1 @node Introduction, Error Reporting, Top, Top
4 The C language provides no built-in facilities for performing such
5 common operations as input/output, memory management, string
6 manipulation, and the like. Instead, these facilities are defined
7 in a standard @dfn{library}, which you compile and link with your
11 The GNU C library, described in this document, defines all of the
12 library functions that are specified by the @w{ISO C} standard, as well as
13 additional features specific to POSIX and other derivatives of the Unix
14 operating system, and extensions specific to the GNU system.
16 The purpose of this manual is to tell you how to use the facilities
17 of the GNU library. We have mentioned which features belong to which
18 standards to help you identify things that are potentially non-portable
19 to other systems. But the emphasis in this manual is not on strict
23 * Getting Started:: What this manual is for and how to use it.
24 * Standards and Portability:: Standards and sources upon which the GNU
26 * Using the Library:: Some practical uses for the library.
27 * Roadmap to the Manual:: Overview of the remaining chapters in
31 @node Getting Started, Standards and Portability, , Introduction
32 @section Getting Started
34 This manual is written with the assumption that you are at least
35 somewhat familiar with the C programming language and basic programming
36 concepts. Specifically, familiarity with ISO standard C
37 (@pxref{ISO C}), rather than ``traditional'' pre-ISO C dialects, is
40 The GNU C library includes several @dfn{header files}, each of which
41 provides definitions and declarations for a group of related facilities;
42 this information is used by the C compiler when processing your program.
43 For example, the header file @file{stdio.h} declares facilities for
44 performing input and output, and the header file @file{string.h}
45 declares string processing utilities. The organization of this manual
46 generally follows the same division as the header files.
48 If you are reading this manual for the first time, you should read all
49 of the introductory material and skim the remaining chapters. There are
50 a @emph{lot} of functions in the GNU C library and it's not realistic to
51 expect that you will be able to remember exactly @emph{how} to use each
52 and every one of them. It's more important to become generally familiar
53 with the kinds of facilities that the library provides, so that when you
54 are writing your programs you can recognize @emph{when} to make use of
55 library functions, and @emph{where} in this manual you can find more
56 specific information about them.
59 @node Standards and Portability, Using the Library, Getting Started, Introduction
60 @section Standards and Portability
63 This section discusses the various standards and other sources that the
64 GNU C library is based upon. These sources include the @w{ISO C} and
65 POSIX standards, and the System V and Berkeley Unix implementations.
67 The primary focus of this manual is to tell you how to make effective
68 use of the GNU library facilities. But if you are concerned about
69 making your programs compatible with these standards, or portable to
70 operating systems other than GNU, this can affect how you use the
71 library. This section gives you an overview of these standards, so that
72 you will know what they are when they are mentioned in other parts of
75 @xref{Library Summary}, for an alphabetical list of the functions and
76 other symbols provided by the library. This list also states which
77 standards each function or symbol comes from.
80 * ISO C:: The international standard for the C
82 * POSIX:: The ISO/IEC 9945 (aka IEEE 1003) standards
83 for operating systems.
84 * Berkeley Unix:: BSD and SunOS.
85 * SVID:: The System V Interface Description.
86 * XPG:: The X/Open Portability Guide.
89 @node ISO C, POSIX, , Standards and Portability
93 The GNU C library is compatible with the C standard adopted by the
94 American National Standards Institute (ANSI):
95 @cite{American National Standard X3.159-1989---``ANSI C''} and later
96 by the International Standardization Organization (ISO):
97 @cite{ISO/IEC 9899:1990, ``Programming languages---C''}.
98 We here refer to the standard as @w{ISO C} since this is the more
99 general standard in respect of ratification.
100 The header files and library facilities that make up the GNU library are
101 a superset of those specified by the @w{ISO C} standard.@refill
104 If you are concerned about strict adherence to the @w{ISO C} standard, you
105 should use the @samp{-ansi} option when you compile your programs with
106 the GNU C compiler. This tells the compiler to define @emph{only} ISO
107 standard features from the library header files, unless you explicitly
108 ask for additional features. @xref{Feature Test Macros}, for
109 information on how to do this.
