1 @node File System Interface, Pipes and FIFOs, Low-Level I/O, Top
2 @c %MENU% Functions for manipulating files
3 @chapter File System Interface
5 This chapter describes @theglibc{}'s functions for manipulating
6 files. Unlike the input and output functions (@pxref{I/O on Streams};
7 @pxref{Low-Level I/O}), these functions are concerned with operating
8 on the files themselves rather than on their contents.
10 Among the facilities described in this chapter are functions for
11 examining or modifying directories, functions for renaming and deleting
12 files, and functions for examining and setting file attributes such as
13 access permissions and modification times.
16 * Working Directory:: This is used to resolve relative
18 * Accessing Directories:: Finding out what files a directory
20 * Working with Directory Trees:: Apply actions to all files or a selectable
21 subset of a directory hierarchy.
22 * Hard Links:: Adding alternate names to a file.
23 * Symbolic Links:: A file that ``points to'' a file name.
24 * Deleting Files:: How to delete a file, and what that means.
25 * Renaming Files:: Changing a file's name.
26 * Creating Directories:: A system call just for creating a directory.
27 * File Attributes:: Attributes of individual files.
28 * Making Special Files:: How to create special files.
29 * Temporary Files:: Naming and creating temporary files.
32 @node Working Directory
33 @section Working Directory
35 @cindex current working directory
36 @cindex working directory
37 @cindex change working directory
38 Each process has associated with it a directory, called its @dfn{current
39 working directory} or simply @dfn{working directory}, that is used in
40 the resolution of relative file names (@pxref{File Name Resolution}).
42 When you log in and begin a new session, your working directory is
43 initially set to the home directory associated with your login account
44 in the system user database. You can find any user's home directory
45 using the @code{getpwuid} or @code{getpwnam} functions; see @ref{User
48 Users can change the working directory using shell commands like
49 @code{cd}. The functions described in this section are the primitives
50 used by those commands and by other programs for examining and changing
51 the working directory.
54 Prototypes for these functions are declared in the header file
58 @deftypefun {char *} getcwd (char *@var{buffer}, size_t @var{size})
59 @standards{POSIX.1, unistd.h}
60 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
61 @c If buffer is NULL, this function calls malloc and realloc, and, in
62 @c case of error, free. Linux offers a getcwd syscall that we use on
63 @c GNU/Linux systems, but it may fail if the pathname is too long. As a
64 @c fallback, and on other systems, the generic implementation opens each
65 @c parent directory with opendir, which allocates memory for the
66 @c directory stream with malloc. If a fstatat64 syscall is not
67 @c available, very deep directory trees may also have to malloc to build
68 @c longer sequences of ../../../... than those supported by a global
69 @c const read-only string.
73 @c malloc/realloc/free if buffer is NULL, or if dir is too deep
74 @c lstat64 -> see its own entry
76 @c direct syscall if possible, alloca+snprintf+*stat64 otherwise
77 @c openat64_not_cancel_3, close_not_cancel_no_status
78 @c __fdopendir, __opendir, __readdir, rewinddir
79 The @code{getcwd} function returns an absolute file name representing
80 the current working directory, storing it in the character array
81 @var{buffer} that you provide. The @var{size} argument is how you tell
82 the system the allocation size of @var{buffer}.
84 The @glibcadj{} version of this function also permits you to specify a
85 null pointer for the @var{buffer} argument. Then @code{getcwd}
86 allocates a buffer automatically, as with @code{malloc}
87 (@pxref{Unconstrained Allocation}). If the @var{size} is greater than
88 zero, then the buffer is that large; otherwise, the buffer is as large
89 as necessary to hold the result.
91 The return value is @var{buffer} on success and a null pointer on failure.
92 The following @code{errno} error conditions are defined for this function:
96 The @var{size} argument is zero and @var{buffer} is not a null pointer.
99 The @var{size} argument is less than the length of the working directory
100 name. You need to allocate a bigger array and try again.
103 Permission to read or search a component of the file name was denied.
107 You could implement the behavior of GNU's @w{@code{getcwd (NULL, 0)}}
108 using only the standard behavior of @code{getcwd}:
118 char *buffer = (char *) xmalloc (size);
119 if (getcwd (buffer, size) == buffer)
130 @xref{Malloc Examples}, for information about @code{xmalloc}, which is
131 not a library function but is a customary name used in most GNU
134 @deftypefn {Deprecated Function} {char *} getwd (char *@var{buffer})
135 @standards{BSD, unistd.h}
136 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{} @ascuintl{}}@acunsafe{@acsmem{} @acsfd{}}}
137 @c Besides the getcwd safety issues, it calls strerror_r on error, which
138 @c brings in all of the i18n issues.
139 This is similar to @code{getcwd}, but has no way to specify the size of
140 the buffer. @Theglibc{} provides @code{getwd} only
141 for backwards compatibility with BSD.
143 The @var{buffer} argument should be a pointer to an array at least
144 @code{PATH_MAX} bytes long (@pxref{Limits for Files}). On @gnuhurdsystems{}
145 there is no limit to the size of a file name, so this is not
146 necessarily enough space to contain the directory name. That is why
147 this function is deprecated.
151 @deftypefun {char *} get_current_dir_name (void)
152 @standards{GNU, unistd.h}
153 @safety{@prelim{}@mtsafe{@mtsenv{}}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
154 @c Besides getcwd, which this function calls as a fallback, it calls
155 @c getenv, with the potential thread-safety issues that brings about.
156 The @code{get_current_dir_name} function is basically equivalent to
157 @w{@code{getcwd (NULL, 0)}}, except the value of the @env{PWD}
158 environment variable is first examined, and if it does in fact
159 correspond to the current directory, that value is returned. This is
160 a subtle difference which is visible if the path described by the
161 value in @env{PWD} is using one or more symbolic links, in which case
162 the value returned by @code{getcwd} would resolve the symbolic links
163 and therefore yield a different result.
165 This function is a GNU extension.
168 @deftypefun int chdir (const char *@var{filename})
169 @standards{POSIX.1, unistd.h}
170 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
171 This function is used to set the process's working directory to
174 The normal, successful return value from @code{chdir} is @code{0}. A
175 value of @code{-1} is returned to indicate an error. The @code{errno}
176 error conditions defined for this function are the usual file name
177 syntax errors (@pxref{File Name Errors}), plus @code{ENOTDIR} if the
178 file @var{filename} is not a directory.
181 @deftypefun int fchdir (int @var{filedes})
182 @standards{XPG, unistd.h}
183 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
184 This function is used to set the process's working directory to
185 directory associated with the file descriptor @var{filedes}.
187 The normal, successful return value from @code{fchdir} is @code{0}. A
188 value of @code{-1} is returned to indicate an error. The following
189 @code{errno} error conditions are defined for this function:
193 Read permission is denied for the directory named by @code{dirname}.
196 The @var{filedes} argument is not a valid file descriptor.
199 The file descriptor @var{filedes} is not associated with a directory.
202 The function call was interrupt by a signal.
205 An I/O error occurred.
210 @node Accessing Directories
211 @section Accessing Directories
212 @cindex accessing directories
213 @cindex reading from a directory
214 @cindex directories, accessing
216 The facilities described in this section let you read the contents of a
217 directory file. This is useful if you want your program to list all the
218 files in a directory, perhaps as part of a menu.
220 @cindex directory stream
221 The @code{opendir} function opens a @dfn{directory stream} whose
222 elements are directory entries. Alternatively @code{fdopendir} can be
223 used which can have advantages if the program needs to have more
224 control over the way the directory is opened for reading. This
225 allows, for instance, to pass the @code{O_NOATIME} flag to
228 You use the @code{readdir} function on the directory stream to
229 retrieve these entries, represented as @w{@code{struct dirent}}
230 objects. The name of the file for each entry is stored in the
231 @code{d_name} member of this structure. There are obvious parallels
232 here to the stream facilities for ordinary files, described in
233 @ref{I/O on Streams}.
236 * Directory Entries:: Format of one directory entry.
237 * Opening a Directory:: How to open a directory stream.
238 * Reading/Closing Directory:: How to read directory entries from the stream.
239 * Simple Directory Lister:: A very simple directory listing program.
240 * Random Access Directory:: Rereading part of the directory
241 already read with the same stream.
242 * Scanning Directory Content:: Get entries for user selected subset of
243 contents in given directory.
244 * Simple Directory Lister Mark II:: Revised version of the program.
245 * Low-level Directory Access:: AS-Safe functions for directory access.
248 @node Directory Entries
249 @subsection Format of a Directory Entry
252 This section describes what you find in a single directory entry, as you
253 might obtain it from a directory stream. All the symbols are declared
254 in the header file @file{dirent.h}.
256 @deftp {Data Type} {struct dirent}
257 @standards{POSIX.1, dirent.h}
258 This is a structure type used to return information about directory
259 entries. It contains the following fields:
263 This is the null-terminated file name component. This is the only
264 field you can count on in all POSIX systems.
267 This is the file serial number. For BSD compatibility, you can also
268 refer to this member as @code{d_ino}. On @gnulinuxhurdsystems{} and most POSIX
269 systems, for most files this the same as the @code{st_ino} member that
270 @code{stat} will return for the file. @xref{File Attributes}.
272 @item unsigned char d_namlen
273 This is the length of the file name, not including the terminating
274 null character. Its type is @code{unsigned char} because that is the
275 integer type of the appropriate size. This member is a BSD extension.
276 The symbol @code{_DIRENT_HAVE_D_NAMLEN} is defined if this member is
279 @item unsigned char d_type
280 This is the type of the file, possibly unknown. The following constants
281 are defined for its value:
285 The type is unknown. Only some filesystems have full support to
286 return the type of the file, others might always return this value.
295 A named pipe, or FIFO. @xref{FIFO Special Files}.
298 A local-domain socket. @c !!! @xref{Local Domain}.
310 This member is a BSD extension. The symbol @code{_DIRENT_HAVE_D_TYPE}
311 is defined if this member is available. On systems where it is used, it
312 corresponds to the file type bits in the @code{st_mode} member of
313 @code{struct stat}. If the value cannot be determined the member
314 value is DT_UNKNOWN. These two macros convert between @code{d_type}
315 values and @code{st_mode} values:
317 @deftypefun int IFTODT (mode_t @var{mode})
318 @standards{BSD, dirent.h}
319 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
320 This returns the @code{d_type} value corresponding to @var{mode}.
323 @deftypefun mode_t DTTOIF (int @var{dtype})
324 @standards{BSD, dirent.h}
325 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
326 This returns the @code{st_mode} value corresponding to @var{dtype}.
330 This structure may contain additional members in the future. Their
331 availability is always announced in the compilation environment by a
332 macro named @code{_DIRENT_HAVE_D_@var{xxx}} where @var{xxx} is replaced
333 by the name of the new member. For instance, the member @code{d_reclen}
334 available on some systems is announced through the macro
335 @code{_DIRENT_HAVE_D_RECLEN}.
337 When a file has multiple names, each name has its own directory entry.
338 The only way you can tell that the directory entries belong to a
339 single file is that they have the same value for the @code{d_fileno}
342 File attributes such as size, modification times etc., are part of the
343 file itself, not of any particular directory entry. @xref{File
347 @node Opening a Directory
348 @subsection Opening a Directory Stream
351 This section describes how to open a directory stream. All the symbols
352 are declared in the header file @file{dirent.h}.
354 @deftp {Data Type} DIR
355 @standards{POSIX.1, dirent.h}
356 The @code{DIR} data type represents a directory stream.
359 You shouldn't ever allocate objects of the @code{struct dirent} or
360 @code{DIR} data types, since the directory access functions do that for
361 you. Instead, you refer to these objects using the pointers returned by
362 the following functions.
364 Directory streams are a high-level interface. On Linux, alternative
365 interfaces for accessing directories using file descriptors are
366 available. @xref{Low-level Directory Access}.
368 @deftypefun {DIR *} opendir (const char *@var{dirname})
369 @standards{POSIX.1, dirent.h}
370 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
371 @c Besides the safe syscall, we have to allocate the DIR object with
372 @c __alloc_dir, that calls malloc.
373 The @code{opendir} function opens and returns a directory stream for
374 reading the directory whose file name is @var{dirname}. The stream has
377 If unsuccessful, @code{opendir} returns a null pointer. In addition to
378 the usual file name errors (@pxref{File Name Errors}), the
379 following @code{errno} error conditions are defined for this function:
383 Read permission is denied for the directory named by @code{dirname}.
386 The process has too many files open.
389 The entire system, or perhaps the file system which contains the
390 directory, cannot support any additional open files at the moment.
391 (This problem cannot happen on @gnuhurdsystems{}.)
394 Not enough memory available.
397 The @code{DIR} type is typically implemented using a file descriptor,
398 and the @code{opendir} function in terms of the @code{open} function.
399 @xref{Low-Level I/O}. Directory streams and the underlying
400 file descriptors are closed on @code{exec} (@pxref{Executing a File}).
