vanten-s/geos
1
0
Fork 0
Code Issues Pull requests Packages Projects Releases Wiki Activity
geos/opt/share/info/cpp.info
vanten-s b2547051f3
First version
2024-03-26 15:15:06 +01:00

5633 lines
245 KiB
Plaintext
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

This is cpp.info, produced by makeinfo version 7.0.3 from cpp.texi.
Copyright © 1987-2023 Free Software Foundation, Inc.
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3 or
any later version published by the Free Software Foundation. A copy of
the license is included in the section entitled “GNU Free Documentation
License”.
This manual contains no Invariant Sections. The Front-Cover Texts
are (a) (see below), and the Back-Cover Texts are (b) (see below).
(a) The FSFs Front-Cover Text is:
A GNU Manual
(b) The FSFs Back-Cover Text is:
You have freedom to copy and modify this GNU Manual, like GNU
software. Copies published by the Free Software Foundation raise funds
for GNU development.
INFO-DIR-SECTION Software development
START-INFO-DIR-ENTRY
* Cpp: (cpp). The GNU C preprocessor.
END-INFO-DIR-ENTRY

File: cpp.info, Node: Top, Next: Overview, Up: (dir)
The C Preprocessor
******************
The C preprocessor implements the macro language used to transform C,
C++, and Objective-C programs before they are compiled. It can also be
useful on its own.
* Menu:
* Overview::
* Header Files::
* Macros::
* Conditionals::
* Diagnostics::
* Line Control::
* Pragmas::
* Other Directives::
* Preprocessor Output::
* Traditional Mode::
* Implementation Details::
* Invocation::
* Environment Variables::
* GNU Free Documentation License::
* Index of Directives::
* Option Index::
* Concept Index::
— The Detailed Node Listing —
Overview
* Character sets::
* Initial processing::
* Tokenization::
* The preprocessing language::
Header Files
* Include Syntax::
* Include Operation::
* Search Path::
* Once-Only Headers::
* Alternatives to Wrapper #ifndef::
* Computed Includes::
* Wrapper Headers::
* System Headers::
Macros
* Object-like Macros::
* Function-like Macros::
* Macro Arguments::
* Stringizing::
* Concatenation::
* Variadic Macros::
* Predefined Macros::
* Undefining and Redefining Macros::
* Directives Within Macro Arguments::
* Macro Pitfalls::
Predefined Macros
* Standard Predefined Macros::
* Common Predefined Macros::
* System-specific Predefined Macros::
* C++ Named Operators::
Macro Pitfalls
* Misnesting::
* Operator Precedence Problems::
* Swallowing the Semicolon::
* Duplication of Side Effects::
* Self-Referential Macros::
* Argument Prescan::
* Newlines in Arguments::
Conditionals
* Conditional Uses::
* Conditional Syntax::
* Deleted Code::
Conditional Syntax
* Ifdef::
* If::
* Defined::
* Else::
* Elif::
Implementation Details
* Implementation-defined behavior::
* Implementation limits::
* Obsolete Features::
Obsolete Features
* Obsolete Features::
Copyright © 1987-2023 Free Software Foundation, Inc.
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3 or
any later version published by the Free Software Foundation. A copy of
the license is included in the section entitled “GNU Free Documentation
License”.
This manual contains no Invariant Sections. The Front-Cover Texts
are (a) (see below), and the Back-Cover Texts are (b) (see below).
(a) The FSFs Front-Cover Text is:
A GNU Manual
(b) The FSFs Back-Cover Text is:
You have freedom to copy and modify this GNU Manual, like GNU
software. Copies published by the Free Software Foundation raise funds
for GNU development.

File: cpp.info, Node: Overview, Next: Header Files, Prev: Top, Up: Top
1 Overview
**********
The C preprocessor, often known as “cpp”, is a “macro processor” that is
used automatically by the C compiler to transform your program before
compilation. It is called a macro processor because it allows you to
define “macros”, which are brief abbreviations for longer constructs.
The C preprocessor is intended to be used only with C, C++, and
Objective-C source code. In the past, it has been abused as a general
text processor. It will choke on input which does not obey Cs lexical
rules. For example, apostrophes will be interpreted as the beginning of
character constants, and cause errors. Also, you cannot rely on it
preserving characteristics of the input which are not significant to
C-family languages. If a Makefile is preprocessed, all the hard tabs
will be removed, and the Makefile will not work.
Having said that, you can often get away with using cpp on things
which are not C. Other Algol-ish programming languages are often safe
(Ada, etc.) So is assembly, with caution. -traditional-cpp mode
preserves more white space, and is otherwise more permissive. Many of
the problems can be avoided by writing C or C++ style comments instead
of native language comments, and keeping macros simple.
Wherever possible, you should use a preprocessor geared to the
language you are writing in. Modern versions of the GNU assembler have
macro facilities. Most high level programming languages have their own
conditional compilation and inclusion mechanism. If all else fails, try
a true general text processor, such as GNU M4.
C preprocessors vary in some details. This manual discusses the GNU
C preprocessor, which provides a small superset of the features of ISO
Standard C. In its default mode, the GNU C preprocessor does not do a
few things required by the standard. These are features which are
rarely, if ever, used, and may cause surprising changes to the meaning
of a program which does not expect them. To get strict ISO Standard C,
you should use the -std=c90, -std=c99, -std=c11 or -std=c17
options, depending on which version of the standard you want. To get
all the mandatory diagnostics, you must also use -pedantic. *Note
Invocation::.
This manual describes the behavior of the ISO preprocessor. To
minimize gratuitous differences, where the ISO preprocessors behavior
does not conflict with traditional semantics, the traditional
preprocessor should behave the same way. The various differences that
do exist are detailed in the section *note Traditional Mode::.
For clarity, unless noted otherwise, references to CPP in this
manual refer to GNU CPP.
* Menu:
* Character sets::
* Initial processing::
* Tokenization::
* The preprocessing language::

File: cpp.info, Node: Character sets, Next: Initial processing, Up: Overview
1.1 Character sets
==================
Source code character set processing in C and related languages is
rather complicated. The C standard discusses two character sets, but
there are really at least four.
The files input to CPP might be in any character set at all. CPPs
very first action, before it even looks for line boundaries, is to
convert the file into the character set it uses for internal processing.
That set is what the C standard calls the “source” character set. It
must be isomorphic with ISO 10646, also known as Unicode. CPP uses the
UTF-8 encoding of Unicode.
The character sets of the input files are specified using the
-finput-charset= option.
All preprocessing work (the subject of the rest of this manual) is
carried out in the source character set. If you request textual output
from the preprocessor with the -E option, it will be in UTF-8.
After preprocessing is complete, string and character constants are
converted again, into the “execution” character set. This character set
is under control of the user; the default is UTF-8, matching the source
character set. Wide string and character constants have their own
character set, which is not called out specifically in the standard.
Again, it is under control of the user. The default is UTF-16 or
UTF-32, whichever fits in the targets wchar_t type, in the target
machines byte order.(1) Octal and hexadecimal escape sequences do not
undergo conversion; '\x12' has the value 0x12 regardless of the
currently selected execution character set. All other escapes are
replaced by the character in the source character set that they
represent, then converted to the execution character set, just like
unescaped characters.
In identifiers, characters outside the ASCII range can be specified
with the \u and \U escapes or used directly in the input encoding.
If strict ISO C90 conformance is specified with an option such as
-std=c90, or -fno-extended-identifiers is used, then those
constructs are not permitted in identifiers.
---------- Footnotes ----------
(1) UTF-16 does not meet the requirements of the C standard for a
wide character set, but the choice of 16-bit wchar_t is enshrined in
some system ABIs so we cannot fix this.

File: cpp.info, Node: Initial processing, Next: Tokenization, Prev: Character sets, Up: Overview
1.2 Initial processing
======================
The preprocessor performs a series of textual transformations on its
input. These happen before all other processing. Conceptually, they
happen in a rigid order, and the entire file is run through each
transformation before the next one begins. CPP actually does them all
at once, for performance reasons. These transformations correspond
roughly to the first three “phases of translation” described in the C
standard.
1. The input file is read into memory and broken into lines.
Different systems use different conventions to indicate the end of
a line. GCC accepts the ASCII control sequences LF, CR LF and
CR as end-of-line markers. These are the canonical sequences
used by Unix, DOS and VMS, and the classic Mac OS (before OSX)
respectively. You may therefore safely copy source code written on
any of those systems to a different one and use it without
conversion. (GCC may lose track of the current line number if a
file doesnt consistently use one convention, as sometimes happens
when it is edited on computers with different conventions that
share a network file system.)
If the last line of any input file lacks an end-of-line marker, the
end of the file is considered to implicitly supply one. The C
standard says that this condition provokes undefined behavior, so
GCC will emit a warning message.
2. If trigraphs are enabled, they are replaced by their corresponding
single characters. By default GCC ignores trigraphs, but if you
request a strictly conforming mode with the -std option, or you
specify the -trigraphs option, then it converts them.
These are nine three-character sequences, all starting with ??,
that are defined by ISO C to stand for single characters. They
permit obsolete systems that lack some of Cs punctuation to use C.
For example, ??/ stands for \, so '??/n' is a character
constant for a newline.
Trigraphs are not popular and many compilers implement them
incorrectly. Portable code should not rely on trigraphs being
either converted or ignored. With -Wtrigraphs GCC will warn you
when a trigraph may change the meaning of your program if it were
converted. *Note Wtrigraphs::.
In a string constant, you can prevent a sequence of question marks
from being confused with a trigraph by inserting a backslash
between the question marks, or by separating the string literal at
the trigraph and making use of string literal concatenation.
"(??\?)" is the string (???), not (?]. Traditional C compilers
do not recognize these idioms.
The nine trigraphs and their replacements are
Trigraph: ??( ??) ??< ??> ??= ??/ ??' ??! ??-
Replacement: [ ] { } # \ ^ | ~
3. Continued lines are merged into one long line.
A continued line is a line which ends with a backslash, \. The
backslash is removed and the following line is joined with the
current one. No space is inserted, so you may split a line
anywhere, even in the middle of a word. (It is generally more
readable to split lines only at white space.)
The trailing backslash on a continued line is commonly referred to
as a “backslash-newline”.
If there is white space between a backslash and the end of a line,
that is still a continued line. However, as this is usually the
result of an editing mistake, and many compilers will not accept it
as a continued line, GCC will warn you about it.
4. All comments are replaced with single spaces.
There are two kinds of comments. “Block comments” begin with /*
and continue until the next */. Block comments do not nest:
/* this is /* one comment */ text outside comment
“Line comments” begin with // and continue to the end of the
current line. Line comments do not nest either, but it does not
matter, because they would end in the same place anyway.
// this is // one comment
text outside comment
It is safe to put line comments inside block comments, or vice versa.
/* block comment
// contains line comment
yet more comment
*/ outside comment
// line comment /* contains block comment */
But beware of commenting out one end of a block comment with a line
comment.
// l.c. /* block comment begins
oops! this isnt a comment anymore */
Comments are not recognized within string literals. "/* blah */" is
the string constant /* blah */, not an empty string.
Line comments are not in the 1989 edition of the C standard, but they
are recognized by GCC as an extension. In C++ and in the 1999 edition
of the C standard, they are an official part of the language.
Since these transformations happen before all other processing, you
can split a line mechanically with backslash-newline anywhere. You can
comment out the end of a line. You can continue a line comment onto the
next line with backslash-newline. You can even split /*, */, and
// onto multiple lines with backslash-newline. For example:
/\
*
*/ # /*
*/ defi\
ne FO\
O 10\
20
is equivalent to #define FOO 1020. All these tricks are extremely
confusing and should not be used in code intended to be readable.
There is no way to prevent a backslash at the end of a line from
being interpreted as a backslash-newline. This cannot affect any
correct program, however.

File: cpp.info, Node: Tokenization, Next: The preprocessing language, Prev: Initial processing, Up: Overview
1.3 Tokenization
================
After the textual transformations are finished, the input file is
converted into a sequence of “preprocessing tokens”. These mostly
correspond to the syntactic tokens used by the C compiler, but there are
a few differences. White space separates tokens; it is not itself a
token of any kind. Tokens do not have to be separated by white space,
but it is often necessary to avoid ambiguities.
When faced with a sequence of characters that has more than one
possible tokenization, the preprocessor is greedy. It always makes each
token, starting from the left, as big as possible before moving on to
the next token. For instance, a+++++b is interpreted as
a ++ ++ + b, not as a ++ + ++ b, even though the latter tokenization
could be part of a valid C program and the former could not.
Once the input file is broken into tokens, the token boundaries never
change, except when the ## preprocessing operator is used to paste
tokens together. *Note Concatenation::. For example,
#define foo() bar
foo()baz
↦ bar baz
_not_
↦ barbaz
The compiler does not re-tokenize the preprocessors output. Each
preprocessing token becomes one compiler token.
Preprocessing tokens fall into five broad classes: identifiers,
preprocessing numbers, string literals, punctuators, and other. An
“identifier” is the same as an identifier in C: any sequence of letters,
digits, or underscores, which begins with a letter or underscore.
Keywords of C have no significance to the preprocessor; they are
ordinary identifiers. You can define a macro whose name is a keyword,
for instance. The only identifier which can be considered a
preprocessing keyword is defined. *Note Defined::.
This is mostly true of other languages which use the C preprocessor.
However, a few of the keywords of C++ are significant even in the
preprocessor. *Note C++ Named Operators::.
In the 1999 C standard, identifiers may contain letters which are not
part of the “basic source character set”, at the implementations
discretion (such as accented Latin letters, Greek letters, or Chinese
ideograms). This may be done with an extended character set, or the
\u and \U escape sequences.
As an extension, GCC treats $ as a letter. This is for
compatibility with some systems, such as VMS, where $ is commonly used
in system-defined function and object names. $ is not a letter in
strictly conforming mode, or if you specify the -$ option. *Note
Invocation::.
A “preprocessing number” has a rather bizarre definition. The
category includes all the normal integer and floating point constants
one expects of C, but also a number of other things one might not
initially recognize as a number. Formally, preprocessing numbers begin
with an optional period, a required decimal digit, and then continue
with any sequence of letters, digits, underscores, periods, and
exponents. Exponents are the two-character sequences e+, e-, E+,
E-, p+, p-, P+, and P-. (The exponents that begin with p or
P are used for hexadecimal floating-point constants.)
The purpose of this unusual definition is to isolate the preprocessor
from the full complexity of numeric constants. It does not have to
distinguish between lexically valid and invalid floating-point numbers,
which is complicated. The definition also permits you to split an
identifier at any position and get exactly two tokens, which can then be
pasted back together with the ## operator.
Its possible for preprocessing numbers to cause programs to be
misinterpreted. For example, 0xE+12 is a preprocessing number which
does not translate to any valid numeric constant, therefore a syntax
error. It does not mean 0xE + 12, which is what you might have
intended.
“String literals” are string constants, character constants, and
header file names (the argument of #include).(1) String constants and
character constants are straightforward: "..." or '...'. In either case
embedded quotes should be escaped with a backslash: '\'' is the
character constant for '. There is no limit on the length of a
character constant, but the value of a character constant that contains
more than one character is implementation-defined. *Note Implementation
Details::.
Header file names either look like string constants, "...", or are
written with angle brackets instead, <...>. In either case, backslash
is an ordinary character. There is no way to escape the closing quote
or angle bracket. The preprocessor looks for the header file in
different places depending on which form you use. *Note Include
Operation::.
No string literal may extend past the end of a line. You may use
continued lines instead, or string constant concatenation.
“Punctuators” are all the usual bits of punctuation which are
meaningful to C and C++. All but three of the punctuation characters in
ASCII are C punctuators. The exceptions are @, $, and `. In
addition, all the two- and three-character operators are punctuators.
There are also six “digraphs”, which the C++ standard calls “alternative
tokens”, which are merely alternate ways to spell other punctuators.
This is a second attempt to work around missing punctuation in obsolete
systems. It has no negative side effects, unlike trigraphs, but does
not cover as much ground. The digraphs and their corresponding normal
punctuators are:
Digraph: <% %> <: :> %: %:%:
Punctuator: { } [ ] # ##
Any other single byte is considered “other” and passed on to the
preprocessors output unchanged. The C compiler will almost certainly
reject source code containing “other” tokens. In ASCII, the only
“other” characters are @, $, `, and control characters other than
NUL (all bits zero). (Note that $ is normally considered a letter.)
All bytes with the high bit set (numeric range 0x7F0xFF) that were not
succesfully interpreted as part of an extended character in the input
encoding are also “other” in the present implementation.
NUL is a special case because of the high probability that its
appearance is accidental, and because it may be invisible to the user
(many terminals do not display NUL at all). Within comments, NULs are
silently ignored, just as any other character would be. In running
text, NUL is considered white space. For example, these two directives
have the same meaning.
#define X^@1
#define X 1
(where ^@ is ASCII NUL). Within string or character constants, NULs
are preserved. In the latter two cases the preprocessor emits a warning
message.
---------- Footnotes ----------
(1) The C standard uses the term “string literal” to refer only to
what we are calling “string constants”.

File: cpp.info, Node: The preprocessing language, Prev: Tokenization, Up: Overview
1.4 The preprocessing language
==============================
After tokenization, the stream of tokens may simply be passed straight
to the compilers parser. However, if it contains any operations in the
“preprocessing language”, it will be transformed first. This stage
corresponds roughly to the standards “translation phase 4” and is what
most people think of as the preprocessors job.
The preprocessing language consists of “directives” to be executed
and “macros” to be expanded. Its primary capabilities are:
• Inclusion of header files. These are files of declarations that
can be substituted into your program.
• Macro expansion. You can define “macros”, which are abbreviations
for arbitrary fragments of C code. The preprocessor will replace
the macros with their definitions throughout the program. Some
macros are automatically defined for you.
• Conditional compilation. You can include or exclude parts of the
program according to various conditions.
• Line control. If you use a program to combine or rearrange source
files into an intermediate file which is then compiled, you can use
line control to inform the compiler where each source line
originally came from.
• Diagnostics. You can detect problems at compile time and issue
errors or warnings.
There are a few more, less useful, features.
Except for expansion of predefined macros, all these operations are
triggered with “preprocessing directives”. Preprocessing directives are
lines in your program that start with #. Whitespace is allowed before
and after the #. The # is followed by an identifier, the “directive
name”. It specifies the operation to perform. Directives are commonly
referred to as #NAME where NAME is the directive name. For example,
#define is the directive that defines a macro.
The # which begins a directive cannot come from a macro expansion.
Also, the directive name is not macro expanded. Thus, if foo is
defined as a macro expanding to define, that does not make #foo a
valid preprocessing directive.
The set of valid directive names is fixed. Programs cannot define
new preprocessing directives.
Some directives require arguments; these make up the rest of the
directive line and must be separated from the directive name by
whitespace. For example, #define must be followed by a macro name and
the intended expansion of the macro.
A preprocessing directive cannot cover more than one line. The line
may, however, be continued with backslash-newline, or by a block comment
which extends past the end of the line. In either case, when the
directive is processed, the continuations have already been merged with
the first line to make one long line.

File: cpp.info, Node: Header Files, Next: Macros, Prev: Overview, Up: Top
2 Header Files
**************
A header file is a file containing C declarations and macro definitions
(*note Macros::) to be shared between several source files. You request
the use of a header file in your program by “including” it, with the C
preprocessing directive #include.
Header files serve two purposes.
• System header files declare the interfaces to parts of the
operating system. You include them in your program to supply the
definitions and declarations you need to invoke system calls and
libraries.
• Your own header files contain declarations for interfaces between
the source files of your program. Each time you have a group of
related declarations and macro definitions all or most of which are
needed in several different source files, it is a good idea to
create a header file for them.
Including a header file produces the same results as copying the
header file into each source file that needs it. Such copying would be
time-consuming and error-prone. With a header file, the related
declarations appear in only one place. If they need to be changed, they
can be changed in one place, and programs that include the header file
will automatically use the new version when next recompiled. The header
file eliminates the labor of finding and changing all the copies as well
as the risk that a failure to find one copy will result in
inconsistencies within a program.
In C, the usual convention is to give header files names that end
with .h. It is most portable to use only letters, digits, dashes, and
underscores in header file names, and at most one dot.
* Menu:
* Include Syntax::
* Include Operation::
* Search Path::
* Once-Only Headers::
* Alternatives to Wrapper #ifndef::
* Computed Includes::
* Wrapper Headers::
* System Headers::

File: cpp.info, Node: Include Syntax, Next: Include Operation, Up: Header Files
2.1 Include Syntax
==================
Both user and system header files are included using the preprocessing
directive #include. It has two variants:
#include <FILE>
This variant is used for system header files. It searches for a
file named FILE in a standard list of system directories. You can
prepend directories to this list with the -I option (*note
Invocation::).
#include "FILE"
This variant is used for header files of your own program. It
searches for a file named FILE first in the directory containing
the current file, then in the quote directories and then the same
directories used for <FILE>. You can prepend directories to the
list of quote directories with the -iquote option.
The argument of #include, whether delimited with quote marks or
angle brackets, behaves like a string constant in that comments are not
recognized, and macro names are not expanded. Thus, #include <x/*y>
specifies inclusion of a system header file named x/*y.
However, if backslashes occur within FILE, they are considered
ordinary text characters, not escape characters. None of the character
escape sequences appropriate to string constants in C are processed.
Thus, #include "x\n\\y" specifies a filename containing three
backslashes. (Some systems interpret \ as a pathname separator. All
of these also interpret / the same way. It is most portable to use
only /.)
It is an error if there is anything (other than comments) on the line
after the file name.

File: cpp.info, Node: Include Operation, Next: Search Path, Prev: Include Syntax, Up: Header Files
2.2 Include Operation
=====================
The #include directive works by directing the C preprocessor to scan
the specified file as input before continuing with the rest of the
current file. The output from the preprocessor contains the output
already generated, followed by the output resulting from the included
file, followed by the output that comes from the text after the
#include directive. For example, if you have a header file header.h
as follows,
char *test (void);
and a main program called program.c that uses the header file, like
this,
int x;
#include "header.h"
int
main (void)
{
puts (test ());
}
the compiler will see the same token stream as it would if program.c
read
int x;
char *test (void);
int
main (void)
{
puts (test ());
}
Included files are not limited to declarations and macro definitions;
those are merely the typical uses. Any fragment of a C program can be
included from another file. The include file could even contain the
beginning of a statement that is concluded in the containing file, or
the end of a statement that was started in the including file. However,
an included file must consist of complete tokens. Comments and string
literals which have not been closed by the end of an included file are
invalid. For error recovery, they are considered to end at the end of
the file.
To avoid confusion, it is best if header files contain only complete
syntactic units—function declarations or definitions, type declarations,
etc.
The line following the #include directive is always treated as a
separate line by the C preprocessor, even if the included file lacks a
final newline.

