3 @settitle The C Preprocessor
9 @include gcc-common.texi
12 @c man begin COPYRIGHT
13 Copyright @copyright{} 1987-2018 Free Software Foundation, Inc.
15 Permission is granted to copy, distribute and/or modify this document
16 under the terms of the GNU Free Documentation License, Version 1.3 or
17 any later version published by the Free Software Foundation. A copy of
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22 @c man begin COPYRIGHT
27 @c man begin COPYRIGHT
28 This manual contains no Invariant Sections. The Front-Cover Texts are
29 (a) (see below), and the Back-Cover Texts are (b) (see below).
31 (a) The FSF's Front-Cover Text is:
35 (b) The FSF's Back-Cover Text is:
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43 @c Create a separate index for command line options.
47 @c Used in cppopts.texi and cppenv.texi.
51 @dircategory Software development
53 * Cpp: (cpp). The GNU C preprocessor.
58 @title The C Preprocessor
60 @author Richard M. Stallman, Zachary Weinberg
62 @c There is a fill at the bottom of the page, so we need a filll to
64 @vskip 0pt plus 1filll
73 The C preprocessor implements the macro language used to transform C,
74 C++, and Objective-C programs before they are compiled. It can also be
86 * Preprocessor Output::
88 * Implementation Details::
90 * Environment Variables::
91 * GNU Free Documentation License::
92 * Index of Directives::
97 --- The Detailed Node Listing ---
102 * Initial processing::
104 * The preprocessing language::
109 * Include Operation::
111 * Once-Only Headers::
112 * Alternatives to Wrapper #ifndef::
113 * Computed Includes::
119 * Object-like Macros::
120 * Function-like Macros::
125 * Predefined Macros::
126 * Undefining and Redefining Macros::
127 * Directives Within Macro Arguments::
132 * Standard Predefined Macros::
133 * Common Predefined Macros::
134 * System-specific Predefined Macros::
135 * C++ Named Operators::
140 * Operator Precedence Problems::
141 * Swallowing the Semicolon::
142 * Duplication of Side Effects::
143 * Self-Referential Macros::
145 * Newlines in Arguments::
150 * Conditional Syntax::
161 Implementation Details
163 * Implementation-defined behavior::
164 * Implementation limits::
165 * Obsolete Features::
169 * Obsolete Features::
179 @c man begin DESCRIPTION
180 The C preprocessor, often known as @dfn{cpp}, is a @dfn{macro processor}
181 that is used automatically by the C compiler to transform your program
182 before compilation. It is called a macro processor because it allows
183 you to define @dfn{macros}, which are brief abbreviations for longer
186 The C preprocessor is intended to be used only with C, C++, and
187 Objective-C source code. In the past, it has been abused as a general
188 text processor. It will choke on input which does not obey C's lexical
189 rules. For example, apostrophes will be interpreted as the beginning of
190 character constants, and cause errors. Also, you cannot rely on it
191 preserving characteristics of the input which are not significant to
192 C-family languages. If a Makefile is preprocessed, all the hard tabs
193 will be removed, and the Makefile will not work.
195 Having said that, you can often get away with using cpp on things which
196 are not C@. Other Algol-ish programming languages are often safe
197 (Pascal, Ada, etc.) So is assembly, with caution. @option{-traditional-cpp}
198 mode preserves more white space, and is otherwise more permissive. Many
199 of the problems can be avoided by writing C or C++ style comments
200 instead of native language comments, and keeping macros simple.
202 Wherever possible, you should use a preprocessor geared to the language
203 you are writing in. Modern versions of the GNU assembler have macro
204 facilities. Most high level programming languages have their own
205 conditional compilation and inclusion mechanism. If all else fails,
206 try a true general text processor, such as GNU M4.
208 C preprocessors vary in some details. This manual discusses the GNU C
209 preprocessor, which provides a small superset of the features of ISO
210 Standard C@. In its default mode, the GNU C preprocessor does not do a
211 few things required by the standard. These are features which are
212 rarely, if ever, used, and may cause surprising changes to the meaning
213 of a program which does not expect them. To get strict ISO Standard C,
214 you should use the @option{-std=c90}, @option{-std=c99},
215 @option{-std=c11} or @option{-std=c17} options, depending
216 on which version of the standard you want. To get all the mandatory
217 diagnostics, you must also use @option{-pedantic}. @xref{Invocation}.
219 This manual describes the behavior of the ISO preprocessor. To
220 minimize gratuitous differences, where the ISO preprocessor's
221 behavior does not conflict with traditional semantics, the
222 traditional preprocessor should behave the same way. The various
223 differences that do exist are detailed in the section @ref{Traditional
226 For clarity, unless noted otherwise, references to @samp{CPP} in this
227 manual refer to GNU CPP@.
232 * Initial processing::
234 * The preprocessing language::
238 @section Character sets
240 Source code character set processing in C and related languages is
241 rather complicated. The C standard discusses two character sets, but
242 there are really at least four.
244 The files input to CPP might be in any character set at all. CPP's
245 very first action, before it even looks for line boundaries, is to
246 convert the file into the character set it uses for internal
247 processing. That set is what the C standard calls the @dfn{source}
248 character set. It must be isomorphic with ISO 10646, also known as
249 Unicode. CPP uses the UTF-8 encoding of Unicode.
251 The character sets of the input files are specified using the
252 @option{-finput-charset=} option.
254 All preprocessing work (the subject of the rest of this manual) is
255 carried out in the source character set. If you request textual
256 output from the preprocessor with the @option{-E} option, it will be
259 After preprocessing is complete, string and character constants are
260 converted again, into the @dfn{execution} character set. This
261 character set is under control of the user; the default is UTF-8,
262 matching the source character set. Wide string and character
263 constants have their own character set, which is not called out
264 specifically in the standard. Again, it is under control of the user.
265 The default is UTF-16 or UTF-32, whichever fits in the target's
266 @code{wchar_t} type, in the target machine's byte
267 order.@footnote{UTF-16 does not meet the requirements of the C
268 standard for a wide character set, but the choice of 16-bit
269 @code{wchar_t} is enshrined in some system ABIs so we cannot fix
270 this.} Octal and hexadecimal escape sequences do not undergo
271 conversion; @t{'\x12'} has the value 0x12 regardless of the currently
272 selected execution character set. All other escapes are replaced by
273 the character in the source character set that they represent, then
274 converted to the execution character set, just like unescaped
277 In identifiers, characters outside the ASCII range can only be
278 specified with the @samp{\u} and @samp{\U} escapes, not used
279 directly. If strict ISO C90 conformance is specified with an option
280 such as @option{-std=c90}, or @option{-fno-extended-identifiers} is
281 used, then those escapes are not permitted in identifiers.
283 @node Initial processing
284 @section Initial processing
286 The preprocessor performs a series of textual transformations on its
287 input. These happen before all other processing. Conceptually, they
288 happen in a rigid order, and the entire file is run through each
289 transformation before the next one begins. CPP actually does them
290 all at once, for performance reasons. These transformations correspond
291 roughly to the first three ``phases of translation'' described in the C
297 The input file is read into memory and broken into lines.
299 Different systems use different conventions to indicate the end of a
300 line. GCC accepts the ASCII control sequences @kbd{LF}, @kbd{@w{CR
301 LF}} and @kbd{CR} as end-of-line markers. These are the canonical
302 sequences used by Unix, DOS and VMS, and the classic Mac OS (before
303 OSX) respectively. You may therefore safely copy source code written
304 on any of those systems to a different one and use it without
305 conversion. (GCC may lose track of the current line number if a file
306 doesn't consistently use one convention, as sometimes happens when it
307 is edited on computers with different conventions that share a network
310 If the last line of any input file lacks an end-of-line marker, the end
311 of the file is considered to implicitly supply one. The C standard says
312 that this condition provokes undefined behavior, so GCC will emit a
317 @anchor{trigraphs}If trigraphs are enabled, they are replaced by their
318 corresponding single characters. By default GCC ignores trigraphs,
319 but if you request a strictly conforming mode with the @option{-std}
320 option, or you specify the @option{-trigraphs} option, then it
323 These are nine three-character sequences, all starting with @samp{??},
324 that are defined by ISO C to stand for single characters. They permit
325 obsolete systems that lack some of C's punctuation to use C@. For
326 example, @samp{??/} stands for @samp{\}, so @t{'??/n'} is a character
327 constant for a newline.
329 Trigraphs are not popular and many compilers implement them
330 incorrectly. Portable code should not rely on trigraphs being either
331 converted or ignored. With @option{-Wtrigraphs} GCC will warn you
332 when a trigraph may change the meaning of your program if it were
333 converted. @xref{Wtrigraphs}.
335 In a string constant, you can prevent a sequence of question marks
336 from being confused with a trigraph by inserting a backslash between
337 the question marks, or by separating the string literal at the
338 trigraph and making use of string literal concatenation. @t{"(??\?)"}
339 is the string @samp{(???)}, not @samp{(?]}. Traditional C compilers
340 do not recognize these idioms.
342 The nine trigraphs and their replacements are
345 Trigraph: ??( ??) ??< ??> ??= ??/ ??' ??! ??-
346 Replacement: [ ] @{ @} # \ ^ | ~
350 @cindex continued lines
351 @cindex backslash-newline
352 Continued lines are merged into one long line.
354 A continued line is a line which ends with a backslash, @samp{\}. The
355 backslash is removed and the following line is joined with the current
356 one. No space is inserted, so you may split a line anywhere, even in
357 the middle of a word. (It is generally more readable to split lines
358 only at white space.)
360 The trailing backslash on a continued line is commonly referred to as a
361 @dfn{backslash-newline}.
363 If there is white space between a backslash and the end of a line, that
364 is still a continued line. However, as this is usually the result of an
365 editing mistake, and many compilers will not accept it as a continued
366 line, GCC will warn you about it.
370 @cindex line comments
371 @cindex block comments
372 All comments are replaced with single spaces.
374 There are two kinds of comments. @dfn{Block comments} begin with
375 @samp{/*} and continue until the next @samp{*/}. Block comments do not
379 /* @r{this is} /* @r{one comment} */ @r{text outside comment}
382 @dfn{Line comments} begin with @samp{//} and continue to the end of the
383 current line. Line comments do not nest either, but it does not matter,
384 because they would end in the same place anyway.
387 // @r{this is} // @r{one comment}
388 @r{text outside comment}
392 It is safe to put line comments inside block comments, or vice versa.
397 // @r{contains line comment}
399 */ @r{outside comment}
401 // @r{line comment} /* @r{contains block comment} */
405 But beware of commenting out one end of a block comment with a line
410 // @r{l.c.} /* @r{block comment begins}
411 @r{oops! this isn't a comment anymore} */
415 Comments are not recognized within string literals.
416 @t{@w{"/* blah */"}} is the string constant @samp{@w{/* blah */}}, not
419 Line comments are not in the 1989 edition of the C standard, but they
420 are recognized by GCC as an extension. In C++ and in the 1999 edition
421 of the C standard, they are an official part of the language.
423 Since these transformations happen before all other processing, you can
424 split a line mechanically with backslash-newline anywhere. You can
425 comment out the end of a line. You can continue a line comment onto the
426 next line with backslash-newline. You can even split @samp{/*},
427 @samp{*/}, and @samp{//} onto multiple lines with backslash-newline.
443 is equivalent to @code{@w{#define FOO 1020}}. All these tricks are
444 extremely confusing and should not be used in code intended to be
447 There is no way to prevent a backslash at the end of a line from being
448 interpreted as a backslash-newline. This cannot affect any correct
452 @section Tokenization
455 @cindex preprocessing tokens
456 After the textual transformations are finished, the input file is
457 converted into a sequence of @dfn{preprocessing tokens}. These mostly
458 correspond to the syntactic tokens used by the C compiler, but there are
459 a few differences. White space separates tokens; it is not itself a
460 token of any kind. Tokens do not have to be separated by white space,
461 but it is often necessary to avoid ambiguities.
463 When faced with a sequence of characters that has more than one possible
464 tokenization, the preprocessor is greedy. It always makes each token,
465 starting from the left, as big as possible before moving on to the next
466 token. For instance, @code{a+++++b} is interpreted as
467 @code{@w{a ++ ++ + b}}, not as @code{@w{a ++ + ++ b}}, even though the
468 latter tokenization could be part of a valid C program and the former
471 Once the input file is broken into tokens, the token boundaries never
472 change, except when the @samp{##} preprocessing operator is used to paste
473 tokens together. @xref{Concatenation}. For example,
485 The compiler does not re-tokenize the preprocessor's output. Each
486 preprocessing token becomes one compiler token.
489 Preprocessing tokens fall into five broad classes: identifiers,
490 preprocessing numbers, string literals, punctuators, and other. An
491 @dfn{identifier} is the same as an identifier in C: any sequence of
492 letters, digits, or underscores, which begins with a letter or
493 underscore. Keywords of C have no significance to the preprocessor;
494 they are ordinary identifiers. You can define a macro whose name is a
495 keyword, for instance. The only identifier which can be considered a
496 preprocessing keyword is @code{defined}. @xref{Defined}.
498 This is mostly true of other languages which use the C preprocessor.
499 However, a few of the keywords of C++ are significant even in the
500 preprocessor. @xref{C++ Named Operators}.
502 In the 1999 C standard, identifiers may contain letters which are not
503 part of the ``basic source character set'', at the implementation's
504 discretion (such as accented Latin letters, Greek letters, or Chinese
505 ideograms). This may be done with an extended character set, or the
506 @samp{\u} and @samp{\U} escape sequences. GCC only accepts such
507 characters in the @samp{\u} and @samp{\U} forms.
509 As an extension, GCC treats @samp{$} as a letter. This is for
510 compatibility with some systems, such as VMS, where @samp{$} is commonly
511 used in system-defined function and object names. @samp{$} is not a
512 letter in strictly conforming mode, or if you specify the @option{-$}
513 option. @xref{Invocation}.
516 @cindex preprocessing numbers
517 A @dfn{preprocessing number} has a rather bizarre definition. The
518 category includes all the normal integer and floating point constants
519 one expects of C, but also a number of other things one might not
520 initially recognize as a number. Formally, preprocessing numbers begin
521 with an optional period, a required decimal digit, and then continue
522 with any sequence of letters, digits, underscores, periods, and
523 exponents. Exponents are the two-character sequences @samp{e+},
524 @samp{e-}, @samp{E+}, @samp{E-}, @samp{p+}, @samp{p-}, @samp{P+}, and
525 @samp{P-}. (The exponents that begin with @samp{p} or @samp{P} are
526 used for hexadecimal floating-point constants.)
528 The purpose of this unusual definition is to isolate the preprocessor
529 from the full complexity of numeric constants. It does not have to
530 distinguish between lexically valid and invalid floating-point numbers,
531 which is complicated. The definition also permits you to split an
532 identifier at any position and get exactly two tokens, which can then be
533 pasted back together with the @samp{##} operator.
535 It's possible for preprocessing numbers to cause programs to be
536 misinterpreted. For example, @code{0xE+12} is a preprocessing number
537 which does not translate to any valid numeric constant, therefore a
538 syntax error. It does not mean @code{@w{0xE + 12}}, which is what you
541 @cindex string literals
542 @cindex string constants
543 @cindex character constants
544 @cindex header file names
545 @c the @: prevents makeinfo from turning '' into ".
546 @dfn{String literals} are string constants, character constants, and
547 header file names (the argument of @samp{#include}).@footnote{The C
548 standard uses the term @dfn{string literal} to refer only to what we are
549 calling @dfn{string constants}.} String constants and character
550 constants are straightforward: @t{"@dots{}"} or @t{'@dots{}'}. In
551 either case embedded quotes should be escaped with a backslash:
552 @t{'\'@:'} is the character constant for @samp{'}. There is no limit on
553 the length of a character constant, but the value of a character
554 constant that contains more than one character is
555 implementation-defined. @xref{Implementation Details}.
557 Header file names either look like string constants, @t{"@dots{}"}, or are
558 written with angle brackets instead, @t{<@dots{}>}. In either case,
559 backslash is an ordinary character. There is no way to escape the
560 closing quote or angle bracket. The preprocessor looks for the header
561 file in different places depending on which form you use. @xref{Include
564 No string literal may extend past the end of a line. You may use continued
565 lines instead, or string constant concatenation.
569 @cindex alternative tokens
570 @dfn{Punctuators} are all the usual bits of punctuation which are
571 meaningful to C and C++. All but three of the punctuation characters in
572 ASCII are C punctuators. The exceptions are @samp{@@}, @samp{$}, and
573 @samp{`}. In addition, all the two- and three-character operators are
574 punctuators. There are also six @dfn{digraphs}, which the C++ standard
575 calls @dfn{alternative tokens}, which are merely alternate ways to spell
576 other punctuators. This is a second attempt to work around missing
577 punctuation in obsolete systems. It has no negative side effects,
578 unlike trigraphs, but does not cover as much ground. The digraphs and
579 their corresponding normal punctuators are:
582 Digraph: <% %> <: :> %: %:%:
583 Punctuator: @{ @} [ ] # ##
587 Any other single character is considered ``other''. It is passed on to
588 the preprocessor's output unmolested. The C compiler will almost
589 certainly reject source code containing ``other'' tokens. In ASCII, the
590 only other characters are @samp{@@}, @samp{$}, @samp{`}, and control
591 characters other than NUL (all bits zero). (Note that @samp{$} is
592 normally considered a letter.) All characters with the high bit set
593 (numeric range 0x7F--0xFF) are also ``other'' in the present
594 implementation. This will change when proper support for international
595 character sets is added to GCC@.
597 NUL is a special case because of the high probability that its
598 appearance is accidental, and because it may be invisible to the user
599 (many terminals do not display NUL at all). Within comments, NULs are
600 silently ignored, just as any other character would be. In running
601 text, NUL is considered white space. For example, these two directives
602 have the same meaning.
610 (where @samp{^@@} is ASCII NUL)@. Within string or character constants,
611 NULs are preserved. In the latter two cases the preprocessor emits a
614 @node The preprocessing language
615 @section The preprocessing language
617 @cindex preprocessing directives
618 @cindex directive line
619 @cindex directive name
621 After tokenization, the stream of tokens may simply be passed straight
622 to the compiler's parser. However, if it contains any operations in the
623 @dfn{preprocessing language}, it will be transformed first. This stage
624 corresponds roughly to the standard's ``translation phase 4'' and is
625 what most people think of as the preprocessor's job.
627 The preprocessing language consists of @dfn{directives} to be executed
628 and @dfn{macros} to be expanded. Its primary capabilities are:
632 Inclusion of header files. These are files of declarations that can be
633 substituted into your program.
636 Macro expansion. You can define @dfn{macros}, which are abbreviations
637 for arbitrary fragments of C code. The preprocessor will replace the
638 macros with their definitions throughout the program. Some macros are
639 automatically defined for you.
