i486, pentium,	and pentiumpro.	 Spec-
	      ifying -march=cpu	type implies -mcpu=cpu type.

       -msoft-float
	      Generate	output	containing  library  calls for floating	point.
	      Warning: the requisite libraries are not part of GNU  CC.	  Nor-
	      mally the	facilities of the machine's usual C compiler are used,
	      but  this	can't 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 re-
	      turned in	ordinary CPU registers instead.

       -mprofiler-epilogue

       -mno-profiler-epilogue
	      Generate extra code to write profile  information	 for  function
	      exits.

       These `-m' options are defined for the HPPA family of computers:

       -mpa-risc-1-0
	      Generate code for	a PA 1.0 processor.

       -mpa-risc-1-1
	      Generate code for	a PA 1.1 processor.

       -mkernel
	      Generate code which is suitable for use in kernels.  Specifical-
	      ly,  avoid add instructions in which one of the arguments	is the
	      DP register; generate addil instructions instead.	 This avoids a
	      rather serious bug in the	HP-UX linker.

       -mshared-libs
	      Generate code that can be	linked against HP-UX shared libraries.
	      This option is not fully function	yet, and is not	on by  default
	      for  any	PA target.  Using this option can cause	incorrect code
	      to be generated by the compiler.

       -mno-shared-libs
	      Don't generate code that	will  be  linked  against  shared  li-
	      braries.	This is	the default for	all PA targets.

       -mlong-calls
	      Generate	code which allows calls	to functions greater than 256K
	      away from	the caller when	the caller and callee are in the  same
	      source  file.  Do	not turn this option on	unless code refuses to
	      link with	"branch	out of range errors from the linker.

       -mdisable-fpregs
	      Prevent floating point registers from being used in any  manner.
	      This  is necessary for compiling kernels which perform lazy con-
	      text switching of	floating point registers.  If you use this op-
	      tion and attempt to perform floating point operations, the  com-
	      piler will abort.

       -mdisable-indexing
	      Prevent  the  compiler  from using indexing address modes.  This
	      avoids some rather obscure problems when compiling MIG generated
	      code under MACH.

       -mtrailing-colon
	      Add a colon to the end of	 label	definitions  (for  ELF	assem-
	      blers).

       These `-m' options are defined for the Intel 80960 family of computers:

       -mcpu-type
	      Assume  the  defaults for	the machine type cpu-type for instruc-
	      tion and addressing-mode availability and	 alignment.   The  de-
	      fault  cpu-type is kb; other choices are ka, mc, ca, cf, sa, and
	      sb.

       -mnumerics

       -msoft-float
	      The -mnumerics option indicates that the processor does  support
	      floating-point  instructions.  The -msoft-float option indicates
	      that floating-point support should not be	assumed.

       -mleaf-procedures

       -mno-leaf-procedures
	      Do (or do	not) attempt to	alter leaf procedures to  be  callable
	      with  the	 bal instruction as well as call.  This	will result in
	      more efficient code for explicit calls when the bal  instruction
	      can  be  substituted  by the assembler or	linker,	but less effi-
	      cient code in other cases, such as calls via function  pointers,
	      or using a linker	that doesn't support this optimization.

       -mtail-call

       -mno-tail-call
	      Do (or do	not) make additional attempts (beyond those of the ma-
	      chine-independent	portions of the	compiler) to optimize tail-re-
	      cursive  calls  into  branches.  You may not want	to do this be-
	      cause the	detection of cases where this is not valid is not  to-
	      tally complete.  The default is -mno-tail-call.

       -mcomplex-addr

       -mno-complex-addr
	      Assume  (or  do not assume) that the use of a complex addressing
	      mode is a	win on this implementation of the i960.	  Complex  ad-
	      dressing	modes  may not be worthwhile on	the K-series, but they
	      definitely are on	the C-series.  The default is currently	-mcom-
	      plex-addr	for all	processors except the CB and CC.

       -mcode-align

       -mno-code-align
	      Align code to 8-byte boundaries for faster  fetching  (or	 don't
	      bother).	 Currently turned on by	default	for C-series implemen-
	      tations only.

       -mic-compat

       -mic2.0-compat

       -mic3.0-compat
	      Enable compatibility with	iC960 v2.0 or v3.0.

       -masm-compat

       -mintel-asm
	      Enable compatibility with	the iC960 assembler.

       -mstrict-align

       -mno-strict-align
	      Do not permit (do	permit)	unaligned accesses.

       -mold-align
	      Enable structure-alignment compatibility with  Intel's  gcc  re-
	      lease  version 1.3 (based	on gcc 1.37).  Currently this is buggy
	      in that #pragma align 1 is always	assumed	as well, and cannot be
	      turned off.