403 The directory which is opened for reading by @code{opendir} is
404 identified by the name. In some situations this is not sufficient.
405 Or the way @code{opendir} implicitly creates a file descriptor for the
406 directory is not the way a program might want it. In these cases an
407 alternative interface can be used.
409 @deftypefun {DIR *} fdopendir (int @var{fd})
410 @standards{GNU, dirent.h}
411 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
412 @c The DIR object is allocated with __alloc_dir, that calls malloc.
413 The @code{fdopendir} function works just like @code{opendir} but
414 instead of taking a file name and opening a file descriptor for the
415 directory the caller is required to provide a file descriptor. This
416 file descriptor is then used in subsequent uses of the returned
417 directory stream object.
419 The caller must make sure the file descriptor is associated with a
420 directory and it allows reading.
422 If the @code{fdopendir} call returns successfully the file descriptor
423 is now under the control of the system. It can be used in the same
424 way the descriptor implicitly created by @code{opendir} can be used
425 but the program must not close the descriptor.
427 In case the function is unsuccessful it returns a null pointer and the
428 file descriptor remains to be usable by the program. The following
429 @code{errno} error conditions are defined for this function:
433 The file descriptor is not valid.
436 The file descriptor is not associated with a directory.
439 The descriptor does not allow reading the directory content.
442 Not enough memory available.
446 In some situations it can be desirable to get hold of the file
447 descriptor which is created by the @code{opendir} call. For instance,
448 to switch the current working directory to the directory just read the
449 @code{fchdir} function could be used. Historically the @code{DIR} type
450 was exposed and programs could access the fields. This does not happen
451 in @theglibc{}. Instead a separate function is provided to allow
454 @deftypefun int dirfd (DIR *@var{dirstream})
455 @standards{GNU, dirent.h}
456 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
457 The function @code{dirfd} returns the file descriptor associated with
458 the directory stream @var{dirstream}. This descriptor can be used until
459 the directory is closed with @code{closedir}. If the directory stream
460 implementation is not using file descriptors the return value is
464 @node Reading/Closing Directory
465 @subsection Reading and Closing a Directory Stream
468 This section describes how to read directory entries from a directory
469 stream, and how to close the stream when you are done with it. All the
470 symbols are declared in the header file @file{dirent.h}.
472 @deftypefun {struct dirent *} readdir (DIR *@var{dirstream})
473 @standards{POSIX.1, dirent.h}
474 @safety{@prelim{}@mtsafe{}@asunsafe{@asulock{}}@acunsafe{@aculock{}}}
475 @c This function holds dirstream's non-recursive lock, which brings
476 @c about the usual issues with locks and async signals and cancellation,
477 @c but the lock taking is not enough to make the returned value safe to
478 @c use, since it points to a stream's internal buffer that can be
479 @c overwritten by subsequent calls or even released by closedir.
480 This function reads the next entry from the directory. It normally
481 returns a pointer to a structure containing information about the
482 file. This structure is associated with the @var{dirstream} handle
483 and can be rewritten by a subsequent call.
485 @strong{Portability Note:} On some systems @code{readdir} may not
486 return entries for @file{.} and @file{..}, even though these are always
487 valid file names in any directory. @xref{File Name Resolution}.
489 If there are no more entries in the directory or an error is detected,
490 @code{readdir} returns a null pointer. The following @code{errno} error
491 conditions are defined for this function:
495 The @var{dirstream} argument is not valid.
498 To distinguish between an end-of-directory condition or an error, you
499 must set @code{errno} to zero before calling @code{readdir}. To avoid
500 entering an infinite loop, you should stop reading from the directory
501 after the first error.
503 @strong{Caution:} The pointer returned by @code{readdir} points to
504 a buffer within the @code{DIR} object. The data in that buffer will
505 be overwritten by the next call to @code{readdir}. You must take care,
506 for instance, to copy the @code{d_name} string if you need it later.
508 Because of this, it is not safe to share a @code{DIR} object among
509 multiple threads, unless you use your own locking to ensure that
510 no thread calls @code{readdir} while another thread is still using the
511 data from the previous call. In @theglibc{}, it is safe to call
512 @code{readdir} from multiple threads as long as each thread uses
513 its own @code{DIR} object. POSIX.1-2008 does not require this to
514 be safe, but we are not aware of any operating systems where it
517 @code{readdir_r} allows you to provide your own buffer for the
518 @code{struct dirent}, but it is less portable than @code{readdir}, and
519 has problems with very long filenames (see below). We recommend
520 you use @code{readdir}, but do not share @code{DIR} objects.
523 @deftypefun int readdir_r (DIR *@var{dirstream}, struct dirent *@var{entry}, struct dirent **@var{result})
524 @standards{GNU, dirent.h}
525 @safety{@prelim{}@mtsafe{}@asunsafe{@asulock{}}@acunsafe{@aculock{}}}
526 This function is a version of @code{readdir} which performs internal
527 locking. Like @code{readdir} it returns the next entry from the
528 directory. To prevent conflicts between simultaneously running
529 threads the result is stored inside the @var{entry} object.
531 @strong{Portability Note:} @code{readdir_r} is deprecated. It is
532 recommended to use @code{readdir} instead of @code{readdir_r} for the
537 On systems which do not define @code{NAME_MAX}, it may not be possible
538 to use @code{readdir_r} safely because the caller does not specify the
539 length of the buffer for the directory entry.
542 On some systems, @code{readdir_r} cannot read directory entries with
543 very long names. If such a name is encountered, @theglibc{}
544 implementation of @code{readdir_r} returns with an error code of
545 @code{ENAMETOOLONG} after the final directory entry has been read. On
546 other systems, @code{readdir_r} may return successfully, but the
547 @code{d_name} member may not be NUL-terminated or may be truncated.
550 POSIX-1.2008 does not guarantee that @code{readdir} is thread-safe,
551 even when access to the same @var{dirstream} is serialized. But in
552 current implementations (including @theglibc{}), it is safe to call
553 @code{readdir} concurrently on different @var{dirstream}s, so there is
554 no need to use @code{readdir_r} in most multi-threaded programs. In
555 the rare case that multiple threads need to read from the same
556 @var{dirstream}, it is still better to use @code{readdir} and external
560 It is expected that future versions of POSIX will obsolete
561 @code{readdir_r} and mandate the level of thread safety for
562 @code{readdir} which is provided by @theglibc{} and other
563 implementations today.
566 Normally @code{readdir_r} returns zero and sets @code{*@var{result}}
567 to @var{entry}. If there are no more entries in the directory or an
568 error is detected, @code{readdir_r} sets @code{*@var{result}} to a
569 null pointer and returns a nonzero error code, also stored in
570 @code{errno}, as described for @code{readdir}.
572 It is also important to look at the definition of the @code{struct
573 dirent} type. Simply passing a pointer to an object of this type for
574 the second parameter of @code{readdir_r} might not be enough. Some
575 systems don't define the @code{d_name} element sufficiently long. In
576 this case the user has to provide additional space. There must be room
577 for at least @code{NAME_MAX + 1} characters in the @code{d_name} array.
578 Code to call @code{readdir_r} could look like this:
584 char b[offsetof (struct dirent, d_name) + NAME_MAX + 1];
587 if (readdir_r (dir, &u.d, &res) == 0)
592 To support large filesystems on 32-bit machines there are LFS variants
593 of the last two functions.
595 @deftypefun {struct dirent64 *} readdir64 (DIR *@var{dirstream})
596 @standards{LFS, dirent.h}
597 @safety{@prelim{}@mtsafe{}@asunsafe{@asulock{}}@acunsafe{@aculock{}}}
598 The @code{readdir64} function is just like the @code{readdir} function
599 except that it returns a pointer to a record of type @code{struct
600 dirent64}. Some of the members of this data type (notably @code{d_ino})
601 might have a different size to allow large filesystems.
603 In all other aspects this function is equivalent to @code{readdir}.
606 @deftypefun int readdir64_r (DIR *@var{dirstream}, struct dirent64 *@var{entry}, struct dirent64 **@var{result})
607 @standards{LFS, dirent.h}
608 @safety{@prelim{}@mtsafe{}@asunsafe{@asulock{}}@acunsafe{@aculock{}}}
609 The deprecated @code{readdir64_r} function is equivalent to the
610 @code{readdir_r} function except that it takes parameters of base type
611 @code{struct dirent64} instead of @code{struct dirent} in the second and
612 third position. The same precautions mentioned in the documentation of
613 @code{readdir_r} also apply here.
616 @deftypefun int closedir (DIR *@var{dirstream})
617 @standards{POSIX.1, dirent.h}
618 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{} @asulock{/hurd}}@acunsafe{@acsmem{} @acsfd{} @aculock{/hurd}}}
619 @c No synchronization in the posix implementation, only in the hurd
620 @c one. This is regarded as safe because it is undefined behavior if
621 @c other threads could still be using the dir stream while it's closed.
622 This function closes the directory stream @var{dirstream}. It returns
623 @code{0} on success and @code{-1} on failure.
625 The following @code{errno} error conditions are defined for this
630 The @var{dirstream} argument is not valid.
634 @node Simple Directory Lister
635 @subsection Simple Program to List a Directory
637 Here's a simple program that prints the names of the files in
638 the current working directory:
644 The order in which files appear in a directory tends to be fairly
645 random. A more useful program would sort the entries (perhaps by
646 alphabetizing them) before printing them; see
647 @ref{Scanning Directory Content}, and @ref{Array Sort Function}.
650 @node Random Access Directory
651 @subsection Random Access in a Directory Stream
654 This section describes how to reread parts of a directory that you have
655 already read from an open directory stream. All the symbols are
656 declared in the header file @file{dirent.h}.
658 @deftypefun void rewinddir (DIR *@var{dirstream})
659 @standards{POSIX.1, dirent.h}
660 @safety{@prelim{}@mtsafe{}@asunsafe{@asulock{}}@acunsafe{@aculock{}}}
661 The @code{rewinddir} function is used to reinitialize the directory
662 stream @var{dirstream}, so that if you call @code{readdir} it
663 returns information about the first entry in the directory again. This
664 function also notices if files have been added or removed to the
665 directory since it was opened with @code{opendir}. (Entries for these
666 files might or might not be returned by @code{readdir} if they were
667 added or removed since you last called @code{opendir} or
671 @deftypefun {long int} telldir (DIR *@var{dirstream})
672 @standards{BSD, dirent.h}
673 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{/bsd} @asulock{/bsd}}@acunsafe{@acsmem{/bsd} @aculock{/bsd}}}
674 @c The implementation is safe on most platforms, but on BSD it uses
675 @c cookies, buckets and records, and the global array of pointers to
676 @c dynamically allocated records is guarded by a non-recursive lock.
677 The @code{telldir} function returns the file position of the directory
678 stream @var{dirstream}. You can use this value with @code{seekdir} to
679 restore the directory stream to that position.
682 @deftypefun void seekdir (DIR *@var{dirstream}, long int @var{pos})
683 @standards{BSD, dirent.h}
684 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{/bsd} @asulock{/bsd}}@acunsafe{@acsmem{/bsd} @aculock{/bsd}}}
685 @c The implementation is safe on most platforms, but on BSD it uses
686 @c cookies, buckets and records, and the global array of pointers to
687 @c dynamically allocated records is guarded by a non-recursive lock.
688 The @code{seekdir} function sets the file position of the directory
689 stream @var{dirstream} to @var{pos}. The value @var{pos} must be the
690 result of a previous call to @code{telldir} on this particular stream;
691 closing and reopening the directory can invalidate values returned by
696 @node Scanning Directory Content
697 @subsection Scanning the Content of a Directory
699 A higher-level interface to the directory handling functions is the
700 @code{scandir} function. With its help one can select a subset of the
701 entries in a directory, possibly sort them and get a list of names as
704 @deftypefun int scandir (const char *@var{dir}, struct dirent ***@var{namelist}, int (*@var{selector}) (const struct dirent *), int (*@var{cmp}) (const struct dirent **, const struct dirent **))
705 @standards{BSD, dirent.h}
706 @standards{SVID, dirent.h}
707 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
708 @c The scandir function calls __opendirat, __readdir, and __closedir to
709 @c go over the named dir; malloc and realloc to allocate the namelist
710 @c and copies of each selected dirent, besides the selector, if given,
711 @c and qsort and the cmp functions if the latter is given. In spite of
712 @c the cleanup handler that releases memory and the file descriptor in
713 @c case of synchronous cancellation, an asynchronous cancellation may
714 @c still leak memory and a file descriptor. Although readdir is unsafe
715 @c in general, the use of an internal dir stream for sequential scanning
716 @c of the directory with copying of dirents before subsequent calls
717 @c makes the use safe, and the fact that the dir stream is private to
718 @c each scandir call does away with the lock issues in readdir and
721 The @code{scandir} function scans the contents of the directory selected
722 by @var{dir}. The result in *@var{namelist} is an array of pointers to
723 structures of type @code{struct dirent} which describe all selected
724 directory entries and which is allocated using @code{malloc}. Instead
725 of always getting all directory entries returned, the user supplied
726 function @var{selector} can be used to decide which entries are in the
727 result. Only the entries for which @var{selector} returns a non-zero
730 Finally the entries in *@var{namelist} are sorted using the
731 user-supplied function @var{cmp}. The arguments passed to the @var{cmp}
732 function are of type @code{struct dirent **}, therefore one cannot
733 directly use the @code{strcmp} or @code{strcoll} functions; instead see
734 the functions @code{alphasort} and @code{versionsort} below.