111 Being able to restrict the library to include only @w{ISO C} features is
112 important because @w{ISO C} puts limitations on what names can be defined
113 by the library implementation, and the GNU extensions don't fit these
114 limitations. @xref{Reserved Names}, for more information about these
117 This manual does not attempt to give you complete details on the
118 differences between @w{ISO C} and older dialects. It gives advice on how
119 to write programs to work portably under multiple C dialects, but does
120 not aim for completeness.
123 @node POSIX, Berkeley Unix, ISO C, Standards and Portability
124 @subsection POSIX (The Portable Operating System Interface)
127 @cindex IEEE Std 1003.1
128 @cindex ISO/IEC 9945-1
130 @cindex IEEE Std 1003.2
131 @cindex ISO/IEC 9945-2
133 The GNU library is also compatible with the ISO @dfn{POSIX} family of
134 standards, known more formally as the @dfn{Portable Operating System
135 Interface for Computer Environments} (ISO/IEC 9945). They were also
136 published as ANSI/IEEE Std 1003. POSIX is derived mostly from various
137 versions of the Unix operating system.
139 The library facilities specified by the POSIX standards are a superset
140 of those required by @w{ISO C}; POSIX specifies additional features for
141 @w{ISO C} functions, as well as specifying new additional functions. In
142 general, the additional requirements and functionality defined by the
143 POSIX standards are aimed at providing lower-level support for a
144 particular kind of operating system environment, rather than general
145 programming language support which can run in many diverse operating
146 system environments.@refill
148 The GNU C library implements all of the functions specified in
149 @cite{ISO/IEC 9945-1:1996, the POSIX System Application Program
150 Interface}, commonly referred to as POSIX.1. The primary extensions to
151 the @w{ISO C} facilities specified by this standard include file system
152 interface primitives (@pxref{File System Interface}), device-specific
153 terminal control functions (@pxref{Low-Level Terminal Interface}), and
154 process control functions (@pxref{Processes}).
156 Some facilities from @cite{ISO/IEC 9945-2:1993, the POSIX Shell and
157 Utilities standard} (POSIX.2) are also implemented in the GNU library.
158 These include utilities for dealing with regular expressions and other
159 pattern matching facilities (@pxref{Pattern Matching}).
162 @comment The GNU C library as it stands conforms to 1003.2 draft 11, which
165 @comment Several new macros in <limits.h>.
166 @comment popen, pclose
167 @comment <regex.h> (which is not yet fully implemented--wait on this)
171 @comment <wordexp.h> (not yet implemented)
175 @node Berkeley Unix, SVID, POSIX, Standards and Portability
176 @subsection Berkeley Unix
178 @cindex 4.@var{n} BSD Unix
179 @cindex Berkeley Unix
181 @cindex Unix, Berkeley
183 The GNU C library defines facilities from some versions of Unix which
184 are not formally standardized, specifically from the 4.2 BSD, 4.3 BSD,
185 and 4.4 BSD Unix systems (also known as @dfn{Berkeley Unix}) and from
186 @dfn{SunOS} (a popular 4.2 BSD derivative that includes some Unix System
187 V functionality). These systems support most of the @w{ISO C} and POSIX
188 facilities, and 4.4 BSD and newer releases of SunOS in fact support them all.
190 The BSD facilities include symbolic links (@pxref{Symbolic Links}), the
191 @code{select} function (@pxref{Waiting for I/O}), the BSD signal
192 functions (@pxref{BSD Signal Handling}), and sockets (@pxref{Sockets}).
194 @node SVID, XPG, Berkeley Unix, Standards and Portability
195 @subsection SVID (The System V Interface Description)
197 @cindex System V Unix
198 @cindex Unix, System V
200 The @dfn{System V Interface Description} (SVID) is a document describing
201 the AT&T Unix System V operating system. It is to some extent a
202 superset of the POSIX standard (@pxref{POSIX}).
204 The GNU C library defines most of the facilities required by the SVID
205 that are not also required by the @w{ISO C} or POSIX standards, for
206 compatibility with System V Unix and other Unix systems (such as
207 SunOS) which include these facilities. However, many of the more
208 obscure and less generally useful facilities required by the SVID are
209 not included. (In fact, Unix System V itself does not provide them all.)