       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 `libgcc1.c' will be 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 will issue	float-
	      ing-point	operations.   If you are compiling for an Alpha	 with-
	      out  floating-point operations, you must ensure that the library
	      is built so as not to call them.

	      Note that	Alpha implementations  without	floating-point	opera-
	      tions are	required to have floating-point	registers.

       -mfp-reg

       -mno-fp-regs
	      Generate code that uses (does not	use) the floating-point	regis-
	      ter  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	float-
	      ing-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.

       These  additional  options are available	on System V Release 4 for com-
       patibility with other compilers on those	systems:

       -G     On SVr4 systems, gcc accepts the option `-G' (and	passes	it  to
	      the  system  linker),  for  compatibility	 with other compilers.
	      However, we suggest you use `-symbolic' or `-shared'  as	appro-
	      priate,  instead	of supplying linker options on the gcc command
	      line.

       -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	speci-
	      fied with	`-l'.  You can separate	directory entries in dirs from
	      one another with colons.

       -Ym,dir
	      Look in the directory dir	to find	the M4 preprocessor.  The  as-
	      sembler uses this	option.

CODE GENERATION	OPTIONS
       These  machine-independent  options  control  the interface conventions
       used in code generation.

       Most of them begin with `-f'.  These options  have  both	 positive  and
       negative	 forms;	 the negative form of `-ffoo' would be `-fno-foo'.  In
       the table below,	only one of the	forms is listed--the one which is  not
       the  default.   You  can	 figure	 out the other form by either removing
       `no-' or	adding it.

       -fnonnull-objects
	      Assume that objects reached through references are not null (C++
	      only).

	      Normally,	GNU C++	makes conservative assumptions	about  objects
	      reached  through	references.   For  example,  the compiler must
	      check that a is not null in code like the	following:

	      obj &a = g (); a.f (2);

	      Checking that references of this sort have non-null  values  re-
	      quires  extra code, however, and it is unnecessary for many pro-
	      grams.  You can use `-fnonnull-objects' to omit the  checks  for
	      null, if your program doesn't require checking.

       -fpcc-struct-return
	      Use  the	same  convention for returning struct and union	values
	      that is used by the usual	C compiler on your system.  This  con-
	      vention  is less efficient for small structures, and on many ma-
	      chines it	fails to be reentrant; but it has the advantage	of al-
	      lowing intercallability between GCC-compiled code	 and  PCC-com-
	      piled code.

       -freg-struct-return
	      Use  the convention that struct and union	values are returned 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-re-
	      turn, GNU	CC defaults to whichever convention  is	 standard  for
	      the target.  If there is no standard convention, GNU CC defaults
	      to -fpcc-struct-return.

       -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
	      will be equivalent to the	smallest integer type which has	enough
	      room.

       -fshort-double
	      Use the same size	for double as for float	.

       -fshared-data
	      Requests	that the data and non-const variables of this compila-
	      tion be shared data rather than private data.   The  distinction
	      makes sense only on certain operating systems, where shared data
	      is shared	between	processes running the same program, while pri-
	      vate data	exists in one copy per process.

       -fno-common
	      Allocate	even uninitialized global variables in the bss section
	      of the object  file,  rather  than  generating  them  as	common
	      blocks.	This  has  the effect that if the same variable	is de-
	      clared (without extern) in two different compilations, you  will
	      get  an error when you link them.	 The only reason this might be
	      useful is	if you wish to verify that the program	will  work  on
	      other systems which always work this way.

       -fno-ident
	      Ignore the `#ident' directive.

       -fno-gnu-linker
	      Do  not  output global initializations (such as C++ constructors
	      and destructors) in the form used	by the GNU linker (on  systems
	      where  the  GNU linker is	the standard method of handling	them).
	      Use this option when you want to use a non-GNU linker, which al-
	      so requires using	the collect2 program to	make sure  the	system
	      linker  includes constructors and	destructors.  (collect2	is in-
	      cluded in	the GNU	CC distribution.)  For systems which must  use
	      collect2,	the compiler driver gcc	is configured to do this auto-
	      matically.

       -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).

       -fvolatile
	      Consider all memory references through pointers to be volatile.

       -fvolatile-global
	      Consider all memory references to	extern and global  data	 items
	      to be volatile.

       -fpic  If supported for the target machines, generate position-indepen-
	      dent code, suitable for use in a shared library.

       -fPIC  If  supported  for the target machine, emit position-independent
	      code, suitable for dynamic linking, even if branches need	 large
	      displacements.

       -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	tempo-
	      raries  or  variables that do not	live across a call.  Functions
	      compiled this way	will not save and restore the register reg.

	      Use of this flag for a register that has a fixed pervasive  role
	      in  the  machine's execution model, such as the stack pointer or
	      frame pointer, will produce 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	 vari-
	      ables that live across a call.  Functions	compiled this way will
	      save and restore the register reg	if they	use it.