736 The return value of the function is the number of entries placed in
737 *@var{namelist}. If it is @code{-1} an error occurred (either the
738 directory could not be opened for reading or memory allocation failed) and
739 the global variable @code{errno} contains more information on the error.
742 As described above, the fourth argument to the @code{scandir} function
743 must be a pointer to a sorting function. For the convenience of the
744 programmer @theglibc{} contains implementations of functions which
745 are very helpful for this purpose.
747 @deftypefun int alphasort (const struct dirent **@var{a}, const struct dirent **@var{b})
748 @standards{BSD, dirent.h}
749 @standards{SVID, dirent.h}
750 @safety{@prelim{}@mtsafe{@mtslocale{}}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{}}}
752 The @code{alphasort} function behaves like the @code{strcoll} function
753 (@pxref{String/Array Comparison}). The difference is that the arguments
754 are not string pointers but instead they are of type
755 @code{struct dirent **}.
757 The return value of @code{alphasort} is less than, equal to, or greater
758 than zero depending on the order of the two entries @var{a} and @var{b}.
761 @deftypefun int versionsort (const struct dirent **@var{a}, const struct dirent **@var{b})
762 @standards{GNU, dirent.h}
763 @safety{@prelim{}@mtsafe{@mtslocale{}}@assafe{}@acsafe{}}
764 @c Calls strverscmp, which will accesses the locale object multiple
766 The @code{versionsort} function is like @code{alphasort} except that it
767 uses the @code{strverscmp} function internally.
770 If the filesystem supports large files we cannot use the @code{scandir}
771 anymore since the @code{dirent} structure might not able to contain all
772 the information. The LFS provides the new type @w{@code{struct
773 dirent64}}. To use this we need a new function.
775 @deftypefun int scandir64 (const char *@var{dir}, struct dirent64 ***@var{namelist}, int (*@var{selector}) (const struct dirent64 *), int (*@var{cmp}) (const struct dirent64 **, const struct dirent64 **))
776 @standards{GNU, dirent.h}
777 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
779 The @code{scandir64} function works like the @code{scandir} function
780 except that the directory entries it returns are described by elements
781 of type @w{@code{struct dirent64}}. The function pointed to by
782 @var{selector} is again used to select the desired entries, except that
783 @var{selector} now must point to a function which takes a
784 @w{@code{struct dirent64 *}} parameter.
786 Similarly the @var{cmp} function should expect its two arguments to be
787 of type @code{struct dirent64 **}.
790 As @var{cmp} is now a function of a different type, the functions
791 @code{alphasort} and @code{versionsort} cannot be supplied for that
792 argument. Instead we provide the two replacement functions below.
794 @deftypefun int alphasort64 (const struct dirent64 **@var{a}, const struct dirent **@var{b})
795 @standards{GNU, dirent.h}
796 @safety{@prelim{}@mtsafe{@mtslocale{}}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{}}}
798 The @code{alphasort64} function behaves like the @code{strcoll} function
799 (@pxref{String/Array Comparison}). The difference is that the arguments
800 are not string pointers but instead they are of type
801 @code{struct dirent64 **}.
803 Return value of @code{alphasort64} is less than, equal to, or greater
804 than zero depending on the order of the two entries @var{a} and @var{b}.
807 @deftypefun int versionsort64 (const struct dirent64 **@var{a}, const struct dirent64 **@var{b})
808 @standards{GNU, dirent.h}
809 @safety{@prelim{}@mtsafe{@mtslocale{}}@assafe{}@acsafe{}}
811 The @code{versionsort64} function is like @code{alphasort64}, excepted that it
812 uses the @code{strverscmp} function internally.
815 It is important not to mix the use of @code{scandir} and the 64-bit
816 comparison functions or vice versa. There are systems on which this
817 works but on others it will fail miserably.
819 @node Simple Directory Lister Mark II
820 @subsection Simple Program to List a Directory, Mark II
822 Here is a revised version of the directory lister found above
823 (@pxref{Simple Directory Lister}). Using the @code{scandir} function we
824 can avoid the functions which work directly with the directory contents.
825 After the call the returned entries are available for direct use.
831 Note the simple selector function in this example. Since we want to see
832 all directory entries we always return @code{1}.
834 @node Low-level Directory Access
835 @subsection Low-level Directory Access
837 The stream-based directory functions are not AS-Safe and cannot be
838 used after @code{vfork}. @xref{POSIX Safety Concepts}. The functions
839 below provide an alternative that can be used in these contexts.
841 Directory data is obtained from a file descriptor, as created by the
842 @code{open} function, with or without the @code{O_DIRECTORY} flag.
843 @xref{Opening and Closing Files}.
845 @deftypefun ssize_t getdents64 (int @var{fd}, void *@var{buffer}, size_t @var{length})
846 @standards{Linux, dirent.h}
847 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
848 The @code{getdents64} function reads at most @var{length} bytes of
849 directory entry data from the file descriptor @var{fd} and stores it
850 into the byte array starting at @var{buffer}.
852 On success, the function returns the number of bytes written to the
853 buffer. This number is zero if @var{fd} is already at the end of the
854 directory stream. On error, the function returns @code{-1} and sets
855 @code{errno} to the appropriate error code.
857 The data is stored as a sequence of @code{struct dirent64} records,
858 which can be traversed using the @code{d_reclen} member. The buffer
859 should be large enough to hold the largest possible directory entry.
860 Note that some file systems support file names longer than
861 @code{NAME_MAX} bytes (e.g., because they support up to 255 Unicode
862 characters), so a buffer size of at least 1024 is recommended.
864 This function is specific to Linux.
868 @node Working with Directory Trees
869 @section Working with Directory Trees
870 @cindex directory hierarchy
871 @cindex hierarchy, directory
872 @cindex tree, directory
874 The functions described so far for handling the files in a directory
875 have allowed you to either retrieve the information bit by bit, or to
876 process all the files as a group (see @code{scandir}). Sometimes it is
877 useful to process whole hierarchies of directories and their contained
878 files. The X/Open specification defines two functions to do this. The
879 simpler form is derived from an early definition in @w{System V} systems
880 and therefore this function is available on SVID-derived systems. The
881 prototypes and required definitions can be found in the @file{ftw.h}
884 There are four functions in this family: @code{ftw}, @code{nftw} and
885 their 64-bit counterparts @code{ftw64} and @code{nftw64}. These
886 functions take as one of their arguments a pointer to a callback
887 function of the appropriate type.
889 @deftp {Data Type} __ftw_func_t
890 @standards{GNU, ftw.h}
893 int (*) (const char *, const struct stat *, int)
896 The type of callback functions given to the @code{ftw} function. The
897 first parameter points to the file name, the second parameter to an
898 object of type @code{struct stat} which is filled in for the file named
899 in the first parameter.
902 The last parameter is a flag giving more information about the current
903 file. It can have the following values:
907 The item is either a normal file or a file which does not fit into one
908 of the following categories. This could be special files, sockets etc.
910 The item is a directory.
912 The @code{stat} call failed and so the information pointed to by the
913 second parameter is invalid.
915 The item is a directory which cannot be read.
917 The item is a symbolic link. Since symbolic links are normally followed
918 seeing this value in a @code{ftw} callback function means the referenced
919 file does not exist. The situation for @code{nftw} is different.
921 This value is only available if the program is compiled with
922 @code{_XOPEN_EXTENDED} defined before including
923 the first header. The original SVID systems do not have symbolic links.
926 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
927 type is in fact @code{__ftw64_func_t} since this mode changes
928 @code{struct stat} to be @code{struct stat64}.
931 For the LFS interface and for use in the function @code{ftw64}, the
932 header @file{ftw.h} defines another function type.
934 @deftp {Data Type} __ftw64_func_t
935 @standards{GNU, ftw.h}
938 int (*) (const char *, const struct stat64 *, int)
941 This type is used just like @code{__ftw_func_t} for the callback
942 function, but this time is called from @code{ftw64}. The second
943 parameter to the function is a pointer to a variable of type
944 @code{struct stat64} which is able to represent the larger values.
947 @deftp {Data Type} __nftw_func_t
948 @standards{GNU, ftw.h}
951 int (*) (const char *, const struct stat *, int, struct FTW *)
954 The first three arguments are the same as for the @code{__ftw_func_t}
955 type. However for the third argument some additional values are defined
956 to allow finer differentiation:
959 The current item is a directory and all subdirectories have already been
960 visited and reported. This flag is returned instead of @code{FTW_D} if
961 the @code{FTW_DEPTH} flag is passed to @code{nftw} (see below).
963 The current item is a stale symbolic link. The file it points to does
967 The last parameter of the callback function is a pointer to a structure
968 with some extra information as described below.
970 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
971 type is in fact @code{__nftw64_func_t} since this mode changes
972 @code{struct stat} to be @code{struct stat64}.
975 For the LFS interface there is also a variant of this data type
976 available which has to be used with the @code{nftw64} function.
978 @deftp {Data Type} __nftw64_func_t
979 @standards{GNU, ftw.h}
982 int (*) (const char *, const struct stat64 *, int, struct FTW *)
985 This type is used just like @code{__nftw_func_t} for the callback
986 function, but this time is called from @code{nftw64}. The second
987 parameter to the function is this time a pointer to a variable of type
988 @code{struct stat64} which is able to represent the larger values.
991 @deftp {Data Type} {struct FTW}
992 @standards{XPG4.2, ftw.h}
993 The information contained in this structure helps in interpreting the
994 name parameter and gives some information about the current state of the
995 traversal of the directory hierarchy.
999 The value is the offset into the string passed in the first parameter to
1000 the callback function of the beginning of the file name. The rest of
1001 the string is the path of the file. This information is especially
1002 important if the @code{FTW_CHDIR} flag was set in calling @code{nftw}
1003 since then the current directory is the one the current item is found
1006 Whilst processing, the code tracks how many directories down it has gone
1007 to find the current file. This nesting level starts at @math{0} for
1008 files in the initial directory (or is zero for the initial file if a
1014 @deftypefun int ftw (const char *@var{filename}, __ftw_func_t @var{func}, int @var{descriptors})
1015 @standards{SVID, ftw.h}
1016 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
1017 @c see nftw for safety details
1018 The @code{ftw} function calls the callback function given in the
1019 parameter @var{func} for every item which is found in the directory
1020 specified by @var{filename} and all directories below. The function
1021 follows symbolic links if necessary but does not process an item twice.
1022 If @var{filename} is not a directory then it itself is the only object
1023 returned to the callback function.
1025 The file name passed to the callback function is constructed by taking
1026 the @var{filename} parameter and appending the names of all passed
1027 directories and then the local file name. So the callback function can
1028 use this parameter to access the file. @code{ftw} also calls
1029 @code{stat} for the file and passes that information on to the callback
1030 function. If this @code{stat} call is not successful the failure is
1031 indicated by setting the third argument of the callback function to
1032 @code{FTW_NS}. Otherwise it is set according to the description given
1033 in the account of @code{__ftw_func_t} above.
1035 The callback function is expected to return @math{0} to indicate that no
1036 error occurred and that processing should continue. If an error
1037 occurred in the callback function or it wants @code{ftw} to return
1038 immediately, the callback function can return a value other than
1039 @math{0}. This is the only correct way to stop the function. The
1040 program must not use @code{setjmp} or similar techniques to continue
1041 from another place. This would leave resources allocated by the
1042 @code{ftw} function unfreed.
1044 The @var{descriptors} parameter to @code{ftw} specifies how many file
1045 descriptors it is allowed to consume. The function runs faster the more
1046 descriptors it can use. For each level in the directory hierarchy at
1047 most one descriptor is used, but for very deep ones any limit on open
1048 file descriptors for the process or the system may be exceeded.
1049 Moreover, file descriptor limits in a multi-threaded program apply to
1050 all the threads as a group, and therefore it is a good idea to supply a
1051 reasonable limit to the number of open descriptors.
1053 The return value of the @code{ftw} function is @math{0} if all callback
1054 function calls returned @math{0} and all actions performed by the
1055 @code{ftw} succeeded. If a function call failed (other than calling
1056 @code{stat} on an item) the function returns @math{-1}. If a callback
1057 function returns a value other than @math{0} this value is returned as
1058 the return value of @code{ftw}.