211 The supported facilities from System V include the methods for
212 inter-process communication and shared memory, the @code{hsearch} and
213 @code{drand48} families of functions, @code{fmtmsg} and several of the
214 mathematical functions.
216 @node XPG, , SVID, Standards and Portability
217 @subsection XPG (The X/Open Portability Guide)
219 The X/Open Portability Guide, published by the X/Open Company, Ltd., is
220 a more general standard than POSIX. X/Open owns the Unix copyright and
221 the XPG specifies the requirements for systems which are intended to be
224 The GNU C library complies to the X/Open Portability Guide, Issue 4.2,
225 with all extensions common to XSI (X/Open System Interface)
226 compliant systems and also all X/Open UNIX extensions.
228 The additions on top of POSIX are mainly derived from functionality
229 available in @w{System V} and BSD systems. Some of the really bad
230 mistakes in @w{System V} systems were corrected, though. Since
231 fulfilling the XPG standard with the Unix extensions is a
232 precondition for getting the Unix brand chances are good that the
233 functionality is available on commercial systems.
236 @node Using the Library, Roadmap to the Manual, Standards and Portability, Introduction
237 @section Using the Library
239 This section describes some of the practical issues involved in using
243 * Header Files:: How to include the header files in your
245 * Macro Definitions:: Some functions in the library may really
246 be implemented as macros.
247 * Reserved Names:: The C standard reserves some names for
248 the library, and some for users.
249 * Feature Test Macros:: How to control what names are defined.
252 @node Header Files, Macro Definitions, , Using the Library
253 @subsection Header Files
256 Libraries for use by C programs really consist of two parts: @dfn{header
257 files} that define types and macros and declare variables and
258 functions; and the actual library or @dfn{archive} that contains the
259 definitions of the variables and functions.
261 (Recall that in C, a @dfn{declaration} merely provides information that
262 a function or variable exists and gives its type. For a function
263 declaration, information about the types of its arguments might be
264 provided as well. The purpose of declarations is to allow the compiler
265 to correctly process references to the declared variables and functions.
266 A @dfn{definition}, on the other hand, actually allocates storage for a
267 variable or says what a function does.)
268 @cindex definition (compared to declaration)
269 @cindex declaration (compared to definition)
271 In order to use the facilities in the GNU C library, you should be sure
272 that your program source files include the appropriate header files.
273 This is so that the compiler has declarations of these facilities
274 available and can correctly process references to them. Once your
275 program has been compiled, the linker resolves these references to
276 the actual definitions provided in the archive file.
278 Header files are included into a program source file by the
279 @samp{#include} preprocessor directive. The C language supports two
280 forms of this directive; the first,
283 #include "@var{header}"
287 is typically used to include a header file @var{header} that you write
288 yourself; this would contain definitions and declarations describing the
289 interfaces between the different parts of your particular application.
297 is typically used to include a header file @file{file.h} that contains
298 definitions and declarations for a standard library. This file would
299 normally be installed in a standard place by your system administrator.
300 You should use this second form for the C library header files.
302 Typically, @samp{#include} directives are placed at the top of the C
303 source file, before any other code. If you begin your source files with
304 some comments explaining what the code in the file does (a good idea),
305 put the @samp{#include} directives immediately afterwards, following the
306 feature test macro definition (@pxref{Feature Test Macros}).
308 For more information about the use of header files and @samp{#include}
309 directives, @pxref{Header Files,,, cpp.info, The GNU C Preprocessor
312 The GNU C library provides several header files, each of which contains
313 the type and macro definitions and variable and function declarations
314 for a group of related facilities. This means that your programs may
315 need to include several header files, depending on exactly which
316 facilities you are using.
318 Some library header files include other library header files
319 automatically. However, as a matter of programming style, you should
320 not rely on this; it is better to explicitly include all the header
321 files required for the library facilities you are using. The GNU C
322 library header files have been written in such a way that it doesn't
323 matter if a header file is accidentally included more than once;
324 including a header file a second time has no effect. Likewise, if your
325 program needs to include multiple header files, the order in which they
326 are included doesn't matter.