File: cpp.info, Node: Search Path, Next: Once-Only Headers, Prev: Include Operation, Up: Header Files
2.3 Search Path
===============
By default, the preprocessor looks for header files included by the
quote form of the directive #include "FILE" first relative to the
directory of the current file, and then in a preconfigured list of
standard system directories. For example, if /usr/include/sys/stat.h
contains #include "types.h", GCC looks for types.h first in
/usr/include/sys, then in its usual search path.
For the angle-bracket form #include <FILE>, the preprocessors
default behavior is to look only in the standard system directories.
The exact search directory list depends on the target system, how GCC is
configured, and where it is installed. You can find the default search
directory list for your version of CPP by invoking it with the -v
option. For example,
cpp -v /dev/null -o /dev/null
There are a number of command-line options you can use to add
additional directories to the search path. The most commonly-used
option is -IDIR, which causes DIR to be searched after the current
directory (for the quote form of the directive) and ahead of the
standard system directories. You can specify multiple -I options on
the command line, in which case the directories are searched in
left-to-right order.
If you need separate control over the search paths for the quote and
angle-bracket forms of the #include directive, you can use the
-iquote and/or -isystem options instead of -I. *Note
Invocation::, for a detailed description of these options, as well as
others that are less generally useful.
If you specify other options on the command line, such as -I, that
affect where the preprocessor searches for header files, the directory
list printed by the -v option reflects the actual search path used by
the preprocessor.
Note that you can also prevent the preprocessor from searching any of
the default system header directories with the -nostdinc option. This
is useful when you are compiling an operating system kernel or some
other program that does not use the standard C library facilities, or
the standard C library itself.

File: cpp.info, Node: Once-Only Headers, Next: Alternatives to Wrapper #ifndef, Prev: Search Path, Up: Header Files
2.4 Once-Only Headers
=====================
If a header file happens to be included twice, the compiler will process
its contents twice. This is very likely to cause an error, e.g. when
the compiler sees the same structure definition twice. Even if it does
not, it will certainly waste time.
The standard way to prevent this is to enclose the entire real
contents of the file in a conditional, like this:
/* File foo. */
#ifndef FILE_FOO_SEEN
#define FILE_FOO_SEEN
THE ENTIRE FILE
#endif /* !FILE_FOO_SEEN */
This construct is commonly known as a “wrapper #ifndef”. When the
header is included again, the conditional will be false, because
FILE_FOO_SEEN is defined. The preprocessor will skip over the entire
contents of the file, and the compiler will not see it twice.
CPP optimizes even further. It remembers when a header file has a
wrapper #ifndef. If a subsequent #include specifies that header,
and the macro in the #ifndef is still defined, it does not bother to
rescan the file at all.
You can put comments outside the wrapper. They will not interfere
with this optimization.
The macro FILE_FOO_SEEN is called the “controlling macro” or “guard
macro”. In a user header file, the macro name should not begin with
_. In a system header file, it should begin with __ to avoid
conflicts with user programs. In any kind of header file, the macro
name should contain the name of the file and some additional text, to
avoid conflicts with other header files.

File: cpp.info, Node: Alternatives to Wrapper #ifndef, Next: Computed Includes, Prev: Once-Only Headers, Up: Header Files
2.5 Alternatives to Wrapper #ifndef
===================================
CPP supports two more ways of indicating that a header file should be
read only once. Neither one is as portable as a wrapper #ifndef and
we recommend you do not use them in new programs, with the caveat that
#import is standard practice in Objective-C.
CPP supports a variant of #include called #import which includes
a file, but does so at most once. If you use #import instead of
#include, then you dont need the conditionals inside the header file
to prevent multiple inclusion of the contents. #import is standard in
Objective-C, but is considered a deprecated extension in C and C++.
#import is not a well designed feature. It requires the users of a
header file to know that it should only be included once. It is much
better for the header files implementor to write the file so that users
dont need to know this. Using a wrapper #ifndef accomplishes this
goal.
In the present implementation, a single use of #import will prevent
the file from ever being read again, by either #import or #include.
You should not rely on this; do not use both #import and #include to
refer to the same header file.
Another way to prevent a header file from being included more than
once is with the #pragma once directive (*note Pragmas::). #pragma
once does not have the problems that #import does, but it is not
recognized by all preprocessors, so you cannot rely on it in a portable
program.

File: cpp.info, Node: Computed Includes, Next: Wrapper Headers, Prev: Alternatives to Wrapper #ifndef, Up: Header Files
2.6 Computed Includes
=====================
Sometimes it is necessary to select one of several different header
files to be included into your program. They might specify
configuration parameters to be used on different sorts of operating
systems, for instance. You could do this with a series of conditionals,
#if SYSTEM_1
# include "system_1.h"
#elif SYSTEM_2
# include "system_2.h"
#elif SYSTEM_3
...
#endif
That rapidly becomes tedious. Instead, the preprocessor offers the
ability to use a macro for the header name. This is called a “computed
include”. Instead of writing a header name as the direct argument of
#include, you simply put a macro name there instead:
#define SYSTEM_H "system_1.h"
...
#include SYSTEM_H
SYSTEM_H will be expanded, and the preprocessor will look for
system_1.h as if the #include had been written that way originally.
SYSTEM_H could be defined by your Makefile with a -D option.
You must be careful when you define the macro. #define saves
tokens, not text. The preprocessor has no way of knowing that the macro
will be used as the argument of #include, so it generates ordinary
tokens, not a header name. This is unlikely to cause problems if you
use double-quote includes, which are close enough to string constants.
If you use angle brackets, however, you may have trouble.
The syntax of a computed include is actually a bit more general than
the above. If the first non-whitespace character after #include is
not " or <, then the entire line is macro-expanded like running text
would be.
If the line expands to a single string constant, the contents of that
string constant are the file to be included. CPP does not re-examine
the string for embedded quotes, but neither does it process backslash
escapes in the string. Therefore
#define HEADER "a\"b"
#include HEADER
looks for a file named a\"b. CPP searches for the file according to
the rules for double-quoted includes.
If the line expands to a token stream beginning with a < token and
including a > token, then the tokens between the < and the first >
are combined to form the filename to be included. Any whitespace
between tokens is reduced to a single space; then any space after the
initial < is retained, but a trailing space before the closing > is
ignored. CPP searches for the file according to the rules for
angle-bracket includes.
In either case, if there are any tokens on the line after the file
name, an error occurs and the directive is not processed. It is also an
error if the result of expansion does not match either of the two
expected forms.
These rules are implementation-defined behavior according to the C
standard. To minimize the risk of different compilers interpreting your
computed includes differently, we recommend you use only a single
object-like macro which expands to a string constant. This will also
minimize confusion for people reading your program.

File: cpp.info, Node: Wrapper Headers, Next: System Headers, Prev: Computed Includes, Up: Header Files
2.7 Wrapper Headers
===================
Sometimes it is necessary to adjust the contents of a system-provided
header file without editing it directly. GCCs fixincludes operation
does this, for example. One way to do that would be to create a new
header file with the same name and insert it in the search path before
the original header. That works fine as long as youre willing to
replace the old header entirely. But what if you want to refer to the
old header from the new one?
You cannot simply include the old header with #include. That will
start from the beginning, and find your new header again. If your
header is not protected from multiple inclusion (*note Once-Only
Headers::), it will recurse infinitely and cause a fatal error.
You could include the old header with an absolute pathname:
#include "/usr/include/old-header.h"
This works, but is not clean; should the system headers ever move, you
would have to edit the new headers to match.
There is no way to solve this problem within the C standard, but you
can use the GNU extension #include_next. It means, “Include the
_next_ file with this name”. This directive works like #include
except in searching for the specified file: it starts searching the list
of header file directories _after_ the directory in which the current
file was found.
Suppose you specify -I /usr/local/include, and the list of
directories to search also includes /usr/include; and suppose both
directories contain signal.h. Ordinary #include <signal.h> finds
the file under /usr/local/include. If that file contains
#include_next <signal.h>, it starts searching after that directory,
and finds the file in /usr/include.
#include_next does not distinguish between <FILE> and "FILE"
inclusion, nor does it check that the file you specify has the same name
as the current file. It simply looks for the file named, starting with
the directory in the search path after the one where the current file
was found.
The use of #include_next can lead to great confusion. We recommend
it be used only when there is no other alternative. In particular, it
should not be used in the headers belonging to a specific program; it
should be used only to make global corrections along the lines of
fixincludes.

File: cpp.info, Node: System Headers, Prev: Wrapper Headers, Up: Header Files
2.8 System Headers
==================
The header files declaring interfaces to the operating system and
runtime libraries often cannot be written in strictly conforming C.
Therefore, GCC gives code found in “system headers” special treatment.
All warnings, other than those generated by #warning (*note
Diagnostics::), are suppressed while GCC is processing a system header.
Macros defined in a system header are immune to a few warnings wherever
they are expanded. This immunity is granted on an ad-hoc basis, when we
find that a warning generates lots of false positives because of code in
macros defined in system headers.
Normally, only the headers found in specific directories are
considered system headers. These directories are determined when GCC is
compiled. There are, however, two ways to make normal headers into
system headers:
• Header files found in directories added to the search path with the
-isystem and -idirafter command-line options are treated as
system headers for the purposes of diagnostics.
• There is also a directive, #pragma GCC system_header, which tells
GCC to consider the rest of the current include file a system
header, no matter where it was found. Code that comes before the
#pragma in the file is not affected. #pragma GCC system_header
has no effect in the primary source file.
On some targets, such as RS/6000 AIX, GCC implicitly surrounds all
system headers with an extern "C" block when compiling as C++.

File: cpp.info, Node: Macros, Next: Conditionals, Prev: Header Files, Up: Top
3 Macros
********
A “macro” is a fragment of code which has been given a name. Whenever
the name is used, it is replaced by the contents of the macro. There
are two kinds of macros. They differ mostly in what they look like when
they are used. “Object-like” macros resemble data objects when used,
“function-like” macros resemble function calls.
You may define any valid identifier as a macro, even if it is a C
keyword. The preprocessor does not know anything about keywords. This
can be useful if you wish to hide a keyword such as const from an
older compiler that does not understand it. However, the preprocessor
operator defined (*note Defined::) can never be defined as a macro,
and C++s named operators (*note C++ Named Operators::) cannot be macros
when you are compiling C++.
* Menu:
* Object-like Macros::
* Function-like Macros::
* Macro Arguments::
* Stringizing::
* Concatenation::
* Variadic Macros::
* Predefined Macros::
* Undefining and Redefining Macros::
* Directives Within Macro Arguments::
* Macro Pitfalls::

File: cpp.info, Node: Object-like Macros, Next: Function-like Macros, Up: Macros
3.1 Object-like Macros
======================
An “object-like macro” is a simple identifier which will be replaced by
a code fragment. It is called object-like because it looks like a data
object in code that uses it. They are most commonly used to give
symbolic names to numeric constants.
You create macros with the #define directive. #define is
followed by the name of the macro and then the token sequence it should
be an abbreviation for, which is variously referred to as the macros
“body”, “expansion” or “replacement list”. For example,
#define BUFFER_SIZE 1024
defines a macro named BUFFER_SIZE as an abbreviation for the token
1024. If somewhere after this #define directive there comes a C
statement of the form
foo = (char *) malloc (BUFFER_SIZE);
then the C preprocessor will recognize and “expand” the macro
BUFFER_SIZE. The C compiler will see the same tokens as it would if
you had written
foo = (char *) malloc (1024);
By convention, macro names are written in uppercase. Programs are
easier to read when it is possible to tell at a glance which names are
macros.
The macros body ends at the end of the #define line. You may
continue the definition onto multiple lines, if necessary, using
backslash-newline. When the macro is expanded, however, it will all
come out on one line. For example,
#define NUMBERS 1, \
2, \
3
int x[] = { NUMBERS };
↦ int x[] = { 1, 2, 3 };
The most common visible consequence of this is surprising line numbers
in error messages.
There is no restriction on what can go in a macro body provided it
decomposes into valid preprocessing tokens. Parentheses need not
balance, and the body need not resemble valid C code. (If it does not,
you may get error messages from the C compiler when you use the macro.)
The C preprocessor scans your program sequentially. Macro
definitions take effect at the place you write them. Therefore, the
following input to the C preprocessor
foo = X;
#define X 4
bar = X;
produces
foo = X;
bar = 4;
When the preprocessor expands a macro name, the macros expansion
replaces the macro invocation, then the expansion is examined for more
macros to expand. For example,
#define TABLESIZE BUFSIZE
#define BUFSIZE 1024
TABLESIZE
↦ BUFSIZE
↦ 1024
TABLESIZE is expanded first to produce BUFSIZE, then that macro is
expanded to produce the final result, 1024.
Notice that BUFSIZE was not defined when TABLESIZE was defined.
The #define for TABLESIZE uses exactly the expansion you specify—in
this case, BUFSIZE—and does not check to see whether it too contains
macro names. Only when you _use_ TABLESIZE is the result of its
expansion scanned for more macro names.
This makes a difference if you change the definition of BUFSIZE at
some point in the source file. TABLESIZE, defined as shown, will
always expand using the definition of BUFSIZE that is currently in
effect:
#define BUFSIZE 1020
#define TABLESIZE BUFSIZE
#undef BUFSIZE
#define BUFSIZE 37
Now TABLESIZE expands (in two stages) to 37.
If the expansion of a macro contains its own name, either directly or
via intermediate macros, it is not expanded again when the expansion is
examined for more macros. This prevents infinite recursion. *Note
Self-Referential Macros::, for the precise details.

File: cpp.info, Node: Function-like Macros, Next: Macro Arguments, Prev: Object-like Macros, Up: Macros
3.2 Function-like Macros
========================
You can also define macros whose use looks like a function call. These
are called “function-like macros”. To define a function-like macro, you
use the same #define directive, but you put a pair of parentheses
immediately after the macro name. For example,
#define lang_init() c_init()
lang_init()
↦ c_init()
A function-like macro is only expanded if its name appears with a
pair of parentheses after it. If you write just the name, it is left
alone. This can be useful when you have a function and a macro of the
same name, and you wish to use the function sometimes.
extern void foo(void);
#define foo() /* optimized inline version */
...
foo();
funcptr = foo;
Here the call to foo() will use the macro, but the function pointer
will get the address of the real function. If the macro were to be
expanded, it would cause a syntax error.
If you put spaces between the macro name and the parentheses in the
macro definition, that does not define a function-like macro, it defines
an object-like macro whose expansion happens to begin with a pair of
parentheses.
#define lang_init () c_init()
lang_init()
↦ () c_init()()
The first two pairs of parentheses in this expansion come from the
macro. The third is the pair that was originally after the macro
invocation. Since lang_init is an object-like macro, it does not
consume those parentheses.

File: cpp.info, Node: Macro Arguments, Next: Stringizing, Prev: Function-like Macros, Up: Macros
3.3 Macro Arguments
===================
Function-like macros can take “arguments”, just like true functions. To
define a macro that uses arguments, you insert “parameters” between the
pair of parentheses in the macro definition that make the macro
function-like. The parameters must be valid C identifiers, separated by
commas and optionally whitespace.
To invoke a macro that takes arguments, you write the name of the
macro followed by a list of “actual arguments” in parentheses, separated
by commas. The invocation of the macro need not be restricted to a
single logical line—it can cross as many lines in the source file as you
wish. The number of arguments you give must match the number of
parameters in the macro definition. When the macro is expanded, each
use of a parameter in its body is replaced by the tokens of the
corresponding argument. (You need not use all of the parameters in the
macro body.)
As an example, here is a macro that computes the minimum of two
numeric values, as it is defined in many C programs, and some uses.
#define min(X, Y) ((X) < (Y) ? (X) : (Y))
x = min(a, b); ↦ x = ((a) < (b) ? (a) : (b));
y = min(1, 2); ↦ y = ((1) < (2) ? (1) : (2));
z = min(a + 28, *p); ↦ z = ((a + 28) < (*p) ? (a + 28) : (*p));
(In this small example you can already see several of the dangers of
macro arguments. *Note Macro Pitfalls::, for detailed explanations.)
Leading and trailing whitespace in each argument is dropped, and all
whitespace between the tokens of an argument is reduced to a single
space. Parentheses within each argument must balance; a comma within
such parentheses does not end the argument. However, there is no
requirement for square brackets or braces to balance, and they do not
prevent a comma from separating arguments. Thus,
macro (array[x = y, x + 1])
passes two arguments to macro: array[x = y and x + 1]. If you
want to supply array[x = y, x + 1] as an argument, you can write it as
array[(x = y, x + 1)], which is equivalent C code.
All arguments to a macro are completely macro-expanded before they
are substituted into the macro body. After substitution, the complete
text is scanned again for macros to expand, including the arguments.
This rule may seem strange, but it is carefully designed so you need not
worry about whether any function call is actually a macro invocation.
You can run into trouble if you try to be too clever, though. *Note
Argument Prescan::, for detailed discussion.
For example, min (min (a, b), c) is first expanded to
min (((a) < (b) ? (a) : (b)), (c))
and then to
((((a) < (b) ? (a) : (b))) < (c)
? (((a) < (b) ? (a) : (b)))
: (c))
(Line breaks shown here for clarity would not actually be generated.)
You can leave macro arguments empty; this is not an error to the
preprocessor (but many macros will then expand to invalid code). You
cannot leave out arguments entirely; if a macro takes two arguments,
there must be exactly one comma at the top level of its argument list.
Here are some silly examples using min:
min(, b) ↦ (( ) < (b) ? ( ) : (b))
min(a, ) ↦ ((a ) < ( ) ? (a ) : ( ))
min(,) ↦ (( ) < ( ) ? ( ) : ( ))
min((,),) ↦ (((,)) < ( ) ? ((,)) : ( ))
min() error→ macro "min" requires 2 arguments, but only 1 given
min(,,) error→ macro "min" passed 3 arguments, but takes just 2
Whitespace is not a preprocessing token, so if a macro foo takes
one argument, foo () and foo ( ) both supply it an empty argument.
Previous GNU preprocessor implementations and documentation were
incorrect on this point, insisting that a function-like macro that takes
a single argument be passed a space if an empty argument was required.
Macro parameters appearing inside string literals are not replaced by
their corresponding actual arguments.
#define foo(x) x, "x"
foo(bar) ↦ bar, "x"

File: cpp.info, Node: Stringizing, Next: Concatenation, Prev: Macro Arguments, Up: Macros
3.4 Stringizing
===============
Sometimes you may want to convert a macro argument into a string
constant. Parameters are not replaced inside string constants, but you
can use the # preprocessing operator instead. When a macro parameter
is used with a leading #, the preprocessor replaces it with the
literal text of the actual argument, converted to a string constant.
Unlike normal parameter replacement, the argument is not macro-expanded
first. This is called “stringizing”.
There is no way to combine an argument with surrounding text and
stringize it all together. Instead, you can write a series of adjacent
string constants and stringized arguments. The preprocessor replaces
the stringized arguments with string constants. The C compiler then
combines all the adjacent string constants into one long string.
Here is an example of a macro definition that uses stringizing:
#define WARN_IF(EXP) \
do { if (EXP) \
fprintf (stderr, "Warning: " #EXP "\n"); } \
while (0)
WARN_IF (x == 0);
↦ do { if (x == 0)
fprintf (stderr, "Warning: " "x == 0" "\n"); } while (0);
The argument for EXP is substituted once, as-is, into the if
statement, and once, stringized, into the argument to fprintf. If x
were a macro, it would be expanded in the if statement, but not in the
string.
The do and while (0) are a kludge to make it possible to write
WARN_IF (ARG);, which the resemblance of WARN_IF to a function would
make C programmers want to do; see *note Swallowing the Semicolon::.
Stringizing in C involves more than putting double-quote characters
around the fragment. The preprocessor backslash-escapes the quotes
surrounding embedded string constants, and all backslashes within string
and character constants, in order to get a valid C string constant with
the proper contents. Thus, stringizing p = "foo\n"; results in
"p = \"foo\\n\";". However, backslashes that are not inside string or
character constants are not duplicated: \n by itself stringizes to
"\n".
All leading and trailing whitespace in text being stringized is
ignored. Any sequence of whitespace in the middle of the text is
converted to a single space in the stringized result. Comments are
replaced by whitespace long before stringizing happens, so they never
appear in stringized text.
There is no way to convert a macro argument into a character
constant.
If you want to stringize the result of expansion of a macro argument,
you have to use two levels of macros.
#define xstr(s) str(s)
#define str(s) #s
#define foo 4
str (foo)
↦ "foo"
xstr (foo)
↦ xstr (4)
↦ str (4)
↦ "4"
s is stringized when it is used in str, so it is not
macro-expanded first. But s is an ordinary argument to xstr, so it
is completely macro-expanded before xstr itself is expanded (*note
Argument Prescan::). Therefore, by the time str gets to its argument,
it has already been macro-expanded.