1060 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
1061 32-bit system this function is in fact @code{ftw64}, i.e., the LFS
1062 interface transparently replaces the old interface.
1065 @deftypefun int ftw64 (const char *@var{filename}, __ftw64_func_t @var{func}, int @var{descriptors})
1066 @standards{Unix98, ftw.h}
1067 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
1068 This function is similar to @code{ftw} but it can work on filesystems
1069 with large files. File information is reported using a variable of type
1070 @code{struct stat64} which is passed by reference to the callback
1073 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
1074 32-bit system this function is available under the name @code{ftw} and
1075 transparently replaces the old implementation.
1078 @deftypefun int nftw (const char *@var{filename}, __nftw_func_t @var{func}, int @var{descriptors}, int @var{flag})
1079 @standards{XPG4.2, ftw.h}
1080 @safety{@prelim{}@mtsafe{@mtasscwd{}}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{} @acscwd{}}}
1081 @c ftw_startup calls alloca, malloc, free, xstat/lxstat, tdestroy, and ftw_dir
1082 @c if FTW_CHDIR, call open, and fchdir, or chdir and getcwd
1083 @c ftw_dir calls open_dir_stream, readdir64, process_entry, closedir
1084 @c if FTW_CHDIR, also calls fchdir
1085 @c open_dir_stream calls malloc, realloc, readdir64, free, closedir,
1086 @c then openat64_not_cancel_3 and fdopendir or opendir, then dirfd.
1087 @c process_entry may cal realloc, fxstatat/lxstat/xstat, ftw_dir, and
1088 @c find_object (tsearch) and add_object (tfind).
1089 @c Since each invocation of *ftw uses its own private search tree, none
1090 @c of the search tree concurrency issues apply.
1091 The @code{nftw} function works like the @code{ftw} functions. They call
1092 the callback function @var{func} for all items found in the directory
1093 @var{filename} and below. At most @var{descriptors} file descriptors
1094 are consumed during the @code{nftw} call.
1096 One difference is that the callback function is of a different type. It
1097 is of type @w{@code{struct FTW *}} and provides the callback function
1098 with the extra information described above.
1100 A second difference is that @code{nftw} takes a fourth argument, which
1101 is @math{0} or a bitwise-OR combination of any of the following values.
1105 While traversing the directory symbolic links are not followed. Instead
1106 symbolic links are reported using the @code{FTW_SL} value for the type
1107 parameter to the callback function. If the file referenced by a
1108 symbolic link does not exist @code{FTW_SLN} is returned instead.
1110 The callback function is only called for items which are on the same
1111 mounted filesystem as the directory given by the @var{filename}
1112 parameter to @code{nftw}.
1114 If this flag is given the current working directory is changed to the
1115 directory of the reported object before the callback function is called.
1116 When @code{ntfw} finally returns the current directory is restored to
1119 If this option is specified then all subdirectories and files within
1120 them are processed before processing the top directory itself
1121 (depth-first processing). This also means the type flag given to the
1122 callback function is @code{FTW_DP} and not @code{FTW_D}.
1123 @item FTW_ACTIONRETVAL
1124 If this option is specified then return values from callbacks
1125 are handled differently. If the callback returns @code{FTW_CONTINUE},
1126 walking continues normally. @code{FTW_STOP} means walking stops
1127 and @code{FTW_STOP} is returned to the caller. If @code{FTW_SKIP_SUBTREE}
1128 is returned by the callback with @code{FTW_D} argument, the subtree
1129 is skipped and walking continues with next sibling of the directory.
1130 If @code{FTW_SKIP_SIBLINGS} is returned by the callback, all siblings
1131 of the current entry are skipped and walking continues in its parent.
1132 No other return values should be returned from the callbacks if
1133 this option is set. This option is a GNU extension.
1136 The return value is computed in the same way as for @code{ftw}.
1137 @code{nftw} returns @math{0} if no failures occurred and all callback
1138 functions returned @math{0}. In case of internal errors, such as memory
1139 problems, the return value is @math{-1} and @code{errno} is set
1140 accordingly. If the return value of a callback invocation was non-zero
1141 then that value is returned.
1143 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
1144 32-bit system this function is in fact @code{nftw64}, i.e., the LFS
1145 interface transparently replaces the old interface.
1148 @deftypefun int nftw64 (const char *@var{filename}, __nftw64_func_t @var{func}, int @var{descriptors}, int @var{flag})
1149 @standards{Unix98, ftw.h}
1150 @safety{@prelim{}@mtsafe{@mtasscwd{}}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{} @acscwd{}}}
1151 This function is similar to @code{nftw} but it can work on filesystems
1152 with large files. File information is reported using a variable of type
1153 @code{struct stat64} which is passed by reference to the callback
1156 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
1157 32-bit system this function is available under the name @code{nftw} and
1158 transparently replaces the old implementation.
1166 @cindex multiple names for one file
1167 @cindex file names, multiple
1169 In POSIX systems, one file can have many names at the same time. All of
1170 the names are equally real, and no one of them is preferred to the
1173 To add a name to a file, use the @code{link} function. (The new name is
1174 also called a @dfn{hard link} to the file.) Creating a new link to a
1175 file does not copy the contents of the file; it simply makes a new name
1176 by which the file can be known, in addition to the file's existing name
1179 One file can have names in several directories, so the organization
1180 of the file system is not a strict hierarchy or tree.
1182 In most implementations, it is not possible to have hard links to the
1183 same file in multiple file systems. @code{link} reports an error if you
1184 try to make a hard link to the file from another file system when this
1187 The prototype for the @code{link} function is declared in the header
1188 file @file{unistd.h}.
1191 @deftypefun int link (const char *@var{oldname}, const char *@var{newname})
1192 @standards{POSIX.1, unistd.h}
1193 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1194 The @code{link} function makes a new link to the existing file named by
1195 @var{oldname}, under the new name @var{newname}.
1197 This function returns a value of @code{0} if it is successful and
1198 @code{-1} on failure. In addition to the usual file name errors
1199 (@pxref{File Name Errors}) for both @var{oldname} and @var{newname}, the
1200 following @code{errno} error conditions are defined for this function:
1204 You are not allowed to write to the directory in which the new link is
1207 Some implementations also require that the existing file be accessible
1208 by the caller, and use this error to report failure for that reason.
1212 There is already a file named @var{newname}. If you want to replace
1213 this link with a new link, you must remove the old link explicitly first.
1216 There are already too many links to the file named by @var{oldname}.
1217 (The maximum number of links to a file is @w{@code{LINK_MAX}}; see
1218 @ref{Limits for Files}.)
1221 The file named by @var{oldname} doesn't exist. You can't make a link to
1222 a file that doesn't exist.
1225 The directory or file system that would contain the new link is full
1226 and cannot be extended.
1229 On @gnulinuxhurdsystems{} and some others, you cannot make links to
1231 Many systems allow only privileged users to do so. This error
1232 is used to report the problem.
1235 The directory containing the new link can't be modified because it's on
1236 a read-only file system.
1239 The directory specified in @var{newname} is on a different file system
1240 than the existing file.
1243 A hardware error occurred while trying to read or write the to filesystem.
1247 @deftypefun int linkat (int oldfd, const char *@var{oldname}, int newfd, const char *@var{newname}, int flags)
1248 @standards{POSIX.1, unistd.h}
1249 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1251 The @code{linkat} function is analogous to the @code{link} function,
1252 except that it identifies its source and target using a combination of a
1253 file descriptor (referring to a directory) and a pathname. If a
1254 pathnames is not absolute, it is resolved relative to the corresponding
1255 file descriptor. The special file descriptor @code{AT_FDCWD} denotes
1256 the current directory.
1258 The @var{flags} argument is a combination of the following flags:
1261 @item AT_SYMLINK_FOLLOW
1262 If the source path identified by @var{oldfd} and @var{oldname} is a
1263 symbolic link, @code{linkat} follows the symbolic link and creates a
1264 link to its target. If the flag is not set, a link for the symbolic
1265 link itself is created; this is not supported by all file systems and
1266 @code{linkat} can fail in this case.
1269 If this flag is specified, @var{oldname} can be an empty string. In
1270 this case, a new link to the file denoted by the descriptor @var{oldfd}
1271 is created, which may have been opened with @code{O_PATH} or
1272 @code{O_TMPFILE}. This flag is a GNU extension.
1276 @node Symbolic Links
1277 @section Symbolic Links
1280 @cindex symbolic link
1281 @cindex link, symbolic
1283 @gnusystems{} support @dfn{soft links} or @dfn{symbolic links}. This
1284 is a kind of ``file'' that is essentially a pointer to another file
1285 name. Unlike hard links, symbolic links can be made to directories or
1286 across file systems with no restrictions. You can also make a symbolic
1287 link to a name which is not the name of any file. (Opening this link
1288 will fail until a file by that name is created.) Likewise, if the
1289 symbolic link points to an existing file which is later deleted, the
1290 symbolic link continues to point to the same file name even though the
1291 name no longer names any file.
1293 The reason symbolic links work the way they do is that special things
1294 happen when you try to open the link. The @code{open} function realizes
1295 you have specified the name of a link, reads the file name contained in
1296 the link, and opens that file name instead. The @code{stat} function
1297 likewise operates on the file that the symbolic link points to, instead
1298 of on the link itself.
1300 By contrast, other operations such as deleting or renaming the file
1301 operate on the link itself. The functions @code{readlink} and
1302 @code{lstat} also refrain from following symbolic links, because their
1303 purpose is to obtain information about the link. @code{link}, the
1304 function that makes a hard link, does too. It makes a hard link to the
1305 symbolic link, which one rarely wants.
1307 Some systems have, for some functions operating on files, a limit on
1308 how many symbolic links are followed when resolving a path name. The
1309 limit if it exists is published in the @file{sys/param.h} header file.
1311 @deftypevr Macro int MAXSYMLINKS
1312 @standards{BSD, sys/param.h}
1314 The macro @code{MAXSYMLINKS} specifies how many symlinks some function
1315 will follow before returning @code{ELOOP}. Not all functions behave the
1316 same and this value is not the same as that returned for
1317 @code{_SC_SYMLOOP} by @code{sysconf}. In fact, the @code{sysconf}
1318 result can indicate that there is no fixed limit although
1319 @code{MAXSYMLINKS} exists and has a finite value.
1322 Prototypes for most of the functions listed in this section are in
1326 @deftypefun int symlink (const char *@var{oldname}, const char *@var{newname})
1327 @standards{BSD, unistd.h}
1328 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1329 The @code{symlink} function makes a symbolic link to @var{oldname} named
1332 The normal return value from @code{symlink} is @code{0}. A return value
1333 of @code{-1} indicates an error. In addition to the usual file name
1334 syntax errors (@pxref{File Name Errors}), the following @code{errno}
1335 error conditions are defined for this function:
1339 There is already an existing file named @var{newname}.
1342 The file @var{newname} would exist on a read-only file system.
1345 The directory or file system cannot be extended to make the new link.
1348 A hardware error occurred while reading or writing data on the disk.
1350 @comment not sure about these
1353 There are too many levels of indirection. This can be the result of
1354 circular symbolic links to directories.
1357 The new link can't be created because the user's disk quota has been
1363 @deftypefun ssize_t readlink (const char *@var{filename}, char *@var{buffer}, size_t @var{size})
1364 @standards{BSD, unistd.h}
1365 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1366 The @code{readlink} function gets the value of the symbolic link
1367 @var{filename}. The file name that the link points to is copied into
1368 @var{buffer}. This file name string is @emph{not} null-terminated;
1369 @code{readlink} normally returns the number of characters copied. The
1370 @var{size} argument specifies the maximum number of characters to copy,
1371 usually the allocation size of @var{buffer}.
1373 If the return value equals @var{size}, you cannot tell whether or not
1374 there was room to return the entire name. So make a bigger buffer and
1375 call @code{readlink} again. Here is an example:
1379 readlink_malloc (const char *filename)
1382 char *buffer = NULL;
1386 buffer = xreallocarray (buffer, size, 2);
1388 ssize_t nchars = readlink (filename, buffer, size);
1400 @c @group Invalid outside example.
1401 A value of @code{-1} is returned in case of error. In addition to the
1402 usual file name errors (@pxref{File Name Errors}), the following
1403 @code{errno} error conditions are defined for this function:
1407 The named file is not a symbolic link.
1410 A hardware error occurred while reading or writing data on the disk.
1415 In some situations it is desirable to resolve all the
1416 symbolic links to get the real
1417 name of a file where no prefix names a symbolic link which is followed
1418 and no filename in the path is @code{.} or @code{..}. This is for
1419 instance desirable if files have to be compared in which case different
1420 names can refer to the same inode.