642 Conditional compilation. You can include or exclude parts of the
643 program according to various conditions.
646 Line control. If you use a program to combine or rearrange source files
647 into an intermediate file which is then compiled, you can use line
648 control to inform the compiler where each source line originally came
652 Diagnostics. You can detect problems at compile time and issue errors
656 There are a few more, less useful, features.
658 Except for expansion of predefined macros, all these operations are
659 triggered with @dfn{preprocessing directives}. Preprocessing directives
660 are lines in your program that start with @samp{#}. Whitespace is
661 allowed before and after the @samp{#}. The @samp{#} is followed by an
662 identifier, the @dfn{directive name}. It specifies the operation to
663 perform. Directives are commonly referred to as @samp{#@var{name}}
664 where @var{name} is the directive name. For example, @samp{#define} is
665 the directive that defines a macro.
667 The @samp{#} which begins a directive cannot come from a macro
668 expansion. Also, the directive name is not macro expanded. Thus, if
669 @code{foo} is defined as a macro expanding to @code{define}, that does
670 not make @samp{#foo} a valid preprocessing directive.
672 The set of valid directive names is fixed. Programs cannot define new
673 preprocessing directives.
675 Some directives require arguments; these make up the rest of the
676 directive line and must be separated from the directive name by
677 whitespace. For example, @samp{#define} must be followed by a macro
678 name and the intended expansion of the macro.
680 A preprocessing directive cannot cover more than one line. The line
681 may, however, be continued with backslash-newline, or by a block comment
682 which extends past the end of the line. In either case, when the
683 directive is processed, the continuations have already been merged with
684 the first line to make one long line.
687 @chapter Header Files
690 A header file is a file containing C declarations and macro definitions
691 (@pxref{Macros}) to be shared between several source files. You request
692 the use of a header file in your program by @dfn{including} it, with the
693 C preprocessing directive @samp{#include}.
695 Header files serve two purposes.
699 @cindex system header files
700 System header files declare the interfaces to parts of the operating
701 system. You include them in your program to supply the definitions and
702 declarations you need to invoke system calls and libraries.
705 Your own header files contain declarations for interfaces between the
706 source files of your program. Each time you have a group of related
707 declarations and macro definitions all or most of which are needed in
708 several different source files, it is a good idea to create a header
712 Including a header file produces the same results as copying the header
713 file into each source file that needs it. Such copying would be
714 time-consuming and error-prone. With a header file, the related
715 declarations appear in only one place. If they need to be changed, they
716 can be changed in one place, and programs that include the header file
717 will automatically use the new version when next recompiled. The header
718 file eliminates the labor of finding and changing all the copies as well
719 as the risk that a failure to find one copy will result in
720 inconsistencies within a program.
722 In C, the usual convention is to give header files names that end with
723 @file{.h}. It is most portable to use only letters, digits, dashes, and
724 underscores in header file names, and at most one dot.
728 * Include Operation::
730 * Once-Only Headers::
731 * Alternatives to Wrapper #ifndef::
732 * Computed Includes::
738 @section Include Syntax
741 Both user and system header files are included using the preprocessing
742 directive @samp{#include}. It has two variants:
745 @item #include <@var{file}>
746 This variant is used for system header files. It searches for a file
747 named @var{file} in a standard list of system directories. You can prepend
748 directories to this list with the @option{-I} option (@pxref{Invocation}).
750 @item #include "@var{file}"
751 This variant is used for header files of your own program. It
752 searches for a file named @var{file} first in the directory containing
753 the current file, then in the quote directories and then the same
754 directories used for @code{<@var{file}>}. You can prepend directories
755 to the list of quote directories with the @option{-iquote} option.
758 The argument of @samp{#include}, whether delimited with quote marks or
759 angle brackets, behaves like a string constant in that comments are not
760 recognized, and macro names are not expanded. Thus, @code{@w{#include
761 <x/*y>}} specifies inclusion of a system header file named @file{x/*y}.
763 However, if backslashes occur within @var{file}, they are considered
764 ordinary text characters, not escape characters. None of the character
765 escape sequences appropriate to string constants in C are processed.
766 Thus, @code{@w{#include "x\n\\y"}} specifies a filename containing three
767 backslashes. (Some systems interpret @samp{\} as a pathname separator.
768 All of these also interpret @samp{/} the same way. It is most portable
769 to use only @samp{/}.)
771 It is an error if there is anything (other than comments) on the line
774 @node Include Operation
775 @section Include Operation
777 The @samp{#include} directive works by directing the C preprocessor to
778 scan the specified file as input before continuing with the rest of the
779 current file. The output from the preprocessor contains the output
780 already generated, followed by the output resulting from the included
781 file, followed by the output that comes from the text after the
782 @samp{#include} directive. For example, if you have a header file
783 @file{header.h} as follows,
790 and a main program called @file{program.c} that uses the header file,
805 the compiler will see the same token stream as it would if
806 @file{program.c} read
819 Included files are not limited to declarations and macro definitions;
820 those are merely the typical uses. Any fragment of a C program can be
821 included from another file. The include file could even contain the
822 beginning of a statement that is concluded in the containing file, or
823 the end of a statement that was started in the including file. However,
824 an included file must consist of complete tokens. Comments and string
825 literals which have not been closed by the end of an included file are
826 invalid. For error recovery, they are considered to end at the end of
829 To avoid confusion, it is best if header files contain only complete
830 syntactic units---function declarations or definitions, type
833 The line following the @samp{#include} directive is always treated as a
834 separate line by the C preprocessor, even if the included file lacks a
840 By default, the preprocessor looks for header files included by the quote
841 form of the directive @code{@w{#include "@var{file}"}} first relative to
842 the directory of the current file, and then in a preconfigured list
843 of standard system directories.
844 For example, if @file{/usr/include/sys/stat.h} contains
845 @code{@w{#include "types.h"}}, GCC looks for @file{types.h} first in
846 @file{/usr/include/sys}, then in its usual search path.
848 For the angle-bracket form @code{@w{#include <@var{file}>}}, the
849 preprocessor's default behavior is to look only in the standard system
850 directories. The exact search directory list depends on the target
851 system, how GCC is configured, and where it is installed. You can
852 find the default search directory list for your version of CPP by
853 invoking it with the @option{-v} option. For example,
856 cpp -v /dev/null -o /dev/null
859 There are a number of command-line options you can use to add
860 additional directories to the search path.
861 The most commonly-used option is @option{-I@var{dir}}, which causes
862 @var{dir} to be searched after the current directory (for the quote
863 form of the directive) and ahead of the standard system directories.
864 You can specify multiple @option{-I} options on the command line,
865 in which case the directories are searched in left-to-right order.
867 If you need separate control over the search paths for the quote and
868 angle-bracket forms of the @samp{#include} directive, you can use the
869 @option{-iquote} and/or @option{-isystem} options instead of @option{-I}.
870 @xref{Invocation}, for a detailed description of these options, as
871 well as others that are less generally useful.
873 If you specify other options on the command line, such as @option{-I},
874 that affect where the preprocessor searches for header files, the
875 directory list printed by the @option{-v} option reflects the actual
876 search path used by the preprocessor.
878 Note that you can also prevent the preprocessor from searching any of
879 the default system header directories with the @option{-nostdinc}
880 option. This is useful when you are compiling an operating system
881 kernel or some other program that does not use the standard C library
882 facilities, or the standard C library itself.
884 @node Once-Only Headers
885 @section Once-Only Headers
886 @cindex repeated inclusion
887 @cindex including just once
888 @cindex wrapper @code{#ifndef}
890 If a header file happens to be included twice, the compiler will process
891 its contents twice. This is very likely to cause an error, e.g.@: when the
892 compiler sees the same structure definition twice. Even if it does not,
893 it will certainly waste time.
895 The standard way to prevent this is to enclose the entire real contents
896 of the file in a conditional, like this:
901 #ifndef FILE_FOO_SEEN
902 #define FILE_FOO_SEEN
904 @var{the entire file}
906 #endif /* !FILE_FOO_SEEN */
910 This construct is commonly known as a @dfn{wrapper #ifndef}.
911 When the header is included again, the conditional will be false,
912 because @code{FILE_FOO_SEEN} is defined. The preprocessor will skip
913 over the entire contents of the file, and the compiler will not see it
916 CPP optimizes even further. It remembers when a header file has a
917 wrapper @samp{#ifndef}. If a subsequent @samp{#include} specifies that
918 header, and the macro in the @samp{#ifndef} is still defined, it does
919 not bother to rescan the file at all.
921 You can put comments outside the wrapper. They will not interfere with
924 @cindex controlling macro
926 The macro @code{FILE_FOO_SEEN} is called the @dfn{controlling macro} or
927 @dfn{guard macro}. In a user header file, the macro name should not
928 begin with @samp{_}. In a system header file, it should begin with
929 @samp{__} to avoid conflicts with user programs. In any kind of header
930 file, the macro name should contain the name of the file and some
931 additional text, to avoid conflicts with other header files.
933 @node Alternatives to Wrapper #ifndef
934 @section Alternatives to Wrapper #ifndef
936 CPP supports two more ways of indicating that a header file should be
937 read only once. Neither one is as portable as a wrapper @samp{#ifndef}
938 and we recommend you do not use them in new programs, with the caveat
939 that @samp{#import} is standard practice in Objective-C.
942 CPP supports a variant of @samp{#include} called @samp{#import} which
943 includes a file, but does so at most once. If you use @samp{#import}
944 instead of @samp{#include}, then you don't need the conditionals
945 inside the header file to prevent multiple inclusion of the contents.
946 @samp{#import} is standard in Objective-C, but is considered a
947 deprecated extension in C and C++.
949 @samp{#import} is not a well designed feature. It requires the users of
950 a header file to know that it should only be included once. It is much
951 better for the header file's implementor to write the file so that users
952 don't need to know this. Using a wrapper @samp{#ifndef} accomplishes
955 In the present implementation, a single use of @samp{#import} will
956 prevent the file from ever being read again, by either @samp{#import} or
957 @samp{#include}. You should not rely on this; do not use both
958 @samp{#import} and @samp{#include} to refer to the same header file.
960 Another way to prevent a header file from being included more than once
961 is with the @samp{#pragma once} directive. If @samp{#pragma once} is
962 seen when scanning a header file, that file will never be read again, no
965 @samp{#pragma once} does not have the problems that @samp{#import} does,
966 but it is not recognized by all preprocessors, so you cannot rely on it
967 in a portable program.
969 @node Computed Includes
970 @section Computed Includes
971 @cindex computed includes
972 @cindex macros in include
974 Sometimes it is necessary to select one of several different header
975 files to be included into your program. They might specify
976 configuration parameters to be used on different sorts of operating
977 systems, for instance. You could do this with a series of conditionals,
981 # include "system_1.h"
983 # include "system_2.h"
989 That rapidly becomes tedious. Instead, the preprocessor offers the
990 ability to use a macro for the header name. This is called a
991 @dfn{computed include}. Instead of writing a header name as the direct
992 argument of @samp{#include}, you simply put a macro name there instead:
995 #define SYSTEM_H "system_1.h"
1001 @code{SYSTEM_H} will be expanded, and the preprocessor will look for
1002 @file{system_1.h} as if the @samp{#include} had been written that way
1003 originally. @code{SYSTEM_H} could be defined by your Makefile with a
1006 You must be careful when you define the macro. @samp{#define} saves
1007 tokens, not text. The preprocessor has no way of knowing that the macro
1008 will be used as the argument of @samp{#include}, so it generates
1009 ordinary tokens, not a header name. This is unlikely to cause problems
1010 if you use double-quote includes, which are close enough to string
1011 constants. If you use angle brackets, however, you may have trouble.
1013 The syntax of a computed include is actually a bit more general than the
1014 above. If the first non-whitespace character after @samp{#include} is
1015 not @samp{"} or @samp{<}, then the entire line is macro-expanded
1016 like running text would be.
1018 If the line expands to a single string constant, the contents of that
1019 string constant are the file to be included. CPP does not re-examine the
1020 string for embedded quotes, but neither does it process backslash
1021 escapes in the string. Therefore
1024 #define HEADER "a\"b"
1029 looks for a file named @file{a\"b}. CPP searches for the file according
1030 to the rules for double-quoted includes.
1032 If the line expands to a token stream beginning with a @samp{<} token
1033 and including a @samp{>} token, then the tokens between the @samp{<} and
1034 the first @samp{>} are combined to form the filename to be included.
1035 Any whitespace between tokens is reduced to a single space; then any
1036 space after the initial @samp{<} is retained, but a trailing space
1037 before the closing @samp{>} is ignored. CPP searches for the file
1038 according to the rules for angle-bracket includes.
1040 In either case, if there are any tokens on the line after the file name,
1041 an error occurs and the directive is not processed. It is also an error
1042 if the result of expansion does not match either of the two expected
1045 These rules are implementation-defined behavior according to the C
1046 standard. To minimize the risk of different compilers interpreting your
1047 computed includes differently, we recommend you use only a single
1048 object-like macro which expands to a string constant. This will also
1049 minimize confusion for people reading your program.
1051 @node Wrapper Headers
1052 @section Wrapper Headers
1053 @cindex wrapper headers
1054 @cindex overriding a header file
1055 @findex #include_next
1057 Sometimes it is necessary to adjust the contents of a system-provided
1058 header file without editing it directly. GCC's @command{fixincludes}
1059 operation does this, for example. One way to do that would be to create
1060 a new header file with the same name and insert it in the search path
1061 before the original header. That works fine as long as you're willing
1062 to replace the old header entirely. But what if you want to refer to
1063 the old header from the new one?
1065 You cannot simply include the old header with @samp{#include}. That
1066 will start from the beginning, and find your new header again. If your
1067 header is not protected from multiple inclusion (@pxref{Once-Only
1068 Headers}), it will recurse infinitely and cause a fatal error.
1070 You could include the old header with an absolute pathname:
1072 #include "/usr/include/old-header.h"
1075 This works, but is not clean; should the system headers ever move, you
1076 would have to edit the new headers to match.
1078 There is no way to solve this problem within the C standard, but you can
1079 use the GNU extension @samp{#include_next}. It means, ``Include the
1080 @emph{next} file with this name''. This directive works like
1081 @samp{#include} except in searching for the specified file: it starts
1082 searching the list of header file directories @emph{after} the directory
1083 in which the current file was found.
1085 Suppose you specify @option{-I /usr/local/include}, and the list of
1086 directories to search also includes @file{/usr/include}; and suppose
1087 both directories contain @file{signal.h}. Ordinary @code{@w{#include
1088 <signal.h>}} finds the file under @file{/usr/local/include}. If that
1089 file contains @code{@w{#include_next <signal.h>}}, it starts searching
1090 after that directory, and finds the file in @file{/usr/include}.
1092 @samp{#include_next} does not distinguish between @code{<@var{file}>}
1093 and @code{"@var{file}"} inclusion, nor does it check that the file you
1094 specify has the same name as the current file. It simply looks for the
1095 file named, starting with the directory in the search path after the one
1096 where the current file was found.
1098 The use of @samp{#include_next} can lead to great confusion. We
1099 recommend it be used only when there is no other alternative. In
1100 particular, it should not be used in the headers belonging to a specific
1101 program; it should be used only to make global corrections along the
1102 lines of @command{fixincludes}.
1104 @node System Headers
1105 @section System Headers
1106 @cindex system header files
1108 The header files declaring interfaces to the operating system and
1109 runtime libraries often cannot be written in strictly conforming C@.
1110 Therefore, GCC gives code found in @dfn{system headers} special
1111 treatment. All warnings, other than those generated by @samp{#warning}
1112 (@pxref{Diagnostics}), are suppressed while GCC is processing a system
1113 header. Macros defined in a system header are immune to a few warnings
1114 wherever they are expanded. This immunity is granted on an ad-hoc
1115 basis, when we find that a warning generates lots of false positives
1116 because of code in macros defined in system headers.
1118 Normally, only the headers found in specific directories are considered
1119 system headers. These directories are determined when GCC is compiled.
1120 There are, however, two ways to make normal headers into system headers:
1124 Header files found in directories added to the search path with the
1125 @option{-isystem} and @option{-idirafter} command-line options are
1126 treated as system headers for the purposes of diagnostics.
1129 @findex #pragma GCC system_header
1130 There is also a directive, @code{@w{#pragma GCC system_header}}, which
1131 tells GCC to consider the rest of the current include file a system
1132 header, no matter where it was found. Code that comes before the
1133 @samp{#pragma} in the file is not affected. @code{@w{#pragma GCC
1134 system_header}} has no effect in the primary source file.
1140 A @dfn{macro} is a fragment of code which has been given a name.
1141 Whenever the name is used, it is replaced by the contents of the macro.
1142 There are two kinds of macros. They differ mostly in what they look
1143 like when they are used. @dfn{Object-like} macros resemble data objects
1144 when used, @dfn{function-like} macros resemble function calls.
1146 You may define any valid identifier as a macro, even if it is a C
1147 keyword. The preprocessor does not know anything about keywords. This
1148 can be useful if you wish to hide a keyword such as @code{const} from an
1149 older compiler that does not understand it. However, the preprocessor
1150 operator @code{defined} (@pxref{Defined}) can never be defined as a
1151 macro, and C++'s named operators (@pxref{C++ Named Operators}) cannot be
1152 macros when you are compiling C++.
1155 * Object-like Macros::
1156 * Function-like Macros::
1161 * Predefined Macros::
1162 * Undefining and Redefining Macros::
1163 * Directives Within Macro Arguments::
1167 @node Object-like Macros
1168 @section Object-like Macros
1169 @cindex object-like macro
1170 @cindex symbolic constants
1171 @cindex manifest constants
1173 An @dfn{object-like macro} is a simple identifier which will be replaced
1174 by a code fragment. It is called object-like because it looks like a
1175 data object in code that uses it. They are most commonly used to give
1176 symbolic names to numeric constants.
1179 You create macros with the @samp{#define} directive. @samp{#define} is
1180 followed by the name of the macro and then the token sequence it should
1181 be an abbreviation for, which is variously referred to as the macro's
1182 @dfn{body}, @dfn{expansion} or @dfn{replacement list}. For example,
1185 #define BUFFER_SIZE 1024
1189 defines a macro named @code{BUFFER_SIZE} as an abbreviation for the
1190 token @code{1024}. If somewhere after this @samp{#define} directive
1191 there comes a C statement of the form
1194 foo = (char *) malloc (BUFFER_SIZE);
1198 then the C preprocessor will recognize and @dfn{expand} the macro
1199 @code{BUFFER_SIZE}. The C compiler will see the same tokens as it would
1203 foo = (char *) malloc (1024);
1206 By convention, macro names are written in uppercase. Programs are
1207 easier to read when it is possible to tell at a glance which names are
1210 The macro's body ends at the end of the @samp{#define} line. You may
1211 continue the definition onto multiple lines, if necessary, using
1212 backslash-newline. When the macro is expanded, however, it will all
1213 come out on one line. For example,
1216 #define NUMBERS 1, \
1219 int x[] = @{ NUMBERS @};
1220 @expansion{} int x[] = @{ 1, 2, 3 @};
1224 The most common visible consequence of this is surprising line numbers
1227 There is no restriction on what can go in a macro body provided it
1228 decomposes into valid preprocessing tokens. Parentheses need not
1229 balance, and the body need not resemble valid C code. (If it does not,
1230 you may get error messages from the C compiler when you use the macro.)