File: cpp.info, Node: Concatenation, Next: Variadic Macros, Prev: Stringizing, Up: Macros
3.5 Concatenation
=================
It is often useful to merge two tokens into one while expanding macros.
This is called “token pasting” or “token concatenation”. The ##
preprocessing operator performs token pasting. When a macro is
expanded, the two tokens on either side of each ## operator are
combined into a single token, which then replaces the ## and the two
original tokens in the macro expansion. Usually both will be
identifiers, or one will be an identifier and the other a preprocessing
number. When pasted, they make a longer identifier. This isnt the
only valid case. It is also possible to concatenate two numbers (or a
number and a name, such as 1.5 and e3) into a number. Also,
multi-character operators such as += can be formed by token pasting.
However, two tokens that dont together form a valid token cannot be
pasted together. For example, you cannot concatenate x with + in
either order. If you try, the preprocessor issues a warning and emits
the two tokens. Whether it puts white space between the tokens is
undefined. It is common to find unnecessary uses of ## in complex
macros. If you get this warning, it is likely that you can simply
remove the ##.
Both the tokens combined by ## could come from the macro body, but
you could just as well write them as one token in the first place.
Token pasting is most useful when one or both of the tokens comes from a
macro argument. If either of the tokens next to an ## is a parameter
name, it is replaced by its actual argument before ## executes. As
with stringizing, the actual argument is not macro-expanded first. If
the argument is empty, that ## has no effect.
Keep in mind that the C preprocessor converts comments to whitespace
before macros are even considered. Therefore, you cannot create a
comment by concatenating / and *. You can put as much whitespace
between ## and its operands as you like, including comments, and you
can put comments in arguments that will be concatenated. However, it is
an error if ## appears at either end of a macro body.
Consider a C program that interprets named commands. There probably
needs to be a table of commands, perhaps an array of structures declared
as follows:
struct command
{
char *name;
void (*function) (void);
};
struct command commands[] =
{
{ "quit", quit_command },
{ "help", help_command },
...
};
It would be cleaner not to have to give each command name twice, once
in the string constant and once in the function name. A macro which
takes the name of a command as an argument can make this unnecessary.
The string constant can be created with stringizing, and the function
name by concatenating the argument with _command. Here is how it is
done:
#define COMMAND(NAME) { #NAME, NAME ## _command }
struct command commands[] =
{
COMMAND (quit),
COMMAND (help),
...
};

File: cpp.info, Node: Variadic Macros, Next: Predefined Macros, Prev: Concatenation, Up: Macros
3.6 Variadic Macros
===================
A macro can be declared to accept a variable number of arguments much as
a function can. The syntax for defining the macro is similar to that of
a function. Here is an example:
#define eprintf(...) fprintf (stderr, __VA_ARGS__)
This kind of macro is called “variadic”. When the macro is invoked,
all the tokens in its argument list after the last named argument (this
macro has none), including any commas, become the “variable argument”.
This sequence of tokens replaces the identifier __VA_ARGS__ in the
macro body wherever it appears. Thus, we have this expansion:
eprintf ("%s:%d: ", input_file, lineno)
↦ fprintf (stderr, "%s:%d: ", input_file, lineno)
The variable argument is completely macro-expanded before it is
inserted into the macro expansion, just like an ordinary argument. You
may use the # and ## operators to stringize the variable argument or
to paste its leading or trailing token with another token. (But see
below for an important special case for ##.)
If your macro is complicated, you may want a more descriptive name
for the variable argument than __VA_ARGS__. CPP permits this, as an
extension. You may write an argument name immediately before the ...;
that name is used for the variable argument. The eprintf macro above
could be written
#define eprintf(args...) fprintf (stderr, args)
using this extension. You cannot use __VA_ARGS__ and this extension
in the same macro.
You can have named arguments as well as variable arguments in a
variadic macro. We could define eprintf like this, instead:
#define eprintf(format, ...) fprintf (stderr, format, __VA_ARGS__)
This formulation looks more descriptive, but historically it was less
flexible: you had to supply at least one argument after the format
string. In standard C, you could not omit the comma separating the
named argument from the variable arguments. (Note that this restriction
has been lifted in C++20, and never existed in GNU C; see below.)
Furthermore, if you left the variable argument empty, you would have
gotten a syntax error, because there would have been an extra comma
after the format string.
eprintf("success!\n", );
↦ fprintf(stderr, "success!\n", );
This has been fixed in C++20, and GNU CPP also has a pair of
extensions which deal with this problem.
First, in GNU CPP, and in C++ beginning in C++20, you are allowed to
leave the variable argument out entirely:
eprintf ("success!\n")
↦ fprintf(stderr, "success!\n", );
Second, C++20 introduces the __VA_OPT__ function macro. This macro
may only appear in the definition of a variadic macro. If the variable
argument has any tokens, then a __VA_OPT__ invocation expands to its
argument; but if the variable argument does not have any tokens, the
__VA_OPT__ expands to nothing:
#define eprintf(format, ...) \
fprintf (stderr, format __VA_OPT__(,) __VA_ARGS__)
__VA_OPT__ is also available in GNU C and GNU C++.
Historically, GNU CPP has also had another extension to handle the
trailing comma: the ## token paste operator has a special meaning when
placed between a comma and a variable argument. Despite the
introduction of __VA_OPT__, this extension remains supported in GNU
CPP, for backward compatibility. If you write
#define eprintf(format, ...) fprintf (stderr, format, ##__VA_ARGS__)
and the variable argument is left out when the eprintf macro is used,
then the comma before the ## will be deleted. This does _not_ happen
if you pass an empty argument, nor does it happen if the token preceding
## is anything other than a comma.
eprintf ("success!\n")
↦ fprintf(stderr, "success!\n");
The above explanation is ambiguous about the case where the only macro
parameter is a variable arguments parameter, as it is meaningless to try
to distinguish whether no argument at all is an empty argument or a
missing argument. CPP retains the comma when conforming to a specific C
standard. Otherwise the comma is dropped as an extension to the
standard.
The C standard mandates that the only place the identifier
__VA_ARGS__ can appear is in the replacement list of a variadic macro.
It may not be used as a macro name, macro argument name, or within a
different type of macro. It may also be forbidden in open text; the
standard is ambiguous. We recommend you avoid using it except for its
defined purpose.
Likewise, C++ forbids __VA_OPT__ anywhere outside the replacement
list of a variadic macro.
Variadic macros became a standard part of the C language with C99.
GNU CPP previously supported them with a named variable argument
(args..., not ... and __VA_ARGS__), which is still supported for
backward compatibility.

File: cpp.info, Node: Predefined Macros, Next: Undefining and Redefining Macros, Prev: Variadic Macros, Up: Macros
3.7 Predefined Macros
=====================
Several object-like macros are predefined; you use them without
supplying their definitions. They fall into three classes: standard,
common, and system-specific.
In C++, there is a fourth category, the named operators. They act
like predefined macros, but you cannot undefine them.
* Menu:
* Standard Predefined Macros::
* Common Predefined Macros::
* System-specific Predefined Macros::
* C++ Named Operators::

File: cpp.info, Node: Standard Predefined Macros, Next: Common Predefined Macros, Up: Predefined Macros
3.7.1 Standard Predefined Macros
--------------------------------
The standard predefined macros are specified by the relevant language
standards, so they are available with all compilers that implement those
standards. Older compilers may not provide all of them. Their names
all start with double underscores.
__FILE__
This macro expands to the name of the current input file, in the
form of a C string constant. This is the path by which the
preprocessor opened the file, not the short name specified in
#include or as the input file name argument. For example,
"/usr/local/include/myheader.h" is a possible expansion of this
macro.
__LINE__
This macro expands to the current input line number, in the form of
a decimal integer constant. While we call it a predefined macro,
its a pretty strange macro, since its “definition” changes with
each new line of source code.
__FILE__ and __LINE__ are useful in generating an error message
to report an inconsistency detected by the program; the message can
state the source line at which the inconsistency was detected. For
example,
fprintf (stderr, "Internal error: "
"negative string length "
"%d at %s, line %d.",
length, __FILE__, __LINE__);
An #include directive changes the expansions of __FILE__ and
__LINE__ to correspond to the included file. At the end of that file,
when processing resumes on the input file that contained the #include
directive, the expansions of __FILE__ and __LINE__ revert to the
values they had before the #include (but __LINE__ is then
incremented by one as processing moves to the line after the
#include).
A #line directive changes __LINE__, and may change __FILE__ as
well. *Note Line Control::.
C99 introduced __func__, and GCC has provided __FUNCTION__ for a
long time. Both of these are strings containing the name of the current
function (there are slight semantic differences; see the GCC manual).
Neither of them is a macro; the preprocessor does not know the name of
the current function. They tend to be useful in conjunction with
__FILE__ and __LINE__, though.
__DATE__
This macro expands to a string constant that describes the date on
which the preprocessor is being run. The string constant contains
eleven characters and looks like "Feb 12 1996". If the day of
the month is less than 10, it is padded with a space on the left.
If GCC cannot determine the current date, it will emit a warning
message (once per compilation) and __DATE__ will expand to
"??? ?? ????".
__TIME__
This macro expands to a string constant that describes the time at
which the preprocessor is being run. The string constant contains
eight characters and looks like "23:59:01".
If GCC cannot determine the current time, it will emit a warning
message (once per compilation) and __TIME__ will expand to
"??:??:??".
__STDC__
In normal operation, this macro expands to the constant 1, to
signify that this compiler conforms to ISO Standard C. If GNU CPP
is used with a compiler other than GCC, this is not necessarily
true; however, the preprocessor always conforms to the standard
unless the -traditional-cpp option is used.
This macro is not defined if the -traditional-cpp option is used.
On some hosts, the system compiler uses a different convention,
where __STDC__ is normally 0, but is 1 if the user specifies
strict conformance to the C Standard. CPP follows the host
convention when processing system header files, but when processing
user files __STDC__ is always 1. This has been reported to cause
problems; for instance, some versions of Solaris provide X Windows
headers that expect __STDC__ to be either undefined or 1. *Note
Invocation::.
__STDC_VERSION__
This macro expands to the C Standards version number, a long
integer constant of the form YYYYMML where YYYY and MM are the
year and month of the Standard version. This signifies which
version of the C Standard the compiler conforms to. Like
__STDC__, this is not necessarily accurate for the entire
implementation, unless GNU CPP is being used with GCC.
The value 199409L signifies the 1989 C standard as amended in
1994, which is the current default; the value 199901L signifies
the 1999 revision of the C standard; the value 201112L signifies
the 2011 revision of the C standard; the value 201710L signifies
the 2017 revision of the C standard (which is otherwise identical
to the 2011 version apart from correction of defects). An
unspecified value larger than 201710L is used for the
experimental -std=c2x and -std=gnu2x modes.
This macro is not defined if the -traditional-cpp option is used,
nor when compiling C++ or Objective-C.
__STDC_HOSTED__
This macro is defined, with value 1, if the compilers target is a
“hosted environment”. A hosted environment has the complete
facilities of the standard C library available.
__cplusplus
This macro is defined when the C++ compiler is in use. You can use
__cplusplus to test whether a header is compiled by a C compiler
or a C++ compiler. This macro is similar to __STDC_VERSION__, in
that it expands to a version number. Depending on the language
standard selected, the value of the macro is 199711L for the 1998
C++ standard, 201103L for the 2011 C++ standard, 201402L for
the 2014 C++ standard, 201703L for the 2017 C++ standard,
202002L for the 2020 C++ standard, or an unspecified value
strictly larger than 202002L for the experimental languages
enabled by -std=c++23 and -std=gnu++23.
__OBJC__
This macro is defined, with value 1, when the Objective-C compiler
is in use. You can use __OBJC__ to test whether a header is
compiled by a C compiler or an Objective-C compiler.
__ASSEMBLER__
This macro is defined with value 1 when preprocessing assembly
language.

File: cpp.info, Node: Common Predefined Macros, Next: System-specific Predefined Macros, Prev: Standard Predefined Macros, Up: Predefined Macros
3.7.2 Common Predefined Macros
------------------------------
The common predefined macros are GNU C extensions. They are available
with the same meanings regardless of the machine or operating system on
which you are using GNU C or GNU Fortran. Their names all start with
double underscores.
__COUNTER__
This macro expands to sequential integral values starting from 0.
In conjunction with the ## operator, this provides a convenient
means to generate unique identifiers. Care must be taken to ensure
that __COUNTER__ is not expanded prior to inclusion of
precompiled headers which use it. Otherwise, the precompiled
headers will not be used.
__GFORTRAN__
The GNU Fortran compiler defines this.
__GNUC__
__GNUC_MINOR__
__GNUC_PATCHLEVEL__
These macros are defined by all GNU compilers that use the C
preprocessor: C, C++, Objective-C and Fortran. Their values are
the major version, minor version, and patch level of the compiler,
as integer constants. For example, GCC version X.Y.Z defines
__GNUC__ to X, __GNUC_MINOR__ to Y, and __GNUC_PATCHLEVEL__
to Z. These macros are also defined if you invoke the preprocessor
directly.
If all you need to know is whether or not your program is being
compiled by GCC, or a non-GCC compiler that claims to accept the
GNU C dialects, you can simply test __GNUC__. If you need to
write code which depends on a specific version, you must be more
careful. Each time the minor version is increased, the patch level
is reset to zero; each time the major version is increased, the
minor version and patch level are reset. If you wish to use the
predefined macros directly in the conditional, you will need to
write it like this:
/* Test for GCC > 3.2.0 */
#if __GNUC__ > 3 || \
(__GNUC__ == 3 && (__GNUC_MINOR__ > 2 || \
(__GNUC_MINOR__ == 2 && \
__GNUC_PATCHLEVEL__ > 0))
Another approach is to use the predefined macros to calculate a
single number, then compare that against a threshold:
#define GCC_VERSION (__GNUC__ * 10000 \
+ __GNUC_MINOR__ * 100 \
+ __GNUC_PATCHLEVEL__)
...
/* Test for GCC > 3.2.0 */
#if GCC_VERSION > 30200
Many people find this form easier to understand.
__GNUG__
The GNU C++ compiler defines this. Testing it is equivalent to
testing (__GNUC__ && __cplusplus).
__STRICT_ANSI__
GCC defines this macro if and only if the -ansi switch, or a
-std switch specifying strict conformance to some version of ISO
C or ISO C++, was specified when GCC was invoked. It is defined to
1. This macro exists primarily to direct GNU libcs header files
to use only definitions found in standard C.
__BASE_FILE__
This macro expands to the name of the main input file, in the form
of a C string constant. This is the source file that was specified
on the command line of the preprocessor or C compiler.
__FILE_NAME__
This macro expands to the basename of the current input file, in
the form of a C string constant. This is the last path component
by which the preprocessor opened the file. For example, processing
"/usr/local/include/myheader.h" would set this macro to
"myheader.h".
__INCLUDE_LEVEL__
This macro expands to a decimal integer constant that represents
the depth of nesting in include files. The value of this macro is
incremented on every #include directive and decremented at the
end of every included file. It starts out at 0, its value within
the base file specified on the command line.
__ELF__
This macro is defined if the target uses the ELF object format.
__VERSION__
This macro expands to a string constant which describes the version
of the compiler in use. You should not rely on its contents having
any particular form, but it can be counted on to contain at least
the release number.
__OPTIMIZE__
__OPTIMIZE_SIZE__
__NO_INLINE__
These macros describe the compilation mode. __OPTIMIZE__ is
defined in all optimizing compilations. __OPTIMIZE_SIZE__ is
defined if the compiler is optimizing for size, not speed.
__NO_INLINE__ is defined if no functions will be inlined into
their callers (when not optimizing, or when inlining has been
specifically disabled by -fno-inline).
These macros cause certain GNU header files to provide optimized
definitions, using macros or inline functions, of system library
functions. You should not use these macros in any way unless you
make sure that programs will execute with the same effect whether
or not they are defined. If they are defined, their value is 1.
__GNUC_GNU_INLINE__
GCC defines this macro if functions declared inline will be
handled in GCCs traditional gnu90 mode. Object files will contain
externally visible definitions of all functions declared inline
without extern or static. They will not contain any
definitions of any functions declared extern inline.
__GNUC_STDC_INLINE__
GCC defines this macro if functions declared inline will be
handled according to the ISO C99 or later standards. Object files
will contain externally visible definitions of all functions
declared extern inline. They will not contain definitions of any
functions declared inline without extern.
If this macro is defined, GCC supports the gnu_inline function
attribute as a way to always get the gnu90 behavior.
__CHAR_UNSIGNED__
GCC defines this macro if and only if the data type char is
unsigned on the target machine. It exists to cause the standard
header file limits.h to work correctly. You should not use this
macro yourself; instead, refer to the standard macros defined in
limits.h.
__WCHAR_UNSIGNED__
Like __CHAR_UNSIGNED__, this macro is defined if and only if the
data type wchar_t is unsigned and the front-end is in C++ mode.
__REGISTER_PREFIX__
This macro expands to a single token (not a string constant) which
is the prefix applied to CPU register names in assembly language
for this target. You can use it to write assembly that is usable
in multiple environments. For example, in the m68k-aout
environment it expands to nothing, but in the m68k-coff
environment it expands to a single %.
__USER_LABEL_PREFIX__
This macro expands to a single token which is the prefix applied to
user labels (symbols visible to C code) in assembly. For example,
in the m68k-aout environment it expands to an _, but in the
m68k-coff environment it expands to nothing.
This macro will have the correct definition even if
-f(no-)underscores is in use, but it will not be correct if
target-specific options that adjust this prefix are used (e.g. the
OSF/rose -mno-underscores option).
__SIZE_TYPE__
__PTRDIFF_TYPE__
__WCHAR_TYPE__
__WINT_TYPE__
__INTMAX_TYPE__
__UINTMAX_TYPE__
__SIG_ATOMIC_TYPE__
__INT8_TYPE__
__INT16_TYPE__
__INT32_TYPE__
__INT64_TYPE__
__UINT8_TYPE__
__UINT16_TYPE__
__UINT32_TYPE__
__UINT64_TYPE__
__INT_LEAST8_TYPE__
__INT_LEAST16_TYPE__
__INT_LEAST32_TYPE__
__INT_LEAST64_TYPE__
__UINT_LEAST8_TYPE__
__UINT_LEAST16_TYPE__
__UINT_LEAST32_TYPE__
__UINT_LEAST64_TYPE__
__INT_FAST8_TYPE__
__INT_FAST16_TYPE__
__INT_FAST32_TYPE__
__INT_FAST64_TYPE__
__UINT_FAST8_TYPE__
__UINT_FAST16_TYPE__
__UINT_FAST32_TYPE__
__UINT_FAST64_TYPE__
__INTPTR_TYPE__
__UINTPTR_TYPE__
These macros are defined to the correct underlying types for the
size_t, ptrdiff_t, wchar_t, wint_t, intmax_t,
uintmax_t, sig_atomic_t, int8_t, int16_t, int32_t,
int64_t, uint8_t, uint16_t, uint32_t, uint64_t,
int_least8_t, int_least16_t, int_least32_t, int_least64_t,
uint_least8_t, uint_least16_t, uint_least32_t,
uint_least64_t, int_fast8_t, int_fast16_t, int_fast32_t,
int_fast64_t, uint_fast8_t, uint_fast16_t, uint_fast32_t,
uint_fast64_t, intptr_t, and uintptr_t typedefs,
respectively. They exist to make the standard header files
stddef.h, stdint.h, and wchar.h work correctly. You should
not use these macros directly; instead, include the appropriate
headers and use the typedefs. Some of these macros may not be
defined on particular systems if GCC does not provide a stdint.h
header on those systems.
__CHAR_BIT__
Defined to the number of bits used in the representation of the
char data type. It exists to make the standard header given
numerical limits work correctly. You should not use this macro
directly; instead, include the appropriate headers.
__SCHAR_MAX__
__WCHAR_MAX__
__SHRT_MAX__
__INT_MAX__
__LONG_MAX__
__LONG_LONG_MAX__
__WINT_MAX__
__SIZE_MAX__
__PTRDIFF_MAX__
__INTMAX_MAX__
__UINTMAX_MAX__
__SIG_ATOMIC_MAX__
__INT8_MAX__
__INT16_MAX__
__INT32_MAX__
__INT64_MAX__
__UINT8_MAX__
__UINT16_MAX__
__UINT32_MAX__
__UINT64_MAX__
__INT_LEAST8_MAX__
__INT_LEAST16_MAX__
__INT_LEAST32_MAX__
__INT_LEAST64_MAX__
__UINT_LEAST8_MAX__
__UINT_LEAST16_MAX__
__UINT_LEAST32_MAX__
__UINT_LEAST64_MAX__
__INT_FAST8_MAX__
__INT_FAST16_MAX__
__INT_FAST32_MAX__
__INT_FAST64_MAX__
__UINT_FAST8_MAX__
__UINT_FAST16_MAX__
__UINT_FAST32_MAX__
__UINT_FAST64_MAX__
__INTPTR_MAX__
__UINTPTR_MAX__
__WCHAR_MIN__
__WINT_MIN__
__SIG_ATOMIC_MIN__
Defined to the maximum value of the signed char, wchar_t,
signed short, signed int, signed long, signed long long,
wint_t, size_t, ptrdiff_t, intmax_t, uintmax_t,
sig_atomic_t, int8_t, int16_t, int32_t, int64_t,
uint8_t, uint16_t, uint32_t, uint64_t, int_least8_t,
int_least16_t, int_least32_t, int_least64_t, uint_least8_t,
uint_least16_t, uint_least32_t, uint_least64_t,
int_fast8_t, int_fast16_t, int_fast32_t, int_fast64_t,
uint_fast8_t, uint_fast16_t, uint_fast32_t, uint_fast64_t,
intptr_t, and uintptr_t types and to the minimum value of the
wchar_t, wint_t, and sig_atomic_t types respectively. They
exist to make the standard header given numerical limits work
correctly. You should not use these macros directly; instead,
include the appropriate headers. Some of these macros may not be
defined on particular systems if GCC does not provide a stdint.h
header on those systems.
__INT8_C
__INT16_C
__INT32_C
__INT64_C
__UINT8_C
__UINT16_C
__UINT32_C
__UINT64_C
__INTMAX_C
__UINTMAX_C
Defined to implementations of the standard stdint.h macros with
the same names without the leading __. They exist the make the
implementation of that header work correctly. You should not use
these macros directly; instead, include the appropriate headers.
Some of these macros may not be defined on particular systems if
GCC does not provide a stdint.h header on those systems.
__SCHAR_WIDTH__
__SHRT_WIDTH__
__INT_WIDTH__
__LONG_WIDTH__
__LONG_LONG_WIDTH__
__PTRDIFF_WIDTH__
__SIG_ATOMIC_WIDTH__
__SIZE_WIDTH__
__WCHAR_WIDTH__
__WINT_WIDTH__
__INT_LEAST8_WIDTH__
__INT_LEAST16_WIDTH__
__INT_LEAST32_WIDTH__
__INT_LEAST64_WIDTH__
__INT_FAST8_WIDTH__
__INT_FAST16_WIDTH__
__INT_FAST32_WIDTH__
__INT_FAST64_WIDTH__
__INTPTR_WIDTH__
__INTMAX_WIDTH__
Defined to the bit widths of the corresponding types. They exist
to make the implementations of limits.h and stdint.h behave
correctly. You should not use these macros directly; instead,
include the appropriate headers. Some of these macros may not be
defined on particular systems if GCC does not provide a stdint.h
header on those systems.
__SIZEOF_INT__
__SIZEOF_LONG__
__SIZEOF_LONG_LONG__
__SIZEOF_SHORT__
__SIZEOF_POINTER__
__SIZEOF_FLOAT__
__SIZEOF_DOUBLE__
__SIZEOF_LONG_DOUBLE__
__SIZEOF_SIZE_T__
__SIZEOF_WCHAR_T__
__SIZEOF_WINT_T__
__SIZEOF_PTRDIFF_T__
Defined to the number of bytes of the C standard data types: int,
long, long long, short, void *, float, double, long
double, size_t, wchar_t, wint_t and ptrdiff_t.
__BYTE_ORDER__
__ORDER_LITTLE_ENDIAN__
__ORDER_BIG_ENDIAN__
__ORDER_PDP_ENDIAN__
__BYTE_ORDER__ is defined to one of the values
__ORDER_LITTLE_ENDIAN__, __ORDER_BIG_ENDIAN__, or
__ORDER_PDP_ENDIAN__ to reflect the layout of multi-byte and
multi-word quantities in memory. If __BYTE_ORDER__ is equal to
__ORDER_LITTLE_ENDIAN__ or __ORDER_BIG_ENDIAN__, then
multi-byte and multi-word quantities are laid out identically: the
byte (word) at the lowest address is the least significant or most
significant byte (word) of the quantity, respectively. If
__BYTE_ORDER__ is equal to __ORDER_PDP_ENDIAN__, then bytes in
16-bit words are laid out in a little-endian fashion, whereas the
16-bit subwords of a 32-bit quantity are laid out in big-endian
fashion.
You should use these macros for testing like this:
/* Test for a little-endian machine */
#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
__FLOAT_WORD_ORDER__
__FLOAT_WORD_ORDER__ is defined to one of the values
__ORDER_LITTLE_ENDIAN__ or __ORDER_BIG_ENDIAN__ to reflect the
layout of the words of multi-word floating-point quantities.
__DEPRECATED
This macro is defined, with value 1, when compiling a C++ source
file with warnings about deprecated constructs enabled. These
warnings are enabled by default, but can be disabled with
-Wno-deprecated.
__EXCEPTIONS
This macro is defined, with value 1, when compiling a C++ source
file with exceptions enabled. If -fno-exceptions is used when
compiling the file, then this macro is not defined.
__GXX_RTTI
This macro is defined, with value 1, when compiling a C++ source
file with runtime type identification enabled. If -fno-rtti is
used when compiling the file, then this macro is not defined.
__USING_SJLJ_EXCEPTIONS__
This macro is defined, with value 1, if the compiler uses the old
mechanism based on setjmp and longjmp for exception handling.
__GXX_EXPERIMENTAL_CXX0X__
This macro is defined when compiling a C++ source file with C++11
features enabled, i.e., for all C++ language dialects except
-std=c++98 and -std=gnu++98. This macro is obsolete, but can
be used to detect experimental C++0x features in very old versions
of GCC. Since GCC 4.7.0 the __cplusplus macro is defined
correctly, so most code should test __cplusplus >= 201103L
instead of using this macro.
__GXX_WEAK__
This macro is defined when compiling a C++ source file. It has the
value 1 if the compiler will use weak symbols, COMDAT sections, or
other similar techniques to collapse symbols with “vague linkage”
that are defined in multiple translation units. If the compiler
will not collapse such symbols, this macro is defined with value 0.
In general, user code should not need to make use of this macro;
the purpose of this macro is to ease implementation of the C++
runtime library provided with G++.
__NEXT_RUNTIME__
This macro is defined, with value 1, if (and only if) the NeXT
runtime (as in -fnext-runtime) is in use for Objective-C. If the
GNU runtime is used, this macro is not defined, so that you can use
this macro to determine which runtime (NeXT or GNU) is being used.
__LP64__
_LP64
These macros are defined, with value 1, if (and only if) the
compilation is for a target where long int and pointer both use
64-bits and int uses 32-bit.
__SSP__
This macro is defined, with value 1, when -fstack-protector is in
use.
__SSP_ALL__
This macro is defined, with value 2, when -fstack-protector-all
is in use.
__SSP_STRONG__
This macro is defined, with value 3, when
-fstack-protector-strong is in use.
__SSP_EXPLICIT__
This macro is defined, with value 4, when
-fstack-protector-explicit is in use.
__SANITIZE_ADDRESS__
This macro is defined, with value 1, when -fsanitize=address or
-fsanitize=kernel-address are in use.
__SANITIZE_THREAD__
This macro is defined, with value 1, when -fsanitize=thread is in
use.
__TIMESTAMP__
This macro expands to a string constant that describes the date and
time of the last modification of the current source file. The
string constant contains abbreviated day of the week, month, day of
the month, time in hh:mm:ss form, year and looks like
"Sun Sep 16 01:03:52 1973". If the day of the month is less than
10, it is padded with a space on the left.
If GCC cannot determine the current date, it will emit a warning
message (once per compilation) and __TIMESTAMP__ will expand to
"??? ??? ?? ??:??:?? ????".
__GCC_HAVE_SYNC_COMPARE_AND_SWAP_1
__GCC_HAVE_SYNC_COMPARE_AND_SWAP_2
__GCC_HAVE_SYNC_COMPARE_AND_SWAP_4
__GCC_HAVE_SYNC_COMPARE_AND_SWAP_8
__GCC_HAVE_SYNC_COMPARE_AND_SWAP_16
These macros are defined when the target processor supports atomic
compare and swap operations on operands 1, 2, 4, 8 or 16 bytes in
length, respectively.
__HAVE_SPECULATION_SAFE_VALUE
This macro is defined with the value 1 to show that this version of
GCC supports __builtin_speculation_safe_value.
__GCC_HAVE_DWARF2_CFI_ASM
This macro is defined when the compiler is emitting DWARF CFI
directives to the assembler. When this is defined, it is possible
to emit those same directives in inline assembly.
__FP_FAST_FMA
__FP_FAST_FMAF
__FP_FAST_FMAL
These macros are defined with value 1 if the backend supports the
fma, fmaf, and fmal builtin functions, so that the include
file math.h can define the macros FP_FAST_FMA, FP_FAST_FMAF,
and FP_FAST_FMAL for compatibility with the 1999 C standard.
__FP_FAST_FMAF16
__FP_FAST_FMAF32
__FP_FAST_FMAF64
__FP_FAST_FMAF128
__FP_FAST_FMAF32X
__FP_FAST_FMAF64X
__FP_FAST_FMAF128X
These macros are defined with the value 1 if the backend supports
the fma functions using the additional _FloatN and _FloatNx
types that are defined in ISO/IEC TS 18661-3:2015. The include
file math.h can define the FP_FAST_FMAFN and FP_FAST_FMAFNx
macros if the user defined __STDC_WANT_IEC_60559_TYPES_EXT__
before including math.h.
__GCC_IEC_559
This macro is defined to indicate the intended level of support for
IEEE 754 (IEC 60559) floating-point arithmetic. It expands to a
nonnegative integer value. If 0, it indicates that the combination
of the compiler configuration and the command-line options is not
intended to support IEEE 754 arithmetic for float and double as
defined in C99 and C11 Annex F (for example, that the standard
rounding modes and exceptions are not supported, or that
optimizations are enabled that conflict with IEEE 754 semantics).
If 1, it indicates that IEEE 754 arithmetic is intended to be
supported; this does not mean that all relevant language features
are supported by GCC. If 2 or more, it additionally indicates
support for IEEE 754-2008 (in particular, that the binary encodings
for quiet and signaling NaNs are as specified in IEEE 754-2008).
This macro does not indicate the default state of command-line
options that control optimizations that C99 and C11 permit to be
controlled by standard pragmas, where those standards do not
require a particular default state. It does not indicate whether
optimizations respect signaling NaN semantics (the macro for that
is __SUPPORT_SNAN__). It does not indicate support for decimal
floating point or the IEEE 754 binary16 and binary128 types.
__GCC_IEC_559_COMPLEX
This macro is defined to indicate the intended level of support for
IEEE 754 (IEC 60559) floating-point arithmetic for complex numbers,
as defined in C99 and C11 Annex G. It expands to a nonnegative
integer value. If 0, it indicates that the combination of the
compiler configuration and the command-line options is not intended
to support Annex G requirements (for example, because
-fcx-limited-range was used). If 1 or more, it indicates that it
is intended to support those requirements; this does not mean that
all relevant language features are supported by GCC.
__NO_MATH_ERRNO__
This macro is defined if -fno-math-errno is used, or enabled by
another option such as -ffast-math or by default.
__RECIPROCAL_MATH__
This macro is defined if -freciprocal-math is used, or enabled by
another option such as -ffast-math or by default.
__NO_SIGNED_ZEROS__
This macro is defined if -fno-signed-zeros is used, or enabled by
another option such as -ffast-math or by default.
__NO_TRAPPING_MATH__
This macro is defined if -fno-trapping-math is used.
__ASSOCIATIVE_MATH__
This macro is defined if -fassociative-math is used, or enabled
by another option such as -ffast-math or by default.
__ROUNDING_MATH__
This macro is defined if -frounding-math is used.
__GNUC_EXECUTION_CHARSET_NAME
__GNUC_WIDE_EXECUTION_CHARSET_NAME
These macros are defined to expand to a narrow string literal of
the name of the narrow and wide compile-time execution character
set used. It directly reflects the name passed to the options
-fexec-charset and -fwide-exec-charset, or the defaults
documented for those options (that is, it can expand to something
like "UTF-8"). *Note Invocation::.