1422 @deftypefun {char *} canonicalize_file_name (const char *@var{name})
1423 @standards{GNU, stdlib.h}
1424 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
1427 The @code{canonicalize_file_name} function returns the absolute name of
1428 the file named by @var{name} which contains no @code{.}, @code{..}
1429 components nor any repeated path separators (@code{/}) or symlinks. The
1430 result is passed back as the return value of the function in a block of
1431 memory allocated with @code{malloc}. If the result is not used anymore
1432 the memory should be freed with a call to @code{free}.
1434 If any of the path components are missing the function returns a NULL
1435 pointer. This is also what is returned if the length of the path
1436 reaches or exceeds @code{PATH_MAX} characters. In any case
1437 @code{errno} is set accordingly.
1441 The resulting path is too long. This error only occurs on systems which
1442 have a limit on the file name length.
1445 At least one of the path components is not readable.
1448 The input file name is empty.
1451 At least one of the path components does not exist.
1454 More than @code{MAXSYMLINKS} many symlinks have been followed.
1457 This function is a GNU extension and is declared in @file{stdlib.h}.
1460 The Unix standard includes a similar function which differs from
1461 @code{canonicalize_file_name} in that the user has to provide the buffer
1462 where the result is placed in.
1464 @deftypefun {char *} realpath (const char *restrict @var{name}, char *restrict @var{resolved})
1465 @standards{XPG, stdlib.h}
1466 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{} @acsfd{}}}
1467 @c Calls malloc, realloc, getcwd, lxstat64, readlink, alloca.
1469 A call to @code{realpath} where the @var{resolved} parameter is
1470 @code{NULL} behaves exactly like @code{canonicalize_file_name}. The
1471 function allocates a buffer for the file name and returns a pointer to
1472 it. If @var{resolved} is not @code{NULL} it points to a buffer into
1473 which the result is copied. It is the callers responsibility to
1474 allocate a buffer which is large enough. On systems which define
1475 @code{PATH_MAX} this means the buffer must be large enough for a
1476 pathname of this size. For systems without limitations on the pathname
1477 length the requirement cannot be met and programs should not call
1478 @code{realpath} with anything but @code{NULL} for the second parameter.
1480 One other difference is that the buffer @var{resolved} (if nonzero) will
1481 contain the part of the path component which does not exist or is not
1482 readable if the function returns @code{NULL} and @code{errno} is set to
1483 @code{EACCES} or @code{ENOENT}.
1485 This function is declared in @file{stdlib.h}.
1488 The advantage of using this function is that it is more widely
1489 available. The drawback is that it reports failures for long paths on
1490 systems which have no limits on the file name length.
1492 @node Deleting Files
1493 @section Deleting Files
1494 @cindex deleting a file
1495 @cindex removing a file
1496 @cindex unlinking a file
1498 You can delete a file with @code{unlink} or @code{remove}.
1500 Deletion actually deletes a file name. If this is the file's only name,
1501 then the file is deleted as well. If the file has other remaining names
1502 (@pxref{Hard Links}), it remains accessible under those names.
1504 @deftypefun int unlink (const char *@var{filename})
1505 @standards{POSIX.1, unistd.h}
1506 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1507 The @code{unlink} function deletes the file name @var{filename}. If
1508 this is a file's sole name, the file itself is also deleted. (Actually,
1509 if any process has the file open when this happens, deletion is
1510 postponed until all processes have closed the file.)
1513 The function @code{unlink} is declared in the header file @file{unistd.h}.
1515 This function returns @code{0} on successful completion, and @code{-1}
1516 on error. In addition to the usual file name errors
1517 (@pxref{File Name Errors}), the following @code{errno} error conditions are
1518 defined for this function:
1522 Write permission is denied for the directory from which the file is to be
1523 removed, or the directory has the sticky bit set and you do not own the file.
1526 This error indicates that the file is being used by the system in such a
1527 way that it can't be unlinked. For example, you might see this error if
1528 the file name specifies the root directory or a mount point for a file
1532 The file name to be deleted doesn't exist.
1535 On some systems @code{unlink} cannot be used to delete the name of a
1536 directory, or at least can only be used this way by a privileged user.
1537 To avoid such problems, use @code{rmdir} to delete directories. (On
1538 @gnulinuxhurdsystems{} @code{unlink} can never delete the name of a directory.)
1541 The directory containing the file name to be deleted is on a read-only
1542 file system and can't be modified.
1546 @deftypefun int rmdir (const char *@var{filename})
1547 @standards{POSIX.1, unistd.h}
1548 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1549 @cindex directories, deleting
1550 @cindex deleting a directory
1551 The @code{rmdir} function deletes a directory. The directory must be
1552 empty before it can be removed; in other words, it can only contain
1553 entries for @file{.} and @file{..}.
1555 In most other respects, @code{rmdir} behaves like @code{unlink}. There
1556 are two additional @code{errno} error conditions defined for
1562 The directory to be deleted is not empty.
1565 These two error codes are synonymous; some systems use one, and some use
1566 the other. @gnulinuxhurdsystems{} always use @code{ENOTEMPTY}.
1568 The prototype for this function is declared in the header file
1573 @deftypefun int remove (const char *@var{filename})
1574 @standards{ISO, stdio.h}
1575 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1576 @c Calls unlink and rmdir.
1577 This is the @w{ISO C} function to remove a file. It works like
1578 @code{unlink} for files and like @code{rmdir} for directories.
1579 @code{remove} is declared in @file{stdio.h}.
1583 @node Renaming Files
1584 @section Renaming Files
1586 The @code{rename} function is used to change a file's name.
1588 @cindex renaming a file
1589 @deftypefun int rename (const char *@var{oldname}, const char *@var{newname})
1590 @standards{ISO, stdio.h}
1591 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1592 @c In the absence of a rename syscall, there's an emulation with link
1593 @c and unlink, but it's racy, even more so if newname exists and is
1595 The @code{rename} function renames the file @var{oldname} to
1596 @var{newname}. The file formerly accessible under the name
1597 @var{oldname} is afterwards accessible as @var{newname} instead. (If
1598 the file had any other names aside from @var{oldname}, it continues to
1601 The directory containing the name @var{newname} must be on the same file
1602 system as the directory containing the name @var{oldname}.
1604 One special case for @code{rename} is when @var{oldname} and
1605 @var{newname} are two names for the same file. The consistent way to
1606 handle this case is to delete @var{oldname}. However, in this case
1607 POSIX requires that @code{rename} do nothing and report success---which
1608 is inconsistent. We don't know what your operating system will do.
1610 If @var{oldname} is not a directory, then any existing file named
1611 @var{newname} is removed during the renaming operation. However, if
1612 @var{newname} is the name of a directory, @code{rename} fails in this
1615 If @var{oldname} is a directory, then either @var{newname} must not
1616 exist or it must name a directory that is empty. In the latter case,
1617 the existing directory named @var{newname} is deleted first. The name
1618 @var{newname} must not specify a subdirectory of the directory
1619 @code{oldname} which is being renamed.
1621 One useful feature of @code{rename} is that the meaning of @var{newname}
1622 changes ``atomically'' from any previously existing file by that name to
1623 its new meaning (i.e., the file that was called @var{oldname}). There is
1624 no instant at which @var{newname} is non-existent ``in between'' the old
1625 meaning and the new meaning. If there is a system crash during the
1626 operation, it is possible for both names to still exist; but
1627 @var{newname} will always be intact if it exists at all.
1629 If @code{rename} fails, it returns @code{-1}. In addition to the usual
1630 file name errors (@pxref{File Name Errors}), the following
1631 @code{errno} error conditions are defined for this function:
1635 One of the directories containing @var{newname} or @var{oldname}
1636 refuses write permission; or @var{newname} and @var{oldname} are
1637 directories and write permission is refused for one of them.
1640 A directory named by @var{oldname} or @var{newname} is being used by
1641 the system in a way that prevents the renaming from working. This includes
1642 directories that are mount points for filesystems, and directories
1643 that are the current working directories of processes.
1647 The directory @var{newname} isn't empty. @gnulinuxhurdsystems{} always return
1648 @code{ENOTEMPTY} for this, but some other systems return @code{EEXIST}.
1651 @var{oldname} is a directory that contains @var{newname}.
1654 @var{newname} is a directory but the @var{oldname} isn't.
1657 The parent directory of @var{newname} would have too many links
1661 The file @var{oldname} doesn't exist.
1664 The directory that would contain @var{newname} has no room for another
1665 entry, and there is no space left in the file system to expand it.
1668 The operation would involve writing to a directory on a read-only file
1672 The two file names @var{newname} and @var{oldname} are on different
1677 @node Creating Directories
1678 @section Creating Directories
1679 @cindex creating a directory
1680 @cindex directories, creating
1683 Directories are created with the @code{mkdir} function. (There is also
1684 a shell command @code{mkdir} which does the same thing.)
1687 @deftypefun int mkdir (const char *@var{filename}, mode_t @var{mode})
1688 @standards{POSIX.1, sys/stat.h}
1689 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
1690 The @code{mkdir} function creates a new, empty directory with name
1693 The argument @var{mode} specifies the file permissions for the new
1694 directory file. @xref{Permission Bits}, for more information about
1697 A return value of @code{0} indicates successful completion, and
1698 @code{-1} indicates failure. In addition to the usual file name syntax
1699 errors (@pxref{File Name Errors}), the following @code{errno} error
1700 conditions are defined for this function:
1704 Write permission is denied for the parent directory in which the new
1705 directory is to be added.
1708 A file named @var{filename} already exists.
1711 The parent directory has too many links (entries).
1713 Well-designed file systems never report this error, because they permit
1714 more links than your disk could possibly hold. However, you must still
1715 take account of the possibility of this error, as it could result from
1716 network access to a file system on another machine.
1719 The file system doesn't have enough room to create the new directory.
1722 The parent directory of the directory being created is on a read-only
1723 file system and cannot be modified.
1726 To use this function, your program should include the header file
1731 @node File Attributes
1732 @section File Attributes
1735 When you issue an @samp{ls -l} shell command on a file, it gives you
1736 information about the size of the file, who owns it, when it was last
1737 modified, etc. These are called the @dfn{file attributes}, and are
1738 associated with the file itself and not a particular one of its names.
1740 This section contains information about how you can inquire about and
1741 modify the attributes of a file.
1744 * Attribute Meanings:: The names of the file attributes,
1745 and what their values mean.
1746 * Reading Attributes:: How to read the attributes of a file.
1747 * Testing File Type:: Distinguishing ordinary files,
1748 directories, links@dots{}
1749 * File Owner:: How ownership for new files is determined,
1750 and how to change it.
1751 * Permission Bits:: How information about a file's access
1753 * Access Permission:: How the system decides who can access a file.
1754 * Setting Permissions:: How permissions for new files are assigned,
1755 and how to change them.
1756 * Testing File Access:: How to find out if your process can
1758 * File Times:: About the time attributes of a file.
1759 * File Size:: Manually changing the size of a file.
1760 * Storage Allocation:: Allocate backing storage for files.
1763 @node Attribute Meanings
1764 @subsection The meaning of the File Attributes
1765 @cindex status of a file
1766 @cindex attributes of a file
1767 @cindex file attributes
1769 When you read the attributes of a file, they come back in a structure
1770 called @code{struct stat}. This section describes the names of the
1771 attributes, their data types, and what they mean. For the functions
1772 to read the attributes of a file, see @ref{Reading Attributes}.
1774 The header file @file{sys/stat.h} declares all the symbols defined
1778 @deftp {Data Type} {struct stat}
1779 @standards{POSIX.1, sys/stat.h}
1780 The @code{stat} structure type is used to return information about the
1781 attributes of a file. It contains at least the following members:
1784 @item mode_t st_mode
1785 Specifies the mode of the file. This includes file type information
1786 (@pxref{Testing File Type}) and the file permission bits
1787 (@pxref{Permission Bits}).
1790 The file serial number, which distinguishes this file from all other
1791 files on the same device.
1794 Identifies the device containing the file. The @code{st_ino} and
1795 @code{st_dev}, taken together, uniquely identify the file. The
1796 @code{st_dev} value is not necessarily consistent across reboots or
1797 system crashes, however.
1799 @item nlink_t st_nlink
1800 The number of hard links to the file. This count keeps track of how
1801 many directories have entries for this file. If the count is ever
1802 decremented to zero, then the file itself is discarded as soon as no
1803 process still holds it open. Symbolic links are not counted in the
1807 The user ID of the file's owner. @xref{File Owner}.
1810 The group ID of the file. @xref{File Owner}.
1813 This specifies the size of a regular file in bytes. For files that are
1814 really devices this field isn't usually meaningful. For symbolic links
1815 this specifies the length of the file name the link refers to.
1817 @item time_t st_atime
1818 This is the last access time for the file. @xref{File Times}.
1820 @item unsigned long int st_atime_usec
1821 This is the fractional part of the last access time for the file.
1824 @item time_t st_mtime
1825 This is the time of the last modification to the contents of the file.
1828 @item unsigned long int st_mtime_usec
1829 This is the fractional part of the time of the last modification to the
1830 contents of the file. @xref{File Times}.