1232 The C preprocessor scans your program sequentially. Macro definitions
1233 take effect at the place you write them. Therefore, the following input
1234 to the C preprocessor
1250 When the preprocessor expands a macro name, the macro's expansion
1251 replaces the macro invocation, then the expansion is examined for more
1252 macros to expand. For example,
1256 #define TABLESIZE BUFSIZE
1257 #define BUFSIZE 1024
1259 @expansion{} BUFSIZE
1265 @code{TABLESIZE} is expanded first to produce @code{BUFSIZE}, then that
1266 macro is expanded to produce the final result, @code{1024}.
1268 Notice that @code{BUFSIZE} was not defined when @code{TABLESIZE} was
1269 defined. The @samp{#define} for @code{TABLESIZE} uses exactly the
1270 expansion you specify---in this case, @code{BUFSIZE}---and does not
1271 check to see whether it too contains macro names. Only when you
1272 @emph{use} @code{TABLESIZE} is the result of its expansion scanned for
1275 This makes a difference if you change the definition of @code{BUFSIZE}
1276 at some point in the source file. @code{TABLESIZE}, defined as shown,
1277 will always expand using the definition of @code{BUFSIZE} that is
1278 currently in effect:
1281 #define BUFSIZE 1020
1282 #define TABLESIZE BUFSIZE
1288 Now @code{TABLESIZE} expands (in two stages) to @code{37}.
1290 If the expansion of a macro contains its own name, either directly or
1291 via intermediate macros, it is not expanded again when the expansion is
1292 examined for more macros. This prevents infinite recursion.
1293 @xref{Self-Referential Macros}, for the precise details.
1295 @node Function-like Macros
1296 @section Function-like Macros
1297 @cindex function-like macros
1299 You can also define macros whose use looks like a function call. These
1300 are called @dfn{function-like macros}. To define a function-like macro,
1301 you use the same @samp{#define} directive, but you put a pair of
1302 parentheses immediately after the macro name. For example,
1305 #define lang_init() c_init()
1307 @expansion{} c_init()
1310 A function-like macro is only expanded if its name appears with a pair
1311 of parentheses after it. If you write just the name, it is left alone.
1312 This can be useful when you have a function and a macro of the same
1313 name, and you wish to use the function sometimes.
1316 extern void foo(void);
1317 #define foo() /* @r{optimized inline version} */
1323 Here the call to @code{foo()} will use the macro, but the function
1324 pointer will get the address of the real function. If the macro were to
1325 be expanded, it would cause a syntax error.
1327 If you put spaces between the macro name and the parentheses in the
1328 macro definition, that does not define a function-like macro, it defines
1329 an object-like macro whose expansion happens to begin with a pair of
1333 #define lang_init () c_init()
1335 @expansion{} () c_init()()
1338 The first two pairs of parentheses in this expansion come from the
1339 macro. The third is the pair that was originally after the macro
1340 invocation. Since @code{lang_init} is an object-like macro, it does not
1341 consume those parentheses.
1343 @node Macro Arguments
1344 @section Macro Arguments
1346 @cindex macros with arguments
1347 @cindex arguments in macro definitions
1349 Function-like macros can take @dfn{arguments}, just like true functions.
1350 To define a macro that uses arguments, you insert @dfn{parameters}
1351 between the pair of parentheses in the macro definition that make the
1352 macro function-like. The parameters must be valid C identifiers,
1353 separated by commas and optionally whitespace.
1355 To invoke a macro that takes arguments, you write the name of the macro
1356 followed by a list of @dfn{actual arguments} in parentheses, separated
1357 by commas. The invocation of the macro need not be restricted to a
1358 single logical line---it can cross as many lines in the source file as
1359 you wish. The number of arguments you give must match the number of
1360 parameters in the macro definition. When the macro is expanded, each
1361 use of a parameter in its body is replaced by the tokens of the
1362 corresponding argument. (You need not use all of the parameters in the
1365 As an example, here is a macro that computes the minimum of two numeric
1366 values, as it is defined in many C programs, and some uses.
1369 #define min(X, Y) ((X) < (Y) ? (X) : (Y))
1370 x = min(a, b); @expansion{} x = ((a) < (b) ? (a) : (b));
1371 y = min(1, 2); @expansion{} y = ((1) < (2) ? (1) : (2));
1372 z = min(a + 28, *p); @expansion{} z = ((a + 28) < (*p) ? (a + 28) : (*p));
1376 (In this small example you can already see several of the dangers of
1377 macro arguments. @xref{Macro Pitfalls}, for detailed explanations.)
1379 Leading and trailing whitespace in each argument is dropped, and all
1380 whitespace between the tokens of an argument is reduced to a single
1381 space. Parentheses within each argument must balance; a comma within
1382 such parentheses does not end the argument. However, there is no
1383 requirement for square brackets or braces to balance, and they do not
1384 prevent a comma from separating arguments. Thus,
1387 macro (array[x = y, x + 1])
1391 passes two arguments to @code{macro}: @code{array[x = y} and @code{x +
1392 1]}. If you want to supply @code{array[x = y, x + 1]} as an argument,
1393 you can write it as @code{array[(x = y, x + 1)]}, which is equivalent C
1396 All arguments to a macro are completely macro-expanded before they are
1397 substituted into the macro body. After substitution, the complete text
1398 is scanned again for macros to expand, including the arguments. This rule
1399 may seem strange, but it is carefully designed so you need not worry
1400 about whether any function call is actually a macro invocation. You can
1401 run into trouble if you try to be too clever, though. @xref{Argument
1402 Prescan}, for detailed discussion.
1404 For example, @code{min (min (a, b), c)} is first expanded to
1407 min (((a) < (b) ? (a) : (b)), (c))
1415 ((((a) < (b) ? (a) : (b))) < (c)
1416 ? (((a) < (b) ? (a) : (b)))
1422 (Line breaks shown here for clarity would not actually be generated.)
1424 @cindex empty macro arguments
1425 You can leave macro arguments empty; this is not an error to the
1426 preprocessor (but many macros will then expand to invalid code).
1427 You cannot leave out arguments entirely; if a macro takes two arguments,
1428 there must be exactly one comma at the top level of its argument list.
1429 Here are some silly examples using @code{min}:
1432 min(, b) @expansion{} (( ) < (b) ? ( ) : (b))
1433 min(a, ) @expansion{} ((a ) < ( ) ? (a ) : ( ))
1434 min(,) @expansion{} (( ) < ( ) ? ( ) : ( ))
1435 min((,),) @expansion{} (((,)) < ( ) ? ((,)) : ( ))
1437 min() @error{} macro "min" requires 2 arguments, but only 1 given
1438 min(,,) @error{} macro "min" passed 3 arguments, but takes just 2
1441 Whitespace is not a preprocessing token, so if a macro @code{foo} takes
1442 one argument, @code{@w{foo ()}} and @code{@w{foo ( )}} both supply it an
1443 empty argument. Previous GNU preprocessor implementations and
1444 documentation were incorrect on this point, insisting that a
1445 function-like macro that takes a single argument be passed a space if an
1446 empty argument was required.
1448 Macro parameters appearing inside string literals are not replaced by
1449 their corresponding actual arguments.
1452 #define foo(x) x, "x"
1453 foo(bar) @expansion{} bar, "x"
1457 @section Stringizing
1459 @cindex @samp{#} operator
1461 Sometimes you may want to convert a macro argument into a string
1462 constant. Parameters are not replaced inside string constants, but you
1463 can use the @samp{#} preprocessing operator instead. When a macro
1464 parameter is used with a leading @samp{#}, the preprocessor replaces it
1465 with the literal text of the actual argument, converted to a string
1466 constant. Unlike normal parameter replacement, the argument is not
1467 macro-expanded first. This is called @dfn{stringizing}.
1469 There is no way to combine an argument with surrounding text and
1470 stringize it all together. Instead, you can write a series of adjacent
1471 string constants and stringized arguments. The preprocessor
1472 replaces the stringized arguments with string constants. The C
1473 compiler then combines all the adjacent string constants into one
1476 Here is an example of a macro definition that uses stringizing:
1480 #define WARN_IF(EXP) \
1482 fprintf (stderr, "Warning: " #EXP "\n"); @} \
1485 @expansion{} do @{ if (x == 0)
1486 fprintf (stderr, "Warning: " "x == 0" "\n"); @} while (0);
1491 The argument for @code{EXP} is substituted once, as-is, into the
1492 @code{if} statement, and once, stringized, into the argument to
1493 @code{fprintf}. If @code{x} were a macro, it would be expanded in the
1494 @code{if} statement, but not in the string.
1496 The @code{do} and @code{while (0)} are a kludge to make it possible to
1497 write @code{WARN_IF (@var{arg});}, which the resemblance of
1498 @code{WARN_IF} to a function would make C programmers want to do; see
1499 @ref{Swallowing the Semicolon}.
1501 Stringizing in C involves more than putting double-quote characters
1502 around the fragment. The preprocessor backslash-escapes the quotes
1503 surrounding embedded string constants, and all backslashes within string and
1504 character constants, in order to get a valid C string constant with the
1505 proper contents. Thus, stringizing @code{@w{p = "foo\n";}} results in
1506 @t{@w{"p = \"foo\\n\";"}}. However, backslashes that are not inside string
1507 or character constants are not duplicated: @samp{\n} by itself
1508 stringizes to @t{"\n"}.
1510 All leading and trailing whitespace in text being stringized is
1511 ignored. Any sequence of whitespace in the middle of the text is
1512 converted to a single space in the stringized result. Comments are
1513 replaced by whitespace long before stringizing happens, so they
1514 never appear in stringized text.
1516 There is no way to convert a macro argument into a character constant.
1518 If you want to stringize the result of expansion of a macro argument,
1519 you have to use two levels of macros.
1522 #define xstr(s) str(s)
1528 @expansion{} xstr (4)
1529 @expansion{} str (4)
1533 @code{s} is stringized when it is used in @code{str}, so it is not
1534 macro-expanded first. But @code{s} is an ordinary argument to
1535 @code{xstr}, so it is completely macro-expanded before @code{xstr}
1536 itself is expanded (@pxref{Argument Prescan}). Therefore, by the time
1537 @code{str} gets to its argument, it has already been macro-expanded.
1540 @section Concatenation
1541 @cindex concatenation
1542 @cindex token pasting
1543 @cindex token concatenation
1544 @cindex @samp{##} operator
1546 It is often useful to merge two tokens into one while expanding macros.
1547 This is called @dfn{token pasting} or @dfn{token concatenation}. The
1548 @samp{##} preprocessing operator performs token pasting. When a macro
1549 is expanded, the two tokens on either side of each @samp{##} operator
1550 are combined into a single token, which then replaces the @samp{##} and
1551 the two original tokens in the macro expansion. Usually both will be
1552 identifiers, or one will be an identifier and the other a preprocessing
1553 number. When pasted, they make a longer identifier. This isn't the
1554 only valid case. It is also possible to concatenate two numbers (or a
1555 number and a name, such as @code{1.5} and @code{e3}) into a number.
1556 Also, multi-character operators such as @code{+=} can be formed by
1559 However, two tokens that don't together form a valid token cannot be
1560 pasted together. For example, you cannot concatenate @code{x} with
1561 @code{+} in either order. If you try, the preprocessor issues a warning
1562 and emits the two tokens. Whether it puts white space between the
1563 tokens is undefined. It is common to find unnecessary uses of @samp{##}
1564 in complex macros. If you get this warning, it is likely that you can
1565 simply remove the @samp{##}.
1567 Both the tokens combined by @samp{##} could come from the macro body,
1568 but you could just as well write them as one token in the first place.
1569 Token pasting is most useful when one or both of the tokens comes from a
1570 macro argument. If either of the tokens next to an @samp{##} is a
1571 parameter name, it is replaced by its actual argument before @samp{##}
1572 executes. As with stringizing, the actual argument is not
1573 macro-expanded first. If the argument is empty, that @samp{##} has no
1576 Keep in mind that the C preprocessor converts comments to whitespace
1577 before macros are even considered. Therefore, you cannot create a
1578 comment by concatenating @samp{/} and @samp{*}. You can put as much
1579 whitespace between @samp{##} and its operands as you like, including
1580 comments, and you can put comments in arguments that will be
1581 concatenated. However, it is an error if @samp{##} appears at either
1582 end of a macro body.
1584 Consider a C program that interprets named commands. There probably
1585 needs to be a table of commands, perhaps an array of structures declared
1593 void (*function) (void);
1598 struct command commands[] =
1600 @{ "quit", quit_command @},
1601 @{ "help", help_command @},
1607 It would be cleaner not to have to give each command name twice, once in
1608 the string constant and once in the function name. A macro which takes the
1609 name of a command as an argument can make this unnecessary. The string
1610 constant can be created with stringizing, and the function name by
1611 concatenating the argument with @samp{_command}. Here is how it is done:
1614 #define COMMAND(NAME) @{ #NAME, NAME ## _command @}
1616 struct command commands[] =
1624 @node Variadic Macros
1625 @section Variadic Macros
1626 @cindex variable number of arguments
1627 @cindex macros with variable arguments
1628 @cindex variadic macros
1630 A macro can be declared to accept a variable number of arguments much as
1631 a function can. The syntax for defining the macro is similar to that of
1632 a function. Here is an example:
1635 #define eprintf(@dots{}) fprintf (stderr, __VA_ARGS__)
1638 This kind of macro is called @dfn{variadic}. When the macro is invoked,
1639 all the tokens in its argument list after the last named argument (this
1640 macro has none), including any commas, become the @dfn{variable
1641 argument}. This sequence of tokens replaces the identifier
1642 @code{@w{__VA_ARGS__}} in the macro body wherever it appears. Thus, we
1643 have this expansion:
1646 eprintf ("%s:%d: ", input_file, lineno)
1647 @expansion{} fprintf (stderr, "%s:%d: ", input_file, lineno)
1650 The variable argument is completely macro-expanded before it is inserted
1651 into the macro expansion, just like an ordinary argument. You may use
1652 the @samp{#} and @samp{##} operators to stringize the variable argument
1653 or to paste its leading or trailing token with another token. (But see
1654 below for an important special case for @samp{##}.)
1656 If your macro is complicated, you may want a more descriptive name for
1657 the variable argument than @code{@w{__VA_ARGS__}}. CPP permits
1658 this, as an extension. You may write an argument name immediately
1659 before the @samp{@dots{}}; that name is used for the variable argument.
1660 The @code{eprintf} macro above could be written
1663 #define eprintf(args@dots{}) fprintf (stderr, args)
1667 using this extension. You cannot use @code{@w{__VA_ARGS__}} and this
1668 extension in the same macro.
1670 You can have named arguments as well as variable arguments in a variadic
1671 macro. We could define @code{eprintf} like this, instead:
1674 #define eprintf(format, @dots{}) fprintf (stderr, format, __VA_ARGS__)
1678 This formulation looks more descriptive, but historically it was less
1679 flexible: you had to supply at least one argument after the format
1680 string. In standard C, you could not omit the comma separating the
1681 named argument from the variable arguments. (Note that this
1682 restriction has been lifted in C++2a, and never existed in GNU C; see
1685 Furthermore, if you left the variable argument empty, you would have
1686 gotten a syntax error, because there would have been an extra comma
1687 after the format string.
1690 eprintf("success!\n", );
1691 @expansion{} fprintf(stderr, "success!\n", );
1694 This has been fixed in C++2a, and GNU CPP also has a pair of
1695 extensions which deal with this problem.
1697 First, in GNU CPP, and in C++ beginning in C++2a, you are allowed to
1698 leave the variable argument out entirely:
1701 eprintf ("success!\n")
1702 @expansion{} fprintf(stderr, "success!\n", );
1706 Second, C++2a introduces the @code{@w{__VA_OPT__}} function macro.
1707 This macro may only appear in the definition of a variadic macro. If
1708 the variable argument has any tokens, then a @code{@w{__VA_OPT__}}
1709 invocation expands to its argument; but if the variable argument does
1710 not have any tokens, the @code{@w{__VA_OPT__}} expands to nothing:
1713 #define eprintf(format, @dots{}) \\
1714 fprintf (stderr, format __VA_OPT__(,) __VA_ARGS__)
1717 @code{@w{__VA_OPT__}} is also available in GNU C and GNU C++.
1719 Historically, GNU CPP has also had another extension to handle the
1720 trailing comma: the @samp{##} token paste operator has a special
1721 meaning when placed between a comma and a variable argument. Despite
1722 the introduction of @code{@w{__VA_OPT__}}, this extension remains
1723 supported in GNU CPP, for backward compatibility. If you write
1726 #define eprintf(format, @dots{}) fprintf (stderr, format, ##__VA_ARGS__)
1730 and the variable argument is left out when the @code{eprintf} macro is
1731 used, then the comma before the @samp{##} will be deleted. This does
1732 @emph{not} happen if you pass an empty argument, nor does it happen if
1733 the token preceding @samp{##} is anything other than a comma.
1736 eprintf ("success!\n")
1737 @expansion{} fprintf(stderr, "success!\n");
1741 The above explanation is ambiguous about the case where the only macro
1742 parameter is a variable arguments parameter, as it is meaningless to
1743 try to distinguish whether no argument at all is an empty argument or
1745 CPP retains the comma when conforming to a specific C
1746 standard. Otherwise the comma is dropped as an extension to the standard.
1749 mandates that the only place the identifier @code{@w{__VA_ARGS__}}
1750 can appear is in the replacement list of a variadic macro. It may not
1751 be used as a macro name, macro argument name, or within a different type
1752 of macro. It may also be forbidden in open text; the standard is
1753 ambiguous. We recommend you avoid using it except for its defined
1756 Likewise, C++ forbids @code{@w{__VA_OPT__}} anywhere outside the
1757 replacement list of a variadic macro.
1759 Variadic macros became a standard part of the C language with C99.
1760 GNU CPP previously supported them
1761 with a named variable argument
1762 (@samp{args@dots{}}, not @samp{@dots{}} and @code{@w{__VA_ARGS__}}), which
1763 is still supported for backward compatibility.
1765 @node Predefined Macros
1766 @section Predefined Macros
1768 @cindex predefined macros
1769 Several object-like macros are predefined; you use them without
1770 supplying their definitions. They fall into three classes: standard,
1771 common, and system-specific.