File: cpp.info, Node: System-specific Predefined Macros, Next: C++ Named Operators, Prev: Common Predefined Macros, Up: Predefined Macros
3.7.3 System-specific Predefined Macros
---------------------------------------
The C preprocessor normally predefines several macros that indicate what
type of system and machine is in use. They are obviously different on
each target supported by GCC. This manual, being for all systems and
machines, cannot tell you what their names are, but you can use cpp
-dM to see them all. *Note Invocation::. All system-specific
predefined macros expand to a constant value, so you can test them with
either #ifdef or #if.
The C standard requires that all system-specific macros be part of
the “reserved namespace”. All names which begin with two underscores,
or an underscore and a capital letter, are reserved for the compiler and
library to use as they wish. However, historically system-specific
macros have had names with no special prefix; for instance, it is common
to find unix defined on Unix systems. For all such macros, GCC
provides a parallel macro with two underscores added at the beginning
and the end. If unix is defined, __unix__ will be defined too.
There will never be more than two underscores; the parallel of _mips
is __mips__.
When the -ansi option, or any -std option that requests strict
conformance, is given to the compiler, all the system-specific
predefined macros outside the reserved namespace are suppressed. The
parallel macros, inside the reserved namespace, remain defined.
We are slowly phasing out all predefined macros which are outside the
reserved namespace. You should never use them in new programs, and we
encourage you to correct older code to use the parallel macros whenever
you find it. We dont recommend you use the system-specific macros that
are in the reserved namespace, either. It is better in the long run to
check specifically for features you need, using a tool such as
autoconf.

File: cpp.info, Node: C++ Named Operators, Prev: System-specific Predefined Macros, Up: Predefined Macros
3.7.4 C++ Named Operators
-------------------------
In C++, there are eleven keywords which are simply alternate spellings
of operators normally written with punctuation. These keywords are
treated as such even in the preprocessor. They function as operators in
#if, and they cannot be defined as macros or poisoned. In C, you can
request that those keywords take their C++ meaning by including
iso646.h. That header defines each one as a normal object-like macro
expanding to the appropriate punctuator.
These are the named operators and their corresponding punctuators:
Named Operator Punctuator
and &&
and_eq &=
bitand &
bitor |
compl ~
not !
not_eq !=
or ||
or_eq |=
xor ^
xor_eq ^=

File: cpp.info, Node: Undefining and Redefining Macros, Next: Directives Within Macro Arguments, Prev: Predefined Macros, Up: Macros
3.8 Undefining and Redefining Macros
====================================
If a macro ceases to be useful, it may be “undefined” with the #undef
directive. #undef takes a single argument, the name of the macro to
undefine. You use the bare macro name, even if the macro is
function-like. It is an error if anything appears on the line after the
macro name. #undef has no effect if the name is not a macro.
#define FOO 4
x = FOO; ↦ x = 4;
#undef FOO
x = FOO; ↦ x = FOO;
Once a macro has been undefined, that identifier may be “redefined”
as a macro by a subsequent #define directive. The new definition need
not have any resemblance to the old definition.
However, if an identifier which is currently a macro is redefined,
then the new definition must be “effectively the same” as the old one.
Two macro definitions are effectively the same if:
• Both are the same type of macro (object- or function-like).
• All the tokens of the replacement list are the same.
• If there are any parameters, they are the same.
• Whitespace appears in the same places in both. It need not be
exactly the same amount of whitespace, though. Remember that
comments count as whitespace.
These definitions are effectively the same:
#define FOUR (2 + 2)
#define FOUR (2 + 2)
#define FOUR (2 /* two */ + 2)
but these are not:
#define FOUR (2 + 2)
#define FOUR ( 2+2 )
#define FOUR (2 * 2)
#define FOUR(score,and,seven,years,ago) (2 + 2)
If a macro is redefined with a definition that is not effectively the
same as the old one, the preprocessor issues a warning and changes the
macro to use the new definition. If the new definition is effectively
the same, the redefinition is silently ignored. This allows, for
instance, two different headers to define a common macro. The
preprocessor will only complain if the definitions do not match.

File: cpp.info, Node: Directives Within Macro Arguments, Next: Macro Pitfalls, Prev: Undefining and Redefining Macros, Up: Macros
3.9 Directives Within Macro Arguments
=====================================
Occasionally it is convenient to use preprocessor directives within the
arguments of a macro. The C and C++ standards declare that behavior in
these cases is undefined. GNU CPP processes arbitrary directives within
macro arguments in exactly the same way as it would have processed the
directive were the function-like macro invocation not present.
If, within a macro invocation, that macro is redefined, then the new
definition takes effect in time for argument pre-expansion, but the
original definition is still used for argument replacement. Here is a
pathological example:
#define f(x) x x
f (1
#undef f
#define f 2
f)
which expands to
1 2 1 2
with the semantics described above.

File: cpp.info, Node: Macro Pitfalls, Prev: Directives Within Macro Arguments, Up: Macros
3.10 Macro Pitfalls
===================
In this section we describe some special rules that apply to macros and
macro expansion, and point out certain cases in which the rules have
counter-intuitive consequences that you must watch out for.
* Menu:
* Misnesting::
* Operator Precedence Problems::
* Swallowing the Semicolon::
* Duplication of Side Effects::
* Self-Referential Macros::
* Argument Prescan::
* Newlines in Arguments::

File: cpp.info, Node: Misnesting, Next: Operator Precedence Problems, Up: Macro Pitfalls
3.10.1 Misnesting
-----------------
When a macro is called with arguments, the arguments are substituted
into the macro body and the result is checked, together with the rest of
the input file, for more macro calls. It is possible to piece together
a macro call coming partially from the macro body and partially from the
arguments. For example,
#define twice(x) (2*(x))
#define call_with_1(x) x(1)
call_with_1 (twice)
↦ twice(1)
↦ (2*(1))
Macro definitions do not have to have balanced parentheses. By
writing an unbalanced open parenthesis in a macro body, it is possible
to create a macro call that begins inside the macro body but ends
outside of it. For example,
#define strange(file) fprintf (file, "%s %d",
...
strange(stderr) p, 35)
↦ fprintf (stderr, "%s %d", p, 35)
The ability to piece together a macro call can be useful, but the use
of unbalanced open parentheses in a macro body is just confusing, and
should be avoided.

File: cpp.info, Node: Operator Precedence Problems, Next: Swallowing the Semicolon, Prev: Misnesting, Up: Macro Pitfalls
3.10.2 Operator Precedence Problems
-----------------------------------
You may have noticed that in most of the macro definition examples shown
above, each occurrence of a macro argument name had parentheses around
it. In addition, another pair of parentheses usually surround the
entire macro definition. Here is why it is best to write macros that
way.
Suppose you define a macro as follows,
#define ceil_div(x, y) (x + y - 1) / y
whose purpose is to divide, rounding up. (One use for this operation is
to compute how many int objects are needed to hold a certain number of
char objects.) Then suppose it is used as follows:
a = ceil_div (b & c, sizeof (int));
↦ a = (b & c + sizeof (int) - 1) / sizeof (int);
This does not do what is intended. The operator-precedence rules of C
make it equivalent to this:
a = (b & (c + sizeof (int) - 1)) / sizeof (int);
What we want is this:
a = ((b & c) + sizeof (int) - 1)) / sizeof (int);
Defining the macro as
#define ceil_div(x, y) ((x) + (y) - 1) / (y)
provides the desired result.
Unintended grouping can result in another way. Consider sizeof
ceil_div(1, 2). That has the appearance of a C expression that would
compute the size of the type of ceil_div (1, 2), but in fact it means
something very different. Here is what it expands to:
sizeof ((1) + (2) - 1) / (2)
This would take the size of an integer and divide it by two. The
precedence rules have put the division outside the sizeof when it was
intended to be inside.
Parentheses around the entire macro definition prevent such problems.
Here, then, is the recommended way to define ceil_div:
#define ceil_div(x, y) (((x) + (y) - 1) / (y))

File: cpp.info, Node: Swallowing the Semicolon, Next: Duplication of Side Effects, Prev: Operator Precedence Problems, Up: Macro Pitfalls
3.10.3 Swallowing the Semicolon
-------------------------------
Often it is desirable to define a macro that expands into a compound
statement. Consider, for example, the following macro, that advances a
pointer (the argument p says where to find it) across whitespace
characters:
#define SKIP_SPACES(p, limit) \
{ char *lim = (limit); \
while (p < lim) { \
if (*p++ != ' ') { \
p--; break; }}}
Here backslash-newline is used to split the macro definition, which must
be a single logical line, so that it resembles the way such code would
be laid out if not part of a macro definition.
A call to this macro might be SKIP_SPACES (p, lim). Strictly
speaking, the call expands to a compound statement, which is a complete
statement with no need for a semicolon to end it. However, since it
looks like a function call, it minimizes confusion if you can use it
like a function call, writing a semicolon afterward, as in SKIP_SPACES
(p, lim);
This can cause trouble before else statements, because the
semicolon is actually a null statement. Suppose you write
if (*p != 0)
SKIP_SPACES (p, lim);
else ...
The presence of two statements—the compound statement and a null
statement—in between the if condition and the else makes invalid C
code.
The definition of the macro SKIP_SPACES can be altered to solve
this problem, using a do ... while statement. Here is how:
#define SKIP_SPACES(p, limit) \
do { char *lim = (limit); \
while (p < lim) { \
if (*p++ != ' ') { \
p--; break; }}} \
while (0)
Now SKIP_SPACES (p, lim); expands into
do {...} while (0);
which is one statement. The loop executes exactly once; most compilers
generate no extra code for it.

File: cpp.info, Node: Duplication of Side Effects, Next: Self-Referential Macros, Prev: Swallowing the Semicolon, Up: Macro Pitfalls
3.10.4 Duplication of Side Effects
----------------------------------
Many C programs define a macro min, for “minimum”, like this:
#define min(X, Y) ((X) < (Y) ? (X) : (Y))
When you use this macro with an argument containing a side effect, as
shown here,
next = min (x + y, foo (z));
it expands as follows:
next = ((x + y) < (foo (z)) ? (x + y) : (foo (z)));
where x + y has been substituted for X and foo (z) for Y.
The function foo is used only once in the statement as it appears
in the program, but the expression foo (z) has been substituted twice
into the macro expansion. As a result, foo might be called two times
when the statement is executed. If it has side effects or if it takes a
long time to compute, the results might not be what you intended. We
say that min is an “unsafe” macro.
The best solution to this problem is to define min in a way that
computes the value of foo (z) only once. The C language offers no
standard way to do this, but it can be done with GNU extensions as
follows:
#define min(X, Y) \
({ typeof (X) x_ = (X); \
typeof (Y) y_ = (Y); \
(x_ < y_) ? x_ : y_; })
The ({ ... }) notation produces a compound statement that acts as
an expression. Its value is the value of its last statement. This
permits us to define local variables and assign each argument to one.
The local variables have underscores after their names to reduce the
risk of conflict with an identifier of wider scope (it is impossible to
avoid this entirely). Now each argument is evaluated exactly once.
If you do not wish to use GNU C extensions, the only solution is to
be careful when _using_ the macro min. For example, you can calculate
the value of foo (z), save it in a variable, and use that variable in
min:
#define min(X, Y) ((X) < (Y) ? (X) : (Y))
...
{
int tem = foo (z);
next = min (x + y, tem);
}
(where we assume that foo returns type int).

File: cpp.info, Node: Self-Referential Macros, Next: Argument Prescan, Prev: Duplication of Side Effects, Up: Macro Pitfalls
3.10.5 Self-Referential Macros
------------------------------
A “self-referential” macro is one whose name appears in its definition.
Recall that all macro definitions are rescanned for more macros to
replace. If the self-reference were considered a use of the macro, it
would produce an infinitely large expansion. To prevent this, the
self-reference is not considered a macro call. It is passed into the
preprocessor output unchanged. Consider an example:
#define foo (4 + foo)
where foo is also a variable in your program.
Following the ordinary rules, each reference to foo will expand
into (4 + foo); then this will be rescanned and will expand into (4 +
(4 + foo)); and so on until the computer runs out of memory.
The self-reference rule cuts this process short after one step, at
(4 + foo). Therefore, this macro definition has the possibly useful
effect of causing the program to add 4 to the value of foo wherever
foo is referred to.
In most cases, it is a bad idea to take advantage of this feature. A
person reading the program who sees that foo is a variable will not
expect that it is a macro as well. The reader will come across the
identifier foo in the program and think its value should be that of
the variable foo, whereas in fact the value is four greater.
One common, useful use of self-reference is to create a macro which
expands to itself. If you write
#define EPERM EPERM
then the macro EPERM expands to EPERM. Effectively, it is left
alone by the preprocessor whenever its used in running text. You can
tell that its a macro with #ifdef. You might do this if you want to
define numeric constants with an enum, but have #ifdef be true for
each constant.
If a macro x expands to use a macro y, and the expansion of y
refers to the macro x, that is an “indirect self-reference” of x.
x is not expanded in this case either. Thus, if we have
#define x (4 + y)
#define y (2 * x)
then x and y expand as follows:
x ↦ (4 + y)
↦ (4 + (2 * x))
y ↦ (2 * x)
↦ (2 * (4 + y))
Each macro is expanded when it appears in the definition of the other
macro, but not when it indirectly appears in its own definition.

File: cpp.info, Node: Argument Prescan, Next: Newlines in Arguments, Prev: Self-Referential Macros, Up: Macro Pitfalls
3.10.6 Argument Prescan
-----------------------
Macro arguments are completely macro-expanded before they are
substituted into a macro body, unless they are stringized or pasted with
other tokens. After substitution, the entire macro body, including the
substituted arguments, is scanned again for macros to be expanded. The
result is that the arguments are scanned _twice_ to expand macro calls
in them.
Most of the time, this has no effect. If the argument contained any
macro calls, they are expanded during the first scan. The result
therefore contains no macro calls, so the second scan does not change
it. If the argument were substituted as given, with no prescan, the
single remaining scan would find the same macro calls and produce the
same results.
You might expect the double scan to change the results when a
self-referential macro is used in an argument of another macro (*note
Self-Referential Macros::): the self-referential macro would be expanded
once in the first scan, and a second time in the second scan. However,
this is not what happens. The self-references that do not expand in the
first scan are marked so that they will not expand in the second scan
either.
You might wonder, “Why mention the prescan, if it makes no
difference? And why not skip it and make the preprocessor faster?” The
answer is that the prescan does make a difference in three special
cases:
• Nested calls to a macro.
We say that “nested” calls to a macro occur when a macros argument
contains a call to that very macro. For example, if f is a macro
that expects one argument, f (f (1)) is a nested pair of calls to
f. The desired expansion is made by expanding f (1) and
substituting that into the definition of f. The prescan causes
the expected result to happen. Without the prescan, f (1) itself
would be substituted as an argument, and the inner use of f would
appear during the main scan as an indirect self-reference and would
not be expanded.
• Macros that call other macros that stringize or concatenate.
If an argument is stringized or concatenated, the prescan does not
occur. If you _want_ to expand a macro, then stringize or
concatenate its expansion, you can do that by causing one macro to
call another macro that does the stringizing or concatenation. For
instance, if you have
#define AFTERX(x) X_ ## x
#define XAFTERX(x) AFTERX(x)
#define TABLESIZE 1024
#define BUFSIZE TABLESIZE
then AFTERX(BUFSIZE) expands to X_BUFSIZE, and
XAFTERX(BUFSIZE) expands to X_1024. (Not to X_TABLESIZE.
Prescan always does a complete expansion.)
• Macros used in arguments, whose expansions contain unshielded
commas.
This can cause a macro expanded on the second scan to be called
with the wrong number of arguments. Here is an example:
#define foo a,b
#define bar(x) lose(x)
#define lose(x) (1 + (x))
We would like bar(foo) to turn into (1 + (foo)), which would
then turn into (1 + (a,b)). Instead, bar(foo) expands into
lose(a,b), and you get an error because lose requires a single
argument. In this case, the problem is easily solved by the same
parentheses that ought to be used to prevent misnesting of
arithmetic operations:
#define foo (a,b)
or
#define bar(x) lose((x))
The extra pair of parentheses prevents the comma in foos
definition from being interpreted as an argument separator.

File: cpp.info, Node: Newlines in Arguments, Prev: Argument Prescan, Up: Macro Pitfalls
3.10.7 Newlines in Arguments
----------------------------
The invocation of a function-like macro can extend over many logical
lines. However, in the present implementation, the entire expansion
comes out on one line. Thus line numbers emitted by the compiler or
debugger refer to the line the invocation started on, which might be
different to the line containing the argument causing the problem.
Here is an example illustrating this:
#define ignore_second_arg(a,b,c) a; c
ignore_second_arg (foo (),
ignored (),
syntax error);
The syntax error triggered by the tokens syntax error results in an
error message citing line three—the line of ignore_second_arg— even
though the problematic code comes from line five.
We consider this a bug, and intend to fix it in the near future.