1832 @item time_t st_ctime
1833 This is the time of the last modification to the attributes of the file.
1836 @item unsigned long int st_ctime_usec
1837 This is the fractional part of the time of the last modification to the
1838 attributes of the file. @xref{File Times}.
1841 @item blkcnt_t st_blocks
1842 This is the amount of disk space that the file occupies, measured in
1843 units of 512-byte blocks.
1845 The number of disk blocks is not strictly proportional to the size of
1846 the file, for two reasons: the file system may use some blocks for
1847 internal record keeping; and the file may be sparse---it may have
1848 ``holes'' which contain zeros but do not actually take up space on the
1851 You can tell (approximately) whether a file is sparse by comparing this
1852 value with @code{st_size}, like this:
1855 (st.st_blocks * 512 < st.st_size)
1858 This test is not perfect because a file that is just slightly sparse
1859 might not be detected as sparse at all. For practical applications,
1860 this is not a problem.
1862 @item unsigned int st_blksize
1863 The optimal block size for reading or writing this file, in bytes. You
1864 might use this size for allocating the buffer space for reading or
1865 writing the file. (This is unrelated to @code{st_blocks}.)
1869 The extensions for the Large File Support (LFS) require, even on 32-bit
1870 machines, types which can handle file sizes up to @twoexp{63}.
1871 Therefore a new definition of @code{struct stat} is necessary.
1873 @deftp {Data Type} {struct stat64}
1874 @standards{LFS, sys/stat.h}
1875 The members of this type are the same and have the same names as those
1876 in @code{struct stat}. The only difference is that the members
1877 @code{st_ino}, @code{st_size}, and @code{st_blocks} have a different
1878 type to support larger values.
1881 @item mode_t st_mode
1882 Specifies the mode of the file. This includes file type information
1883 (@pxref{Testing File Type}) and the file permission bits
1884 (@pxref{Permission Bits}).
1886 @item ino64_t st_ino
1887 The file serial number, which distinguishes this file from all other
1888 files on the same device.
1891 Identifies the device containing the file. The @code{st_ino} and
1892 @code{st_dev}, taken together, uniquely identify the file. The
1893 @code{st_dev} value is not necessarily consistent across reboots or
1894 system crashes, however.
1896 @item nlink_t st_nlink
1897 The number of hard links to the file. This count keeps track of how
1898 many directories have entries for this file. If the count is ever
1899 decremented to zero, then the file itself is discarded as soon as no
1900 process still holds it open. Symbolic links are not counted in the
1904 The user ID of the file's owner. @xref{File Owner}.
1907 The group ID of the file. @xref{File Owner}.
1909 @item off64_t st_size
1910 This specifies the size of a regular file in bytes. For files that are
1911 really devices this field isn't usually meaningful. For symbolic links
1912 this specifies the length of the file name the link refers to.
1914 @item time_t st_atime
1915 This is the last access time for the file. @xref{File Times}.
1917 @item unsigned long int st_atime_usec
1918 This is the fractional part of the last access time for the file.
1921 @item time_t st_mtime
1922 This is the time of the last modification to the contents of the file.
1925 @item unsigned long int st_mtime_usec
1926 This is the fractional part of the time of the last modification to the
1927 contents of the file. @xref{File Times}.
1929 @item time_t st_ctime
1930 This is the time of the last modification to the attributes of the file.
1933 @item unsigned long int st_ctime_usec
1934 This is the fractional part of the time of the last modification to the
1935 attributes of the file. @xref{File Times}.
1938 @item blkcnt64_t st_blocks
1939 This is the amount of disk space that the file occupies, measured in
1940 units of 512-byte blocks.
1942 @item unsigned int st_blksize
1943 The optimal block size for reading of writing this file, in bytes. You
1944 might use this size for allocating the buffer space for reading of
1945 writing the file. (This is unrelated to @code{st_blocks}.)
1949 Some of the file attributes have special data type names which exist
1950 specifically for those attributes. (They are all aliases for well-known
1951 integer types that you know and love.) These typedef names are defined
1952 in the header file @file{sys/types.h} as well as in @file{sys/stat.h}.
1953 Here is a list of them.
1955 @deftp {Data Type} mode_t
1956 @standards{POSIX.1, sys/types.h}
1957 This is an integer data type used to represent file modes. In
1958 @theglibc{}, this is an unsigned type no narrower than @code{unsigned
1962 @cindex inode number
1963 @deftp {Data Type} ino_t
1964 @standards{POSIX.1, sys/types.h}
1965 This is an unsigned integer type used to represent file serial numbers.
1966 (In Unix jargon, these are sometimes called @dfn{inode numbers}.)
1967 In @theglibc{}, this type is no narrower than @code{unsigned int}.
1969 If the source is compiled with @code{_FILE_OFFSET_BITS == 64} this type
1970 is transparently replaced by @code{ino64_t}.
1973 @deftp {Data Type} ino64_t
1974 @standards{Unix98, sys/types.h}
1975 This is an unsigned integer type used to represent file serial numbers
1976 for the use in LFS. In @theglibc{}, this type is no narrower than
1977 @code{unsigned int}.
1979 When compiling with @code{_FILE_OFFSET_BITS == 64} this type is
1980 available under the name @code{ino_t}.
1983 @deftp {Data Type} dev_t
1984 @standards{POSIX.1, sys/types.h}
1985 This is an arithmetic data type used to represent file device numbers.
1986 In @theglibc{}, this is an integer type no narrower than @code{int}.
1989 @deftp {Data Type} nlink_t
1990 @standards{POSIX.1, sys/types.h}
1991 This is an integer type used to represent file link counts.
1994 @deftp {Data Type} blkcnt_t
1995 @standards{Unix98, sys/types.h}
1996 This is a signed integer type used to represent block counts.
1997 In @theglibc{}, this type is no narrower than @code{int}.
1999 If the source is compiled with @code{_FILE_OFFSET_BITS == 64} this type
2000 is transparently replaced by @code{blkcnt64_t}.
2003 @deftp {Data Type} blkcnt64_t
2004 @standards{Unix98, sys/types.h}
2005 This is a signed integer type used to represent block counts for the
2006 use in LFS. In @theglibc{}, this type is no narrower than @code{int}.
2008 When compiling with @code{_FILE_OFFSET_BITS == 64} this type is
2009 available under the name @code{blkcnt_t}.
2012 @node Reading Attributes
2013 @subsection Reading the Attributes of a File
2015 To examine the attributes of files, use the functions @code{stat},
2016 @code{fstat} and @code{lstat}. They return the attribute information in
2017 a @code{struct stat} object. All three functions are declared in the
2018 header file @file{sys/stat.h}.
2020 @deftypefun int stat (const char *@var{filename}, struct stat *@var{buf})
2021 @standards{POSIX.1, sys/stat.h}
2022 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2023 The @code{stat} function returns information about the attributes of the
2024 file named by @w{@var{filename}} in the structure pointed to by @var{buf}.
2026 If @var{filename} is the name of a symbolic link, the attributes you get
2027 describe the file that the link points to. If the link points to a
2028 nonexistent file name, then @code{stat} fails reporting a nonexistent
2031 The return value is @code{0} if the operation is successful, or
2032 @code{-1} on failure. In addition to the usual file name errors
2033 (@pxref{File Name Errors}, the following @code{errno} error conditions
2034 are defined for this function:
2038 The file named by @var{filename} doesn't exist.
2041 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2042 function is in fact @code{stat64} since the LFS interface transparently
2043 replaces the normal implementation.
2046 @deftypefun int stat64 (const char *@var{filename}, struct stat64 *@var{buf})
2047 @standards{Unix98, sys/stat.h}
2048 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2049 This function is similar to @code{stat} but it is also able to work on
2050 files larger than @twoexp{31} bytes on 32-bit systems. To be able to do
2051 this the result is stored in a variable of type @code{struct stat64} to
2052 which @var{buf} must point.
2054 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2055 function is available under the name @code{stat} and so transparently
2056 replaces the interface for small files on 32-bit machines.
2059 @deftypefun int fstat (int @var{filedes}, struct stat *@var{buf})
2060 @standards{POSIX.1, sys/stat.h}
2061 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2062 The @code{fstat} function is like @code{stat}, except that it takes an
2063 open file descriptor as an argument instead of a file name.
2064 @xref{Low-Level I/O}.
2066 Like @code{stat}, @code{fstat} returns @code{0} on success and @code{-1}
2067 on failure. The following @code{errno} error conditions are defined for
2072 The @var{filedes} argument is not a valid file descriptor.
2075 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2076 function is in fact @code{fstat64} since the LFS interface transparently
2077 replaces the normal implementation.
2080 @deftypefun int fstat64 (int @var{filedes}, struct stat64 *@var{buf})
2081 @standards{Unix98, sys/stat.h}
2082 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2083 This function is similar to @code{fstat} but is able to work on large
2084 files on 32-bit platforms. For large files the file descriptor
2085 @var{filedes} should be obtained by @code{open64} or @code{creat64}.
2086 The @var{buf} pointer points to a variable of type @code{struct stat64}
2087 which is able to represent the larger values.
2089 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2090 function is available under the name @code{fstat} and so transparently
2091 replaces the interface for small files on 32-bit machines.
2094 @c fstatat will call alloca and snprintf if the syscall is not
2096 @c @safety{@mtsafe{}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{}}}
2098 @deftypefun int lstat (const char *@var{filename}, struct stat *@var{buf})
2099 @standards{BSD, sys/stat.h}
2100 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2101 @c Direct system call through lxstat, sometimes with an xstat conv call
2103 The @code{lstat} function is like @code{stat}, except that it does not
2104 follow symbolic links. If @var{filename} is the name of a symbolic
2105 link, @code{lstat} returns information about the link itself; otherwise
2106 @code{lstat} works like @code{stat}. @xref{Symbolic Links}.
2108 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2109 function is in fact @code{lstat64} since the LFS interface transparently
2110 replaces the normal implementation.
2113 @deftypefun int lstat64 (const char *@var{filename}, struct stat64 *@var{buf})
2114 @standards{Unix98, sys/stat.h}
2115 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2116 @c Direct system call through lxstat64, sometimes with an xstat conv
2118 This function is similar to @code{lstat} but it is also able to work on
2119 files larger than @twoexp{31} bytes on 32-bit systems. To be able to do
2120 this the result is stored in a variable of type @code{struct stat64} to
2121 which @var{buf} must point.
2123 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2124 function is available under the name @code{lstat} and so transparently
2125 replaces the interface for small files on 32-bit machines.
2128 @node Testing File Type
2129 @subsection Testing the Type of a File
2131 The @dfn{file mode}, stored in the @code{st_mode} field of the file
2132 attributes, contains two kinds of information: the file type code, and
2133 the access permission bits. This section discusses only the type code,
2134 which you can use to tell whether the file is a directory, socket,
2135 symbolic link, and so on. For details about access permissions see
2136 @ref{Permission Bits}.
2138 There are two ways you can access the file type information in a file
2139 mode. Firstly, for each file type there is a @dfn{predicate macro}
2140 which examines a given file mode and returns whether it is of that type
2141 or not. Secondly, you can mask out the rest of the file mode to leave
2142 just the file type code, and compare this against constants for each of
2143 the supported file types.
2145 All of the symbols listed in this section are defined in the header file
2149 The following predicate macros test the type of a file, given the value
2150 @var{m} which is the @code{st_mode} field returned by @code{stat} on
2153 @deftypefn Macro int S_ISDIR (mode_t @var{m})
2154 @standards{POSIX, sys/stat.h}
2155 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2156 This macro returns non-zero if the file is a directory.
2159 @deftypefn Macro int S_ISCHR (mode_t @var{m})
2160 @standards{POSIX, sys/stat.h}
2161 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2162 This macro returns non-zero if the file is a character special file (a
2163 device like a terminal).
2166 @deftypefn Macro int S_ISBLK (mode_t @var{m})
2167 @standards{POSIX, sys/stat.h}
2168 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2169 This macro returns non-zero if the file is a block special file (a device
2173 @deftypefn Macro int S_ISREG (mode_t @var{m})
2174 @standards{POSIX, sys/stat.h}
2175 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2176 This macro returns non-zero if the file is a regular file.
2179 @deftypefn Macro int S_ISFIFO (mode_t @var{m})
2180 @standards{POSIX, sys/stat.h}
2181 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2182 This macro returns non-zero if the file is a FIFO special file, or a
2183 pipe. @xref{Pipes and FIFOs}.
2186 @deftypefn Macro int S_ISLNK (mode_t @var{m})
2187 @standards{GNU, sys/stat.h}
2188 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2189 This macro returns non-zero if the file is a symbolic link.
2190 @xref{Symbolic Links}.
2193 @deftypefn Macro int S_ISSOCK (mode_t @var{m})
2194 @standards{GNU, sys/stat.h}
2195 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2196 This macro returns non-zero if the file is a socket. @xref{Sockets}.