328 @strong{Compatibility Note:} Inclusion of standard header files in any
329 order and any number of times works in any @w{ISO C} implementation.
330 However, this has traditionally not been the case in many older C
333 Strictly speaking, you don't @emph{have to} include a header file to use
334 a function it declares; you could declare the function explicitly
335 yourself, according to the specifications in this manual. But it is
336 usually better to include the header file because it may define types
337 and macros that are not otherwise available and because it may define
338 more efficient macro replacements for some functions. It is also a sure
339 way to have the correct declaration.
341 @node Macro Definitions, Reserved Names, Header Files, Using the Library
342 @subsection Macro Definitions of Functions
343 @cindex shadowing functions with macros
344 @cindex removing macros that shadow functions
345 @cindex undefining macros that shadow functions
347 If we describe something as a function in this manual, it may have a
348 macro definition as well. This normally has no effect on how your
349 program runs---the macro definition does the same thing as the function
350 would. In particular, macro equivalents for library functions evaluate
351 arguments exactly once, in the same way that a function call would. The
352 main reason for these macro definitions is that sometimes they can
353 produce an inline expansion that is considerably faster than an actual
356 Taking the address of a library function works even if it is also
357 defined as a macro. This is because, in this context, the name of the
358 function isn't followed by the left parenthesis that is syntactically
359 necessary to recognize a macro call.
361 You might occasionally want to avoid using the macro definition of a
362 function---perhaps to make your program easier to debug. There are
363 two ways you can do this:
367 You can avoid a macro definition in a specific use by enclosing the name
368 of the function in parentheses. This works because the name of the
369 function doesn't appear in a syntactic context where it is recognizable
373 You can suppress any macro definition for a whole source file by using
374 the @samp{#undef} preprocessor directive, unless otherwise stated
375 explicitly in the description of that facility.
378 For example, suppose the header file @file{stdlib.h} declares a function
379 named @code{abs} with
382 extern int abs (int);
386 and also provides a macro definition for @code{abs}. Then, in:
390 int f (int *i) @{ return abs (++*i); @}
394 the reference to @code{abs} might refer to either a macro or a function.
395 On the other hand, in each of the following examples the reference is
396 to a function and not a macro.
400 int g (int *i) @{ return (abs) (++*i); @}
403 int h (int *i) @{ return abs (++*i); @}
406 Since macro definitions that double for a function behave in
407 exactly the same way as the actual function version, there is usually no
408 need for any of these methods. In fact, removing macro definitions usually
409 just makes your program slower.
412 @node Reserved Names, Feature Test Macros, Macro Definitions, Using the Library
413 @subsection Reserved Names
414 @cindex reserved names
417 The names of all library types, macros, variables and functions that
418 come from the @w{ISO C} standard are reserved unconditionally; your program
419 @strong{may not} redefine these names. All other library names are
420 reserved if your program explicitly includes the header file that
421 defines or declares them. There are several reasons for these
426 Other people reading your code could get very confused if you were using
427 a function named @code{exit} to do something completely different from
428 what the standard @code{exit} function does, for example. Preventing
429 this situation helps to make your programs easier to understand and
430 contributes to modularity and maintainability.
433 It avoids the possibility of a user accidentally redefining a library
434 function that is called by other library functions. If redefinition
435 were allowed, those other functions would not work properly.
438 It allows the compiler to do whatever special optimizations it pleases
439 on calls to these functions, without the possibility that they may have
440 been redefined by the user. Some library facilities, such as those for
441 dealing with variadic arguments (@pxref{Variadic Functions})
442 and non-local exits (@pxref{Non-Local Exits}), actually require a
443 considerable amount of cooperation on the part of the C compiler, and
444 implementationally it might be easier for the compiler to treat these as
445 built-in parts of the language.
448 In addition to the names documented in this manual, reserved names
449 include all external identifiers (global functions and variables) that
450 begin with an underscore (@samp{_}) and all identifiers regardless of
451 use that begin with either two underscores or an underscore followed by
452 a capital letter are reserved names. This is so that the library and
453 header files can define functions, variables, and macros for internal
454 purposes without risk of conflict with names in user programs.