File: cpp.info, Node: Conditionals, Next: Diagnostics, Prev: Macros, Up: Top
4 Conditionals
**************
A “conditional” is a directive that instructs the preprocessor to select
whether or not to include a chunk of code in the final token stream
passed to the compiler. Preprocessor conditionals can test arithmetic
expressions, or whether a name is defined as a macro, or both
simultaneously using the special defined operator.
A conditional in the C preprocessor resembles in some ways an if
statement in C, but it is important to understand the difference between
them. The condition in an if statement is tested during the execution
of your program. Its purpose is to allow your program to behave
differently from run to run, depending on the data it is operating on.
The condition in a preprocessing conditional directive is tested when
your program is compiled. Its purpose is to allow different code to be
included in the program depending on the situation at the time of
compilation.
However, the distinction is becoming less clear. Modern compilers
often do test if statements when a program is compiled, if their
conditions are known not to vary at run time, and eliminate code which
can never be executed. If you can count on your compiler to do this,
you may find that your program is more readable if you use if
statements with constant conditions (perhaps determined by macros). Of
course, you can only use this to exclude code, not type definitions or
other preprocessing directives, and you can only do it if the code
remains syntactically valid when it is not to be used.
* Menu:
* Conditional Uses::
* Conditional Syntax::
* Deleted Code::

File: cpp.info, Node: Conditional Uses, Next: Conditional Syntax, Up: Conditionals
4.1 Conditional Uses
====================
There are three general reasons to use a conditional.
• A program may need to use different code depending on the machine
or operating system it is to run on. In some cases the code for
one operating system may be erroneous on another operating system;
for example, it might refer to data types or constants that do not
exist on the other system. When this happens, it is not enough to
avoid executing the invalid code. Its mere presence will cause the
compiler to reject the program. With a preprocessing conditional,
the offending code can be effectively excised from the program when
it is not valid.
• You may want to be able to compile the same source file into two
different programs. One version might make frequent time-consuming
consistency checks on its intermediate data, or print the values of
those data for debugging, and the other not.
• A conditional whose condition is always false is one way to exclude
code from the program but keep it as a sort of comment for future
reference.
Simple programs that do not need system-specific logic or complex
debugging hooks generally will not need to use preprocessing
conditionals.

File: cpp.info, Node: Conditional Syntax, Next: Deleted Code, Prev: Conditional Uses, Up: Conditionals
4.2 Conditional Syntax
======================
A conditional in the C preprocessor begins with a “conditional
directive”: #if, #ifdef or #ifndef.
* Menu:
* Ifdef::
* If::
* Defined::
* Else::
* Elif::
* __has_attribute::
* __has_cpp_attribute::
* __has_c_attribute::
* __has_builtin::
* __has_include::

File: cpp.info, Node: Ifdef, Next: If, Up: Conditional Syntax
4.2.1 Ifdef
-----------
The simplest sort of conditional is
#ifdef MACRO
CONTROLLED TEXT
#endif /* MACRO */
This block is called a “conditional group”. CONTROLLED TEXT will be
included in the output of the preprocessor if and only if MACRO is
defined. We say that the conditional “succeeds” if MACRO is defined,
“fails” if it is not.
The CONTROLLED TEXT inside of a conditional can include preprocessing
directives. They are executed only if the conditional succeeds. You
can nest conditional groups inside other conditional groups, but they
must be completely nested. In other words, #endif always matches the
nearest #ifdef (or #ifndef, or #if). Also, you cannot start a
conditional group in one file and end it in another.
Even if a conditional fails, the CONTROLLED TEXT inside it is still
run through initial transformations and tokenization. Therefore, it
must all be lexically valid C. Normally the only way this matters is
that all comments and string literals inside a failing conditional group
must still be properly ended.
The comment following the #endif is not required, but it is a good
practice if there is a lot of CONTROLLED TEXT, because it helps people
match the #endif to the corresponding #ifdef. Older programs
sometimes put MACRO directly after the #endif without enclosing it in
a comment. This is invalid code according to the C standard. CPP
accepts it with a warning. It never affects which #ifndef the
#endif matches.
Sometimes you wish to use some code if a macro is _not_ defined. You
can do this by writing #ifndef instead of #ifdef. One common use of
#ifndef is to include code only the first time a header file is
included. *Note Once-Only Headers::.
Macro definitions can vary between compilations for several reasons.
Here are some samples.
• Some macros are predefined on each kind of machine (*note
System-specific Predefined Macros::). This allows you to provide
code specially tuned for a particular machine.
• System header files define more macros, associated with the
features they implement. You can test these macros with
conditionals to avoid using a system feature on a machine where it
is not implemented.
• Macros can be defined or undefined with the -D and -U
command-line options when you compile the program. You can arrange
to compile the same source file into two different programs by
choosing a macro name to specify which program you want, writing
conditionals to test whether or how this macro is defined, and then
controlling the state of the macro with command-line options,
perhaps set in the Makefile. *Note Invocation::.
• Your program might have a special header file (often called
config.h) that is adjusted when the program is compiled. It can
define or not define macros depending on the features of the system
and the desired capabilities of the program. The adjustment can be
automated by a tool such as autoconf, or done by hand.

File: cpp.info, Node: If, Next: Defined, Prev: Ifdef, Up: Conditional Syntax
4.2.2 If
--------
The #if directive allows you to test the value of an arithmetic
expression, rather than the mere existence of one macro. Its syntax is
#if EXPRESSION
CONTROLLED TEXT
#endif /* EXPRESSION */
EXPRESSION is a C expression of integer type, subject to stringent
restrictions. It may contain
• Integer constants.
• Character constants, which are interpreted as they would be in
normal code.
• Arithmetic operators for addition, subtraction, multiplication,
division, bitwise operations, shifts, comparisons, and logical
operations (&& and ||). The latter two obey the usual
short-circuiting rules of standard C.
• Macros. All macros in the expression are expanded before actual
computation of the expressions value begins.
• Uses of the defined operator, which lets you check whether macros
are defined in the middle of an #if.
• Identifiers that are not macros, which are all considered to be the
number zero. This allows you to write #if MACRO instead of
#ifdef MACRO, if you know that MACRO, when defined, will always
have a nonzero value. Function-like macros used without their
function call parentheses are also treated as zero.
In some contexts this shortcut is undesirable. The -Wundef
option causes GCC to warn whenever it encounters an identifier
which is not a macro in an #if.
The preprocessor does not know anything about types in the language.
Therefore, sizeof operators are not recognized in #if, and neither
are enum constants. They will be taken as identifiers which are not
macros, and replaced by zero. In the case of sizeof, this is likely
to cause the expression to be invalid.
The preprocessor calculates the value of EXPRESSION. It carries out
all calculations in the widest integer type known to the compiler; on
most machines supported by GCC this is 64 bits. This is not the same
rule as the compiler uses to calculate the value of a constant
expression, and may give different results in some cases. If the value
comes out to be nonzero, the #if succeeds and the CONTROLLED TEXT is
included; otherwise it is skipped.

File: cpp.info, Node: Defined, Next: Else, Prev: If, Up: Conditional Syntax
4.2.3 Defined
-------------
The special operator defined is used in #if and #elif expressions
to test whether a certain name is defined as a macro. defined NAME
and defined (NAME) are both expressions whose value is 1 if NAME is
defined as a macro at the current point in the program, and 0 otherwise.
Thus, #if defined MACRO is precisely equivalent to #ifdef MACRO.
defined is useful when you wish to test more than one macro for
existence at once. For example,
#if defined (__vax__) || defined (__ns16000__)
would succeed if either of the names __vax__ or __ns16000__ is
defined as a macro.
Conditionals written like this:
#if defined BUFSIZE && BUFSIZE >= 1024
can generally be simplified to just #if BUFSIZE >= 1024, since if
BUFSIZE is not defined, it will be interpreted as having the value
zero.
If the defined operator appears as a result of a macro expansion,
the C standard says the behavior is undefined. GNU cpp treats it as a
genuine defined operator and evaluates it normally. It will warn
wherever your code uses this feature if you use the command-line option
-Wpedantic, since other compilers may handle it differently. The
warning is also enabled by -Wextra, and can also be enabled
individually with -Wexpansion-to-defined.

File: cpp.info, Node: Else, Next: Elif, Prev: Defined, Up: Conditional Syntax
4.2.4 Else
----------
The #else directive can be added to a conditional to provide
alternative text to be used if the condition fails. This is what it
looks like:
#if EXPRESSION
TEXT-IF-TRUE
#else /* Not EXPRESSION */
TEXT-IF-FALSE
#endif /* Not EXPRESSION */
If EXPRESSION is nonzero, the TEXT-IF-TRUE is included and the
TEXT-IF-FALSE is skipped. If EXPRESSION is zero, the opposite happens.
You can use #else with #ifdef and #ifndef, too.

File: cpp.info, Node: Elif, Next: __has_attribute, Prev: Else, Up: Conditional Syntax
4.2.5 Elif
----------
One common case of nested conditionals is used to check for more than
two possible alternatives. For example, you might have
#if X == 1
...
#else /* X != 1 */
#if X == 2
...
#else /* X != 2 */
...
#endif /* X != 2 */
#endif /* X != 1 */
Another conditional directive, #elif, allows this to be abbreviated
as follows:
#if X == 1
...
#elif X == 2
...
#else /* X != 2 and X != 1*/
...
#endif /* X != 2 and X != 1*/
#elif stands for “else if”. Like #else, it goes in the middle of
a conditional group and subdivides it; it does not require a matching
#endif of its own. Like #if, the #elif directive includes an
expression to be tested. The text following the #elif is processed
only if the original #if-condition failed and the #elif condition
succeeds.
More than one #elif can go in the same conditional group. Then the
text after each #elif is processed only if the #elif condition
succeeds after the original #if and all previous #elif directives
within it have failed.
#else is allowed after any number of #elif directives, but
#elif may not follow #else.

File: cpp.info, Node: __has_attribute, Next: __has_cpp_attribute, Prev: Elif, Up: Conditional Syntax
4.2.6 __has_attribute
-----------------------
The special operator __has_attribute (OPERAND) may be used in #if
and #elif expressions to test whether the attribute referenced by its
OPERAND is recognized by GCC. Using the operator in other contexts is
not valid. In C code, if compiling for strict conformance to standards
before C2x, OPERAND must be a valid identifier. Otherwise, OPERAND may
be optionally introduced by the ATTRIBUTE-SCOPE:: prefix. The
ATTRIBUTE-SCOPE prefix identifies the “namespace” within which the
attribute is recognized. The scope of GCC attributes is gnu or
__gnu__. The __has_attribute operator by itself, without any
OPERAND or parentheses, acts as a predefined macro so that support for
it can be tested in portable code. Thus, the recommended use of the
operator is as follows:
#if defined __has_attribute
# if __has_attribute (nonnull)
# define ATTR_NONNULL __attribute__ ((nonnull))
# endif
#endif
The first #if test succeeds only when the operator is supported by
the version of GCC (or another compiler) being used. Only when that
test succeeds is it valid to use __has_attribute as a preprocessor
operator. As a result, combining the two tests into a single expression
as shown below would only be valid with a compiler that supports the
operator but not with others that dont.
#if defined __has_attribute && __has_attribute (nonnull) /* not portable */
...
#endif

File: cpp.info, Node: __has_cpp_attribute, Next: __has_c_attribute, Prev: __has_attribute, Up: Conditional Syntax
4.2.7 __has_cpp_attribute
---------------------------
The special operator __has_cpp_attribute (OPERAND) may be used in
#if and #elif expressions in C++ code to test whether the attribute
referenced by its OPERAND is recognized by GCC. __has_cpp_attribute
(OPERAND) is equivalent to __has_attribute (OPERAND) except that when
OPERAND designates a supported standard attribute it evaluates to an
integer constant of the form YYYYMM indicating the year and month when
the attribute was first introduced into the C++ standard. For
additional information including the dates of the introduction of
current standard attributes, see
SD-6: SG10 Feature Test Recommendations (https://isocpp.org/std/standing-documents/sd-6-sg10-feature-test-recommendations/).

File: cpp.info, Node: __has_c_attribute, Next: __has_builtin, Prev: __has_cpp_attribute, Up: Conditional Syntax
4.2.8 __has_c_attribute
-------------------------
The special operator __has_c_attribute (OPERAND) may be used in #if
and #elif expressions in C code to test whether the attribute
referenced by its OPERAND is recognized by GCC in attributes using the
[[]] syntax. GNU attributes must be specified with the scope gnu or
__gnu__ with __has_c_attribute. When OPERAND designates a supported
standard attribute it evaluates to an integer constant of the form
YYYYMM indicating the year and month when the attribute was first
introduced into the C standard, or when the syntax of operands to the
attribute was extended in the C standard.

File: cpp.info, Node: __has_builtin, Next: __has_include, Prev: __has_c_attribute, Up: Conditional Syntax
4.2.9 __has_builtin
---------------------
The special operator __has_builtin (OPERAND) may be used in constant
integer contexts and in preprocessor #if and #elif expressions to
test whether the symbol named by its OPERAND is recognized as a built-in
function by GCC in the current language and conformance mode. It
evaluates to a constant integer with a nonzero value if the argument
refers to such a function, and to zero otherwise. The operator may also
be used in preprocessor #if and #elif expressions. The
__has_builtin operator by itself, without any OPERAND or parentheses,
acts as a predefined macro so that support for it can be tested in
portable code. Thus, the recommended use of the operator is as follows:
#if defined __has_builtin
# if __has_builtin (__builtin_object_size)
# define builtin_object_size(ptr) __builtin_object_size (ptr, 2)
# endif
#endif
#ifndef builtin_object_size
# define builtin_object_size(ptr) ((size_t)-1)
#endif

File: cpp.info, Node: __has_include, Prev: __has_builtin, Up: Conditional Syntax
4.2.10 __has_include
----------------------
The special operator __has_include (OPERAND) may be used in #if and
#elif expressions to test whether the header referenced by its OPERAND
can be included using the #include directive. Using the operator in
other contexts is not valid. The OPERAND takes the same form as the
file in the #include directive (*note Include Syntax::) and evaluates
to a nonzero value if the header can be included and to zero otherwise.
Note that that the ability to include a header doesnt imply that the
header doesnt contain invalid constructs or #error directives that
would cause the preprocessor to fail.
The __has_include operator by itself, without any OPERAND or
parentheses, acts as a predefined macro so that support for it can be
tested in portable code. Thus, the recommended use of the operator is
as follows:
#if defined __has_include
# if __has_include (<stdatomic.h>)
# include <stdatomic.h>
# endif
#endif
The first #if test succeeds only when the operator is supported by
the version of GCC (or another compiler) being used. Only when that
test succeeds is it valid to use __has_include as a preprocessor
operator. As a result, combining the two tests into a single expression
as shown below would only be valid with a compiler that supports the
operator but not with others that dont.
#if defined __has_include && __has_include ("header.h") /* not portable */
...
#endif

File: cpp.info, Node: Deleted Code, Prev: Conditional Syntax, Up: Conditionals
4.3 Deleted Code
================
If you replace or delete a part of the program but want to keep the old
code around for future reference, you often cannot simply comment it
out. Block comments do not nest, so the first comment inside the old
code will end the commenting-out. The probable result is a flood of
syntax errors.
One way to avoid this problem is to use an always-false conditional
instead. For instance, put #if 0 before the deleted code and #endif
after it. This works even if the code being turned off contains
conditionals, but they must be entire conditionals (balanced #if and
#endif).
Some people use #ifdef notdef instead. This is risky, because
notdef might be accidentally defined as a macro, and then the
conditional would succeed. #if 0 can be counted on to fail.
Do not use #if 0 for comments which are not C code. Use a real
comment, instead. The interior of #if 0 must consist of complete
tokens; in particular, single-quote characters must balance. Comments
often contain unbalanced single-quote characters (known in English as
apostrophes). These confuse #if 0. They dont confuse /*.

File: cpp.info, Node: Diagnostics, Next: Line Control, Prev: Conditionals, Up: Top
5 Diagnostics
*************
The directive #error causes the preprocessor to report a fatal error.
The tokens forming the rest of the line following #error are used as
the error message.
You would use #error inside of a conditional that detects a
combination of parameters which you know the program does not properly
support. For example, if you know that the program will not run
properly on a VAX, you might write
#ifdef __vax__
#error "Won't work on VAXen. See comments at get_last_object."
#endif
If you have several configuration parameters that must be set up by
the installation in a consistent way, you can use conditionals to detect
an inconsistency and report it with #error. For example,
#if !defined(FOO) && defined(BAR)
#error "BAR requires FOO."
#endif
The directive #warning is like #error, but causes the
preprocessor to issue a warning and continue preprocessing. The tokens
following #warning are used as the warning message.
You might use #warning in obsolete header files, with a message
directing the user to the header file which should be used instead.
Neither #error nor #warning macro-expands its argument. Internal
whitespace sequences are each replaced with a single space. The line
must consist of complete tokens. It is wisest to make the argument of
these directives be a single string constant; this avoids problems with
apostrophes and the like.

File: cpp.info, Node: Line Control, Next: Pragmas, Prev: Diagnostics, Up: Top
6 Line Control
**************
The C preprocessor informs the C compiler of the location in your source
code where each token came from. Presently, this is just the file name
and line number. All the tokens resulting from macro expansion are
reported as having appeared on the line of the source file where the
outermost macro was used. We intend to be more accurate in the future.
If you write a program which generates source code, such as the
bison parser generator, you may want to adjust the preprocessors
notion of the current file name and line number by hand. Parts of the
output from bison are generated from scratch, other parts come from a
standard parser file. The rest are copied verbatim from bisons
input. You would like compiler error messages and symbolic debuggers to
be able to refer to bisons input file.
bison or any such program can arrange this by writing #line
directives into the output file. #line is a directive that specifies
the original line number and source file name for subsequent input in
the current preprocessor input file. #line has three variants:
#line LINENUM
LINENUM is a non-negative decimal integer constant. It specifies
the line number which should be reported for the following line of
input. Subsequent lines are counted from LINENUM.
#line LINENUM FILENAME
LINENUM is the same as for the first form, and has the same effect.
In addition, FILENAME is a string constant. The following line and
all subsequent lines are reported to come from the file it
specifies, until something else happens to change that. FILENAME
is interpreted according to the normal rules for a string constant:
backslash escapes are interpreted. This is different from
#include.
#line ANYTHING ELSE
ANYTHING ELSE is checked for macro calls, which are expanded. The
result should match one of the above two forms.
#line directives alter the results of the __FILE__ and __LINE__
predefined macros from that point on. *Note Standard Predefined
Macros::. They do not have any effect on #includes idea of the
directory containing the current file.

File: cpp.info, Node: Pragmas, Next: Other Directives, Prev: Line Control, Up: Top
7 Pragmas
*********
The #pragma directive is the method specified by the C standard for
providing additional information to the compiler, beyond what is
conveyed in the language itself. The forms of this directive (commonly
known as “pragmas”) specified by C standard are prefixed with STDC. A
C compiler is free to attach any meaning it likes to other pragmas.
Most GNU-defined, supported pragmas have been given a GCC prefix.
C99 introduced the _Pragma operator. This feature addresses a
major problem with #pragma: being a directive, it cannot be produced
as the result of macro expansion. _Pragma is an operator, much like
sizeof or defined, and can be embedded in a macro.
Its syntax is _Pragma (STRING-LITERAL), where STRING-LITERAL can be
either a normal or wide-character string literal. It is destringized,
by replacing all \\ with a single \ and all \" with a ". The
result is then processed as if it had appeared as the right hand side of
a #pragma directive. For example,
_Pragma ("GCC dependency \"parse.y\"")
has the same effect as #pragma GCC dependency "parse.y". The same
effect could be achieved using macros, for example
#define DO_PRAGMA(x) _Pragma (#x)
DO_PRAGMA (GCC dependency "parse.y")
The standard is unclear on where a _Pragma operator can appear.
The preprocessor does not accept it within a preprocessing conditional
directive like #if. To be safe, you are probably best keeping it out
of directives other than #define, and putting it on a line of its own.
This manual documents the pragmas which are meaningful to the
preprocessor itself. Other pragmas are meaningful to the C or C++
compilers. They are documented in the GCC manual.
GCC plugins may provide their own pragmas.
#pragma GCC dependency
#pragma GCC dependency allows you to check the relative dates of
the current file and another file. If the other file is more
recent than the current file, a warning is issued. This is useful
if the current file is derived from the other file, and should be
regenerated. The other file is searched for using the normal
include search path. Optional trailing text can be used to give
more information in the warning message.
#pragma GCC dependency "parse.y"
#pragma GCC dependency "/usr/include/time.h" rerun fixincludes
#pragma GCC poison
Sometimes, there is an identifier that you want to remove
completely from your program, and make sure that it never creeps
back in. To enforce this, you can “poison” the identifier with
this pragma. #pragma GCC poison is followed by a list of
identifiers to poison. If any of those identifiers appears
anywhere in the source after the directive, it is a hard error.
For example,
#pragma GCC poison printf sprintf fprintf
sprintf(some_string, "hello");
will produce an error.
If a poisoned identifier appears as part of the expansion of a
macro which was defined before the identifier was poisoned, it will
_not_ cause an error. This lets you poison an identifier without
worrying about system headers defining macros that use it.
For example,
#define strrchr rindex
#pragma GCC poison rindex
strrchr(some_string, 'h');
will not produce an error.
#pragma GCC system_header
This pragma takes no arguments. It causes the rest of the code in
the current file to be treated as if it came from a system header.
*Note System Headers::.
#pragma GCC warning
#pragma GCC error
#pragma GCC warning "message" causes the preprocessor to issue a
warning diagnostic with the text message. The message contained
in the pragma must be a single string literal. Similarly, #pragma
GCC error "message" issues an error message. Unlike the
#warning and #error directives, these pragmas can be embedded
in preprocessor macros using _Pragma.
#pragma once
If #pragma once is seen when scanning a header file, that file
will never be read again, no matter what. It is a less-portable
alternative to using #ifndef to guard the contents of header
files against multiple inclusions.
#pragma region {tokens}...
#pragma endregion {tokens}...
These pragmas are accepted, but have no effect.

File: cpp.info, Node: Other Directives, Next: Preprocessor Output, Prev: Pragmas, Up: Top
8 Other Directives
******************
The #ident directive takes one argument, a string constant. On some
systems, that string constant is copied into a special segment of the
object file. On other systems, the directive is ignored. The #sccs
directive is a synonym for #ident.
These directives are not part of the C standard, but they are not
official GNU extensions either. What historical information we have
been able to find, suggests they originated with System V.
The “null directive” consists of a # followed by a newline, with
only whitespace (including comments) in between. A null directive is
understood as a preprocessing directive but has no effect on the
preprocessor output. The primary significance of the existence of the
null directive is that an input line consisting of just a # will
produce no output, rather than a line of output containing just a #.
Supposedly some old C programs contain such lines.