1773 In C++, there is a fourth category, the named operators. They act like
1774 predefined macros, but you cannot undefine them.
1777 * Standard Predefined Macros::
1778 * Common Predefined Macros::
1779 * System-specific Predefined Macros::
1780 * C++ Named Operators::
1783 @node Standard Predefined Macros
1784 @subsection Standard Predefined Macros
1785 @cindex standard predefined macros.
1787 The standard predefined macros are specified by the relevant
1788 language standards, so they are available with all compilers that
1789 implement those standards. Older compilers may not provide all of
1790 them. Their names all start with double underscores.
1794 This macro expands to the name of the current input file, in the form of
1795 a C string constant. This is the path by which the preprocessor opened
1796 the file, not the short name specified in @samp{#include} or as the
1797 input file name argument. For example,
1798 @code{"/usr/local/include/myheader.h"} is a possible expansion of this
1802 This macro expands to the current input line number, in the form of a
1803 decimal integer constant. While we call it a predefined macro, it's
1804 a pretty strange macro, since its ``definition'' changes with each
1805 new line of source code.
1808 @code{__FILE__} and @code{__LINE__} are useful in generating an error
1809 message to report an inconsistency detected by the program; the message
1810 can state the source line at which the inconsistency was detected. For
1814 fprintf (stderr, "Internal error: "
1815 "negative string length "
1816 "%d at %s, line %d.",
1817 length, __FILE__, __LINE__);
1820 An @samp{#include} directive changes the expansions of @code{__FILE__}
1821 and @code{__LINE__} to correspond to the included file. At the end of
1822 that file, when processing resumes on the input file that contained
1823 the @samp{#include} directive, the expansions of @code{__FILE__} and
1824 @code{__LINE__} revert to the values they had before the
1825 @samp{#include} (but @code{__LINE__} is then incremented by one as
1826 processing moves to the line after the @samp{#include}).
1828 A @samp{#line} directive changes @code{__LINE__}, and may change
1829 @code{__FILE__} as well. @xref{Line Control}.
1831 C99 introduced @code{__func__}, and GCC has provided @code{__FUNCTION__}
1832 for a long time. Both of these are strings containing the name of the
1833 current function (there are slight semantic differences; see the GCC
1834 manual). Neither of them is a macro; the preprocessor does not know the
1835 name of the current function. They tend to be useful in conjunction
1836 with @code{__FILE__} and @code{__LINE__}, though.
1841 This macro expands to a string constant that describes the date on which
1842 the preprocessor is being run. The string constant contains eleven
1843 characters and looks like @code{@w{"Feb 12 1996"}}. If the day of the
1844 month is less than 10, it is padded with a space on the left.
1846 If GCC cannot determine the current date, it will emit a warning message
1847 (once per compilation) and @code{__DATE__} will expand to
1848 @code{@w{"??? ?? ????"}}.
1851 This macro expands to a string constant that describes the time at
1852 which the preprocessor is being run. The string constant contains
1853 eight characters and looks like @code{"23:59:01"}.
1855 If GCC cannot determine the current time, it will emit a warning message
1856 (once per compilation) and @code{__TIME__} will expand to
1860 In normal operation, this macro expands to the constant 1, to signify
1861 that this compiler conforms to ISO Standard C@. If GNU CPP is used with
1862 a compiler other than GCC, this is not necessarily true; however, the
1863 preprocessor always conforms to the standard unless the
1864 @option{-traditional-cpp} option is used.
1866 This macro is not defined if the @option{-traditional-cpp} option is used.
1868 On some hosts, the system compiler uses a different convention, where
1869 @code{__STDC__} is normally 0, but is 1 if the user specifies strict
1870 conformance to the C Standard. CPP follows the host convention when
1871 processing system header files, but when processing user files
1872 @code{__STDC__} is always 1. This has been reported to cause problems;
1873 for instance, some versions of Solaris provide X Windows headers that
1874 expect @code{__STDC__} to be either undefined or 1. @xref{Invocation}.
1876 @item __STDC_VERSION__
1877 This macro expands to the C Standard's version number, a long integer
1878 constant of the form @code{@var{yyyy}@var{mm}L} where @var{yyyy} and
1879 @var{mm} are the year and month of the Standard version. This signifies
1880 which version of the C Standard the compiler conforms to. Like
1881 @code{__STDC__}, this is not necessarily accurate for the entire
1882 implementation, unless GNU CPP is being used with GCC@.
1884 The value @code{199409L} signifies the 1989 C standard as amended in
1885 1994, which is the current default; the value @code{199901L} signifies
1886 the 1999 revision of the C standard; the value @code{201112L}
1887 signifies the 2011 revision of the C standard; the value
1888 @code{201710L} signifies the 2017 revision of the C standard (which is
1889 otherwise identical to the 2011 version apart from correction of
1892 This macro is not defined if the @option{-traditional-cpp} option is
1893 used, nor when compiling C++ or Objective-C@.
1895 @item __STDC_HOSTED__
1896 This macro is defined, with value 1, if the compiler's target is a
1897 @dfn{hosted environment}. A hosted environment has the complete
1898 facilities of the standard C library available.
1901 This macro is defined when the C++ compiler is in use. You can use
1902 @code{__cplusplus} to test whether a header is compiled by a C compiler
1903 or a C++ compiler. This macro is similar to @code{__STDC_VERSION__}, in
1904 that it expands to a version number. Depending on the language standard
1905 selected, the value of the macro is
1906 @code{199711L} for the 1998 C++ standard,
1907 @code{201103L} for the 2011 C++ standard,
1908 @code{201402L} for the 2014 C++ standard,
1909 @code{201703L} for the 2017 C++ standard,
1910 or an unspecified value strictly larger than @code{201703L} for the
1911 experimental languages enabled by @option{-std=c++2a} and
1912 @option{-std=gnu++2a}.
1915 This macro is defined, with value 1, when the Objective-C compiler is in
1916 use. You can use @code{__OBJC__} to test whether a header is compiled
1917 by a C compiler or an Objective-C compiler.
1920 This macro is defined with value 1 when preprocessing assembly
1925 @node Common Predefined Macros
1926 @subsection Common Predefined Macros
1927 @cindex common predefined macros
1929 The common predefined macros are GNU C extensions. They are available
1930 with the same meanings regardless of the machine or operating system on
1931 which you are using GNU C or GNU Fortran. Their names all start with
1937 This macro expands to sequential integral values starting from 0. In
1938 conjunction with the @code{##} operator, this provides a convenient means to
1939 generate unique identifiers. Care must be taken to ensure that
1940 @code{__COUNTER__} is not expanded prior to inclusion of precompiled headers
1941 which use it. Otherwise, the precompiled headers will not be used.
1944 The GNU Fortran compiler defines this.
1947 @itemx __GNUC_MINOR__
1948 @itemx __GNUC_PATCHLEVEL__
1949 These macros are defined by all GNU compilers that use the C
1950 preprocessor: C, C++, Objective-C and Fortran. Their values are the major
1951 version, minor version, and patch level of the compiler, as integer
1952 constants. For example, GCC version @var{x}.@var{y}.@var{z}
1953 defines @code{__GNUC__} to @var{x}, @code{__GNUC_MINOR__} to @var{y},
1954 and @code{__GNUC_PATCHLEVEL__} to @var{z}. These
1955 macros are also defined if you invoke the preprocessor directly.
1957 If all you need to know is whether or not your program is being compiled
1958 by GCC, or a non-GCC compiler that claims to accept the GNU C dialects,
1959 you can simply test @code{__GNUC__}. If you need to write code
1960 which depends on a specific version, you must be more careful. Each
1961 time the minor version is increased, the patch level is reset to zero;
1962 each time the major version is increased, the
1963 minor version and patch level are reset. If you wish to use the
1964 predefined macros directly in the conditional, you will need to write it
1968 /* @r{Test for GCC > 3.2.0} */
1969 #if __GNUC__ > 3 || \
1970 (__GNUC__ == 3 && (__GNUC_MINOR__ > 2 || \
1971 (__GNUC_MINOR__ == 2 && \
1972 __GNUC_PATCHLEVEL__ > 0))
1976 Another approach is to use the predefined macros to
1977 calculate a single number, then compare that against a threshold:
1980 #define GCC_VERSION (__GNUC__ * 10000 \
1981 + __GNUC_MINOR__ * 100 \
1982 + __GNUC_PATCHLEVEL__)
1984 /* @r{Test for GCC > 3.2.0} */
1985 #if GCC_VERSION > 30200
1989 Many people find this form easier to understand.
1992 The GNU C++ compiler defines this. Testing it is equivalent to
1993 testing @code{@w{(__GNUC__ && __cplusplus)}}.
1995 @item __STRICT_ANSI__
1996 GCC defines this macro if and only if the @option{-ansi} switch, or a
1997 @option{-std} switch specifying strict conformance to some version of ISO C
1998 or ISO C++, was specified when GCC was invoked. It is defined to @samp{1}.
1999 This macro exists primarily to direct GNU libc's header files to use only
2000 definitions found in standard C.
2003 This macro expands to the name of the main input file, in the form
2004 of a C string constant. This is the source file that was specified
2005 on the command line of the preprocessor or C compiler.
2007 @item __INCLUDE_LEVEL__
2008 This macro expands to a decimal integer constant that represents the
2009 depth of nesting in include files. The value of this macro is
2010 incremented on every @samp{#include} directive and decremented at the
2011 end of every included file. It starts out at 0, its value within the
2012 base file specified on the command line.
2015 This macro is defined if the target uses the ELF object format.
2018 This macro expands to a string constant which describes the version of
2019 the compiler in use. You should not rely on its contents having any
2020 particular form, but it can be counted on to contain at least the
2024 @itemx __OPTIMIZE_SIZE__
2025 @itemx __NO_INLINE__
2026 These macros describe the compilation mode. @code{__OPTIMIZE__} is
2027 defined in all optimizing compilations. @code{__OPTIMIZE_SIZE__} is
2028 defined if the compiler is optimizing for size, not speed.
2029 @code{__NO_INLINE__} is defined if no functions will be inlined into
2030 their callers (when not optimizing, or when inlining has been
2031 specifically disabled by @option{-fno-inline}).
2033 These macros cause certain GNU header files to provide optimized
2034 definitions, using macros or inline functions, of system library
2035 functions. You should not use these macros in any way unless you make
2036 sure that programs will execute with the same effect whether or not they
2037 are defined. If they are defined, their value is 1.
2039 @item __GNUC_GNU_INLINE__
2040 GCC defines this macro if functions declared @code{inline} will be
2041 handled in GCC's traditional gnu90 mode. Object files will contain
2042 externally visible definitions of all functions declared @code{inline}
2043 without @code{extern} or @code{static}. They will not contain any
2044 definitions of any functions declared @code{extern inline}.
2046 @item __GNUC_STDC_INLINE__
2047 GCC defines this macro if functions declared @code{inline} will be
2048 handled according to the ISO C99 or later standards. Object files will contain
2049 externally visible definitions of all functions declared @code{extern
2050 inline}. They will not contain definitions of any functions declared
2051 @code{inline} without @code{extern}.
2053 If this macro is defined, GCC supports the @code{gnu_inline} function
2054 attribute as a way to always get the gnu90 behavior.
2056 @item __CHAR_UNSIGNED__
2057 GCC defines this macro if and only if the data type @code{char} is
2058 unsigned on the target machine. It exists to cause the standard header
2059 file @file{limits.h} to work correctly. You should not use this macro
2060 yourself; instead, refer to the standard macros defined in @file{limits.h}.
2062 @item __WCHAR_UNSIGNED__
2063 Like @code{__CHAR_UNSIGNED__}, this macro is defined if and only if the
2064 data type @code{wchar_t} is unsigned and the front-end is in C++ mode.
2066 @item __REGISTER_PREFIX__
2067 This macro expands to a single token (not a string constant) which is
2068 the prefix applied to CPU register names in assembly language for this
2069 target. You can use it to write assembly that is usable in multiple
2070 environments. For example, in the @code{m68k-aout} environment it
2071 expands to nothing, but in the @code{m68k-coff} environment it expands
2072 to a single @samp{%}.
2074 @item __USER_LABEL_PREFIX__
2075 This macro expands to a single token which is the prefix applied to
2076 user labels (symbols visible to C code) in assembly. For example, in
2077 the @code{m68k-aout} environment it expands to an @samp{_}, but in the
2078 @code{m68k-coff} environment it expands to nothing.
2080 This macro will have the correct definition even if
2081 @option{-f(no-)underscores} is in use, but it will not be correct if
2082 target-specific options that adjust this prefix are used (e.g.@: the
2083 OSF/rose @option{-mno-underscores} option).
2086 @itemx __PTRDIFF_TYPE__
2087 @itemx __WCHAR_TYPE__
2088 @itemx __WINT_TYPE__
2089 @itemx __INTMAX_TYPE__
2090 @itemx __UINTMAX_TYPE__
2091 @itemx __SIG_ATOMIC_TYPE__
2092 @itemx __INT8_TYPE__
2093 @itemx __INT16_TYPE__
2094 @itemx __INT32_TYPE__
2095 @itemx __INT64_TYPE__
2096 @itemx __UINT8_TYPE__
2097 @itemx __UINT16_TYPE__
2098 @itemx __UINT32_TYPE__
2099 @itemx __UINT64_TYPE__
2100 @itemx __INT_LEAST8_TYPE__
2101 @itemx __INT_LEAST16_TYPE__
2102 @itemx __INT_LEAST32_TYPE__
2103 @itemx __INT_LEAST64_TYPE__
2104 @itemx __UINT_LEAST8_TYPE__
2105 @itemx __UINT_LEAST16_TYPE__
2106 @itemx __UINT_LEAST32_TYPE__
2107 @itemx __UINT_LEAST64_TYPE__
2108 @itemx __INT_FAST8_TYPE__
2109 @itemx __INT_FAST16_TYPE__
2110 @itemx __INT_FAST32_TYPE__
2111 @itemx __INT_FAST64_TYPE__
2112 @itemx __UINT_FAST8_TYPE__
2113 @itemx __UINT_FAST16_TYPE__
2114 @itemx __UINT_FAST32_TYPE__
2115 @itemx __UINT_FAST64_TYPE__
2116 @itemx __INTPTR_TYPE__
2117 @itemx __UINTPTR_TYPE__
2118 These macros are defined to the correct underlying types for the
2119 @code{size_t}, @code{ptrdiff_t}, @code{wchar_t}, @code{wint_t},
2120 @code{intmax_t}, @code{uintmax_t}, @code{sig_atomic_t}, @code{int8_t},
2121 @code{int16_t}, @code{int32_t}, @code{int64_t}, @code{uint8_t},
2122 @code{uint16_t}, @code{uint32_t}, @code{uint64_t},
2123 @code{int_least8_t}, @code{int_least16_t}, @code{int_least32_t},
2124 @code{int_least64_t}, @code{uint_least8_t}, @code{uint_least16_t},
2125 @code{uint_least32_t}, @code{uint_least64_t}, @code{int_fast8_t},
2126 @code{int_fast16_t}, @code{int_fast32_t}, @code{int_fast64_t},
2127 @code{uint_fast8_t}, @code{uint_fast16_t}, @code{uint_fast32_t},
2128 @code{uint_fast64_t}, @code{intptr_t}, and @code{uintptr_t} typedefs,
2129 respectively. They exist to make the standard header files
2130 @file{stddef.h}, @file{stdint.h}, and @file{wchar.h} work correctly.
2131 You should not use these macros directly; instead, include the
2132 appropriate headers and use the typedefs. Some of these macros may
2133 not be defined on particular systems if GCC does not provide a
2134 @file{stdint.h} header on those systems.
2137 Defined to the number of bits used in the representation of the
2138 @code{char} data type. It exists to make the standard header given
2139 numerical limits work correctly. You should not use
2140 this macro directly; instead, include the appropriate headers.
2143 @itemx __WCHAR_MAX__
2147 @itemx __LONG_LONG_MAX__
2150 @itemx __PTRDIFF_MAX__
2151 @itemx __INTMAX_MAX__
2152 @itemx __UINTMAX_MAX__
2153 @itemx __SIG_ATOMIC_MAX__
2155 @itemx __INT16_MAX__
2156 @itemx __INT32_MAX__
2157 @itemx __INT64_MAX__
2158 @itemx __UINT8_MAX__
2159 @itemx __UINT16_MAX__
2160 @itemx __UINT32_MAX__
2161 @itemx __UINT64_MAX__
2162 @itemx __INT_LEAST8_MAX__
2163 @itemx __INT_LEAST16_MAX__
2164 @itemx __INT_LEAST32_MAX__
2165 @itemx __INT_LEAST64_MAX__
2166 @itemx __UINT_LEAST8_MAX__
2167 @itemx __UINT_LEAST16_MAX__
2168 @itemx __UINT_LEAST32_MAX__
2169 @itemx __UINT_LEAST64_MAX__
2170 @itemx __INT_FAST8_MAX__
2171 @itemx __INT_FAST16_MAX__
2172 @itemx __INT_FAST32_MAX__
2173 @itemx __INT_FAST64_MAX__
2174 @itemx __UINT_FAST8_MAX__
2175 @itemx __UINT_FAST16_MAX__
2176 @itemx __UINT_FAST32_MAX__
2177 @itemx __UINT_FAST64_MAX__
2178 @itemx __INTPTR_MAX__
2179 @itemx __UINTPTR_MAX__
2180 @itemx __WCHAR_MIN__
2182 @itemx __SIG_ATOMIC_MIN__
2183 Defined to the maximum value of the @code{signed char}, @code{wchar_t},
2184 @code{signed short},
2185 @code{signed int}, @code{signed long}, @code{signed long long},
2186 @code{wint_t}, @code{size_t}, @code{ptrdiff_t},
2187 @code{intmax_t}, @code{uintmax_t}, @code{sig_atomic_t}, @code{int8_t},
2188 @code{int16_t}, @code{int32_t}, @code{int64_t}, @code{uint8_t},
2189 @code{uint16_t}, @code{uint32_t}, @code{uint64_t},
2190 @code{int_least8_t}, @code{int_least16_t}, @code{int_least32_t},
2191 @code{int_least64_t}, @code{uint_least8_t}, @code{uint_least16_t},
2192 @code{uint_least32_t}, @code{uint_least64_t}, @code{int_fast8_t},
2193 @code{int_fast16_t}, @code{int_fast32_t}, @code{int_fast64_t},
2194 @code{uint_fast8_t}, @code{uint_fast16_t}, @code{uint_fast32_t},
2195 @code{uint_fast64_t}, @code{intptr_t}, and @code{uintptr_t} types and
2196 to the minimum value of the @code{wchar_t}, @code{wint_t}, and
2197 @code{sig_atomic_t} types respectively. They exist to make the
2198 standard header given numerical limits work correctly. You should not
2199 use these macros directly; instead, include the appropriate headers.