456 Some additional classes of identifier names are reserved for future
457 extensions to the C language or the POSIX.1 environment. While using these
458 names for your own purposes right now might not cause a problem, they do
459 raise the possibility of conflict with future versions of the C
460 or POSIX standards, so you should avoid these names.
464 Names beginning with a capital @samp{E} followed a digit or uppercase
465 letter may be used for additional error code names. @xref{Error
469 Names that begin with either @samp{is} or @samp{to} followed by a
470 lowercase letter may be used for additional character testing and
471 conversion functions. @xref{Character Handling}.
474 Names that begin with @samp{LC_} followed by an uppercase letter may be
475 used for additional macros specifying locale attributes.
479 Names of all existing mathematics functions (@pxref{Mathematics})
480 suffixed with @samp{f} or @samp{l} are reserved for corresponding
481 functions that operate on @code{float} and @code{long double} arguments,
485 Names that begin with @samp{SIG} followed by an uppercase letter are
486 reserved for additional signal names. @xref{Standard Signals}.
489 Names that begin with @samp{SIG_} followed by an uppercase letter are
490 reserved for additional signal actions. @xref{Basic Signal Handling}.
493 Names beginning with @samp{str}, @samp{mem}, or @samp{wcs} followed by a
494 lowercase letter are reserved for additional string and array functions.
495 @xref{String and Array Utilities}.
498 Names that end with @samp{_t} are reserved for additional type names.
501 In addition, some individual header files reserve names beyond
502 those that they actually define. You only need to worry about these
503 restrictions if your program includes that particular header file.
507 The header file @file{dirent.h} reserves names prefixed with
512 The header file @file{fcntl.h} reserves names prefixed with
513 @samp{l_}, @samp{F_}, @samp{O_}, and @samp{S_}.
517 The header file @file{grp.h} reserves names prefixed with @samp{gr_}.
521 The header file @file{limits.h} reserves names suffixed with @samp{_MAX}.
525 The header file @file{pwd.h} reserves names prefixed with @samp{pw_}.
529 The header file @file{signal.h} reserves names prefixed with @samp{sa_}
534 The header file @file{sys/stat.h} reserves names prefixed with @samp{st_}
539 The header file @file{sys/times.h} reserves names prefixed with @samp{tms_}.
543 The header file @file{termios.h} reserves names prefixed with @samp{c_},
544 @samp{V}, @samp{I}, @samp{O}, and @samp{TC}; and names prefixed with
545 @samp{B} followed by a digit.
549 @comment Include the section on Creature Nest Macros.
550 @comment It is in a separate file so it can be formatted into ../NOTES.
551 @include creature.texi
553 @node Roadmap to the Manual, , Using the Library, Introduction
554 @section Roadmap to the Manual
556 Here is an overview of the contents of the remaining chapters of
561 @ref{Error Reporting}, describes how errors detected by the library
565 @ref{Language Features}, contains information about library support for
566 standard parts of the C language, including things like the @code{sizeof}
567 operator and the symbolic constant @code{NULL}, how to write functions
568 accepting variable numbers of arguments, and constants describing the
569 ranges and other properties of the numerical types. There is also a simple
570 debugging mechanism which allows you to put assertions in your code, and
571 have diagnostic messages printed if the tests fail.
574 @ref{Memory Allocation}, describes the GNU library's facilities for
575 dynamic allocation of storage. If you do not know in advance how much
576 storage your program needs, you can allocate it dynamically instead,
577 and manipulate it via pointers.
580 @ref{Character Handling}, contains information about character
581 classification functions (such as @code{isspace}) and functions for
582 performing case conversion.
585 @ref{String and Array Utilities}, has descriptions of functions for
586 manipulating strings (null-terminated character arrays) and general
587 byte arrays, including operations such as copying and comparison.