File: cpp.info, Node: Preprocessor Output, Next: Traditional Mode, Prev: Other Directives, Up: Top
9 Preprocessor Output
*********************
When the C preprocessor is used with the C, C++, or Objective-C
compilers, it is integrated into the compiler and communicates a stream
of binary tokens directly to the compilers parser. However, it can
also be used in the more conventional standalone mode, where it produces
textual output.
The output from the C preprocessor looks much like the input, except
that all preprocessing directive lines have been replaced with blank
lines and all comments with spaces. Long runs of blank lines are
discarded.
The ISO standard specifies that it is implementation defined whether
a preprocessor preserves whitespace between tokens, or replaces it with
e.g. a single space. In GNU CPP, whitespace between tokens is collapsed
to become a single space, with the exception that the first token on a
non-directive line is preceded with sufficient spaces that it appears in
the same column in the preprocessed output that it appeared in the
original source file. This is so the output is easy to read. CPP does
not insert any whitespace where there was none in the original source,
except where necessary to prevent an accidental token paste.
Source file name and line number information is conveyed by lines of
the form
# LINENUM FILENAME FLAGS
These are called “linemarkers”. They are inserted as needed into the
output (but never within a string or character constant). They mean
that the following line originated in file FILENAME at line LINENUM.
FILENAME will never contain any non-printing characters; they are
replaced with octal escape sequences.
After the file name comes zero or more flags, which are 1, 2,
3, or 4. If there are multiple flags, spaces separate them. Here
is what the flags mean:
1
This indicates the start of a new file.
2
This indicates returning to a file (after having included another
file).
3
This indicates that the following text comes from a system header
file, so certain warnings should be suppressed.
4
This indicates that the following text should be treated as being
wrapped in an implicit extern "C" block.
As an extension, the preprocessor accepts linemarkers in
non-assembler input files. They are treated like the corresponding
#line directive, (*note Line Control::), except that trailing flags
are permitted, and are interpreted with the meanings described above.
If multiple flags are given, they must be in ascending order.
Some directives may be duplicated in the output of the preprocessor.
These are #ident (always), #pragma (only if the preprocessor does
not handle the pragma itself), and #define and #undef (with certain
debugging options). If this happens, the # of the directive will
always be in the first column, and there will be no space between the
# and the directive name. If macro expansion happens to generate
tokens which might be mistaken for a duplicated directive, a space will
be inserted between the # and the directive name.

File: cpp.info, Node: Traditional Mode, Next: Implementation Details, Prev: Preprocessor Output, Up: Top
10 Traditional Mode
*******************
Traditional (pre-standard) C preprocessing is rather different from the
preprocessing specified by the standard. When the preprocessor is
invoked with the -traditional-cpp option, it attempts to emulate a
traditional preprocessor.
This mode is not useful for compiling C code with GCC, but is
intended for use with non-C preprocessing applications. Thus
traditional mode semantics are supported only when invoking the
preprocessor explicitly, and not in the compiler front ends.
The implementation does not correspond precisely to the behavior of
early pre-standard versions of GCC, nor to any true traditional
preprocessor. After all, inconsistencies among traditional
implementations were a major motivation for C standardization. However,
we intend that it should be compatible with true traditional
preprocessors in all ways that actually matter.
* Menu:
* Traditional lexical analysis::
* Traditional macros::
* Traditional miscellany::
* Traditional warnings::

File: cpp.info, Node: Traditional lexical analysis, Next: Traditional macros, Up: Traditional Mode
10.1 Traditional lexical analysis
=================================
The traditional preprocessor does not decompose its input into tokens
the same way a standards-conforming preprocessor does. The input is
simply treated as a stream of text with minimal internal form.
This implementation does not treat trigraphs (*note trigraphs::)
specially since they were an invention of the standards committee. It
handles arbitrarily-positioned escaped newlines properly and splices the
lines as you would expect; many traditional preprocessors did not do
this.
The form of horizontal whitespace in the input file is preserved in
the output. In particular, hard tabs remain hard tabs. This can be
useful if, for example, you are preprocessing a Makefile.
Traditional CPP only recognizes C-style block comments, and treats
the /* sequence as introducing a comment only if it lies outside
quoted text. Quoted text is introduced by the usual single and double
quotes, and also by an initial < in a #include directive.
Traditionally, comments are completely removed and are not replaced
with a space. Since a traditional compiler does its own tokenization of
the output of the preprocessor, this means that comments can effectively
be used as token paste operators. However, comments behave like
separators for text handled by the preprocessor itself, since it doesnt
re-lex its input. For example, in
#if foo/**/bar
foo and bar are distinct identifiers and expanded separately if they
happen to be macros. In other words, this directive is equivalent to
#if foo bar
rather than
#if foobar
Generally speaking, in traditional mode an opening quote need not
have a matching closing quote. In particular, a macro may be defined
with replacement text that contains an unmatched quote. Of course, if
you attempt to compile preprocessed output containing an unmatched quote
you will get a syntax error.
However, all preprocessing directives other than #define require
matching quotes. For example:
#define m This macro's fine and has an unmatched quote
"/* This is not a comment. */
/* This is a comment. The following #include directive
is ill-formed. */
#include <stdio.h
Just as for the ISO preprocessor, what would be a closing quote can
be escaped with a backslash to prevent the quoted text from closing.

File: cpp.info, Node: Traditional macros, Next: Traditional miscellany, Prev: Traditional lexical analysis, Up: Traditional Mode
10.2 Traditional macros
=======================
The major difference between traditional and ISO macros is that the
former expand to text rather than to a token sequence. CPP removes all
leading and trailing horizontal whitespace from a macros replacement
text before storing it, but preserves the form of internal whitespace.
One consequence is that it is legitimate for the replacement text to
contain an unmatched quote (*note Traditional lexical analysis::). An
unclosed string or character constant continues into the text following
the macro call. Similarly, the text at the end of a macros expansion
can run together with the text after the macro invocation to produce a
single token.
Normally comments are removed from the replacement text after the
macro is expanded, but if the -CC option is passed on the command-line
comments are preserved. (In fact, the current implementation removes
comments even before saving the macro replacement text, but it careful
to do it in such a way that the observed effect is identical even in the
function-like macro case.)
The ISO stringizing operator # and token paste operator ## have
no special meaning. As explained later, an effect similar to these
operators can be obtained in a different way. Macro names that are
embedded in quotes, either from the main file or after macro
replacement, do not expand.
CPP replaces an unquoted object-like macro name with its replacement
text, and then rescans it for further macros to replace. Unlike
standard macro expansion, traditional macro expansion has no provision
to prevent recursion. If an object-like macro appears unquoted in its
replacement text, it will be replaced again during the rescan pass, and
so on _ad infinitum_. GCC detects when it is expanding recursive
macros, emits an error message, and continues after the offending macro
invocation.
#define PLUS +
#define INC(x) PLUS+x
INC(foo);
↦ ++foo;
Function-like macros are similar in form but quite different in
behavior to their ISO counterparts. Their arguments are contained
within parentheses, are comma-separated, and can cross physical lines.
Commas within nested parentheses are not treated as argument separators.
Similarly, a quote in an argument cannot be left unclosed; a following
comma or parenthesis that comes before the closing quote is treated like
any other character. There is no facility for handling variadic macros.
This implementation removes all comments from macro arguments, unless
the -C option is given. The form of all other horizontal whitespace
in arguments is preserved, including leading and trailing whitespace.
In particular
f( )
is treated as an invocation of the macro f with a single argument
consisting of a single space. If you want to invoke a function-like
macro that takes no arguments, you must not leave any whitespace between
the parentheses.
If a macro argument crosses a new line, the new line is replaced with
a space when forming the argument. If the previous line contained an
unterminated quote, the following line inherits the quoted state.
Traditional preprocessors replace parameters in the replacement text
with their arguments regardless of whether the parameters are within
quotes or not. This provides a way to stringize arguments. For example
#define str(x) "x"
str(/* A comment */some text )
↦ "some text "
Note that the comment is removed, but that the trailing space is
preserved. Here is an example of using a comment to effect token
pasting.
#define suffix(x) foo_/**/x
suffix(bar)
↦ foo_bar

File: cpp.info, Node: Traditional miscellany, Next: Traditional warnings, Prev: Traditional macros, Up: Traditional Mode
10.3 Traditional miscellany
===========================
Here are some things to be aware of when using the traditional
preprocessor.
• Preprocessing directives are recognized only when their leading #
appears in the first column. There can be no whitespace between
the beginning of the line and the #, but whitespace can follow
the #.
• A true traditional C preprocessor does not recognize #error or
#pragma, and may not recognize #elif. CPP supports all the
directives in traditional mode that it supports in ISO mode,
including extensions, with the exception that the effects of
#pragma GCC poison are undefined.
• __STDC__ is not defined.
• If you use digraphs the behavior is undefined.
• If a line that looks like a directive appears within macro
arguments, the behavior is undefined.

File: cpp.info, Node: Traditional warnings, Prev: Traditional miscellany, Up: Traditional Mode
10.4 Traditional warnings
=========================
You can request warnings about features that did not exist, or worked
differently, in traditional C with the -Wtraditional option. GCC does
not warn about features of ISO C which you must use when you are using a
conforming compiler, such as the # and ## operators.
Presently -Wtraditional warns about:
• Macro parameters that appear within string literals in the macro
body. In traditional C macro replacement takes place within string
literals, but does not in ISO C.
• In traditional C, some preprocessor directives did not exist.
Traditional preprocessors would only consider a line to be a
directive if the # appeared in column 1 on the line. Therefore
-Wtraditional warns about directives that traditional C
understands but would ignore because the # does not appear as the
first character on the line. It also suggests you hide directives
like #pragma not understood by traditional C by indenting them.
Some traditional implementations would not recognize #elif, so it
suggests avoiding it altogether.
• A function-like macro that appears without an argument list. In
some traditional preprocessors this was an error. In ISO C it
merely means that the macro is not expanded.
• The unary plus operator. This did not exist in traditional C.
• The U and LL integer constant suffixes, which were not
available in traditional C. (Traditional C does support the L
suffix for simple long integer constants.) You are not warned
about uses of these suffixes in macros defined in system headers.
For instance, UINT_MAX may well be defined as 4294967295U, but
you will not be warned if you use UINT_MAX.
You can usually avoid the warning, and the related warning about
constants which are so large that they are unsigned, by writing the
integer constant in question in hexadecimal, with no U suffix.
Take care, though, because this gives the wrong result in exotic
cases.

File: cpp.info, Node: Implementation Details, Next: Invocation, Prev: Traditional Mode, Up: Top
11 Implementation Details
*************************
Here we document details of how the preprocessors implementation
affects its user-visible behavior. You should try to avoid undue
reliance on behavior described here, as it is possible that it will
change subtly in future implementations.
Also documented here are obsolete features still supported by CPP.
* Menu:
* Implementation-defined behavior::
* Implementation limits::
* Obsolete Features::

File: cpp.info, Node: Implementation-defined behavior, Next: Implementation limits, Up: Implementation Details
11.1 Implementation-defined behavior
====================================
This is how CPP behaves in all the cases which the C standard describes
as “implementation-defined”. This term means that the implementation is
free to do what it likes, but must document its choice and stick to it.
• The mapping of physical source file multi-byte characters to the
execution character set.
The input character set can be specified using the
-finput-charset option, while the execution character set may be
controlled using the -fexec-charset and -fwide-exec-charset
options.
• Identifier characters.
The C and C++ standards allow identifiers to be composed of _ and
the alphanumeric characters. C++ also allows universal character
names. C99 and later C standards permit both universal character
names and implementation-defined characters. In both C and C++
modes, GCC accepts in identifiers exactly those extended characters
that correspond to universal character names permitted by the
chosen standard.
GCC allows the $ character in identifiers as an extension for
most targets. This is true regardless of the std= switch, since
this extension cannot conflict with standards-conforming programs.
When preprocessing assembler, however, dollars are not identifier
characters by default.
Currently the targets that by default do not permit $ are AVR,
IP2K, MMIX, MIPS Irix 3, ARM aout, and PowerPC targets for the AIX
operating system.
You can override the default with -fdollars-in-identifiers or
-fno-dollars-in-identifiers. *Note fdollars-in-identifiers::.
• Non-empty sequences of whitespace characters.
In textual output, each whitespace sequence is collapsed to a
single space. For aesthetic reasons, the first token on each
non-directive line of output is preceded with sufficient spaces
that it appears in the same column as it did in the original source
file.
• The numeric value of character constants in preprocessor
expressions.
The preprocessor and compiler interpret character constants in the
same way; i.e. escape sequences such as \a are given the values
they would have on the target machine.
The compiler evaluates a multi-character character constant a
character at a time, shifting the previous value left by the number
of bits per target character, and then or-ing in the bit-pattern of
the new character truncated to the width of a target character.
The final bit-pattern is given type int, and is therefore signed,
regardless of whether single characters are signed or not. If
there are more characters in the constant than would fit in the
target int the compiler issues a warning, and the excess leading
characters are ignored.
For example, 'ab' for a target with an 8-bit char would be
interpreted as
(int) ((unsigned char) 'a' * 256 + (unsigned char) 'b'), and
'\234a' as
(int) ((unsigned char) '\234' * 256 + (unsigned char) 'a').
• Source file inclusion.
For a discussion on how the preprocessor locates header files,
*note Include Operation::.
• Interpretation of the filename resulting from a macro-expanded
#include directive.
*Note Computed Includes::.
• Treatment of a #pragma directive that after macro-expansion
results in a standard pragma.
No macro expansion occurs on any #pragma directive line, so the
question does not arise.
Note that GCC does not yet implement any of the standard pragmas.

File: cpp.info, Node: Implementation limits, Next: Obsolete Features, Prev: Implementation-defined behavior, Up: Implementation Details
11.2 Implementation limits
==========================
CPP has a small number of internal limits. This section lists the
limits which the C standard requires to be no lower than some minimum,
and all the others known. It is intended that there should be as few
limits as possible. If you encounter an undocumented or inconvenient
limit, please report that as a bug. *Note Reporting Bugs: (gcc)Bugs.
Where we say something is limited “only by available memory”, that
means that internal data structures impose no intrinsic limit, and space
is allocated with malloc or equivalent. The actual limit will
therefore depend on many things, such as the size of other things
allocated by the compiler at the same time, the amount of memory
consumed by other processes on the same computer, etc.
• Nesting levels of #include files.
We impose an arbitrary limit of 200 levels, to avoid runaway
recursion. The standard requires at least 15 levels.
• Nesting levels of conditional inclusion.
The C standard mandates this be at least 63. CPP is limited only
by available memory.
• Levels of parenthesized expressions within a full expression.
The C standard requires this to be at least 63. In preprocessor
conditional expressions, it is limited only by available memory.
• Significant initial characters in an identifier or macro name.
The preprocessor treats all characters as significant. The C
standard requires only that the first 63 be significant.
• Number of macros simultaneously defined in a single translation
unit.
The standard requires at least 4095 be possible. CPP is limited
only by available memory.
• Number of parameters in a macro definition and arguments in a macro
call.
We allow USHRT_MAX, which is no smaller than 65,535. The minimum
required by the standard is 127.
• Number of characters on a logical source line.
The C standard requires a minimum of 4096 be permitted. CPP places
no limits on this, but you may get incorrect column numbers
reported in diagnostics for lines longer than 65,535 characters.
• Maximum size of a source file.
The standard does not specify any lower limit on the maximum size
of a source file. GNU cpp maps files into memory, so it is limited
by the available address space. This is generally at least two
gigabytes. Depending on the operating system, the size of physical
memory may or may not be a limitation.

File: cpp.info, Node: Obsolete Features, Prev: Implementation limits, Up: Implementation Details
11.3 Obsolete Features
======================
CPP has some features which are present mainly for compatibility with
older programs. We discourage their use in new code. In some cases, we
plan to remove the feature in a future version of GCC.
11.3.1 Assertions
-----------------
“Assertions” are a deprecated alternative to macros in writing
conditionals to test what sort of computer or system the compiled
program will run on. Assertions are usually predefined, but you can
define them with preprocessing directives or command-line options.
Assertions were intended to provide a more systematic way to describe
the compilers target system and we added them for compatibility with
existing compilers. In practice they are just as unpredictable as the
system-specific predefined macros. In addition, they are not part of
any standard, and only a few compilers support them. Therefore, the use
of assertions is *less* portable than the use of system-specific
predefined macros. We recommend you do not use them at all.
An assertion looks like this:
#PREDICATE (ANSWER)
PREDICATE must be a single identifier. ANSWER can be any sequence of
tokens; all characters are significant except for leading and trailing
whitespace, and differences in internal whitespace sequences are
ignored. (This is similar to the rules governing macro redefinition.)
Thus, (x + y) is different from (x+y) but equivalent to ( x + y ).
Parentheses do not nest inside an answer.
To test an assertion, you write it in an #if. For example, this
conditional succeeds if either vax or ns16000 has been asserted as
an answer for machine.
#if #machine (vax) || #machine (ns16000)
You can test whether _any_ answer is asserted for a predicate by
omitting the answer in the conditional:
#if #machine
Assertions are made with the #assert directive. Its sole argument
is the assertion to make, without the leading # that identifies
assertions in conditionals.
#assert PREDICATE (ANSWER)
You may make several assertions with the same predicate and different
answers. Subsequent assertions do not override previous ones for the
same predicate. All the answers for any given predicate are
simultaneously true.
Assertions can be canceled with the #unassert directive. It has
the same syntax as #assert. In that form it cancels only the answer
which was specified on the #unassert line; other answers for that
predicate remain true. You can cancel an entire predicate by leaving
out the answer:
#unassert PREDICATE
In either form, if no such assertion has been made, #unassert has no
effect.
You can also make or cancel assertions using command-line options.
*Note Invocation::.