2200 Some of these macros may not be defined on particular systems if GCC
2201 does not provide a @file{stdint.h} header on those systems.
2213 Defined to implementations of the standard @file{stdint.h} macros with
2214 the same names without the leading @code{__}. They exist the make the
2215 implementation of that header work correctly. You should not use
2216 these macros directly; instead, include the appropriate headers. Some
2217 of these macros may not be defined on particular systems if GCC does
2218 not provide a @file{stdint.h} header on those systems.
2220 @item __SCHAR_WIDTH__
2221 @itemx __SHRT_WIDTH__
2222 @itemx __INT_WIDTH__
2223 @itemx __LONG_WIDTH__
2224 @itemx __LONG_LONG_WIDTH__
2225 @itemx __PTRDIFF_WIDTH__
2226 @itemx __SIG_ATOMIC_WIDTH__
2227 @itemx __SIZE_WIDTH__
2228 @itemx __WCHAR_WIDTH__
2229 @itemx __WINT_WIDTH__
2230 @itemx __INT_LEAST8_WIDTH__
2231 @itemx __INT_LEAST16_WIDTH__
2232 @itemx __INT_LEAST32_WIDTH__
2233 @itemx __INT_LEAST64_WIDTH__
2234 @itemx __INT_FAST8_WIDTH__
2235 @itemx __INT_FAST16_WIDTH__
2236 @itemx __INT_FAST32_WIDTH__
2237 @itemx __INT_FAST64_WIDTH__
2238 @itemx __INTPTR_WIDTH__
2239 @itemx __INTMAX_WIDTH__
2240 Defined to the bit widths of the corresponding types. They exist to
2241 make the implementations of @file{limits.h} and @file{stdint.h} behave
2242 correctly. You should not use these macros directly; instead, include
2243 the appropriate headers. Some of these macros may not be defined on
2244 particular systems if GCC does not provide a @file{stdint.h} header on
2247 @item __SIZEOF_INT__
2248 @itemx __SIZEOF_LONG__
2249 @itemx __SIZEOF_LONG_LONG__
2250 @itemx __SIZEOF_SHORT__
2251 @itemx __SIZEOF_POINTER__
2252 @itemx __SIZEOF_FLOAT__
2253 @itemx __SIZEOF_DOUBLE__
2254 @itemx __SIZEOF_LONG_DOUBLE__
2255 @itemx __SIZEOF_SIZE_T__
2256 @itemx __SIZEOF_WCHAR_T__
2257 @itemx __SIZEOF_WINT_T__
2258 @itemx __SIZEOF_PTRDIFF_T__
2259 Defined to the number of bytes of the C standard data types: @code{int},
2260 @code{long}, @code{long long}, @code{short}, @code{void *}, @code{float},
2261 @code{double}, @code{long double}, @code{size_t}, @code{wchar_t}, @code{wint_t}
2262 and @code{ptrdiff_t}.
2264 @item __BYTE_ORDER__
2265 @itemx __ORDER_LITTLE_ENDIAN__
2266 @itemx __ORDER_BIG_ENDIAN__
2267 @itemx __ORDER_PDP_ENDIAN__
2268 @code{__BYTE_ORDER__} is defined to one of the values
2269 @code{__ORDER_LITTLE_ENDIAN__}, @code{__ORDER_BIG_ENDIAN__}, or
2270 @code{__ORDER_PDP_ENDIAN__} to reflect the layout of multi-byte and
2271 multi-word quantities in memory. If @code{__BYTE_ORDER__} is equal to
2272 @code{__ORDER_LITTLE_ENDIAN__} or @code{__ORDER_BIG_ENDIAN__}, then
2273 multi-byte and multi-word quantities are laid out identically: the
2274 byte (word) at the lowest address is the least significant or most
2275 significant byte (word) of the quantity, respectively. If
2276 @code{__BYTE_ORDER__} is equal to @code{__ORDER_PDP_ENDIAN__}, then
2277 bytes in 16-bit words are laid out in a little-endian fashion, whereas
2278 the 16-bit subwords of a 32-bit quantity are laid out in big-endian
2281 You should use these macros for testing like this:
2284 /* @r{Test for a little-endian machine} */
2285 #if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
2288 @item __FLOAT_WORD_ORDER__
2289 @code{__FLOAT_WORD_ORDER__} is defined to one of the values
2290 @code{__ORDER_LITTLE_ENDIAN__} or @code{__ORDER_BIG_ENDIAN__} to reflect
2291 the layout of the words of multi-word floating-point quantities.
2294 This macro is defined, with value 1, when compiling a C++ source file
2295 with warnings about deprecated constructs enabled. These warnings are
2296 enabled by default, but can be disabled with @option{-Wno-deprecated}.
2299 This macro is defined, with value 1, when compiling a C++ source file
2300 with exceptions enabled. If @option{-fno-exceptions} is used when
2301 compiling the file, then this macro is not defined.
2304 This macro is defined, with value 1, when compiling a C++ source file
2305 with runtime type identification enabled. If @option{-fno-rtti} is
2306 used when compiling the file, then this macro is not defined.
2308 @item __USING_SJLJ_EXCEPTIONS__
2309 This macro is defined, with value 1, if the compiler uses the old
2310 mechanism based on @code{setjmp} and @code{longjmp} for exception
2313 @item __GXX_EXPERIMENTAL_CXX0X__
2314 This macro is defined when compiling a C++ source file with the option
2315 @option{-std=c++0x} or @option{-std=gnu++0x}. It indicates that some
2316 features likely to be included in C++0x are available. Note that these
2317 features are experimental, and may change or be removed in future
2321 This macro is defined when compiling a C++ source file. It has the
2322 value 1 if the compiler will use weak symbols, COMDAT sections, or
2323 other similar techniques to collapse symbols with ``vague linkage''
2324 that are defined in multiple translation units. If the compiler will
2325 not collapse such symbols, this macro is defined with value 0. In
2326 general, user code should not need to make use of this macro; the
2327 purpose of this macro is to ease implementation of the C++ runtime
2328 library provided with G++.
2330 @item __NEXT_RUNTIME__
2331 This macro is defined, with value 1, if (and only if) the NeXT runtime
2332 (as in @option{-fnext-runtime}) is in use for Objective-C@. If the GNU
2333 runtime is used, this macro is not defined, so that you can use this
2334 macro to determine which runtime (NeXT or GNU) is being used.
2338 These macros are defined, with value 1, if (and only if) the compilation
2339 is for a target where @code{long int} and pointer both use 64-bits and
2340 @code{int} uses 32-bit.
2343 This macro is defined, with value 1, when @option{-fstack-protector} is in
2347 This macro is defined, with value 2, when @option{-fstack-protector-all} is
2350 @item __SSP_STRONG__
2351 This macro is defined, with value 3, when @option{-fstack-protector-strong} is
2354 @item __SSP_EXPLICIT__
2355 This macro is defined, with value 4, when @option{-fstack-protector-explicit} is
2358 @item __SANITIZE_ADDRESS__
2359 This macro is defined, with value 1, when @option{-fsanitize=address}
2360 or @option{-fsanitize=kernel-address} are in use.
2362 @item __SANITIZE_THREAD__
2363 This macro is defined, with value 1, when @option{-fsanitize=thread} is in use.
2366 This macro expands to a string constant that describes the date and time
2367 of the last modification of the current source file. The string constant
2368 contains abbreviated day of the week, month, day of the month, time in
2369 hh:mm:ss form, year and looks like @code{@w{"Sun Sep 16 01:03:52 1973"}}.
2370 If the day of the month is less than 10, it is padded with a space on the left.
2372 If GCC cannot determine the current date, it will emit a warning message
2373 (once per compilation) and @code{__TIMESTAMP__} will expand to
2374 @code{@w{"??? ??? ?? ??:??:?? ????"}}.
2376 @item __GCC_HAVE_SYNC_COMPARE_AND_SWAP_1
2377 @itemx __GCC_HAVE_SYNC_COMPARE_AND_SWAP_2
2378 @itemx __GCC_HAVE_SYNC_COMPARE_AND_SWAP_4
2379 @itemx __GCC_HAVE_SYNC_COMPARE_AND_SWAP_8
2380 @itemx __GCC_HAVE_SYNC_COMPARE_AND_SWAP_16
2381 These macros are defined when the target processor supports atomic compare
2382 and swap operations on operands 1, 2, 4, 8 or 16 bytes in length, respectively.
2384 @item __GCC_HAVE_DWARF2_CFI_ASM
2385 This macro is defined when the compiler is emitting DWARF CFI directives
2386 to the assembler. When this is defined, it is possible to emit those same
2387 directives in inline assembly.
2390 @itemx __FP_FAST_FMAF
2391 @itemx __FP_FAST_FMAL
2392 These macros are defined with value 1 if the backend supports the
2393 @code{fma}, @code{fmaf}, and @code{fmal} builtin functions, so that
2394 the include file @file{math.h} can define the macros
2395 @code{FP_FAST_FMA}, @code{FP_FAST_FMAF}, and @code{FP_FAST_FMAL}
2396 for compatibility with the 1999 C standard.
2398 @item __FP_FAST_FMAF16
2399 @itemx __FP_FAST_FMAF32
2400 @itemx __FP_FAST_FMAF64
2401 @itemx __FP_FAST_FMAF128
2402 @itemx __FP_FAST_FMAF32X
2403 @itemx __FP_FAST_FMAF64X
2404 @itemx __FP_FAST_FMAF128X
2405 These macros are defined with the value 1 if the backend supports the
2406 @code{fma} functions using the additional @code{_Float@var{n}} and
2407 @code{_Float@var{n}x} types that are defined in ISO/IEC TS
2408 18661-3:2015. The include file @file{math.h} can define the
2409 @code{FP_FAST_FMAF@var{n}} and @code{FP_FAST_FMAF@var{n}x} macros if
2410 the user defined @code{__STDC_WANT_IEC_60559_TYPES_EXT__} before
2411 including @file{math.h}.
2414 This macro is defined to indicate the intended level of support for
2415 IEEE 754 (IEC 60559) floating-point arithmetic. It expands to a
2416 nonnegative integer value. If 0, it indicates that the combination of
2417 the compiler configuration and the command-line options is not
2418 intended to support IEEE 754 arithmetic for @code{float} and
2419 @code{double} as defined in C99 and C11 Annex F (for example, that the
2420 standard rounding modes and exceptions are not supported, or that
2421 optimizations are enabled that conflict with IEEE 754 semantics). If
2422 1, it indicates that IEEE 754 arithmetic is intended to be supported;
2423 this does not mean that all relevant language features are supported
2424 by GCC. If 2 or more, it additionally indicates support for IEEE
2425 754-2008 (in particular, that the binary encodings for quiet and
2426 signaling NaNs are as specified in IEEE 754-2008).
2428 This macro does not indicate the default state of command-line options
2429 that control optimizations that C99 and C11 permit to be controlled by
2430 standard pragmas, where those standards do not require a particular
2431 default state. It does not indicate whether optimizations respect
2432 signaling NaN semantics (the macro for that is
2433 @code{__SUPPORT_SNAN__}). It does not indicate support for decimal
2434 floating point or the IEEE 754 binary16 and binary128 types.
2436 @item __GCC_IEC_559_COMPLEX
2437 This macro is defined to indicate the intended level of support for
2438 IEEE 754 (IEC 60559) floating-point arithmetic for complex numbers, as
2439 defined in C99 and C11 Annex G. It expands to a nonnegative integer
2440 value. If 0, it indicates that the combination of the compiler
2441 configuration and the command-line options is not intended to support
2442 Annex G requirements (for example, because @option{-fcx-limited-range}
2443 was used). If 1 or more, it indicates that it is intended to support
2444 those requirements; this does not mean that all relevant language
2445 features are supported by GCC.
2447 @item __NO_MATH_ERRNO__
2448 This macro is defined if @option{-fno-math-errno} is used, or enabled
2449 by another option such as @option{-ffast-math} or by default.
2452 @node System-specific Predefined Macros
2453 @subsection System-specific Predefined Macros
2455 @cindex system-specific predefined macros
2456 @cindex predefined macros, system-specific
2457 @cindex reserved namespace
2459 The C preprocessor normally predefines several macros that indicate what
2460 type of system and machine is in use. They are obviously different on
2461 each target supported by GCC@. This manual, being for all systems and
2462 machines, cannot tell you what their names are, but you can use
2463 @command{cpp -dM} to see them all. @xref{Invocation}. All system-specific
2464 predefined macros expand to a constant value, so you can test them with
2465 either @samp{#ifdef} or @samp{#if}.
2467 The C standard requires that all system-specific macros be part of the
2468 @dfn{reserved namespace}. All names which begin with two underscores,
2469 or an underscore and a capital letter, are reserved for the compiler and
2470 library to use as they wish. However, historically system-specific
2471 macros have had names with no special prefix; for instance, it is common
2472 to find @code{unix} defined on Unix systems. For all such macros, GCC
2473 provides a parallel macro with two underscores added at the beginning
2474 and the end. If @code{unix} is defined, @code{__unix__} will be defined
2475 too. There will never be more than two underscores; the parallel of
2476 @code{_mips} is @code{__mips__}.
2478 When the @option{-ansi} option, or any @option{-std} option that
2479 requests strict conformance, is given to the compiler, all the
2480 system-specific predefined macros outside the reserved namespace are
2481 suppressed. The parallel macros, inside the reserved namespace, remain
2484 We are slowly phasing out all predefined macros which are outside the
2485 reserved namespace. You should never use them in new programs, and we
2486 encourage you to correct older code to use the parallel macros whenever
2487 you find it. We don't recommend you use the system-specific macros that
2488 are in the reserved namespace, either. It is better in the long run to
2489 check specifically for features you need, using a tool such as
2492 @node C++ Named Operators
2493 @subsection C++ Named Operators
2494 @cindex named operators
2495 @cindex C++ named operators
2496 @cindex @file{iso646.h}
2498 In C++, there are eleven keywords which are simply alternate spellings
2499 of operators normally written with punctuation. These keywords are
2500 treated as such even in the preprocessor. They function as operators in
2501 @samp{#if}, and they cannot be defined as macros or poisoned. In C, you
2502 can request that those keywords take their C++ meaning by including
2503 @file{iso646.h}. That header defines each one as a normal object-like
2504 macro expanding to the appropriate punctuator.
2506 These are the named operators and their corresponding punctuators:
2508 @multitable {Named Operator} {Punctuator}
2509 @item Named Operator @tab Punctuator
2510 @item @code{and} @tab @code{&&}
2511 @item @code{and_eq} @tab @code{&=}
2512 @item @code{bitand} @tab @code{&}
2513 @item @code{bitor} @tab @code{|}
2514 @item @code{compl} @tab @code{~}
2515 @item @code{not} @tab @code{!}
2516 @item @code{not_eq} @tab @code{!=}
2517 @item @code{or} @tab @code{||}
2518 @item @code{or_eq} @tab @code{|=}
2519 @item @code{xor} @tab @code{^}
2520 @item @code{xor_eq} @tab @code{^=}
2523 @node Undefining and Redefining Macros
2524 @section Undefining and Redefining Macros
2525 @cindex undefining macros
2526 @cindex redefining macros
2529 If a macro ceases to be useful, it may be @dfn{undefined} with the
2530 @samp{#undef} directive. @samp{#undef} takes a single argument, the
2531 name of the macro to undefine. You use the bare macro name, even if the
2532 macro is function-like. It is an error if anything appears on the line
2533 after the macro name. @samp{#undef} has no effect if the name is not a
2538 x = FOO; @expansion{} x = 4;
2540 x = FOO; @expansion{} x = FOO;
2543 Once a macro has been undefined, that identifier may be @dfn{redefined}
2544 as a macro by a subsequent @samp{#define} directive. The new definition
2545 need not have any resemblance to the old definition.
2547 However, if an identifier which is currently a macro is redefined, then
2548 the new definition must be @dfn{effectively the same} as the old one.
2549 Two macro definitions are effectively the same if:
2551 @item Both are the same type of macro (object- or function-like).
2552 @item All the tokens of the replacement list are the same.
2553 @item If there are any parameters, they are the same.
2554 @item Whitespace appears in the same places in both. It need not be
2555 exactly the same amount of whitespace, though. Remember that comments
2556 count as whitespace.
2560 These definitions are effectively the same:
2562 #define FOUR (2 + 2)
2563 #define FOUR (2 + 2)
2564 #define FOUR (2 /* @r{two} */ + 2)
2569 #define FOUR (2 + 2)
2570 #define FOUR ( 2+2 )
2571 #define FOUR (2 * 2)
2572 #define FOUR(score,and,seven,years,ago) (2 + 2)
2575 If a macro is redefined with a definition that is not effectively the
2576 same as the old one, the preprocessor issues a warning and changes the
2577 macro to use the new definition. If the new definition is effectively
2578 the same, the redefinition is silently ignored. This allows, for
2579 instance, two different headers to define a common macro. The
2580 preprocessor will only complain if the definitions do not match.
2582 @node Directives Within Macro Arguments
2583 @section Directives Within Macro Arguments
2584 @cindex macro arguments and directives
2586 Occasionally it is convenient to use preprocessor directives within
2587 the arguments of a macro. The C and C++ standards declare that
2588 behavior in these cases is undefined. GNU CPP
2589 processes arbitrary directives within macro arguments in
2590 exactly the same way as it would have processed the directive were the
2591 function-like macro invocation not present.
2593 If, within a macro invocation, that macro is redefined, then the new
2594 definition takes effect in time for argument pre-expansion, but the
2595 original definition is still used for argument replacement. Here is a
2596 pathological example:
2614 with the semantics described above.
2616 @node Macro Pitfalls
2617 @section Macro Pitfalls
2618 @cindex problems with macros
2619 @cindex pitfalls of macros
2621 In this section we describe some special rules that apply to macros and
2622 macro expansion, and point out certain cases in which the rules have
2623 counter-intuitive consequences that you must watch out for.
2627 * Operator Precedence Problems::
2628 * Swallowing the Semicolon::
2629 * Duplication of Side Effects::
2630 * Self-Referential Macros::
2631 * Argument Prescan::
2632 * Newlines in Arguments::
2636 @subsection Misnesting
2638 When a macro is called with arguments, the arguments are substituted
2639 into the macro body and the result is checked, together with the rest of
2640 the input file, for more macro calls. It is possible to piece together
2641 a macro call coming partially from the macro body and partially from the
2642 arguments. For example,
2645 #define twice(x) (2*(x))
2646 #define call_with_1(x) x(1)
2648 @expansion{} twice(1)
2649 @expansion{} (2*(1))
2652 Macro definitions do not have to have balanced parentheses. By writing
2653 an unbalanced open parenthesis in a macro body, it is possible to create
2654 a macro call that begins inside the macro body but ends outside of it.