590 @ref{I/O Overview}, gives an overall look at the input and output
591 facilities in the library, and contains information about basic concepts
595 @ref{I/O on Streams}, describes I/O operations involving streams (or
596 @w{@code{FILE *}} objects). These are the normal C library functions
600 @ref{Low-Level I/O}, contains information about I/O operations
601 on file descriptors. File descriptors are a lower-level mechanism
602 specific to the Unix family of operating systems.
605 @ref{File System Interface}, has descriptions of operations on entire
606 files, such as functions for deleting and renaming them and for creating
607 new directories. This chapter also contains information about how you
608 can access the attributes of a file, such as its owner and file protection
612 @ref{Pipes and FIFOs}, contains information about simple interprocess
613 communication mechanisms. Pipes allow communication between two related
614 processes (such as between a parent and child), while FIFOs allow
615 communication between processes sharing a common file system on the same
619 @ref{Sockets}, describes a more complicated interprocess communication
620 mechanism that allows processes running on different machines to
621 communicate over a network. This chapter also contains information about
622 Internet host addressing and how to use the system network databases.
625 @ref{Low-Level Terminal Interface}, describes how you can change the
626 attributes of a terminal device. If you want to disable echo of
627 characters typed by the user, for example, read this chapter.
630 @ref{Mathematics}, contains information about the math library
631 functions. These include things like random-number generators and
632 remainder functions on integers as well as the usual trigonometric and
633 exponential functions on floating-point numbers.
636 @ref{Arithmetic,, Low-Level Arithmetic Functions}, describes functions
637 for simple arithmetic, analysis of floating-point values, and reading
638 numbers from strings.
641 @ref{Searching and Sorting}, contains information about functions
642 for searching and sorting arrays. You can use these functions on any
643 kind of array by providing an appropriate comparison function.
646 @ref{Pattern Matching}, presents functions for matching regular expressions
647 and shell file name patterns, and for expanding words as the shell does.
650 @ref{Date and Time}, describes functions for measuring both calendar time
651 and CPU time, as well as functions for setting alarms and timers.
654 @ref{Extended Characters}, contains information about manipulating
655 characters and strings using character sets larger than will fit in
656 the usual @code{char} data type.
659 @ref{Locales}, describes how selecting a particular country
660 or language affects the behavior of the library. For example, the locale
661 affects collation sequences for strings and how monetary values are
665 @ref{Non-Local Exits}, contains descriptions of the @code{setjmp} and
666 @code{longjmp} functions. These functions provide a facility for
667 @code{goto}-like jumps which can jump from one function to another.
670 @ref{Signal Handling}, tells you all about signals---what they are,
671 how to establish a handler that is called when a particular kind of
672 signal is delivered, and how to prevent signals from arriving during
673 critical sections of your program.
676 @ref{Process Startup}, tells how your programs can access their
677 command-line arguments and environment variables.
680 @ref{Processes}, contains information about how to start new processes
684 @ref{Job Control}, describes functions for manipulating process groups
685 and the controlling terminal. This material is probably only of
686 interest if you are writing a shell or other program which handles job
690 @ref{Name Service Switch}, describes the services which are available
691 for looking up names in the system databases, how to determine which
692 service is used for which database, and how these services are
693 implemented so that contributors can design their own services.
696 @ref{User Database}, and @ref{Group Database}, tell you how to access
697 the system user and group databases.
700 @ref{System Information}, describes functions for getting information
701 about the hardware and software configuration your program is executing
705 @ref{System Configuration}, tells you how you can get information about
706 various operating system limits. Most of these parameters are provided for
707 compatibility with POSIX.
710 @ref{Library Summary}, gives a summary of all the functions, variables, and
711 macros in the library, with complete data types and function prototypes,
712 and says what standard or system each is derived from.
715 @ref{Maintenance}, explains how to build and install the GNU C library on
716 your system, how to report any bugs you might find, and how to add new
717 functions or port the library to a new system.
720 If you already know the name of the facility you are interested in, you
721 can look it up in @ref{Library Summary}. This gives you a summary of
722 its syntax and a pointer to where you can find a more detailed
723 description. This appendix is particularly useful if you just want to
724 verify the order and type of arguments to a function, for example. It
725 also tells you what standard or system each function, variable, or macro