File: cpp.info, Node: Invocation, Next: Environment Variables, Prev: Implementation Details, Up: Top
12 Invocation
*************
Most often when you use the C preprocessor you do not have to invoke it
explicitly: the C compiler does so automatically. However, the
preprocessor is sometimes useful on its own. You can invoke the
preprocessor either with the cpp command, or via gcc -E. In GCC,
the preprocessor is actually integrated with the compiler rather than a
separate program, and both of these commands invoke GCC and tell it to
stop after the preprocessing phase.
The cpp options listed here are also accepted by gcc and have the
same meaning. Likewise the cpp command accepts all the usual gcc
driver options, although those pertaining to compilation phases after
preprocessing are ignored.
Only options specific to preprocessing behavior are documented here.
Refer to the GCC manual for full documentation of other driver options.
The cpp command expects two file names as arguments, INFILE and
OUTFILE. The preprocessor reads INFILE together with any other files it
specifies with #include. All the output generated by the combined
input files is written in OUTFILE.
Either INFILE or OUTFILE may be -, which as INFILE means to read
from standard input and as OUTFILE means to write to standard output.
If either file is omitted, it means the same as if - had been
specified for that file. You can also use the -o OUTFILE option to
specify the output file.
Unless otherwise noted, or the option ends in =, all options which
take an argument may have that argument appear either immediately after
the option, or with a space between option and argument: -Ifoo and -I
foo have the same effect.
Many options have multi-letter names; therefore multiple
single-letter options may _not_ be grouped: -dM is very different from
-d -M.
-D NAME
Predefine NAME as a macro, with definition 1.
-D NAME=DEFINITION
The contents of DEFINITION are tokenized and processed as if they
appeared during translation phase three in a #define directive.
In particular, the definition is truncated by embedded newline
characters.
If you are invoking the preprocessor from a shell or shell-like
program you may need to use the shells quoting syntax to protect
characters such as spaces that have a meaning in the shell syntax.
If you wish to define a function-like macro on the command line,
write its argument list with surrounding parentheses before the
equals sign (if any). Parentheses are meaningful to most shells,
so you should quote the option. With sh and csh,
-D'NAME(ARGS...)=DEFINITION' works.
-D and -U options are processed in the order they are given on
the command line. All -imacros FILE and -include FILE options
are processed after all -D and -U options.
-U NAME
Cancel any previous definition of NAME, either built in or provided
with a -D option.
-include FILE
Process FILE as if #include "file" appeared as the first line of
the primary source file. However, the first directory searched for
FILE is the preprocessors working directory _instead of_ the
directory containing the main source file. If not found there, it
is searched for in the remainder of the #include "..." search
chain as normal.
If multiple -include options are given, the files are included in
the order they appear on the command line.
-imacros FILE
Exactly like -include, except that any output produced by
scanning FILE is thrown away. Macros it defines remain defined.
This allows you to acquire all the macros from a header without
also processing its declarations.
All files specified by -imacros are processed before all files
specified by -include.
-undef
Do not predefine any system-specific or GCC-specific macros. The
standard predefined macros remain defined. *Note Standard
Predefined Macros::.
-pthread
Define additional macros required for using the POSIX threads
library. You should use this option consistently for both
compilation and linking. This option is supported on GNU/Linux
targets, most other Unix derivatives, and also on x86 Cygwin and
MinGW targets.
-M
Instead of outputting the result of preprocessing, output a rule
suitable for make describing the dependencies of the main source
file. The preprocessor outputs one make rule containing the
object file name for that source file, a colon, and the names of
all the included files, including those coming from -include or
-imacros command-line options.
Unless specified explicitly (with -MT or -MQ), the object file
name consists of the name of the source file with any suffix
replaced with object file suffix and with any leading directory
parts removed. If there are many included files then the rule is
split into several lines using \-newline. The rule has no
commands.
This option does not suppress the preprocessors debug output, such
as -dM. To avoid mixing such debug output with the dependency
rules you should explicitly specify the dependency output file with
-MF, or use an environment variable like DEPENDENCIES_OUTPUT
(*note Environment Variables::). Debug output is still sent to the
regular output stream as normal.
Passing -M to the driver implies -E, and suppresses warnings
with an implicit -w.
-MM
Like -M but do not mention header files that are found in system
header directories, nor header files that are included, directly or
indirectly, from such a header.
This implies that the choice of angle brackets or double quotes in
an #include directive does not in itself determine whether that
header appears in -MM dependency output.
-MF FILE
When used with -M or -MM, specifies a file to write the
dependencies to. If no -MF switch is given the preprocessor
sends the rules to the same place it would send preprocessed
output.
When used with the driver options -MD or -MMD, -MF overrides
the default dependency output file.
If FILE is -, then the dependencies are written to stdout.
-MG
In conjunction with an option such as -M requesting dependency
generation, -MG assumes missing header files are generated files
and adds them to the dependency list without raising an error. The
dependency filename is taken directly from the #include directive
without prepending any path. -MG also suppresses preprocessed
output, as a missing header file renders this useless.
This feature is used in automatic updating of makefiles.
-Mno-modules
Disable dependency generation for compiled module interfaces.
-MP
This option instructs CPP to add a phony target for each dependency
other than the main file, causing each to depend on nothing. These
dummy rules work around errors make gives if you remove header
files without updating the Makefile to match.
This is typical output:
test.o: test.c test.h
test.h:
-MT TARGET
Change the target of the rule emitted by dependency generation. By
default CPP takes the name of the main input file, deletes any
directory components and any file suffix such as .c, and appends
the platforms usual object suffix. The result is the target.
An -MT option sets the target to be exactly the string you
specify. If you want multiple targets, you can specify them as a
single argument to -MT, or use multiple -MT options.
For example, -MT '$(objpfx)foo.o' might give
$(objpfx)foo.o: foo.c
-MQ TARGET
Same as -MT, but it quotes any characters which are special to
Make. -MQ '$(objpfx)foo.o' gives
$$(objpfx)foo.o: foo.c
The default target is automatically quoted, as if it were given
with -MQ.
-MD
-MD is equivalent to -M -MF FILE, except that -E is not
implied. The driver determines FILE based on whether an -o
option is given. If it is, the driver uses its argument but with a
suffix of .d, otherwise it takes the name of the input file,
removes any directory components and suffix, and applies a .d
suffix.
If -MD is used in conjunction with -E, any -o switch is
understood to specify the dependency output file (*note -MF:
dashMF.), but if used without -E, each -o is understood to
specify a target object file.
Since -E is not implied, -MD can be used to generate a
dependency output file as a side effect of the compilation process.
-MMD
Like -MD except mention only user header files, not system header
files.
-fpreprocessed
Indicate to the preprocessor that the input file has already been
preprocessed. This suppresses things like macro expansion,
trigraph conversion, escaped newline splicing, and processing of
most directives. The preprocessor still recognizes and removes
comments, so that you can pass a file preprocessed with -C to the
compiler without problems. In this mode the integrated
preprocessor is little more than a tokenizer for the front ends.
-fpreprocessed is implicit if the input file has one of the
extensions .i, .ii or .mi. These are the extensions that GCC
uses for preprocessed files created by -save-temps.
-fdirectives-only
When preprocessing, handle directives, but do not expand macros.
The options behavior depends on the -E and -fpreprocessed
options.
With -E, preprocessing is limited to the handling of directives
such as #define, #ifdef, and #error. Other preprocessor
operations, such as macro expansion and trigraph conversion are not
performed. In addition, the -dD option is implicitly enabled.
With -fpreprocessed, predefinition of command line and most
builtin macros is disabled. Macros such as __LINE__, which are
contextually dependent, are handled normally. This enables
compilation of files previously preprocessed with -E
-fdirectives-only.
With both -E and -fpreprocessed, the rules for -fpreprocessed
take precedence. This enables full preprocessing of files
previously preprocessed with -E -fdirectives-only.
-fdollars-in-identifiers
Accept $ in identifiers. *Note Identifier characters::.
-fextended-identifiers
Accept universal character names and extended characters in
identifiers. This option is enabled by default for C99 (and later
C standard versions) and C++.
-fno-canonical-system-headers
When preprocessing, do not shorten system header paths with
canonicalization.
-fmax-include-depth=DEPTH
Set the maximum depth of the nested #include. The default is 200.
-ftabstop=WIDTH
Set the distance between tab stops. This helps the preprocessor
report correct column numbers in warnings or errors, even if tabs
appear on the line. If the value is less than 1 or greater than
100, the option is ignored. The default is 8.
-ftrack-macro-expansion[=LEVEL]
Track locations of tokens across macro expansions. This allows the
compiler to emit diagnostic about the current macro expansion stack
when a compilation error occurs in a macro expansion. Using this
option makes the preprocessor and the compiler consume more memory.
The LEVEL parameter can be used to choose the level of precision of
token location tracking thus decreasing the memory consumption if
necessary. Value 0 of LEVEL de-activates this option. Value 1
tracks tokens locations in a degraded mode for the sake of minimal
memory overhead. In this mode all tokens resulting from the
expansion of an argument of a function-like macro have the same
location. Value 2 tracks tokens locations completely. This
value is the most memory hungry. When this option is given no
argument, the default parameter value is 2.
Note that -ftrack-macro-expansion=2 is activated by default.
-fmacro-prefix-map=OLD=NEW
When preprocessing files residing in directory OLD, expand the
__FILE__ and __BASE_FILE__ macros as if the files resided in
directory NEW instead. This can be used to change an absolute
path to a relative path by using . for NEW which can result in
more reproducible builds that are location independent. This
option also affects __builtin_FILE() during compilation. See
also -ffile-prefix-map and -fcanon-prefix-map.
-fexec-charset=CHARSET
Set the execution character set, used for string and character
constants. The default is UTF-8. CHARSET can be any encoding
supported by the systems iconv library routine.
-fwide-exec-charset=CHARSET
Set the wide execution character set, used for wide string and
character constants. The default is one of UTF-32BE, UTF-32LE,
UTF-16BE, or UTF-16LE, whichever corresponds to the width of
wchar_t and the big-endian or little-endian byte order being used
for code generation. As with -fexec-charset, CHARSET can be any
encoding supported by the systems iconv library routine;
however, you will have problems with encodings that do not fit
exactly in wchar_t.
-finput-charset=CHARSET
Set the input character set, used for translation from the
character set of the input file to the source character set used by
GCC. If the locale does not specify, or GCC cannot get this
information from the locale, the default is UTF-8. This can be
overridden by either the locale or this command-line option.
Currently the command-line option takes precedence if theres a
conflict. CHARSET can be any encoding supported by the systems
iconv library routine.
-fworking-directory
Enable generation of linemarkers in the preprocessor output that
let the compiler know the current working directory at the time of
preprocessing. When this option is enabled, the preprocessor
emits, after the initial linemarker, a second linemarker with the
current working directory followed by two slashes. GCC uses this
directory, when its present in the preprocessed input, as the
directory emitted as the current working directory in some
debugging information formats. This option is implicitly enabled
if debugging information is enabled, but this can be inhibited with
the negated form -fno-working-directory. If the -P flag is
present in the command line, this option has no effect, since no
#line directives are emitted whatsoever.
-A PREDICATE=ANSWER
Make an assertion with the predicate PREDICATE and answer ANSWER.
This form is preferred to the older form -A PREDICATE(ANSWER),
which is still supported, because it does not use shell special
characters. *Note Obsolete Features::.
-A -PREDICATE=ANSWER
Cancel an assertion with the predicate PREDICATE and answer ANSWER.
-C
Do not discard comments. All comments are passed through to the
output file, except for comments in processed directives, which are
deleted along with the directive.
You should be prepared for side effects when using -C; it causes
the preprocessor to treat comments as tokens in their own right.
For example, comments appearing at the start of what would be a
directive line have the effect of turning that line into an
ordinary source line, since the first token on the line is no
longer a #.
-CC
Do not discard comments, including during macro expansion. This is
like -C, except that comments contained within macros are also
passed through to the output file where the macro is expanded.
In addition to the side effects of the -C option, the -CC
option causes all C++-style comments inside a macro to be converted
to C-style comments. This is to prevent later use of that macro
from inadvertently commenting out the remainder of the source line.
The -CC option is generally used to support lint comments.
-P
Inhibit generation of linemarkers in the output from the
preprocessor. This might be useful when running the preprocessor
on something that is not C code, and will be sent to a program
which might be confused by the linemarkers. *Note Preprocessor
Output::.
-traditional
-traditional-cpp
Try to imitate the behavior of pre-standard C preprocessors, as
opposed to ISO C preprocessors. *Note Traditional Mode::.
Note that GCC does not otherwise attempt to emulate a pre-standard
C compiler, and these options are only supported with the -E
switch, or when invoking CPP explicitly.
-trigraphs
Support ISO C trigraphs. These are three-character sequences, all
starting with ??, that are defined by ISO C to stand for single
characters. For example, ??/ stands for \, so '??/n' is a
character constant for a newline. *Note Initial processing::.
By default, GCC ignores trigraphs, but in standard-conforming modes
it converts them. See the -std and -ansi options.
-remap
Enable special code to work around file systems which only permit
very short file names, such as MS-DOS.
-H
Print the name of each header file used, in addition to other
normal activities. Each name is indented to show how deep in the
#include stack it is. Precompiled header files are also printed,
even if they are found to be invalid; an invalid precompiled header
file is printed with ...x and a valid one with ...! .
-dLETTERS
Says to make debugging dumps during compilation as specified by
LETTERS. The flags documented here are those relevant to the
preprocessor. Other LETTERS are interpreted by the compiler
proper, or reserved for future versions of GCC, and so are silently
ignored. If you specify LETTERS whose behavior conflicts, the
result is undefined.
-dM
Instead of the normal output, generate a list of #define
directives for all the macros defined during the execution of
the preprocessor, including predefined macros. This gives you
a way of finding out what is predefined in your version of the
preprocessor. Assuming you have no file foo.h, the command
touch foo.h; cpp -dM foo.h
shows all the predefined macros.
-dD
Like -dM except in two respects: it does _not_ include the
predefined macros, and it outputs _both_ the #define
directives and the result of preprocessing. Both kinds of
output go to the standard output file.
-dN
Like -dD, but emit only the macro names, not their
expansions.
-dI
Output #include directives in addition to the result of
preprocessing.
-dU
Like -dD except that only macros that are expanded, or whose
definedness is tested in preprocessor directives, are output;
the output is delayed until the use or test of the macro; and
#undef directives are also output for macros tested but
undefined at the time.
-fdebug-cpp
This option is only useful for debugging GCC. When used from CPP or
with -E, it dumps debugging information about location maps.
Every token in the output is preceded by the dump of the map its
location belongs to.
When used from GCC without -E, this option has no effect.
-I DIR
-iquote DIR
-isystem DIR
-idirafter DIR
Add the directory DIR to the list of directories to be searched for
header files during preprocessing. *Note Search Path::. If DIR
begins with = or $SYSROOT, then the = or $SYSROOT is
replaced by the sysroot prefix; see --sysroot and -isysroot.
Directories specified with -iquote apply only to the quote form
of the directive, #include "FILE". Directories specified with
-I, -isystem, or -idirafter apply to lookup for both the
#include "FILE" and #include <FILE> directives.
You can specify any number or combination of these options on the
command line to search for header files in several directories.
The lookup order is as follows:
1. For the quote form of the include directive, the directory of
the current file is searched first.
2. For the quote form of the include directive, the directories
specified by -iquote options are searched in left-to-right
order, as they appear on the command line.
3. Directories specified with -I options are scanned in
left-to-right order.
4. Directories specified with -isystem options are scanned in
left-to-right order.
5. Standard system directories are scanned.
6. Directories specified with -idirafter options are scanned in
left-to-right order.
You can use -I to override a system header file, substituting
your own version, since these directories are searched before the
standard system header file directories. However, you should not
use this option to add directories that contain vendor-supplied
system header files; use -isystem for that.
The -isystem and -idirafter options also mark the directory as
a system directory, so that it gets the same special treatment that
is applied to the standard system directories. *Note System
Headers::.
If a standard system include directory, or a directory specified
with -isystem, is also specified with -I, the -I option is
ignored. The directory is still searched but as a system directory
at its normal position in the system include chain. This is to
ensure that GCCs procedure to fix buggy system headers and the
ordering for the #include_next directive are not inadvertently
changed. If you really need to change the search order for system
directories, use the -nostdinc and/or -isystem options. *Note
System Headers::.
-I-
Split the include path. This option has been deprecated. Please
use -iquote instead for -I directories before the -I- and
remove the -I- option.
Any directories specified with -I options before -I- are
searched only for headers requested with #include "FILE"; they
are not searched for #include <FILE>. If additional directories
are specified with -I options after the -I-, those directories
are searched for all #include directives.
In addition, -I- inhibits the use of the directory of the current
file directory as the first search directory for #include "FILE".
There is no way to override this effect of -I-. *Note Search
Path::.
-iprefix PREFIX
Specify PREFIX as the prefix for subsequent -iwithprefix options.
If the prefix represents a directory, you should include the final
/.
-iwithprefix DIR
-iwithprefixbefore DIR
Append DIR to the prefix specified previously with -iprefix, and
add the resulting directory to the include search path.
-iwithprefixbefore puts it in the same place -I would;
-iwithprefix puts it where -idirafter would.
-isysroot DIR
This option is like the --sysroot option, but applies only to
header files (except for Darwin targets, where it applies to both
header files and libraries). See the --sysroot option for more
information.
-imultilib DIR
Use DIR as a subdirectory of the directory containing
target-specific C++ headers.
-nostdinc
Do not search the standard system directories for header files.
Only the directories explicitly specified with -I, -iquote,
-isystem, and/or -idirafter options (and the directory of the
current file, if appropriate) are searched.
-nostdinc++
Do not search for header files in the C++-specific standard
directories, but do still search the other standard directories.
(This option is used when building the C++ library.)
-Wcomment
-Wcomments
Warn whenever a comment-start sequence /* appears in a /*
comment, or whenever a backslash-newline appears in a // comment.
This warning is enabled by -Wall.
-Wtrigraphs
Warn if any trigraphs are encountered that might change the meaning
of the program. Trigraphs within comments are not warned about,
except those that would form escaped newlines.
This option is implied by -Wall. If -Wall is not given, this
option is still enabled unless trigraphs are enabled. To get
trigraph conversion without warnings, but get the other -Wall
warnings, use -trigraphs -Wall -Wno-trigraphs.
-Wundef
Warn if an undefined identifier is evaluated in an #if directive.
Such identifiers are replaced with zero.
-Wexpansion-to-defined
Warn whenever defined is encountered in the expansion of a macro
(including the case where the macro is expanded by an #if
directive). Such usage is not portable. This warning is also
enabled by -Wpedantic and -Wextra.
-Wunused-macros
Warn about macros defined in the main file that are unused. A
macro is “used” if it is expanded or tested for existence at least
once. The preprocessor also warns if the macro has not been used
at the time it is redefined or undefined.
Built-in macros, macros defined on the command line, and macros
defined in include files are not warned about.
_Note:_ If a macro is actually used, but only used in skipped
conditional blocks, then the preprocessor reports it as unused. To
avoid the warning in such a case, you might improve the scope of
the macros definition by, for example, moving it into the first
skipped block. Alternatively, you could provide a dummy use with
something like:
#if defined the_macro_causing_the_warning
#endif
-Wno-endif-labels
Do not warn whenever an #else or an #endif are followed by
text. This sometimes happens in older programs with code of the
form
#if FOO
...
#else FOO
...
#endif FOO
The second and third FOO should be in comments. This warning is
on by default.

File: cpp.info, Node: Environment Variables, Next: GNU Free Documentation License, Prev: Invocation, Up: Top
13 Environment Variables
************************
This section describes the environment variables that affect how CPP
operates. You can use them to specify directories or prefixes to use
when searching for include files, or to control dependency output.
Note that you can also specify places to search using options such as
-I, and control dependency output with options like -M (*note
Invocation::). These take precedence over environment variables, which
in turn take precedence over the configuration of GCC.
CPATH
C_INCLUDE_PATH
CPLUS_INCLUDE_PATH
OBJC_INCLUDE_PATH
Each variables value is a list of directories separated by a
special character, much like PATH, in which to look for header
files. The special character, PATH_SEPARATOR, is
target-dependent and determined at GCC build time. For Microsoft
Windows-based targets it is a semicolon, and for almost all other
targets it is a colon.
CPATH specifies a list of directories to be searched as if
specified with -I, but after any paths given with -I options on
the command line. This environment variable is used regardless of
which language is being preprocessed.
The remaining environment variables apply only when preprocessing
the particular language indicated. Each specifies a list of
directories to be searched as if specified with -isystem, but
after any paths given with -isystem options on the command line.
In all these variables, an empty element instructs the compiler to
search its current working directory. Empty elements can appear at
the beginning or end of a path. For instance, if the value of
CPATH is :/special/include, that has the same effect as
-I. -I/special/include.
See also *note Search Path::.
DEPENDENCIES_OUTPUT
If this variable is set, its value specifies how to output
dependencies for Make based on the non-system header files
processed by the compiler. System header files are ignored in the
dependency output.
The value of DEPENDENCIES_OUTPUT can be just a file name, in
which case the Make rules are written to that file, guessing the
target name from the source file name. Or the value can have the
form FILE TARGET, in which case the rules are written to file
FILE using TARGET as the target name.
In other words, this environment variable is equivalent to
combining the options -MM and -MF (*note Invocation::), with an
optional -MT switch too.
SUNPRO_DEPENDENCIES
This variable is the same as DEPENDENCIES_OUTPUT (see above),
except that system header files are not ignored, so it implies -M
rather than -MM. However, the dependence on the main input file
is omitted. *Note Invocation::.
SOURCE_DATE_EPOCH
If this variable is set, its value specifies a UNIX timestamp to be
used in replacement of the current date and time in the __DATE__
and __TIME__ macros, so that the embedded timestamps become
reproducible.
The value of SOURCE_DATE_EPOCH must be a UNIX timestamp, defined
as the number of seconds (excluding leap seconds) since 01 Jan 1970
00:00:00 represented in ASCII; identical to the output of date
+%s on GNU/Linux and other systems that support the %s extension
in the date command.
The value should be a known timestamp such as the last modification
time of the source or package and it should be set by the build
process.