2658 #define strange(file) fprintf (file, "%s %d",
2660 strange(stderr) p, 35)
2661 @expansion{} fprintf (stderr, "%s %d", p, 35)
2664 The ability to piece together a macro call can be useful, but the use of
2665 unbalanced open parentheses in a macro body is just confusing, and
2668 @node Operator Precedence Problems
2669 @subsection Operator Precedence Problems
2670 @cindex parentheses in macro bodies
2672 You may have noticed that in most of the macro definition examples shown
2673 above, each occurrence of a macro argument name had parentheses around
2674 it. In addition, another pair of parentheses usually surround the
2675 entire macro definition. Here is why it is best to write macros that
2678 Suppose you define a macro as follows,
2681 #define ceil_div(x, y) (x + y - 1) / y
2685 whose purpose is to divide, rounding up. (One use for this operation is
2686 to compute how many @code{int} objects are needed to hold a certain
2687 number of @code{char} objects.) Then suppose it is used as follows:
2690 a = ceil_div (b & c, sizeof (int));
2691 @expansion{} a = (b & c + sizeof (int) - 1) / sizeof (int);
2695 This does not do what is intended. The operator-precedence rules of
2696 C make it equivalent to this:
2699 a = (b & (c + sizeof (int) - 1)) / sizeof (int);
2703 What we want is this:
2706 a = ((b & c) + sizeof (int) - 1)) / sizeof (int);
2710 Defining the macro as
2713 #define ceil_div(x, y) ((x) + (y) - 1) / (y)
2717 provides the desired result.
2719 Unintended grouping can result in another way. Consider @code{sizeof
2720 ceil_div(1, 2)}. That has the appearance of a C expression that would
2721 compute the size of the type of @code{ceil_div (1, 2)}, but in fact it
2722 means something very different. Here is what it expands to:
2725 sizeof ((1) + (2) - 1) / (2)
2729 This would take the size of an integer and divide it by two. The
2730 precedence rules have put the division outside the @code{sizeof} when it
2731 was intended to be inside.
2733 Parentheses around the entire macro definition prevent such problems.
2734 Here, then, is the recommended way to define @code{ceil_div}:
2737 #define ceil_div(x, y) (((x) + (y) - 1) / (y))
2740 @node Swallowing the Semicolon
2741 @subsection Swallowing the Semicolon
2742 @cindex semicolons (after macro calls)
2744 Often it is desirable to define a macro that expands into a compound
2745 statement. Consider, for example, the following macro, that advances a
2746 pointer (the argument @code{p} says where to find it) across whitespace
2750 #define SKIP_SPACES(p, limit) \
2751 @{ char *lim = (limit); \
2752 while (p < lim) @{ \
2753 if (*p++ != ' ') @{ \
2758 Here backslash-newline is used to split the macro definition, which must
2759 be a single logical line, so that it resembles the way such code would
2760 be laid out if not part of a macro definition.
2762 A call to this macro might be @code{SKIP_SPACES (p, lim)}. Strictly
2763 speaking, the call expands to a compound statement, which is a complete
2764 statement with no need for a semicolon to end it. However, since it
2765 looks like a function call, it minimizes confusion if you can use it
2766 like a function call, writing a semicolon afterward, as in
2767 @code{SKIP_SPACES (p, lim);}
2769 This can cause trouble before @code{else} statements, because the
2770 semicolon is actually a null statement. Suppose you write
2774 SKIP_SPACES (p, lim);
2779 The presence of two statements---the compound statement and a null
2780 statement---in between the @code{if} condition and the @code{else}
2781 makes invalid C code.
2783 The definition of the macro @code{SKIP_SPACES} can be altered to solve
2784 this problem, using a @code{do @dots{} while} statement. Here is how:
2787 #define SKIP_SPACES(p, limit) \
2788 do @{ char *lim = (limit); \
2789 while (p < lim) @{ \
2790 if (*p++ != ' ') @{ \
2791 p--; break; @}@}@} \
2795 Now @code{SKIP_SPACES (p, lim);} expands into
2798 do @{@dots{}@} while (0);
2802 which is one statement. The loop executes exactly once; most compilers
2803 generate no extra code for it.
2805 @node Duplication of Side Effects
2806 @subsection Duplication of Side Effects
2808 @cindex side effects (in macro arguments)
2809 @cindex unsafe macros
2810 Many C programs define a macro @code{min}, for ``minimum'', like this:
2813 #define min(X, Y) ((X) < (Y) ? (X) : (Y))
2816 When you use this macro with an argument containing a side effect,
2820 next = min (x + y, foo (z));
2824 it expands as follows:
2827 next = ((x + y) < (foo (z)) ? (x + y) : (foo (z)));
2831 where @code{x + y} has been substituted for @code{X} and @code{foo (z)}
2834 The function @code{foo} is used only once in the statement as it appears
2835 in the program, but the expression @code{foo (z)} has been substituted
2836 twice into the macro expansion. As a result, @code{foo} might be called
2837 two times when the statement is executed. If it has side effects or if
2838 it takes a long time to compute, the results might not be what you
2839 intended. We say that @code{min} is an @dfn{unsafe} macro.
2841 The best solution to this problem is to define @code{min} in a way that
2842 computes the value of @code{foo (z)} only once. The C language offers
2843 no standard way to do this, but it can be done with GNU extensions as
2848 (@{ typeof (X) x_ = (X); \
2849 typeof (Y) y_ = (Y); \
2850 (x_ < y_) ? x_ : y_; @})
2853 The @samp{(@{ @dots{} @})} notation produces a compound statement that
2854 acts as an expression. Its value is the value of its last statement.
2855 This permits us to define local variables and assign each argument to
2856 one. The local variables have underscores after their names to reduce
2857 the risk of conflict with an identifier of wider scope (it is impossible
2858 to avoid this entirely). Now each argument is evaluated exactly once.
2860 If you do not wish to use GNU C extensions, the only solution is to be
2861 careful when @emph{using} the macro @code{min}. For example, you can
2862 calculate the value of @code{foo (z)}, save it in a variable, and use
2863 that variable in @code{min}:
2867 #define min(X, Y) ((X) < (Y) ? (X) : (Y))
2871 next = min (x + y, tem);
2877 (where we assume that @code{foo} returns type @code{int}).
2879 @node Self-Referential Macros
2880 @subsection Self-Referential Macros
2881 @cindex self-reference
2883 A @dfn{self-referential} macro is one whose name appears in its
2884 definition. Recall that all macro definitions are rescanned for more
2885 macros to replace. If the self-reference were considered a use of the
2886 macro, it would produce an infinitely large expansion. To prevent this,
2887 the self-reference is not considered a macro call. It is passed into
2888 the preprocessor output unchanged. Consider an example:
2891 #define foo (4 + foo)
2895 where @code{foo} is also a variable in your program.
2897 Following the ordinary rules, each reference to @code{foo} will expand
2898 into @code{(4 + foo)}; then this will be rescanned and will expand into
2899 @code{(4 + (4 + foo))}; and so on until the computer runs out of memory.
2901 The self-reference rule cuts this process short after one step, at
2902 @code{(4 + foo)}. Therefore, this macro definition has the possibly
2903 useful effect of causing the program to add 4 to the value of @code{foo}
2904 wherever @code{foo} is referred to.
2906 In most cases, it is a bad idea to take advantage of this feature. A
2907 person reading the program who sees that @code{foo} is a variable will
2908 not expect that it is a macro as well. The reader will come across the
2909 identifier @code{foo} in the program and think its value should be that
2910 of the variable @code{foo}, whereas in fact the value is four greater.
2912 One common, useful use of self-reference is to create a macro which
2913 expands to itself. If you write
2920 then the macro @code{EPERM} expands to @code{EPERM}. Effectively, it is
2921 left alone by the preprocessor whenever it's used in running text. You
2922 can tell that it's a macro with @samp{#ifdef}. You might do this if you
2923 want to define numeric constants with an @code{enum}, but have
2924 @samp{#ifdef} be true for each constant.
2926 If a macro @code{x} expands to use a macro @code{y}, and the expansion of
2927 @code{y} refers to the macro @code{x}, that is an @dfn{indirect
2928 self-reference} of @code{x}. @code{x} is not expanded in this case
2929 either. Thus, if we have
2937 then @code{x} and @code{y} expand as follows:
2941 x @expansion{} (4 + y)
2942 @expansion{} (4 + (2 * x))
2944 y @expansion{} (2 * x)
2945 @expansion{} (2 * (4 + y))
2950 Each macro is expanded when it appears in the definition of the other
2951 macro, but not when it indirectly appears in its own definition.
2953 @node Argument Prescan
2954 @subsection Argument Prescan
2955 @cindex expansion of arguments
2956 @cindex macro argument expansion
2957 @cindex prescan of macro arguments
2959 Macro arguments are completely macro-expanded before they are
2960 substituted into a macro body, unless they are stringized or pasted
2961 with other tokens. After substitution, the entire macro body, including
2962 the substituted arguments, is scanned again for macros to be expanded.
2963 The result is that the arguments are scanned @emph{twice} to expand
2964 macro calls in them.
2966 Most of the time, this has no effect. If the argument contained any
2967 macro calls, they are expanded during the first scan. The result
2968 therefore contains no macro calls, so the second scan does not change
2969 it. If the argument were substituted as given, with no prescan, the
2970 single remaining scan would find the same macro calls and produce the
2973 You might expect the double scan to change the results when a
2974 self-referential macro is used in an argument of another macro
2975 (@pxref{Self-Referential Macros}): the self-referential macro would be
2976 expanded once in the first scan, and a second time in the second scan.
2977 However, this is not what happens. The self-references that do not
2978 expand in the first scan are marked so that they will not expand in the
2981 You might wonder, ``Why mention the prescan, if it makes no difference?
2982 And why not skip it and make the preprocessor faster?'' The answer is
2983 that the prescan does make a difference in three special cases:
2987 Nested calls to a macro.
2989 We say that @dfn{nested} calls to a macro occur when a macro's argument
2990 contains a call to that very macro. For example, if @code{f} is a macro
2991 that expects one argument, @code{f (f (1))} is a nested pair of calls to
2992 @code{f}. The desired expansion is made by expanding @code{f (1)} and
2993 substituting that into the definition of @code{f}. The prescan causes
2994 the expected result to happen. Without the prescan, @code{f (1)} itself
2995 would be substituted as an argument, and the inner use of @code{f} would
2996 appear during the main scan as an indirect self-reference and would not
3000 Macros that call other macros that stringize or concatenate.
3002 If an argument is stringized or concatenated, the prescan does not
3003 occur. If you @emph{want} to expand a macro, then stringize or
3004 concatenate its expansion, you can do that by causing one macro to call
3005 another macro that does the stringizing or concatenation. For
3006 instance, if you have
3009 #define AFTERX(x) X_ ## x
3010 #define XAFTERX(x) AFTERX(x)
3011 #define TABLESIZE 1024
3012 #define BUFSIZE TABLESIZE
3015 then @code{AFTERX(BUFSIZE)} expands to @code{X_BUFSIZE}, and
3016 @code{XAFTERX(BUFSIZE)} expands to @code{X_1024}. (Not to
3017 @code{X_TABLESIZE}. Prescan always does a complete expansion.)
3020 Macros used in arguments, whose expansions contain unshielded commas.
3022 This can cause a macro expanded on the second scan to be called with the
3023 wrong number of arguments. Here is an example:
3027 #define bar(x) lose(x)
3028 #define lose(x) (1 + (x))
3031 We would like @code{bar(foo)} to turn into @code{(1 + (foo))}, which
3032 would then turn into @code{(1 + (a,b))}. Instead, @code{bar(foo)}
3033 expands into @code{lose(a,b)}, and you get an error because @code{lose}
3034 requires a single argument. In this case, the problem is easily solved
3035 by the same parentheses that ought to be used to prevent misnesting of
3036 arithmetic operations:
3041 #define bar(x) lose((x))
3044 The extra pair of parentheses prevents the comma in @code{foo}'s
3045 definition from being interpreted as an argument separator.
3049 @node Newlines in Arguments
3050 @subsection Newlines in Arguments
3051 @cindex newlines in macro arguments
3053 The invocation of a function-like macro can extend over many logical
3054 lines. However, in the present implementation, the entire expansion
3055 comes out on one line. Thus line numbers emitted by the compiler or
3056 debugger refer to the line the invocation started on, which might be
3057 different to the line containing the argument causing the problem.
3059 Here is an example illustrating this:
3062 #define ignore_second_arg(a,b,c) a; c
3064 ignore_second_arg (foo (),
3070 The syntax error triggered by the tokens @code{syntax error} results in
3071 an error message citing line three---the line of ignore_second_arg---
3072 even though the problematic code comes from line five.
3074 We consider this a bug, and intend to fix it in the near future.
3077 @chapter Conditionals
3078 @cindex conditionals
3080 A @dfn{conditional} is a directive that instructs the preprocessor to
3081 select whether or not to include a chunk of code in the final token
3082 stream passed to the compiler. Preprocessor conditionals can test
3083 arithmetic expressions, or whether a name is defined as a macro, or both
3084 simultaneously using the special @code{defined} operator.
3086 A conditional in the C preprocessor resembles in some ways an @code{if}
3087 statement in C, but it is important to understand the difference between
3088 them. The condition in an @code{if} statement is tested during the
3089 execution of your program. Its purpose is to allow your program to
3090 behave differently from run to run, depending on the data it is
3091 operating on. The condition in a preprocessing conditional directive is
3092 tested when your program is compiled. Its purpose is to allow different
3093 code to be included in the program depending on the situation at the
3094 time of compilation.
3096 However, the distinction is becoming less clear. Modern compilers often
3097 do test @code{if} statements when a program is compiled, if their
3098 conditions are known not to vary at run time, and eliminate code which
3099 can never be executed. If you can count on your compiler to do this,
3100 you may find that your program is more readable if you use @code{if}
3101 statements with constant conditions (perhaps determined by macros). Of
3102 course, you can only use this to exclude code, not type definitions or
3103 other preprocessing directives, and you can only do it if the code
3104 remains syntactically valid when it is not to be used.
3107 * Conditional Uses::
3108 * Conditional Syntax::
3112 @node Conditional Uses
3113 @section Conditional Uses
3115 There are three general reasons to use a conditional.
3119 A program may need to use different code depending on the machine or
3120 operating system it is to run on. In some cases the code for one
3121 operating system may be erroneous on another operating system; for
3122 example, it might refer to data types or constants that do not exist on
3123 the other system. When this happens, it is not enough to avoid
3124 executing the invalid code. Its mere presence will cause the compiler
3125 to reject the program. With a preprocessing conditional, the offending
3126 code can be effectively excised from the program when it is not valid.
3129 You may want to be able to compile the same source file into two
3130 different programs. One version might make frequent time-consuming
3131 consistency checks on its intermediate data, or print the values of
3132 those data for debugging, and the other not.
3135 A conditional whose condition is always false is one way to exclude code
3136 from the program but keep it as a sort of comment for future reference.
3139 Simple programs that do not need system-specific logic or complex
3140 debugging hooks generally will not need to use preprocessing
3143 @node Conditional Syntax
3144 @section Conditional Syntax
3147 A conditional in the C preprocessor begins with a @dfn{conditional
3148 directive}: @samp{#if}, @samp{#ifdef} or @samp{#ifndef}.
3163 The simplest sort of conditional is
3169 @var{controlled text}
3171 #endif /* @var{MACRO} */
3175 @cindex conditional group
3176 This block is called a @dfn{conditional group}. @var{controlled text}
3177 will be included in the output of the preprocessor if and only if
3178 @var{MACRO} is defined. We say that the conditional @dfn{succeeds} if
3179 @var{MACRO} is defined, @dfn{fails} if it is not.
3181 The @var{controlled text} inside of a conditional can include
3182 preprocessing directives. They are executed only if the conditional
3183 succeeds. You can nest conditional groups inside other conditional
3184 groups, but they must be completely nested. In other words,
3185 @samp{#endif} always matches the nearest @samp{#ifdef} (or
3186 @samp{#ifndef}, or @samp{#if}). Also, you cannot start a conditional
3187 group in one file and end it in another.
3189 Even if a conditional fails, the @var{controlled text} inside it is
3190 still run through initial transformations and tokenization. Therefore,
3191 it must all be lexically valid C@. Normally the only way this matters is
3192 that all comments and string literals inside a failing conditional group
3193 must still be properly ended.
3195 The comment following the @samp{#endif} is not required, but it is a
3196 good practice if there is a lot of @var{controlled text}, because it
3197 helps people match the @samp{#endif} to the corresponding @samp{#ifdef}.
3198 Older programs sometimes put @var{MACRO} directly after the
3199 @samp{#endif} without enclosing it in a comment. This is invalid code
3200 according to the C standard. CPP accepts it with a warning. It
3201 never affects which @samp{#ifndef} the @samp{#endif} matches.
3204 Sometimes you wish to use some code if a macro is @emph{not} defined.
3205 You can do this by writing @samp{#ifndef} instead of @samp{#ifdef}.
3206 One common use of @samp{#ifndef} is to include code only the first
3207 time a header file is included. @xref{Once-Only Headers}.
3209 Macro definitions can vary between compilations for several reasons.
3210 Here are some samples.
3214 Some macros are predefined on each kind of machine
3215 (@pxref{System-specific Predefined Macros}). This allows you to provide
3216 code specially tuned for a particular machine.
3219 System header files define more macros, associated with the features
3220 they implement. You can test these macros with conditionals to avoid
3221 using a system feature on a machine where it is not implemented.
3224 Macros can be defined or undefined with the @option{-D} and @option{-U}
3225 command-line options when you compile the program. You can arrange to
3226 compile the same source file into two different programs by choosing a
3227 macro name to specify which program you want, writing conditionals to
3228 test whether or how this macro is defined, and then controlling the
3229 state of the macro with command-line options, perhaps set in the
3230 Makefile. @xref{Invocation}.
3233 Your program might have a special header file (often called
3234 @file{config.h}) that is adjusted when the program is compiled. It can
3235 define or not define macros depending on the features of the system and
3236 the desired capabilities of the program. The adjustment can be
3237 automated by a tool such as @command{autoconf}, or done by hand.
3243 The @samp{#if} directive allows you to test the value of an arithmetic
3244 expression, rather than the mere existence of one macro. Its syntax is
3248 #if @var{expression}
3250 @var{controlled text}
3252 #endif /* @var{expression} */
3256 @var{expression} is a C expression of integer type, subject to stringent
3257 restrictions. It may contain
3264 Character constants, which are interpreted as they would be in normal
3268 Arithmetic operators for addition, subtraction, multiplication,
3269 division, bitwise operations, shifts, comparisons, and logical
3270 operations (@code{&&} and @code{||}). The latter two obey the usual
3271 short-circuiting rules of standard C@.
3274 Macros. All macros in the expression are expanded before actual
3275 computation of the expression's value begins.
3278 Uses of the @code{defined} operator, which lets you check whether macros
3279 are defined in the middle of an @samp{#if}.