	      Use  of this flag	for a register that has	a fixed	pervasive role
	      in the machine's execution model,	such as	the stack  pointer  or
	      frame pointer, will produce disastrous results.

	      A	 different  sort  of disaster will result 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.

PRAGMAS
       Two `#pragma' directives	are supported for GNU C++, to permit using the
       same  header  file for two purposes: as a definition of interfaces to a
       given object class, and as the full definition of the contents of  that
       object class.

       #pragma interface
	      (C++  only.)  Use	this directive in header files that define ob-
	      ject classes, to save space in most of the object	files that use
	      those classes.  Normally,	local copies  of  certain  information
	      (backup  copies  of  inline member functions, debugging informa-
	      tion, and	the internal tables that implement virtual  functions)
	      must  be	kept  in  each object file that	includes class defini-
	      tions.  You can use this pragma to avoid such duplication.  When
	      a	header file containing `#pragma	interface' is  included	 in  a
	      compilation,  this  auxiliary  information will not be generated
	      (unless the main input source file itself	uses  `#pragma	imple-
	      mentation').   Instead, the object files will contain references
	      to be resolved at	link time.

       #pragma implementation

       #pragma implementation "objects.h"
	      (C++ only.)  Use this pragma in a	main input file, when you want
	      full output from included	header files to	be generated (and made
	      globally visible).  The included header file,  in	 turn,	should
	      use  `#pragma  interface'.  Backup copies	of inline member func-
	      tions, debugging information, and	the internal  tables  used  to
	      implement	 virtual functions are all generated in	implementation
	      files.

	      If you use `#pragma implementation' with no argument, it applies
	      to an include file with the same basename	as your	 source	 file;
	      for  example,  in	`allclass.cc', `#pragma	implementation'	by it-
	      self is equivalent  to  `#pragma	implementation	"allclass.h"'.
	      Use the string argument if you want a single implementation file
	      to include code from multiple header files.

	      There is no way to split up the contents of a single header file
	      into multiple implementation files.

FILES
       file.c		  C source file
       file.h		  C header (preprocessor) file
       file.i		  preprocessed C source	file
       file.C		  C++ source file
       file.cc		  C++ source file
       file.cxx		  C++ source file
       file.m		  Objective-C source file
       file.s		  assembly language file
       file.o		  object file
       a.out		  link edited output
       TMPDIR/cc*	  temporary files
       LIBDIR/cpp	  preprocessor
       LIBDIR/cc1	  compiler for C
       LIBDIR/cc1plus	  compiler for C++
       LIBDIR/collect	  linker front end needed on some machines
       LIBDIR/libgcc.a	  GCC subroutine library
       /lib/crt[01n].o	  start-up routine
       LIBDIR/ccrt0	  additional start-up routine for C++
       /lib/libc.a	  standard C library, see
       intro(3)
       /usr/include	  standard directory for #include files
       LIBDIR/include	  standard gcc directory for #include files
       LIBDIR/g++-include additional g++ directory for #include

       LIBDIR is usually /usr/local/lib/machine/version.
       TMPDIR  comes from the environment variable TMPDIR (default /usr/tmp if
       available, else /tmp).

SEE ALSO
       as(1), cpp(1), gdb(1), ld(1)
       `gcc', `cpp', `as', `ld', and `gdb' entries in info.
       Using and Porting GNU CC	(for version 2.0), Richard M. Stallman;	The  C
       Preprocessor,  Richard M. Stallman; Debugging with GDB: the GNU Source-
       Level Debugger, Richard M. Stallman and Roland H. Pesch;	Using as:  the
       GNU Assembler, Dean Elsner, Jay Fenlason	& friends; ld: the GNU linker,
       Steve Chamberlain and Roland Pesch.

BUGS
       For instructions	on reporting bugs, see the GCC manual.

COPYING
       Copyright 1991, 1992, 1993 Free Software	Foundation, Inc.

       Permission  is  granted	to make	and distribute verbatim	copies of this
       manual provided the copyright notice and	 this  permission  notice  are
       preserved on all	copies.

       Permission  is granted to copy and distribute modified versions of this
       manual under the	conditions for verbatim	copying, provided that the en-
       tire resulting derived work is distributed under	the terms of a permis-
       sion notice identical to	this one.

       Permission is granted to	copy and distribute translations of this manu-
       al into another language, under the above conditions for	modified  ver-
       sions,  except  that this permission notice may be included in transla-
       tions approved by the Free Software Foundation instead of in the	origi-
       nal English.

AUTHORS
       See the GNU CC Manual for the contributors to GNU CC.

GNU Tools			  1998/12/16				GCC(1)
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