File: cpp.info, Node: GNU Free Documentation License, Next: Index of Directives, Prev: Environment Variables, Up: Top
GNU Free Documentation License
******************************
Version 1.3, 3 November 2008
Copyright © 2000, 2001, 2002, 2007, 2008 Free Software Foundation, Inc.
<https://www.fsf.org>
Everyone is permitted to copy and distribute verbatim copies
of this license document, but changing it is not allowed.
0. PREAMBLE
The purpose of this License is to make a manual, textbook, or other
functional and useful document “free” in the sense of freedom: to
assure everyone the effective freedom to copy and redistribute it,
with or without modifying it, either commercially or
noncommercially. Secondarily, this License preserves for the
author and publisher a way to get credit for their work, while not
being considered responsible for modifications made by others.
This License is a kind of “copyleft”, which means that derivative
works of the document must themselves be free in the same sense.
It complements the GNU General Public License, which is a copyleft
license designed for free software.
We have designed this License in order to use it for manuals for
free software, because free software needs free documentation: a
free program should come with manuals providing the same freedoms
that the software does. But this License is not limited to
software manuals; it can be used for any textual work, regardless
of subject matter or whether it is published as a printed book. We
recommend this License principally for works whose purpose is
instruction or reference.
1. APPLICABILITY AND DEFINITIONS
This License applies to any manual or other work, in any medium,
that contains a notice placed by the copyright holder saying it can
be distributed under the terms of this License. Such a notice
grants a world-wide, royalty-free license, unlimited in duration,
to use that work under the conditions stated herein. The
“Document”, below, refers to any such manual or work. Any member
of the public is a licensee, and is addressed as “you”. You accept
the license if you copy, modify or distribute the work in a way
requiring permission under copyright law.
A “Modified Version” of the Document means any work containing the
Document or a portion of it, either copied verbatim, or with
modifications and/or translated into another language.
A “Secondary Section” is a named appendix or a front-matter section
of the Document that deals exclusively with the relationship of the
publishers or authors of the Document to the Documents overall
subject (or to related matters) and contains nothing that could
fall directly within that overall subject. (Thus, if the Document
is in part a textbook of mathematics, a Secondary Section may not
explain any mathematics.) The relationship could be a matter of
historical connection with the subject or with related matters, or
of legal, commercial, philosophical, ethical or political position
regarding them.
The “Invariant Sections” are certain Secondary Sections whose
titles are designated, as being those of Invariant Sections, in the
notice that says that the Document is released under this License.
If a section does not fit the above definition of Secondary then it
is not allowed to be designated as Invariant. The Document may
contain zero Invariant Sections. If the Document does not identify
any Invariant Sections then there are none.
The “Cover Texts” are certain short passages of text that are
listed, as Front-Cover Texts or Back-Cover Texts, in the notice
that says that the Document is released under this License. A
Front-Cover Text may be at most 5 words, and a Back-Cover Text may
be at most 25 words.
A “Transparent” copy of the Document means a machine-readable copy,
represented in a format whose specification is available to the
general public, that is suitable for revising the document
straightforwardly with generic text editors or (for images composed
of pixels) generic paint programs or (for drawings) some widely
available drawing editor, and that is suitable for input to text
formatters or for automatic translation to a variety of formats
suitable for input to text formatters. A copy made in an otherwise
Transparent file format whose markup, or absence of markup, has
been arranged to thwart or discourage subsequent modification by
readers is not Transparent. An image format is not Transparent if
used for any substantial amount of text. A copy that is not
“Transparent” is called “Opaque”.
Examples of suitable formats for Transparent copies include plain
ASCII without markup, Texinfo input format, LaTeX input format,
SGML or XML using a publicly available DTD, and standard-conforming
simple HTML, PostScript or PDF designed for human modification.
Examples of transparent image formats include PNG, XCF and JPG.
Opaque formats include proprietary formats that can be read and
edited only by proprietary word processors, SGML or XML for which
the DTD and/or processing tools are not generally available, and
the machine-generated HTML, PostScript or PDF produced by some word
processors for output purposes only.
The “Title Page” means, for a printed book, the title page itself,
plus such following pages as are needed to hold, legibly, the
material this License requires to appear in the title page. For
works in formats which do not have any title page as such, “Title
Page” means the text near the most prominent appearance of the
works title, preceding the beginning of the body of the text.
The “publisher” means any person or entity that distributes copies
of the Document to the public.
A section “Entitled XYZ” means a named subunit of the Document
whose title either is precisely XYZ or contains XYZ in parentheses
following text that translates XYZ in another language. (Here XYZ
stands for a specific section name mentioned below, such as
“Acknowledgements”, “Dedications”, “Endorsements”, or “History”.)
To “Preserve the Title” of such a section when you modify the
Document means that it remains a section “Entitled XYZ” according
to this definition.
The Document may include Warranty Disclaimers next to the notice
which states that this License applies to the Document. These
Warranty Disclaimers are considered to be included by reference in
this License, but only as regards disclaiming warranties: any other
implication that these Warranty Disclaimers may have is void and
has no effect on the meaning of this License.
2. VERBATIM COPYING
You may copy and distribute the Document in any medium, either
commercially or noncommercially, provided that this License, the
copyright notices, and the license notice saying this License
applies to the Document are reproduced in all copies, and that you
add no other conditions whatsoever to those of this License. You
may not use technical measures to obstruct or control the reading
or further copying of the copies you make or distribute. However,
you may accept compensation in exchange for copies. If you
distribute a large enough number of copies you must also follow the
conditions in section 3.
You may also lend copies, under the same conditions stated above,
and you may publicly display copies.
3. COPYING IN QUANTITY
If you publish printed copies (or copies in media that commonly
have printed covers) of the Document, numbering more than 100, and
the Documents license notice requires Cover Texts, you must
enclose the copies in covers that carry, clearly and legibly, all
these Cover Texts: Front-Cover Texts on the front cover, and
Back-Cover Texts on the back cover. Both covers must also clearly
and legibly identify you as the publisher of these copies. The
front cover must present the full title with all words of the title
equally prominent and visible. You may add other material on the
covers in addition. Copying with changes limited to the covers, as
long as they preserve the title of the Document and satisfy these
conditions, can be treated as verbatim copying in other respects.
If the required texts for either cover are too voluminous to fit
legibly, you should put the first ones listed (as many as fit
reasonably) on the actual cover, and continue the rest onto
adjacent pages.
If you publish or distribute Opaque copies of the Document
numbering more than 100, you must either include a machine-readable
Transparent copy along with each Opaque copy, or state in or with
each Opaque copy a computer-network location from which the general
network-using public has access to download using public-standard
network protocols a complete Transparent copy of the Document, free
of added material. If you use the latter option, you must take
reasonably prudent steps, when you begin distribution of Opaque
copies in quantity, to ensure that this Transparent copy will
remain thus accessible at the stated location until at least one
year after the last time you distribute an Opaque copy (directly or
through your agents or retailers) of that edition to the public.
It is requested, but not required, that you contact the authors of
the Document well before redistributing any large number of copies,
to give them a chance to provide you with an updated version of the
Document.
4. MODIFICATIONS
You may copy and distribute a Modified Version of the Document
under the conditions of sections 2 and 3 above, provided that you
release the Modified Version under precisely this License, with the
Modified Version filling the role of the Document, thus licensing
distribution and modification of the Modified Version to whoever
possesses a copy of it. In addition, you must do these things in
the Modified Version:
A. Use in the Title Page (and on the covers, if any) a title
distinct from that of the Document, and from those of previous
versions (which should, if there were any, be listed in the
History section of the Document). You may use the same title
as a previous version if the original publisher of that
version gives permission.
B. List on the Title Page, as authors, one or more persons or
entities responsible for authorship of the modifications in
the Modified Version, together with at least five of the
principal authors of the Document (all of its principal
authors, if it has fewer than five), unless they release you
from this requirement.
C. State on the Title page the name of the publisher of the
Modified Version, as the publisher.
D. Preserve all the copyright notices of the Document.
E. Add an appropriate copyright notice for your modifications
adjacent to the other copyright notices.
F. Include, immediately after the copyright notices, a license
notice giving the public permission to use the Modified
Version under the terms of this License, in the form shown in
the Addendum below.
G. Preserve in that license notice the full lists of Invariant
Sections and required Cover Texts given in the Documents
license notice.
H. Include an unaltered copy of this License.
I. Preserve the section Entitled “History”, Preserve its Title,
and add to it an item stating at least the title, year, new
authors, and publisher of the Modified Version as given on the
Title Page. If there is no section Entitled “History” in the
Document, create one stating the title, year, authors, and
publisher of the Document as given on its Title Page, then add
an item describing the Modified Version as stated in the
previous sentence.
J. Preserve the network location, if any, given in the Document
for public access to a Transparent copy of the Document, and
likewise the network locations given in the Document for
previous versions it was based on. These may be placed in the
“History” section. You may omit a network location for a work
that was published at least four years before the Document
itself, or if the original publisher of the version it refers
to gives permission.
K. For any section Entitled “Acknowledgements” or “Dedications”,
Preserve the Title of the section, and preserve in the section
all the substance and tone of each of the contributor
acknowledgements and/or dedications given therein.
L. Preserve all the Invariant Sections of the Document, unaltered
in their text and in their titles. Section numbers or the
equivalent are not considered part of the section titles.
M. Delete any section Entitled “Endorsements”. Such a section
may not be included in the Modified Version.
N. Do not retitle any existing section to be Entitled
“Endorsements” or to conflict in title with any Invariant
Section.
O. Preserve any Warranty Disclaimers.
If the Modified Version includes new front-matter sections or
appendices that qualify as Secondary Sections and contain no
material copied from the Document, you may at your option designate
some or all of these sections as invariant. To do this, add their
titles to the list of Invariant Sections in the Modified Versions
license notice. These titles must be distinct from any other
section titles.
You may add a section Entitled “Endorsements”, provided it contains
nothing but endorsements of your Modified Version by various
parties—for example, statements of peer review or that the text has
been approved by an organization as the authoritative definition of
a standard.
You may add a passage of up to five words as a Front-Cover Text,
and a passage of up to 25 words as a Back-Cover Text, to the end of
the list of Cover Texts in the Modified Version. Only one passage
of Front-Cover Text and one of Back-Cover Text may be added by (or
through arrangements made by) any one entity. If the Document
already includes a cover text for the same cover, previously added
by you or by arrangement made by the same entity you are acting on
behalf of, you may not add another; but you may replace the old
one, on explicit permission from the previous publisher that added
the old one.
The author(s) and publisher(s) of the Document do not by this
License give permission to use their names for publicity for or to
assert or imply endorsement of any Modified Version.
5. COMBINING DOCUMENTS
You may combine the Document with other documents released under
this License, under the terms defined in section 4 above for
modified versions, provided that you include in the combination all
of the Invariant Sections of all of the original documents,
unmodified, and list them all as Invariant Sections of your
combined work in its license notice, and that you preserve all
their Warranty Disclaimers.
The combined work need only contain one copy of this License, and
multiple identical Invariant Sections may be replaced with a single
copy. If there are multiple Invariant Sections with the same name
but different contents, make the title of each such section unique
by adding at the end of it, in parentheses, the name of the
original author or publisher of that section if known, or else a
unique number. Make the same adjustment to the section titles in
the list of Invariant Sections in the license notice of the
combined work.
In the combination, you must combine any sections Entitled
“History” in the various original documents, forming one section
Entitled “History”; likewise combine any sections Entitled
“Acknowledgements”, and any sections Entitled “Dedications”. You
must delete all sections Entitled “Endorsements.”
6. COLLECTIONS OF DOCUMENTS
You may make a collection consisting of the Document and other
documents released under this License, and replace the individual
copies of this License in the various documents with a single copy
that is included in the collection, provided that you follow the
rules of this License for verbatim copying of each of the documents
in all other respects.
You may extract a single document from such a collection, and
distribute it individually under this License, provided you insert
a copy of this License into the extracted document, and follow this
License in all other respects regarding verbatim copying of that
document.
7. AGGREGATION WITH INDEPENDENT WORKS
A compilation of the Document or its derivatives with other
separate and independent documents or works, in or on a volume of a
storage or distribution medium, is called an “aggregate” if the
copyright resulting from the compilation is not used to limit the
legal rights of the compilations users beyond what the individual
works permit. When the Document is included in an aggregate, this
License does not apply to the other works in the aggregate which
are not themselves derivative works of the Document.
If the Cover Text requirement of section 3 is applicable to these
copies of the Document, then if the Document is less than one half
of the entire aggregate, the Documents Cover Texts may be placed
on covers that bracket the Document within the aggregate, or the
electronic equivalent of covers if the Document is in electronic
form. Otherwise they must appear on printed covers that bracket
the whole aggregate.
8. TRANSLATION
Translation is considered a kind of modification, so you may
distribute translations of the Document under the terms of section
4. Replacing Invariant Sections with translations requires special
permission from their copyright holders, but you may include
translations of some or all Invariant Sections in addition to the
original versions of these Invariant Sections. You may include a
translation of this License, and all the license notices in the
Document, and any Warranty Disclaimers, provided that you also
include the original English version of this License and the
original versions of those notices and disclaimers. In case of a
disagreement between the translation and the original version of
this License or a notice or disclaimer, the original version will
prevail.
If a section in the Document is Entitled “Acknowledgements”,
“Dedications”, or “History”, the requirement (section 4) to
Preserve its Title (section 1) will typically require changing the
actual title.
9. TERMINATION
You may not copy, modify, sublicense, or distribute the Document
except as expressly provided under this License. Any attempt
otherwise to copy, modify, sublicense, or distribute it is void,
and will automatically terminate your rights under this License.
However, if you cease all violation of this License, then your
license from a particular copyright holder is reinstated (a)
provisionally, unless and until the copyright holder explicitly and
finally terminates your license, and (b) permanently, if the
copyright holder fails to notify you of the violation by some
reasonable means prior to 60 days after the cessation.
Moreover, your license from a particular copyright holder is
reinstated permanently if the copyright holder notifies you of the
violation by some reasonable means, this is the first time you have
received notice of violation of this License (for any work) from
that copyright holder, and you cure the violation prior to 30 days
after your receipt of the notice.
Termination of your rights under this section does not terminate
the licenses of parties who have received copies or rights from you
under this License. If your rights have been terminated and not
permanently reinstated, receipt of a copy of some or all of the
same material does not give you any rights to use it.
10. FUTURE REVISIONS OF THIS LICENSE
The Free Software Foundation may publish new, revised versions of
the GNU Free Documentation License from time to time. Such new
versions will be similar in spirit to the present version, but may
differ in detail to address new problems or concerns. See
<https://www.gnu.org/copyleft/>.
Each version of the License is given a distinguishing version
number. If the Document specifies that a particular numbered
version of this License “or any later version” applies to it, you
have the option of following the terms and conditions either of
that specified version or of any later version that has been
published (not as a draft) by the Free Software Foundation. If the
Document does not specify a version number of this License, you may
choose any version ever published (not as a draft) by the Free
Software Foundation. If the Document specifies that a proxy can
decide which future versions of this License can be used, that
proxys public statement of acceptance of a version permanently
authorizes you to choose that version for the Document.
11. RELICENSING
“Massive Multiauthor Collaboration Site” (or “MMC Site”) means any
World Wide Web server that publishes copyrightable works and also
provides prominent facilities for anybody to edit those works. A
public wiki that anybody can edit is an example of such a server.
A “Massive Multiauthor Collaboration” (or “MMC”) contained in the
site means any set of copyrightable works thus published on the MMC
site.
“CC-BY-SA” means the Creative Commons Attribution-Share Alike 3.0
license published by Creative Commons Corporation, a not-for-profit
corporation with a principal place of business in San Francisco,
California, as well as future copyleft versions of that license
published by that same organization.
“Incorporate” means to publish or republish a Document, in whole or
in part, as part of another Document.
An MMC is “eligible for relicensing” if it is licensed under this
License, and if all works that were first published under this
License somewhere other than this MMC, and subsequently
incorporated in whole or in part into the MMC, (1) had no cover
texts or invariant sections, and (2) were thus incorporated prior
to November 1, 2008.
The operator of an MMC Site may republish an MMC contained in the
site under CC-BY-SA on the same site at any time before August 1,
2009, provided the MMC is eligible for relicensing.
ADDENDUM: How to use this License for your documents
====================================================
To use this License in a document you have written, include a copy of
the License in the document and put the following copyright and license
notices just after the title page:
Copyright (C) YEAR YOUR NAME.
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3
or any later version published by the Free Software Foundation;
with no Invariant Sections, no Front-Cover Texts, and no Back-Cover
Texts. A copy of the license is included in the section entitled ``GNU
Free Documentation License''.
If you have Invariant Sections, Front-Cover Texts and Back-Cover
Texts, replace the “with...Texts.” line with this:
with the Invariant Sections being LIST THEIR TITLES, with
the Front-Cover Texts being LIST, and with the Back-Cover Texts
being LIST.
If you have Invariant Sections without Cover Texts, or some other
combination of the three, merge those two alternatives to suit the
situation.
If your document contains nontrivial examples of program code, we
recommend releasing these examples in parallel under your choice of free
software license, such as the GNU General Public License, to permit
their use in free software.

File: cpp.info, Node: Index of Directives, Next: Option Index, Prev: GNU Free Documentation License, Up: Top
Index of Directives
*******************
[index]
* Menu:
* #assert: Obsolete Features. (line 48)
* #define: Object-like Macros. (line 11)
* #elif: Elif. (line 6)
* #else: Else. (line 6)
* #endif: Ifdef. (line 6)
* #error: Diagnostics. (line 6)
* #ident: Other Directives. (line 6)
* #if: Conditional Syntax. (line 6)
* #ifdef: Ifdef. (line 6)
* #ifndef: Ifdef. (line 40)
* #import: Alternatives to Wrapper #ifndef.
(line 11)
* #include: Include Syntax. (line 6)
* #include_next: Wrapper Headers. (line 6)
* #line: Line Control. (line 20)
* #pragma endregion {tokens}...: Pragmas. (line 103)
* #pragma GCC dependency: Pragmas. (line 43)
* #pragma GCC error: Pragmas. (line 88)
* #pragma GCC poison: Pragmas. (line 55)
* #pragma GCC system_header: System Headers. (line 25)
* #pragma GCC system_header <1>: Pragmas. (line 82)
* #pragma GCC warning: Pragmas. (line 87)
* #pragma once: Pragmas. (line 96)
* #pragma region {tokens}...: Pragmas. (line 102)
* #sccs: Other Directives. (line 6)
* #unassert: Obsolete Features. (line 59)
* #undef: Undefining and Redefining Macros.
(line 6)
* #warning: Diagnostics. (line 27)

File: cpp.info, Node: Option Index, Next: Concept Index, Prev: Index of Directives, Up: Top
Option Index
************
CPPs command-line options and environment variables are indexed here
without any initial - or --.
[index]
* Menu:
* A: Invocation. (line 336)
* C: Invocation. (line 345)
* CC: Invocation. (line 357)
* CPATH: Environment Variables.
(line 15)
* CPLUS_INCLUDE_PATH: Environment Variables.
(line 17)
* C_INCLUDE_PATH: Environment Variables.
(line 16)
* D: Invocation. (line 42)
* d: Invocation. (line 406)
* dD: Invocation. (line 425)
* DEPENDENCIES_OUTPUT: Environment Variables.
(line 44)
* dI: Invocation. (line 435)
* dM: Invocation. (line 414)
* dN: Invocation. (line 431)
* dU: Invocation. (line 439)
* fdebug-cpp: Invocation. (line 446)
* fdirectives-only: Invocation. (line 229)
* fdollars-in-identifiers: Invocation. (line 250)
* fexec-charset: Invocation. (line 297)
* fextended-identifiers: Invocation. (line 253)
* finput-charset: Invocation. (line 312)
* fmacro-prefix-map: Invocation. (line 288)
* fmax-include-depth: Invocation. (line 262)
* fno-canonical-system-headers: Invocation. (line 258)
* fno-working-directory: Invocation. (line 322)
* fpreprocessed: Invocation. (line 216)
* ftabstop: Invocation. (line 265)
* ftrack-macro-expansion: Invocation. (line 271)
* fwide-exec-charset: Invocation. (line 302)
* fworking-directory: Invocation. (line 322)
* H: Invocation. (line 399)
* I: Invocation. (line 454)
* I-: Invocation. (line 511)
* idirafter: Invocation. (line 454)
* imacros: Invocation. (line 80)
* imultilib: Invocation. (line 545)
* include: Invocation. (line 69)
* iprefix: Invocation. (line 527)
* iquote: Invocation. (line 454)
* isysroot: Invocation. (line 539)
* isystem: Invocation. (line 454)
* iwithprefix: Invocation. (line 532)
* iwithprefixbefore: Invocation. (line 532)
* M: Invocation. (line 101)
* MD: Invocation. (line 196)
* MF: Invocation. (line 135)
* MG: Invocation. (line 146)
* MM: Invocation. (line 126)
* MMD: Invocation. (line 212)
* Mno-modules: Invocation. (line 156)
* MP: Invocation. (line 159)
* MQ: Invocation. (line 186)
* MT: Invocation. (line 171)
* nostdinc: Invocation. (line 549)
* nostdinc++: Invocation. (line 555)
* OBJC_INCLUDE_PATH: Environment Variables.
(line 18)
* P: Invocation. (line 369)
* pthread: Invocation. (line 94)
* remap: Invocation. (line 395)
* SOURCE_DATE_EPOCH: Environment Variables.
(line 66)
* SUNPRO_DEPENDENCIES: Environment Variables.
(line 60)
* traditional: Invocation. (line 376)
* traditional-cpp: Invocation. (line 376)
* trigraphs: Invocation. (line 386)
* U: Invocation. (line 65)
* undef: Invocation. (line 89)
* Wcomment: Invocation. (line 560)
* Wcomments: Invocation. (line 560)
* Wendif-labels: Invocation. (line 605)
* Wexpansion-to-defined: Invocation. (line 580)
* Wno-endif-labels: Invocation. (line 605)
* Wno-undef: Invocation. (line 576)
* Wtrigraphs: Invocation. (line 566)
* Wundef: Invocation. (line 576)
* Wunused-macros: Invocation. (line 586)

File: cpp.info, Node: Concept Index, Prev: Option Index, Up: Top
Concept Index
*************
[index]
* Menu:
* # operator: Stringizing. (line 6)
* ## operator: Concatenation. (line 6)
* _Pragma: Pragmas. (line 13)
* __has_attribute: __has_attribute. (line 6)
* __has_builtin: __has_builtin. (line 6)
* __has_cpp_attribute: __has_cpp_attribute. (line 6)
* __has_c_attribute: __has_c_attribute. (line 6)
* __has_include: __has_include. (line 6)
* alternative tokens: Tokenization. (line 100)
* arguments: Macro Arguments. (line 6)
* arguments in macro definitions: Macro Arguments. (line 6)
* assertions: Obsolete Features. (line 13)
* assertions, canceling: Obsolete Features. (line 59)
* backslash-newline: Initial processing. (line 61)
* block comments: Initial processing. (line 77)
* C language, traditional: Invocation. (line 376)
* C++ named operators: C++ Named Operators. (line 6)
* character constants: Tokenization. (line 81)
* character set, execution: Invocation. (line 297)
* character set, input: Invocation. (line 312)
* character set, wide execution: Invocation. (line 302)
* command line: Invocation. (line 6)
* commenting out code: Deleted Code. (line 6)
* comments: Initial processing. (line 77)
* common predefined macros: Common Predefined Macros.
(line 6)
* computed includes: Computed Includes. (line 6)
* concatenation: Concatenation. (line 6)
* conditional group: Ifdef. (line 14)
* conditionals: Conditionals. (line 6)
* continued lines: Initial processing. (line 61)
* controlling macro: Once-Only Headers. (line 35)
* defined: Defined. (line 6)
* dependencies for make as output: Environment Variables.
(line 44)
* dependencies for make as output <1>: Environment Variables.
(line 60)
* dependencies, make: Invocation. (line 101)
* diagnostic: Diagnostics. (line 6)
* digraphs: Tokenization. (line 100)
* directive line: The preprocessing language.
(line 6)
* directive name: The preprocessing language.
(line 6)
* directives: The preprocessing language.
(line 6)
* empty macro arguments: Macro Arguments. (line 66)
* environment variables: Environment Variables.
(line 6)
* expansion of arguments: Argument Prescan. (line 6)
* FDL, GNU Free Documentation License: GNU Free Documentation License.
(line 6)
* function-like macros: Function-like Macros.
(line 6)
* grouping options: Invocation. (line 38)
* guard macro: Once-Only Headers. (line 35)
* header file: Header Files. (line 6)
* header file names: Tokenization. (line 81)
* identifiers: Tokenization. (line 33)
* implementation limits: Implementation limits.
(line 6)
* implementation-defined behavior: Implementation-defined behavior.
(line 6)
* including just once: Once-Only Headers. (line 6)
* invocation: Invocation. (line 6)
* iso646.h: C++ Named Operators. (line 6)
* line comments: Initial processing. (line 77)
* line control: Line Control. (line 6)
* line endings: Initial processing. (line 14)
* linemarkers: Preprocessor Output. (line 27)
* macro argument expansion: Argument Prescan. (line 6)
* macro arguments and directives: Directives Within Macro Arguments.
(line 6)
* macros in include: Computed Includes. (line 6)
* macros with arguments: Macro Arguments. (line 6)
* macros with variable arguments: Variadic Macros. (line 6)
* make: Invocation. (line 101)
* manifest constants: Object-like Macros. (line 6)
* named operators: C++ Named Operators. (line 6)
* newlines in macro arguments: Newlines in Arguments.
(line 6)
* null directive: Other Directives. (line 15)
* numbers: Tokenization. (line 58)
* object-like macro: Object-like Macros. (line 6)
* options: Invocation. (line 42)
* options, grouping: Invocation. (line 38)
* other tokens: Tokenization. (line 114)
* output format: Preprocessor Output. (line 12)
* overriding a header file: Wrapper Headers. (line 6)
* parentheses in macro bodies: Operator Precedence Problems.
(line 6)
* pitfalls of macros: Macro Pitfalls. (line 6)
* pragma directive: Pragmas. (line 6)
* predefined macros: Predefined Macros. (line 6)
* predefined macros, system-specific: System-specific Predefined Macros.
(line 6)
* predicates: Obsolete Features. (line 26)
* preprocessing directives: The preprocessing language.
(line 6)
* preprocessing numbers: Tokenization. (line 58)
* preprocessing tokens: Tokenization. (line 6)
* prescan of macro arguments: Argument Prescan. (line 6)
* problems with macros: Macro Pitfalls. (line 6)
* punctuators: Tokenization. (line 100)
* redefining macros: Undefining and Redefining Macros.
(line 6)
* repeated inclusion: Once-Only Headers. (line 6)
* reporting errors: Diagnostics. (line 6)
* reporting warnings: Diagnostics. (line 6)
* reserved namespace: System-specific Predefined Macros.
(line 6)
* self-reference: Self-Referential Macros.
(line 6)
* semicolons (after macro calls): Swallowing the Semicolon.
(line 6)
* side effects (in macro arguments): Duplication of Side Effects.
(line 6)
* standard predefined macros.: Standard Predefined Macros.
(line 6)
* string constants: Tokenization. (line 81)
* string literals: Tokenization. (line 81)
* stringizing: Stringizing. (line 6)
* symbolic constants: Object-like Macros. (line 6)
* system header files: Header Files. (line 13)
* system header files <1>: System Headers. (line 6)
* system-specific predefined macros: System-specific Predefined Macros.
(line 6)
* testing predicates: Obsolete Features. (line 37)
* token concatenation: Concatenation. (line 6)
* token pasting: Concatenation. (line 6)
* tokens: Tokenization. (line 6)
* traditional C language: Invocation. (line 376)
* trigraphs: Initial processing. (line 32)
* undefining macros: Undefining and Redefining Macros.
(line 6)
* unsafe macros: Duplication of Side Effects.
(line 6)
* variable number of arguments: Variadic Macros. (line 6)
* variadic macros: Variadic Macros. (line 6)
* wrapper #ifndef: Once-Only Headers. (line 6)
* wrapper headers: Wrapper Headers. (line 6)

Tag Table:
Node: Top954
Node: Overview3524
Node: Character sets6406
Ref: Character sets-Footnote-18620
Node: Initial processing8805
Ref: trigraphs10382
Node: Tokenization14666
Ref: Tokenization-Footnote-121690
Node: The preprocessing language21809
Node: Header Files24772
Node: Include Syntax26704
Node: Include Operation28393
Node: Search Path30266
Node: Once-Only Headers32554
Node: Alternatives to Wrapper #ifndef34253
Node: Computed Includes35976
Node: Wrapper Headers39210
Node: System Headers41705
Node: Macros43342
Node: Object-like Macros44501
Node: Function-like Macros48203
Node: Macro Arguments49835
Node: Stringizing54029
Node: Concatenation57270
Node: Variadic Macros60455
Node: Predefined Macros65507
Node: Standard Predefined Macros66095
Node: Common Predefined Macros72731
Node: System-specific Predefined Macros96938
Node: C++ Named Operators99011
Node: Undefining and Redefining Macros100071
Node: Directives Within Macro Arguments102205
Node: Macro Pitfalls103146
Node: Misnesting103679
Node: Operator Precedence Problems104791
Node: Swallowing the Semicolon106681
Node: Duplication of Side Effects108742
Node: Self-Referential Macros111001
Node: Argument Prescan113514
Node: Newlines in Arguments117358
Node: Conditionals118315
Node: Conditional Uses120035
Node: Conditional Syntax121399
Node: Ifdef121837
Node: If125082
Node: Defined127456
Node: Else128917
Node: Elif129503
Node: __has_attribute130892
Node: __has_cpp_attribute132532
Node: __has_c_attribute133450
Node: __has_builtin134259
Node: __has_include135420
Node: Deleted Code137055
Node: Diagnostics138348
Node: Line Control139937
Node: Pragmas142287
Node: Other Directives146951
Node: Preprocessor Output148029
Node: Traditional Mode151256
Node: Traditional lexical analysis152397
Node: Traditional macros154926
Node: Traditional miscellany158747
Node: Traditional warnings159781
Node: Implementation Details162048
Node: Implementation-defined behavior162613
Ref: Identifier characters163383
Node: Implementation limits166510
Node: Obsolete Features169215
Node: Invocation172117
Ref: dashMF178394
Ref: fdollars-in-identifiers183328
Ref: Wtrigraphs198211
Node: Environment Variables200336
Node: GNU Free Documentation License204161
Node: Index of Directives229514
Node: Option Index231813
Node: Concept Index237925

End Tag Table

Local Variables:
coding: utf-8
End:
Reference in a new issue View git blame Copy permalink