3282 Identifiers that are not macros, which are all considered to be the
3283 number zero. This allows you to write @code{@w{#if MACRO}} instead of
3284 @code{@w{#ifdef MACRO}}, if you know that MACRO, when defined, will
3285 always have a nonzero value. Function-like macros used without their
3286 function call parentheses are also treated as zero.
3288 In some contexts this shortcut is undesirable. The @option{-Wundef}
3289 option causes GCC to warn whenever it encounters an identifier which is
3290 not a macro in an @samp{#if}.
3293 The preprocessor does not know anything about types in the language.
3294 Therefore, @code{sizeof} operators are not recognized in @samp{#if}, and
3295 neither are @code{enum} constants. They will be taken as identifiers
3296 which are not macros, and replaced by zero. In the case of
3297 @code{sizeof}, this is likely to cause the expression to be invalid.
3299 The preprocessor calculates the value of @var{expression}. It carries
3300 out all calculations in the widest integer type known to the compiler;
3301 on most machines supported by GCC this is 64 bits. This is not the same
3302 rule as the compiler uses to calculate the value of a constant
3303 expression, and may give different results in some cases. If the value
3304 comes out to be nonzero, the @samp{#if} succeeds and the @var{controlled
3305 text} is included; otherwise it is skipped.
3310 @cindex @code{defined}
3311 The special operator @code{defined} is used in @samp{#if} and
3312 @samp{#elif} expressions to test whether a certain name is defined as a
3313 macro. @code{defined @var{name}} and @code{defined (@var{name})} are
3314 both expressions whose value is 1 if @var{name} is defined as a macro at
3315 the current point in the program, and 0 otherwise. Thus, @code{@w{#if
3316 defined MACRO}} is precisely equivalent to @code{@w{#ifdef MACRO}}.
3318 @code{defined} is useful when you wish to test more than one macro for
3319 existence at once. For example,
3322 #if defined (__vax__) || defined (__ns16000__)
3326 would succeed if either of the names @code{__vax__} or
3327 @code{__ns16000__} is defined as a macro.
3329 Conditionals written like this:
3332 #if defined BUFSIZE && BUFSIZE >= 1024
3336 can generally be simplified to just @code{@w{#if BUFSIZE >= 1024}},
3337 since if @code{BUFSIZE} is not defined, it will be interpreted as having
3340 If the @code{defined} operator appears as a result of a macro expansion,
3341 the C standard says the behavior is undefined. GNU cpp treats it as a
3342 genuine @code{defined} operator and evaluates it normally. It will warn
3343 wherever your code uses this feature if you use the command-line option
3344 @option{-Wpedantic}, since other compilers may handle it differently. The
3345 warning is also enabled by @option{-Wextra}, and can also be enabled
3346 individually with @option{-Wexpansion-to-defined}.
3352 The @samp{#else} directive can be added to a conditional to provide
3353 alternative text to be used if the condition fails. This is what it
3358 #if @var{expression}
3360 #else /* Not @var{expression} */
3362 #endif /* Not @var{expression} */
3367 If @var{expression} is nonzero, the @var{text-if-true} is included and
3368 the @var{text-if-false} is skipped. If @var{expression} is zero, the
3371 You can use @samp{#else} with @samp{#ifdef} and @samp{#ifndef}, too.
3377 One common case of nested conditionals is used to check for more than two
3378 possible alternatives. For example, you might have
3392 Another conditional directive, @samp{#elif}, allows this to be
3393 abbreviated as follows:
3400 #else /* X != 2 and X != 1*/
3402 #endif /* X != 2 and X != 1*/
3405 @samp{#elif} stands for ``else if''. Like @samp{#else}, it goes in the
3406 middle of a conditional group and subdivides it; it does not require a
3407 matching @samp{#endif} of its own. Like @samp{#if}, the @samp{#elif}
3408 directive includes an expression to be tested. The text following the
3409 @samp{#elif} is processed only if the original @samp{#if}-condition
3410 failed and the @samp{#elif} condition succeeds.
3412 More than one @samp{#elif} can go in the same conditional group. Then
3413 the text after each @samp{#elif} is processed only if the @samp{#elif}
3414 condition succeeds after the original @samp{#if} and all previous
3415 @samp{#elif} directives within it have failed.
3417 @samp{#else} is allowed after any number of @samp{#elif} directives, but
3418 @samp{#elif} may not follow @samp{#else}.
3421 @section Deleted Code
3422 @cindex commenting out code
3424 If you replace or delete a part of the program but want to keep the old
3425 code around for future reference, you often cannot simply comment it
3426 out. Block comments do not nest, so the first comment inside the old
3427 code will end the commenting-out. The probable result is a flood of
3430 One way to avoid this problem is to use an always-false conditional
3431 instead. For instance, put @code{#if 0} before the deleted code and
3432 @code{#endif} after it. This works even if the code being turned
3433 off contains conditionals, but they must be entire conditionals
3434 (balanced @samp{#if} and @samp{#endif}).
3436 Some people use @code{#ifdef notdef} instead. This is risky, because
3437 @code{notdef} might be accidentally defined as a macro, and then the
3438 conditional would succeed. @code{#if 0} can be counted on to fail.
3440 Do not use @code{#if 0} for comments which are not C code. Use a real
3441 comment, instead. The interior of @code{#if 0} must consist of complete
3442 tokens; in particular, single-quote characters must balance. Comments
3443 often contain unbalanced single-quote characters (known in English as
3444 apostrophes). These confuse @code{#if 0}. They don't confuse
3448 @chapter Diagnostics
3450 @cindex reporting errors
3451 @cindex reporting warnings
3454 The directive @samp{#error} causes the preprocessor to report a fatal
3455 error. The tokens forming the rest of the line following @samp{#error}
3456 are used as the error message.
3458 You would use @samp{#error} inside of a conditional that detects a
3459 combination of parameters which you know the program does not properly
3460 support. For example, if you know that the program will not run
3461 properly on a VAX, you might write
3466 #error "Won't work on VAXen. See comments at get_last_object."
3471 If you have several configuration parameters that must be set up by
3472 the installation in a consistent way, you can use conditionals to detect
3473 an inconsistency and report it with @samp{#error}. For example,
3476 #if !defined(FOO) && defined(BAR)
3477 #error "BAR requires FOO."
3482 The directive @samp{#warning} is like @samp{#error}, but causes the
3483 preprocessor to issue a warning and continue preprocessing. The tokens
3484 following @samp{#warning} are used as the warning message.
3486 You might use @samp{#warning} in obsolete header files, with a message
3487 directing the user to the header file which should be used instead.
3489 Neither @samp{#error} nor @samp{#warning} macro-expands its argument.
3490 Internal whitespace sequences are each replaced with a single space.
3491 The line must consist of complete tokens. It is wisest to make the
3492 argument of these directives be a single string constant; this avoids
3493 problems with apostrophes and the like.
3496 @chapter Line Control
3497 @cindex line control
3499 The C preprocessor informs the C compiler of the location in your source
3500 code where each token came from. Presently, this is just the file name
3501 and line number. All the tokens resulting from macro expansion are
3502 reported as having appeared on the line of the source file where the
3503 outermost macro was used. We intend to be more accurate in the future.
3505 If you write a program which generates source code, such as the
3506 @command{bison} parser generator, you may want to adjust the preprocessor's
3507 notion of the current file name and line number by hand. Parts of the
3508 output from @command{bison} are generated from scratch, other parts come
3509 from a standard parser file. The rest are copied verbatim from
3510 @command{bison}'s input. You would like compiler error messages and
3511 symbolic debuggers to be able to refer to @code{bison}'s input file.
3514 @command{bison} or any such program can arrange this by writing
3515 @samp{#line} directives into the output file. @samp{#line} is a
3516 directive that specifies the original line number and source file name
3517 for subsequent input in the current preprocessor input file.
3518 @samp{#line} has three variants:
3521 @item #line @var{linenum}
3522 @var{linenum} is a non-negative decimal integer constant. It specifies
3523 the line number which should be reported for the following line of
3524 input. Subsequent lines are counted from @var{linenum}.
3526 @item #line @var{linenum} @var{filename}
3527 @var{linenum} is the same as for the first form, and has the same
3528 effect. In addition, @var{filename} is a string constant. The
3529 following line and all subsequent lines are reported to come from the
3530 file it specifies, until something else happens to change that.
3531 @var{filename} is interpreted according to the normal rules for a string
3532 constant: backslash escapes are interpreted. This is different from
3535 @item #line @var{anything else}
3536 @var{anything else} is checked for macro calls, which are expanded.
3537 The result should match one of the above two forms.
3540 @samp{#line} directives alter the results of the @code{__FILE__} and
3541 @code{__LINE__} predefined macros from that point on. @xref{Standard
3542 Predefined Macros}. They do not have any effect on @samp{#include}'s
3543 idea of the directory containing the current file.
3548 The @samp{#pragma} directive is the method specified by the C standard
3549 for providing additional information to the compiler, beyond what is
3550 conveyed in the language itself. The forms of this directive
3551 (commonly known as @dfn{pragmas}) specified by C standard are prefixed with
3552 @code{STDC}. A C compiler is free to attach any meaning it likes to other
3553 pragmas. All GNU-defined, supported pragmas have been given a
3556 @cindex @code{_Pragma}
3557 C99 introduced the @code{@w{_Pragma}} operator. This feature addresses a
3558 major problem with @samp{#pragma}: being a directive, it cannot be
3559 produced as the result of macro expansion. @code{@w{_Pragma}} is an
3560 operator, much like @code{sizeof} or @code{defined}, and can be embedded
3563 Its syntax is @code{@w{_Pragma (@var{string-literal})}}, where
3564 @var{string-literal} can be either a normal or wide-character string
3565 literal. It is destringized, by replacing all @samp{\\} with a single
3566 @samp{\} and all @samp{\"} with a @samp{"}. The result is then
3567 processed as if it had appeared as the right hand side of a
3568 @samp{#pragma} directive. For example,
3571 _Pragma ("GCC dependency \"parse.y\"")
3575 has the same effect as @code{#pragma GCC dependency "parse.y"}. The
3576 same effect could be achieved using macros, for example
3579 #define DO_PRAGMA(x) _Pragma (#x)
3580 DO_PRAGMA (GCC dependency "parse.y")
3583 The standard is unclear on where a @code{_Pragma} operator can appear.
3584 The preprocessor does not accept it within a preprocessing conditional
3585 directive like @samp{#if}. To be safe, you are probably best keeping it
3586 out of directives other than @samp{#define}, and putting it on a line of
3589 This manual documents the pragmas which are meaningful to the
3590 preprocessor itself. Other pragmas are meaningful to the C or C++
3591 compilers. They are documented in the GCC manual.
3593 GCC plugins may provide their own pragmas.
3596 @item #pragma GCC dependency
3597 @code{#pragma GCC dependency} allows you to check the relative dates of
3598 the current file and another file. If the other file is more recent than
3599 the current file, a warning is issued. This is useful if the current
3600 file is derived from the other file, and should be regenerated. The
3601 other file is searched for using the normal include search path.
3602 Optional trailing text can be used to give more information in the
3606 #pragma GCC dependency "parse.y"
3607 #pragma GCC dependency "/usr/include/time.h" rerun fixincludes
3610 @item #pragma GCC poison
3611 Sometimes, there is an identifier that you want to remove completely
3612 from your program, and make sure that it never creeps back in. To
3613 enforce this, you can @dfn{poison} the identifier with this pragma.
3614 @code{#pragma GCC poison} is followed by a list of identifiers to
3615 poison. If any of those identifiers appears anywhere in the source
3616 after the directive, it is a hard error. For example,
3619 #pragma GCC poison printf sprintf fprintf
3620 sprintf(some_string, "hello");
3624 will produce an error.
3626 If a poisoned identifier appears as part of the expansion of a macro
3627 which was defined before the identifier was poisoned, it will @emph{not}
3628 cause an error. This lets you poison an identifier without worrying
3629 about system headers defining macros that use it.
3634 #define strrchr rindex
3635 #pragma GCC poison rindex
3636 strrchr(some_string, 'h');
3640 will not produce an error.
3642 @item #pragma GCC system_header
3643 This pragma takes no arguments. It causes the rest of the code in the
3644 current file to be treated as if it came from a system header.
3645 @xref{System Headers}.
3647 @item #pragma GCC warning
3648 @itemx #pragma GCC error
3649 @code{#pragma GCC warning "message"} causes the preprocessor to issue
3650 a warning diagnostic with the text @samp{message}. The message
3651 contained in the pragma must be a single string literal. Similarly,
3652 @code{#pragma GCC error "message"} issues an error message. Unlike
3653 the @samp{#warning} and @samp{#error} directives, these pragmas can be
3654 embedded in preprocessor macros using @samp{_Pragma}.
3658 @node Other Directives
3659 @chapter Other Directives
3663 The @samp{#ident} directive takes one argument, a string constant. On
3664 some systems, that string constant is copied into a special segment of
3665 the object file. On other systems, the directive is ignored. The
3666 @samp{#sccs} directive is a synonym for @samp{#ident}.
3668 These directives are not part of the C standard, but they are not
3669 official GNU extensions either. What historical information we have
3670 been able to find, suggests they originated with System V@.
3672 @cindex null directive
3673 The @dfn{null directive} consists of a @samp{#} followed by a newline,
3674 with only whitespace (including comments) in between. A null directive
3675 is understood as a preprocessing directive but has no effect on the
3676 preprocessor output. The primary significance of the existence of the
3677 null directive is that an input line consisting of just a @samp{#} will
3678 produce no output, rather than a line of output containing just a
3679 @samp{#}. Supposedly some old C programs contain such lines.
3681 @node Preprocessor Output
3682 @chapter Preprocessor Output
3684 When the C preprocessor is used with the C, C++, or Objective-C
3685 compilers, it is integrated into the compiler and communicates a stream
3686 of binary tokens directly to the compiler's parser. However, it can
3687 also be used in the more conventional standalone mode, where it produces
3689 @c FIXME: Document the library interface.
3691 @cindex output format
3692 The output from the C preprocessor looks much like the input, except
3693 that all preprocessing directive lines have been replaced with blank
3694 lines and all comments with spaces. Long runs of blank lines are
3697 The ISO standard specifies that it is implementation defined whether a
3698 preprocessor preserves whitespace between tokens, or replaces it with
3699 e.g.@: a single space. In GNU CPP, whitespace between tokens is collapsed
3700 to become a single space, with the exception that the first token on a
3701 non-directive line is preceded with sufficient spaces that it appears in
3702 the same column in the preprocessed output that it appeared in the
3703 original source file. This is so the output is easy to read.
3704 CPP does not insert any
3705 whitespace where there was none in the original source, except where
3706 necessary to prevent an accidental token paste.
3709 Source file name and line number information is conveyed by lines
3713 # @var{linenum} @var{filename} @var{flags}
3717 These are called @dfn{linemarkers}. They are inserted as needed into
3718 the output (but never within a string or character constant). They mean
3719 that the following line originated in file @var{filename} at line
3720 @var{linenum}. @var{filename} will never contain any non-printing
3721 characters; they are replaced with octal escape sequences.
3723 After the file name comes zero or more flags, which are @samp{1},
3724 @samp{2}, @samp{3}, or @samp{4}. If there are multiple flags, spaces
3725 separate them. Here is what the flags mean:
3729 This indicates the start of a new file.
3731 This indicates returning to a file (after having included another file).
3733 This indicates that the following text comes from a system header file,
3734 so certain warnings should be suppressed.
3736 This indicates that the following text should be treated as being
3737 wrapped in an implicit @code{extern "C"} block.
3738 @c maybe cross reference NO_IMPLICIT_EXTERN_C
3741 As an extension, the preprocessor accepts linemarkers in non-assembler
3742 input files. They are treated like the corresponding @samp{#line}
3743 directive, (@pxref{Line Control}), except that trailing flags are
3744 permitted, and are interpreted with the meanings described above. If
3745 multiple flags are given, they must be in ascending order.
3747 Some directives may be duplicated in the output of the preprocessor.
3748 These are @samp{#ident} (always), @samp{#pragma} (only if the
3749 preprocessor does not handle the pragma itself), and @samp{#define} and
3750 @samp{#undef} (with certain debugging options). If this happens, the
3751 @samp{#} of the directive will always be in the first column, and there
3752 will be no space between the @samp{#} and the directive name. If macro
3753 expansion happens to generate tokens which might be mistaken for a
3754 duplicated directive, a space will be inserted between the @samp{#} and
3757 @node Traditional Mode
3758 @chapter Traditional Mode
3760 Traditional (pre-standard) C preprocessing is rather different from
3761 the preprocessing specified by the standard. When the preprocessor
3763 @option{-traditional-cpp} option, it attempts to emulate a traditional
3766 This mode is not useful for compiling C code with GCC,
3767 but is intended for use with non-C preprocessing applications. Thus
3768 traditional mode semantics are supported only when invoking
3769 the preprocessor explicitly, and not in the compiler front ends.
3771 The implementation does not correspond precisely to the behavior of
3772 early pre-standard versions of GCC, nor to any true traditional preprocessor.
3773 After all, inconsistencies among traditional implementations were a
3774 major motivation for C standardization. However, we intend that it
3775 should be compatible with true traditional preprocessors in all ways
3776 that actually matter.
3779 * Traditional lexical analysis::
3780 * Traditional macros::
3781 * Traditional miscellany::
3782 * Traditional warnings::
3785 @node Traditional lexical analysis
3786 @section Traditional lexical analysis
3788 The traditional preprocessor does not decompose its input into tokens
3789 the same way a standards-conforming preprocessor does. The input is
3790 simply treated as a stream of text with minimal internal form.
3792 This implementation does not treat trigraphs (@pxref{trigraphs})
3793 specially since they were an invention of the standards committee. It
3794 handles arbitrarily-positioned escaped newlines properly and splices
3795 the lines as you would expect; many traditional preprocessors did not
3798 The form of horizontal whitespace in the input file is preserved in
3799 the output. In particular, hard tabs remain hard tabs. This can be
3800 useful if, for example, you are preprocessing a Makefile.
3802 Traditional CPP only recognizes C-style block comments, and treats the
3803 @samp{/*} sequence as introducing a comment only if it lies outside
3804 quoted text. Quoted text is introduced by the usual single and double
3805 quotes, and also by an initial @samp{<} in a @code{#include}
3808 Traditionally, comments are completely removed and are not replaced
3809 with a space. Since a traditional compiler does its own tokenization
3810 of the output of the preprocessor, this means that comments can
3811 effectively be used as token paste operators. However, comments
3812 behave like separators for text handled by the preprocessor itself,
3813 since it doesn't re-lex its input. For example, in
3820 @samp{foo} and @samp{bar} are distinct identifiers and expanded
3821 separately if they happen to be macros. In other words, this
3822 directive is equivalent to
3835 Generally speaking, in traditional mode an opening quote need not have
3836 a matching closing quote. In particular, a macro may be defined with
3837 replacement text that contains an unmatched quote. Of course, if you
3838 attempt to compile preprocessed output containing an unmatched quote
3839 you will get a syntax error.