2199 An alternate non-POSIX method of testing the file type is supported for
2200 compatibility with BSD. The mode can be bitwise AND-ed with
2201 @code{S_IFMT} to extract the file type code, and compared to the
2202 appropriate constant. For example,
2205 S_ISCHR (@var{mode})
2212 ((@var{mode} & S_IFMT) == S_IFCHR)
2215 @deftypevr Macro int S_IFMT
2216 @standards{BSD, sys/stat.h}
2217 This is a bit mask used to extract the file type code from a mode value.
2220 These are the symbolic names for the different file type codes:
2224 @standards{BSD, sys/stat.h}
2225 This is the file type constant of a directory file.
2228 @standards{BSD, sys/stat.h}
2229 This is the file type constant of a character-oriented device file.
2232 @standards{BSD, sys/stat.h}
2233 This is the file type constant of a block-oriented device file.
2236 @standards{BSD, sys/stat.h}
2237 This is the file type constant of a regular file.
2240 @standards{BSD, sys/stat.h}
2241 This is the file type constant of a symbolic link.
2244 @standards{BSD, sys/stat.h}
2245 This is the file type constant of a socket.
2248 @standards{BSD, sys/stat.h}
2249 This is the file type constant of a FIFO or pipe.
2252 The POSIX.1b standard introduced a few more objects which possibly can
2253 be implemented as objects in the filesystem. These are message queues,
2254 semaphores, and shared memory objects. To allow differentiating these
2255 objects from other files the POSIX standard introduced three new test
2256 macros. But unlike the other macros they do not take the value of the
2257 @code{st_mode} field as the parameter. Instead they expect a pointer to
2258 the whole @code{struct stat} structure.
2260 @deftypefn Macro int S_TYPEISMQ (struct stat *@var{s})
2261 @standards{POSIX, sys/stat.h}
2262 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2263 If the system implements POSIX message queues as distinct objects and the
2264 file is a message queue object, this macro returns a non-zero value.
2265 In all other cases the result is zero.
2268 @deftypefn Macro int S_TYPEISSEM (struct stat *@var{s})
2269 @standards{POSIX, sys/stat.h}
2270 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2271 If the system implements POSIX semaphores as distinct objects and the
2272 file is a semaphore object, this macro returns a non-zero value.
2273 In all other cases the result is zero.
2276 @deftypefn Macro int S_TYPEISSHM (struct stat *@var{s})
2277 @standards{POSIX, sys/stat.h}
2278 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2279 If the system implements POSIX shared memory objects as distinct objects
2280 and the file is a shared memory object, this macro returns a non-zero
2281 value. In all other cases the result is zero.
2285 @subsection File Owner
2287 @cindex owner of a file
2288 @cindex group owner of a file
2290 Every file has an @dfn{owner} which is one of the registered user names
2291 defined on the system. Each file also has a @dfn{group} which is one of
2292 the defined groups. The file owner can often be useful for showing you
2293 who edited the file (especially when you edit with GNU Emacs), but its
2294 main purpose is for access control.
2296 The file owner and group play a role in determining access because the
2297 file has one set of access permission bits for the owner, another set
2298 that applies to users who belong to the file's group, and a third set of
2299 bits that applies to everyone else. @xref{Access Permission}, for the
2300 details of how access is decided based on this data.
2302 When a file is created, its owner is set to the effective user ID of the
2303 process that creates it (@pxref{Process Persona}). The file's group ID
2304 may be set to either the effective group ID of the process, or the group
2305 ID of the directory that contains the file, depending on the system
2306 where the file is stored. When you access a remote file system, it
2307 behaves according to its own rules, not according to the system your
2308 program is running on. Thus, your program must be prepared to encounter
2309 either kind of behavior no matter what kind of system you run it on.
2313 You can change the owner and/or group owner of an existing file using
2314 the @code{chown} function. This is the primitive for the @code{chown}
2315 and @code{chgrp} shell commands.
2318 The prototype for this function is declared in @file{unistd.h}.
2320 @deftypefun int chown (const char *@var{filename}, uid_t @var{owner}, gid_t @var{group})
2321 @standards{POSIX.1, unistd.h}
2322 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2323 The @code{chown} function changes the owner of the file @var{filename} to
2324 @var{owner}, and its group owner to @var{group}.
2326 Changing the owner of the file on certain systems clears the set-user-ID
2327 and set-group-ID permission bits. (This is because those bits may not
2328 be appropriate for the new owner.) Other file permission bits are not
2331 The return value is @code{0} on success and @code{-1} on failure.
2332 In addition to the usual file name errors (@pxref{File Name Errors}),
2333 the following @code{errno} error conditions are defined for this function:
2337 This process lacks permission to make the requested change.
2339 Only privileged users or the file's owner can change the file's group.
2340 On most file systems, only privileged users can change the file owner;
2341 some file systems allow you to change the owner if you are currently the
2342 owner. When you access a remote file system, the behavior you encounter
2343 is determined by the system that actually holds the file, not by the
2344 system your program is running on.
2346 @xref{Options for Files}, for information about the
2347 @code{_POSIX_CHOWN_RESTRICTED} macro.
2350 The file is on a read-only file system.
2354 @deftypefun int fchown (int @var{filedes}, uid_t @var{owner}, gid_t @var{group})
2355 @standards{BSD, unistd.h}
2356 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2357 This is like @code{chown}, except that it changes the owner of the open
2358 file with descriptor @var{filedes}.
2360 The return value from @code{fchown} is @code{0} on success and @code{-1}
2361 on failure. The following @code{errno} error codes are defined for this
2366 The @var{filedes} argument is not a valid file descriptor.
2369 The @var{filedes} argument corresponds to a pipe or socket, not an ordinary
2373 This process lacks permission to make the requested change. For details
2374 see @code{chmod} above.
2377 The file resides on a read-only file system.
2381 @node Permission Bits
2382 @subsection The Mode Bits for Access Permission
2384 The @dfn{file mode}, stored in the @code{st_mode} field of the file
2385 attributes, contains two kinds of information: the file type code, and
2386 the access permission bits. This section discusses only the access
2387 permission bits, which control who can read or write the file.
2388 @xref{Testing File Type}, for information about the file type code.
2390 All of the symbols listed in this section are defined in the header file
2394 @cindex file permission bits
2395 These symbolic constants are defined for the file mode bits that control
2396 access permission for the file:
2401 @standards{POSIX.1, sys/stat.h}
2402 @standardsx{S_IREAD, BSD, sys/stat.h}
2403 Read permission bit for the owner of the file. On many systems this bit
2404 is 0400. @code{S_IREAD} is an obsolete synonym provided for BSD
2409 @standards{POSIX.1, sys/stat.h}
2410 @standardsx{S_IWRITE, BSD, sys/stat.h}
2411 Write permission bit for the owner of the file. Usually 0200.
2412 @w{@code{S_IWRITE}} is an obsolete synonym provided for BSD compatibility.
2416 @standards{POSIX.1, sys/stat.h}
2417 @standardsx{S_IEXEC, BSD, sys/stat.h}
2418 Execute (for ordinary files) or search (for directories) permission bit
2419 for the owner of the file. Usually 0100. @code{S_IEXEC} is an obsolete
2420 synonym provided for BSD compatibility.
2423 @standards{POSIX.1, sys/stat.h}
2424 This is equivalent to @samp{(S_IRUSR | S_IWUSR | S_IXUSR)}.
2427 @standards{POSIX.1, sys/stat.h}
2428 Read permission bit for the group owner of the file. Usually 040.
2431 @standards{POSIX.1, sys/stat.h}
2432 Write permission bit for the group owner of the file. Usually 020.
2435 @standards{POSIX.1, sys/stat.h}
2436 Execute or search permission bit for the group owner of the file.
2440 @standards{POSIX.1, sys/stat.h}
2441 This is equivalent to @samp{(S_IRGRP | S_IWGRP | S_IXGRP)}.
2444 @standards{POSIX.1, sys/stat.h}
2445 Read permission bit for other users. Usually 04.
2448 @standards{POSIX.1, sys/stat.h}
2449 Write permission bit for other users. Usually 02.
2452 @standards{POSIX.1, sys/stat.h}
2453 Execute or search permission bit for other users. Usually 01.
2456 @standards{POSIX.1, sys/stat.h}
2457 This is equivalent to @samp{(S_IROTH | S_IWOTH | S_IXOTH)}.
2460 @standards{POSIX, sys/stat.h}
2461 This is the set-user-ID on execute bit, usually 04000.
2462 @xref{How Change Persona}.
2465 @standards{POSIX, sys/stat.h}
2466 This is the set-group-ID on execute bit, usually 02000.
2467 @xref{How Change Persona}.
2471 @standards{BSD, sys/stat.h}
2472 This is the @dfn{sticky} bit, usually 01000.
2474 For a directory it gives permission to delete a file in that directory
2475 only if you own that file. Ordinarily, a user can either delete all the
2476 files in a directory or cannot delete any of them (based on whether the
2477 user has write permission for the directory). The same restriction
2478 applies---you must have both write permission for the directory and own
2479 the file you want to delete. The one exception is that the owner of the
2480 directory can delete any file in the directory, no matter who owns it
2481 (provided the owner has given himself write permission for the
2482 directory). This is commonly used for the @file{/tmp} directory, where
2483 anyone may create files but not delete files created by other users.
2485 Originally the sticky bit on an executable file modified the swapping
2486 policies of the system. Normally, when a program terminated, its pages
2487 in core were immediately freed and reused. If the sticky bit was set on
2488 the executable file, the system kept the pages in core for a while as if
2489 the program were still running. This was advantageous for a program
2490 likely to be run many times in succession. This usage is obsolete in
2491 modern systems. When a program terminates, its pages always remain in
2492 core as long as there is no shortage of memory in the system. When the
2493 program is next run, its pages will still be in core if no shortage
2494 arose since the last run.
2496 On some modern systems where the sticky bit has no useful meaning for an
2497 executable file, you cannot set the bit at all for a non-directory.
2498 If you try, @code{chmod} fails with @code{EFTYPE};
2499 @pxref{Setting Permissions}.
2501 Some systems (particularly SunOS) have yet another use for the sticky
2502 bit. If the sticky bit is set on a file that is @emph{not} executable,
2503 it means the opposite: never cache the pages of this file at all. The
2504 main use of this is for the files on an NFS server machine which are
2505 used as the swap area of diskless client machines. The idea is that the
2506 pages of the file will be cached in the client's memory, so it is a
2507 waste of the server's memory to cache them a second time. With this
2508 usage the sticky bit also implies that the filesystem may fail to record
2509 the file's modification time onto disk reliably (the idea being that
2510 no-one cares for a swap file).
2512 This bit is only available on BSD systems (and those derived from
2513 them). Therefore one has to use the @code{_GNU_SOURCE} feature select
2514 macro, or not define any feature test macros, to get the definition
2515 (@pxref{Feature Test Macros}).
2518 The actual bit values of the symbols are listed in the table above
2519 so you can decode file mode values when debugging your programs.
2520 These bit values are correct for most systems, but they are not
2523 @strong{Warning:} Writing explicit numbers for file permissions is bad
2524 practice. Not only is it not portable, it also requires everyone who
2525 reads your program to remember what the bits mean. To make your program
2526 clean use the symbolic names.
2528 @node Access Permission
2529 @subsection How Your Access to a File is Decided
2530 @cindex permission to access a file
2531 @cindex access permission for a file
2532 @cindex file access permission
2534 Recall that the operating system normally decides access permission for
2535 a file based on the effective user and group IDs of the process and its
2536 supplementary group IDs, together with the file's owner, group and
2537 permission bits. These concepts are discussed in detail in @ref{Process
2540 If the effective user ID of the process matches the owner user ID of the
2541 file, then permissions for read, write, and execute/search are
2542 controlled by the corresponding ``user'' (or ``owner'') bits. Likewise,
2543 if any of the effective group ID or supplementary group IDs of the
2544 process matches the group owner ID of the file, then permissions are
2545 controlled by the ``group'' bits. Otherwise, permissions are controlled
2546 by the ``other'' bits.
2548 Privileged users, like @samp{root}, can access any file regardless of
2549 its permission bits. As a special case, for a file to be executable
2550 even by a privileged user, at least one of its execute bits must be set.
2552 @node Setting Permissions
2553 @subsection Assigning File Permissions
2555 @cindex file creation mask
2557 The primitive functions for creating files (for example, @code{open} or
2558 @code{mkdir}) take a @var{mode} argument, which specifies the file
2559 permissions to give the newly created file. This mode is modified by
2560 the process's @dfn{file creation mask}, or @dfn{umask}, before it is
2563 The bits that are set in the file creation mask identify permissions
2564 that are always to be disabled for newly created files. For example, if
2565 you set all the ``other'' access bits in the mask, then newly created
2566 files are not accessible at all to processes in the ``other'' category,
2567 even if the @var{mode} argument passed to the create function would
2568 permit such access. In other words, the file creation mask is the
2569 complement of the ordinary access permissions you want to grant.