3841 However, all preprocessing directives other than @code{#define}
3842 require matching quotes. For example:
3845 #define m This macro's fine and has an unmatched quote
3846 "/* This is not a comment. */
3847 /* @r{This is a comment. The following #include directive
3852 Just as for the ISO preprocessor, what would be a closing quote can be
3853 escaped with a backslash to prevent the quoted text from closing.
3855 @node Traditional macros
3856 @section Traditional macros
3858 The major difference between traditional and ISO macros is that the
3859 former expand to text rather than to a token sequence. CPP removes
3860 all leading and trailing horizontal whitespace from a macro's
3861 replacement text before storing it, but preserves the form of internal
3864 One consequence is that it is legitimate for the replacement text to
3865 contain an unmatched quote (@pxref{Traditional lexical analysis}). An
3866 unclosed string or character constant continues into the text
3867 following the macro call. Similarly, the text at the end of a macro's
3868 expansion can run together with the text after the macro invocation to
3869 produce a single token.
3871 Normally comments are removed from the replacement text after the
3872 macro is expanded, but if the @option{-CC} option is passed on the
3873 command-line comments are preserved. (In fact, the current
3874 implementation removes comments even before saving the macro
3875 replacement text, but it careful to do it in such a way that the
3876 observed effect is identical even in the function-like macro case.)
3878 The ISO stringizing operator @samp{#} and token paste operator
3879 @samp{##} have no special meaning. As explained later, an effect
3880 similar to these operators can be obtained in a different way. Macro
3881 names that are embedded in quotes, either from the main file or after
3882 macro replacement, do not expand.
3884 CPP replaces an unquoted object-like macro name with its replacement
3885 text, and then rescans it for further macros to replace. Unlike
3886 standard macro expansion, traditional macro expansion has no provision
3887 to prevent recursion. If an object-like macro appears unquoted in its
3888 replacement text, it will be replaced again during the rescan pass,
3889 and so on @emph{ad infinitum}. GCC detects when it is expanding
3890 recursive macros, emits an error message, and continues after the
3891 offending macro invocation.
3895 #define INC(x) PLUS+x
3900 Function-like macros are similar in form but quite different in
3901 behavior to their ISO counterparts. Their arguments are contained
3902 within parentheses, are comma-separated, and can cross physical lines.
3903 Commas within nested parentheses are not treated as argument
3904 separators. Similarly, a quote in an argument cannot be left
3905 unclosed; a following comma or parenthesis that comes before the
3906 closing quote is treated like any other character. There is no
3907 facility for handling variadic macros.
3909 This implementation removes all comments from macro arguments, unless
3910 the @option{-C} option is given. The form of all other horizontal
3911 whitespace in arguments is preserved, including leading and trailing
3912 whitespace. In particular
3919 is treated as an invocation of the macro @samp{f} with a single
3920 argument consisting of a single space. If you want to invoke a
3921 function-like macro that takes no arguments, you must not leave any
3922 whitespace between the parentheses.
3924 If a macro argument crosses a new line, the new line is replaced with
3925 a space when forming the argument. If the previous line contained an
3926 unterminated quote, the following line inherits the quoted state.
3928 Traditional preprocessors replace parameters in the replacement text
3929 with their arguments regardless of whether the parameters are within
3930 quotes or not. This provides a way to stringize arguments. For
3935 str(/* @r{A comment} */some text )
3936 @expansion{} "some text "
3940 Note that the comment is removed, but that the trailing space is
3941 preserved. Here is an example of using a comment to effect token
3945 #define suffix(x) foo_/**/x
3947 @expansion{} foo_bar
3950 @node Traditional miscellany
3951 @section Traditional miscellany
3953 Here are some things to be aware of when using the traditional
3958 Preprocessing directives are recognized only when their leading
3959 @samp{#} appears in the first column. There can be no whitespace
3960 between the beginning of the line and the @samp{#}, but whitespace can
3961 follow the @samp{#}.
3964 A true traditional C preprocessor does not recognize @samp{#error} or
3965 @samp{#pragma}, and may not recognize @samp{#elif}. CPP supports all
3966 the directives in traditional mode that it supports in ISO mode,
3967 including extensions, with the exception that the effects of
3968 @samp{#pragma GCC poison} are undefined.
3971 __STDC__ is not defined.
3974 If you use digraphs the behavior is undefined.
3977 If a line that looks like a directive appears within macro arguments,
3978 the behavior is undefined.
3982 @node Traditional warnings
3983 @section Traditional warnings
3984 You can request warnings about features that did not exist, or worked
3985 differently, in traditional C with the @option{-Wtraditional} option.
3986 GCC does not warn about features of ISO C which you must use when you
3987 are using a conforming compiler, such as the @samp{#} and @samp{##}
3990 Presently @option{-Wtraditional} warns about:
3994 Macro parameters that appear within string literals in the macro body.
3995 In traditional C macro replacement takes place within string literals,
3996 but does not in ISO C@.
3999 In traditional C, some preprocessor directives did not exist.
4000 Traditional preprocessors would only consider a line to be a directive
4001 if the @samp{#} appeared in column 1 on the line. Therefore
4002 @option{-Wtraditional} warns about directives that traditional C
4003 understands but would ignore because the @samp{#} does not appear as the
4004 first character on the line. It also suggests you hide directives like
4005 @samp{#pragma} not understood by traditional C by indenting them. Some
4006 traditional implementations would not recognize @samp{#elif}, so it
4007 suggests avoiding it altogether.
4010 A function-like macro that appears without an argument list. In some
4011 traditional preprocessors this was an error. In ISO C it merely means
4012 that the macro is not expanded.
4015 The unary plus operator. This did not exist in traditional C@.
4018 The @samp{U} and @samp{LL} integer constant suffixes, which were not
4019 available in traditional C@. (Traditional C does support the @samp{L}
4020 suffix for simple long integer constants.) You are not warned about
4021 uses of these suffixes in macros defined in system headers. For
4022 instance, @code{UINT_MAX} may well be defined as @code{4294967295U}, but
4023 you will not be warned if you use @code{UINT_MAX}.
4025 You can usually avoid the warning, and the related warning about
4026 constants which are so large that they are unsigned, by writing the
4027 integer constant in question in hexadecimal, with no U suffix. Take
4028 care, though, because this gives the wrong result in exotic cases.
4031 @node Implementation Details
4032 @chapter Implementation Details
4034 Here we document details of how the preprocessor's implementation
4035 affects its user-visible behavior. You should try to avoid undue
4036 reliance on behavior described here, as it is possible that it will
4037 change subtly in future implementations.
4039 Also documented here are obsolete features still supported by CPP@.
4042 * Implementation-defined behavior::
4043 * Implementation limits::
4044 * Obsolete Features::
4047 @node Implementation-defined behavior
4048 @section Implementation-defined behavior
4049 @cindex implementation-defined behavior
4051 This is how CPP behaves in all the cases which the C standard
4052 describes as @dfn{implementation-defined}. This term means that the
4053 implementation is free to do what it likes, but must document its choice
4055 @c FIXME: Check the C++ standard for more implementation-defined stuff.
4059 @item The mapping of physical source file multi-byte characters to the
4060 execution character set.
4062 The input character set can be specified using the
4063 @option{-finput-charset} option, while the execution character set may
4064 be controlled using the @option{-fexec-charset} and
4065 @option{-fwide-exec-charset} options.
4067 @item Identifier characters.
4068 @anchor{Identifier characters}
4070 The C and C++ standards allow identifiers to be composed of @samp{_}
4071 and the alphanumeric characters. C++ also allows universal character
4072 names. C99 and later C standards permit both universal character
4073 names and implementation-defined characters.
4075 GCC allows the @samp{$} character in identifiers as an extension for
4076 most targets. This is true regardless of the @option{std=} switch,
4077 since this extension cannot conflict with standards-conforming
4078 programs. When preprocessing assembler, however, dollars are not
4079 identifier characters by default.
4081 Currently the targets that by default do not permit @samp{$} are AVR,
4082 IP2K, MMIX, MIPS Irix 3, ARM aout, and PowerPC targets for the AIX
4085 You can override the default with @option{-fdollars-in-identifiers} or
4086 @option{fno-dollars-in-identifiers}. @xref{fdollars-in-identifiers}.
4088 @item Non-empty sequences of whitespace characters.
4090 In textual output, each whitespace sequence is collapsed to a single
4091 space. For aesthetic reasons, the first token on each non-directive
4092 line of output is preceded with sufficient spaces that it appears in the
4093 same column as it did in the original source file.
4095 @item The numeric value of character constants in preprocessor expressions.
4097 The preprocessor and compiler interpret character constants in the
4098 same way; i.e.@: escape sequences such as @samp{\a} are given the
4099 values they would have on the target machine.
4101 The compiler evaluates a multi-character character constant a character
4102 at a time, shifting the previous value left by the number of bits per
4103 target character, and then or-ing in the bit-pattern of the new
4104 character truncated to the width of a target character. The final
4105 bit-pattern is given type @code{int}, and is therefore signed,
4106 regardless of whether single characters are signed or not.
4108 characters in the constant than would fit in the target @code{int} the
4109 compiler issues a warning, and the excess leading characters are
4112 For example, @code{'ab'} for a target with an 8-bit @code{char} would be
4113 interpreted as @w{@samp{(int) ((unsigned char) 'a' * 256 + (unsigned char)
4114 'b')}}, and @code{'\234a'} as @w{@samp{(int) ((unsigned char) '\234' *
4115 256 + (unsigned char) 'a')}}.
4117 @item Source file inclusion.
4119 For a discussion on how the preprocessor locates header files,
4120 @ref{Include Operation}.
4122 @item Interpretation of the filename resulting from a macro-expanded
4123 @samp{#include} directive.
4125 @xref{Computed Includes}.
4127 @item Treatment of a @samp{#pragma} directive that after macro-expansion
4128 results in a standard pragma.
4130 No macro expansion occurs on any @samp{#pragma} directive line, so the
4131 question does not arise.
4133 Note that GCC does not yet implement any of the standard
4138 @node Implementation limits
4139 @section Implementation limits
4140 @cindex implementation limits
4142 CPP has a small number of internal limits. This section lists the
4143 limits which the C standard requires to be no lower than some minimum,
4144 and all the others known. It is intended that there should be as few limits
4145 as possible. If you encounter an undocumented or inconvenient limit,
4146 please report that as a bug. @xref{Bugs, , Reporting Bugs, gcc, Using
4147 the GNU Compiler Collection (GCC)}.
4149 Where we say something is limited @dfn{only by available memory}, that
4150 means that internal data structures impose no intrinsic limit, and space
4151 is allocated with @code{malloc} or equivalent. The actual limit will
4152 therefore depend on many things, such as the size of other things
4153 allocated by the compiler at the same time, the amount of memory
4154 consumed by other processes on the same computer, etc.
4158 @item Nesting levels of @samp{#include} files.
4160 We impose an arbitrary limit of 200 levels, to avoid runaway recursion.
4161 The standard requires at least 15 levels.
4163 @item Nesting levels of conditional inclusion.
4165 The C standard mandates this be at least 63. CPP is limited only by
4168 @item Levels of parenthesized expressions within a full expression.
4170 The C standard requires this to be at least 63. In preprocessor
4171 conditional expressions, it is limited only by available memory.
4173 @item Significant initial characters in an identifier or macro name.
4175 The preprocessor treats all characters as significant. The C standard
4176 requires only that the first 63 be significant.
4178 @item Number of macros simultaneously defined in a single translation unit.
4180 The standard requires at least 4095 be possible. CPP is limited only
4181 by available memory.
4183 @item Number of parameters in a macro definition and arguments in a macro call.
4185 We allow @code{USHRT_MAX}, which is no smaller than 65,535. The minimum
4186 required by the standard is 127.
4188 @item Number of characters on a logical source line.
4190 The C standard requires a minimum of 4096 be permitted. CPP places
4191 no limits on this, but you may get incorrect column numbers reported in
4192 diagnostics for lines longer than 65,535 characters.
4194 @item Maximum size of a source file.
4196 The standard does not specify any lower limit on the maximum size of a
4197 source file. GNU cpp maps files into memory, so it is limited by the
4198 available address space. This is generally at least two gigabytes.
4199 Depending on the operating system, the size of physical memory may or
4200 may not be a limitation.
4204 @node Obsolete Features
4205 @section Obsolete Features
4207 CPP has some features which are present mainly for compatibility with
4208 older programs. We discourage their use in new code. In some cases,
4209 we plan to remove the feature in a future version of GCC@.
4211 @subsection Assertions
4214 @dfn{Assertions} are a deprecated alternative to macros in writing
4215 conditionals to test what sort of computer or system the compiled
4216 program will run on. Assertions are usually predefined, but you can
4217 define them with preprocessing directives or command-line options.
4219 Assertions were intended to provide a more systematic way to describe
4220 the compiler's target system and we added them for compatibility with
4221 existing compilers. In practice they are just as unpredictable as the
4222 system-specific predefined macros. In addition, they are not part of
4223 any standard, and only a few compilers support them.
4224 Therefore, the use of assertions is @strong{less} portable than the use
4225 of system-specific predefined macros. We recommend you do not use them at
4229 An assertion looks like this:
4232 #@var{predicate} (@var{answer})
4236 @var{predicate} must be a single identifier. @var{answer} can be any
4237 sequence of tokens; all characters are significant except for leading
4238 and trailing whitespace, and differences in internal whitespace
4239 sequences are ignored. (This is similar to the rules governing macro
4240 redefinition.) Thus, @code{(x + y)} is different from @code{(x+y)} but
4241 equivalent to @code{@w{( x + y )}}. Parentheses do not nest inside an
4244 @cindex testing predicates
4245 To test an assertion, you write it in an @samp{#if}. For example, this
4246 conditional succeeds if either @code{vax} or @code{ns16000} has been
4247 asserted as an answer for @code{machine}.
4250 #if #machine (vax) || #machine (ns16000)
4254 You can test whether @emph{any} answer is asserted for a predicate by
4255 omitting the answer in the conditional:
4262 Assertions are made with the @samp{#assert} directive. Its sole
4263 argument is the assertion to make, without the leading @samp{#} that
4264 identifies assertions in conditionals.
4267 #assert @var{predicate} (@var{answer})
4271 You may make several assertions with the same predicate and different
4272 answers. Subsequent assertions do not override previous ones for the
4273 same predicate. All the answers for any given predicate are
4274 simultaneously true.
4276 @cindex assertions, canceling
4278 Assertions can be canceled with the @samp{#unassert} directive. It
4279 has the same syntax as @samp{#assert}. In that form it cancels only the
4280 answer which was specified on the @samp{#unassert} line; other answers
4281 for that predicate remain true. You can cancel an entire predicate by
4282 leaving out the answer:
4285 #unassert @var{predicate}
4289 In either form, if no such assertion has been made, @samp{#unassert} has
4292 You can also make or cancel assertions using command-line options.
4298 @cindex command line
4300 Most often when you use the C preprocessor you do not have to invoke it
4301 explicitly: the C compiler does so automatically. However, the
4302 preprocessor is sometimes useful on its own. You can invoke the
4303 preprocessor either with the @command{cpp} command, or via @command{gcc -E}.
4304 In GCC, the preprocessor is actually integrated with the compiler
4305 rather than a separate program, and both of these commands invoke
4306 GCC and tell it to stop after the preprocessing phase.
4308 The @command{cpp} options listed here are also accepted by
4309 @command{gcc} and have the same meaning. Likewise the @command{cpp}
4310 command accepts all the usual @command{gcc} driver options, although those
4311 pertaining to compilation phases after preprocessing are ignored.
4313 Only options specific to preprocessing behavior are documented here.
4314 Refer to the GCC manual for full documentation of other driver options.
4317 @c man begin SYNOPSIS
4318 cpp [@option{-D}@var{macro}[=@var{defn}]@dots{}] [@option{-U}@var{macro}]
4319 [@option{-I}@var{dir}@dots{}] [@option{-iquote}@var{dir}@dots{}]
4320 [@option{-M}|@option{-MM}] [@option{-MG}] [@option{-MF} @var{filename}]
4321 [@option{-MP}] [@option{-MQ} @var{target}@dots{}]
4322 [@option{-MT} @var{target}@dots{}]
4323 @var{infile} [[@option{-o}] @var{outfile}]
4325 Only the most useful options are given above; see below for a more
4326 complete list of preprocessor-specific options.
4327 In addition, @command{cpp} accepts most @command{gcc} driver options, which
4328 are not listed here. Refer to the GCC documentation for details.
4330 @c man begin SEEALSO
4331 gpl(7), gfdl(7), fsf-funding(7),
4332 gcc(1), and the Info entries for @file{cpp} and @file{gcc}.
4336 @c man begin OPTIONS
4337 The @command{cpp} command expects two file names as arguments, @var{infile} and
4338 @var{outfile}. The preprocessor reads @var{infile} together with any
4339 other files it specifies with @samp{#include}. All the output generated
4340 by the combined input files is written in @var{outfile}.
4342 Either @var{infile} or @var{outfile} may be @option{-}, which as
4343 @var{infile} means to read from standard input and as @var{outfile}
4344 means to write to standard output. If either file is omitted, it
4345 means the same as if @option{-} had been specified for that file.
4346 You can also use the @option{-o @var{outfile}} option to specify the
4349 Unless otherwise noted, or the option ends in @samp{=}, all options
4350 which take an argument may have that argument appear either immediately
4351 after the option, or with a space between option and argument:
4352 @option{-Ifoo} and @option{-I foo} have the same effect.
4354 @cindex grouping options
4355 @cindex options, grouping
4356 Many options have multi-letter names; therefore multiple single-letter
4357 options may @emph{not} be grouped: @option{-dM} is very different from
4363 @include cppopts.texi
4364 @include cppdiropts.texi
4365 @include cppwarnopts.texi
4369 @node Environment Variables
4370 @chapter Environment Variables
4371 @cindex environment variables
4372 @c man begin ENVIRONMENT
4374 This section describes the environment variables that affect how CPP
4375 operates. You can use them to specify directories or prefixes to use
4376 when searching for include files, or to control dependency output.
4378 Note that you can also specify places to search using options such as
4379 @option{-I}, and control dependency output with options like
4380 @option{-M} (@pxref{Invocation}). These take precedence over
4381 environment variables, which in turn take precedence over the
4382 configuration of GCC@.
4384 @include cppenv.texi
4391 @node Index of Directives
4392 @unnumbered Index of Directives
4396 @unnumbered Option Index
4398 CPP's command-line options and environment variables are indexed here
4399 without any initial @samp{-} or @samp{--}.
4404 @unnumbered Concept Index