2571 Programs that create files typically specify a @var{mode} argument that
2572 includes all the permissions that make sense for the particular file.
2573 For an ordinary file, this is typically read and write permission for
2574 all classes of users. These permissions are then restricted as
2575 specified by the individual user's own file creation mask.
2578 To change the permission of an existing file given its name, call
2579 @code{chmod}. This function uses the specified permission bits and
2580 ignores the file creation mask.
2583 In normal use, the file creation mask is initialized by the user's login
2584 shell (using the @code{umask} shell command), and inherited by all
2585 subprocesses. Application programs normally don't need to worry about
2586 the file creation mask. It will automatically do what it is supposed to
2589 When your program needs to create a file and bypass the umask for its
2590 access permissions, the easiest way to do this is to use @code{fchmod}
2591 after opening the file, rather than changing the umask. In fact,
2592 changing the umask is usually done only by shells. They use the
2593 @code{umask} function.
2595 The functions in this section are declared in @file{sys/stat.h}.
2598 @deftypefun mode_t umask (mode_t @var{mask})
2599 @standards{POSIX.1, sys/stat.h}
2600 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2601 The @code{umask} function sets the file creation mask of the current
2602 process to @var{mask}, and returns the previous value of the file
2605 Here is an example showing how to read the mask with @code{umask}
2606 without changing it permanently:
2612 mode_t mask = umask (0);
2619 However, on @gnuhurdsystems{} it is better to use @code{getumask} if
2620 you just want to read the mask value, because it is reentrant.
2623 @deftypefun mode_t getumask (void)
2624 @standards{GNU, sys/stat.h}
2625 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2626 Return the current value of the file creation mask for the current
2627 process. This function is a GNU extension and is only available on
2631 @deftypefun int chmod (const char *@var{filename}, mode_t @var{mode})
2632 @standards{POSIX.1, sys/stat.h}
2633 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2634 The @code{chmod} function sets the access permission bits for the file
2635 named by @var{filename} to @var{mode}.
2637 If @var{filename} is a symbolic link, @code{chmod} changes the
2638 permissions of the file pointed to by the link, not those of the link
2641 This function returns @code{0} if successful and @code{-1} if not. In
2642 addition to the usual file name errors (@pxref{File Name
2643 Errors}), the following @code{errno} error conditions are defined for
2648 The named file doesn't exist.
2651 This process does not have permission to change the access permissions
2652 of this file. Only the file's owner (as judged by the effective user ID
2653 of the process) or a privileged user can change them.
2656 The file resides on a read-only file system.
2659 @var{mode} has the @code{S_ISVTX} bit (the ``sticky bit'') set,
2660 and the named file is not a directory. Some systems do not allow setting the
2661 sticky bit on non-directory files, and some do (and only some of those
2662 assign a useful meaning to the bit for non-directory files).
2664 You only get @code{EFTYPE} on systems where the sticky bit has no useful
2665 meaning for non-directory files, so it is always safe to just clear the
2666 bit in @var{mode} and call @code{chmod} again. @xref{Permission Bits},
2667 for full details on the sticky bit.
2671 @deftypefun int fchmod (int @var{filedes}, mode_t @var{mode})
2672 @standards{BSD, sys/stat.h}
2673 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2674 This is like @code{chmod}, except that it changes the permissions of the
2675 currently open file given by @var{filedes}.
2677 The return value from @code{fchmod} is @code{0} on success and @code{-1}
2678 on failure. The following @code{errno} error codes are defined for this
2683 The @var{filedes} argument is not a valid file descriptor.
2686 The @var{filedes} argument corresponds to a pipe or socket, or something
2687 else that doesn't really have access permissions.
2690 This process does not have permission to change the access permissions
2691 of this file. Only the file's owner (as judged by the effective user ID
2692 of the process) or a privileged user can change them.
2695 The file resides on a read-only file system.
2699 @node Testing File Access
2700 @subsection Testing Permission to Access a File
2701 @cindex testing access permission
2702 @cindex access, testing for
2703 @cindex setuid programs and file access
2705 In some situations it is desirable to allow programs to access files or
2706 devices even if this is not possible with the permissions granted to the
2707 user. One possible solution is to set the setuid-bit of the program
2708 file. If such a program is started the @emph{effective} user ID of the
2709 process is changed to that of the owner of the program file. So to
2710 allow write access to files like @file{/etc/passwd}, which normally can
2711 be written only by the super-user, the modifying program will have to be
2712 owned by @code{root} and the setuid-bit must be set.
2714 But besides the files the program is intended to change the user should
2715 not be allowed to access any file to which s/he would not have access
2716 anyway. The program therefore must explicitly check whether @emph{the
2717 user} would have the necessary access to a file, before it reads or
2720 To do this, use the function @code{access}, which checks for access
2721 permission based on the process's @emph{real} user ID rather than the
2722 effective user ID. (The setuid feature does not alter the real user ID,
2723 so it reflects the user who actually ran the program.)
2725 There is another way you could check this access, which is easy to
2726 describe, but very hard to use. This is to examine the file mode bits
2727 and mimic the system's own access computation. This method is
2728 undesirable because many systems have additional access control
2729 features; your program cannot portably mimic them, and you would not
2730 want to try to keep track of the diverse features that different systems
2731 have. Using @code{access} is simple and automatically does whatever is
2732 appropriate for the system you are using.
2734 @code{access} is @emph{only} appropriate to use in setuid programs.
2735 A non-setuid program will always use the effective ID rather than the
2739 The symbols in this section are declared in @file{unistd.h}.
2741 @deftypefun int access (const char *@var{filename}, int @var{how})
2742 @standards{POSIX.1, unistd.h}
2743 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2744 The @code{access} function checks to see whether the file named by
2745 @var{filename} can be accessed in the way specified by the @var{how}
2746 argument. The @var{how} argument either can be the bitwise OR of the
2747 flags @code{R_OK}, @code{W_OK}, @code{X_OK}, or the existence test
2750 This function uses the @emph{real} user and group IDs of the calling
2751 process, rather than the @emph{effective} IDs, to check for access
2752 permission. As a result, if you use the function from a @code{setuid}
2753 or @code{setgid} program (@pxref{How Change Persona}), it gives
2754 information relative to the user who actually ran the program.
2756 The return value is @code{0} if the access is permitted, and @code{-1}
2757 otherwise. (In other words, treated as a predicate function,
2758 @code{access} returns true if the requested access is @emph{denied}.)
2760 In addition to the usual file name errors (@pxref{File Name
2761 Errors}), the following @code{errno} error conditions are defined for
2766 The access specified by @var{how} is denied.
2769 The file doesn't exist.
2772 Write permission was requested for a file on a read-only file system.
2776 These macros are defined in the header file @file{unistd.h} for use
2777 as the @var{how} argument to the @code{access} function. The values
2778 are integer constants.
2781 @deftypevr Macro int R_OK
2782 @standards{POSIX.1, unistd.h}
2783 Flag meaning test for read permission.
2786 @deftypevr Macro int W_OK
2787 @standards{POSIX.1, unistd.h}
2788 Flag meaning test for write permission.
2791 @deftypevr Macro int X_OK
2792 @standards{POSIX.1, unistd.h}
2793 Flag meaning test for execute/search permission.
2796 @deftypevr Macro int F_OK
2797 @standards{POSIX.1, unistd.h}
2798 Flag meaning test for existence of the file.
2802 @subsection File Times
2804 @cindex file access time
2805 @cindex file modification time
2806 @cindex file attribute modification time
2807 Each file has three time stamps associated with it: its access time,
2808 its modification time, and its attribute modification time. These
2809 correspond to the @code{st_atime}, @code{st_mtime}, and @code{st_ctime}
2810 members of the @code{stat} structure; see @ref{File Attributes}.
2812 All of these times are represented in calendar time format, as
2813 @code{time_t} objects. This data type is defined in @file{time.h}.
2814 For more information about representation and manipulation of time
2815 values, see @ref{Calendar Time}.
2818 Reading from a file updates its access time attribute, and writing
2819 updates its modification time. When a file is created, all three
2820 time stamps for that file are set to the current time. In addition, the
2821 attribute change time and modification time fields of the directory that
2822 contains the new entry are updated.
2824 Adding a new name for a file with the @code{link} function updates the
2825 attribute change time field of the file being linked, and both the
2826 attribute change time and modification time fields of the directory
2827 containing the new name. These same fields are affected if a file name
2828 is deleted with @code{unlink}, @code{remove} or @code{rmdir}. Renaming
2829 a file with @code{rename} affects only the attribute change time and
2830 modification time fields of the two parent directories involved, and not
2831 the times for the file being renamed.
2833 Changing the attributes of a file (for example, with @code{chmod})
2834 updates its attribute change time field.
2836 You can also change some of the time stamps of a file explicitly using
2837 the @code{utime} function---all except the attribute change time. You
2838 need to include the header file @file{utime.h} to use this facility.
2841 @deftp {Data Type} {struct utimbuf}
2842 @standards{POSIX.1, utime.h}
2843 The @code{utimbuf} structure is used with the @code{utime} function to
2844 specify new access and modification times for a file. It contains the
2849 This is the access time for the file.
2851 @item time_t modtime
2852 This is the modification time for the file.
2856 @deftypefun int utime (const char *@var{filename}, const struct utimbuf *@var{times})
2857 @standards{POSIX.1, utime.h}
2858 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2859 @c In the absence of a utime syscall, it non-atomically converts times
2860 @c to a struct timeval and calls utimes.
2861 This function is used to modify the file times associated with the file
2862 named @var{filename}.
2864 If @var{times} is a null pointer, then the access and modification times
2865 of the file are set to the current time. Otherwise, they are set to the
2866 values from the @code{actime} and @code{modtime} members (respectively)
2867 of the @code{utimbuf} structure pointed to by @var{times}.
2869 The attribute modification time for the file is set to the current time
2870 in either case (since changing the time stamps is itself a modification
2871 of the file attributes).
2873 The @code{utime} function returns @code{0} if successful and @code{-1}
2874 on failure. In addition to the usual file name errors
2875 (@pxref{File Name Errors}), the following @code{errno} error conditions
2876 are defined for this function:
2880 There is a permission problem in the case where a null pointer was
2881 passed as the @var{times} argument. In order to update the time stamp on
2882 the file, you must either be the owner of the file, have write
2883 permission for the file, or be a privileged user.
2886 The file doesn't exist.
2889 If the @var{times} argument is not a null pointer, you must either be
2890 the owner of the file or be a privileged user.
2893 The file lives on a read-only file system.
2897 Each of the three time stamps has a corresponding microsecond part,
2898 which extends its resolution. These fields are called
2899 @code{st_atime_usec}, @code{st_mtime_usec}, and @code{st_ctime_usec};
2900 each has a value between 0 and 999,999, which indicates the time in
2901 microseconds. They correspond to the @code{tv_usec} field of a
2902 @code{timeval} structure; see @ref{Time Types}.
2904 The @code{utimes} function is like @code{utime}, but also lets you specify
2905 the fractional part of the file times. The prototype for this function is
2906 in the header file @file{sys/time.h}.
2909 @deftypefun int utimes (const char *@var{filename}, const struct timeval @var{tvp}@t{[2]})
2910 @standards{BSD, sys/time.h}
2911 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2912 @c In the absence of a utimes syscall, it non-atomically converts tvp
2913 @c to struct timespec array and issues a utimensat syscall, or to
2914 @c struct utimbuf and calls utime.
2915 This function sets the file access and modification times of the file
2916 @var{filename}. The new file access time is specified by
2917 @code{@var{tvp}[0]}, and the new modification time by
2918 @code{@var{tvp}[1]}. Similar to @code{utime}, if @var{tvp} is a null
2919 pointer then the access and modification times of the file are set to
2920 the current time. This function comes from BSD.
2922 The return values and error conditions are the same as for the @code{utime}
2926 @deftypefun int lutimes (const char *@var{filename}, const struct timeval @var{tvp}@t{[2]})
2927 @standards{BSD, sys/time.h}
2928 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2929 @c Since there's no lutimes syscall, it non-atomically converts tvp
2930 @c to struct timespec array and issues a utimensat syscall.
2931 This function is like @code{utimes}, except that it does not follow
2932 symbolic links. If @var{filename} is the name of a symbolic link,
2933 @code{lutimes} sets the file access and modification times of the
2934 symbolic link special file itself (as seen by @code{lstat};
2935 @pxref{Symbolic Links}) while @code{utimes} sets the file access and
2936 modification times of the file the symbolic link refers to. This
2937 function comes from FreeBSD, and is not available on all platforms (if
2938 not available, it will fail with @code{ENOSYS}).
2940 The return values and error conditions are the same as for the @code{utime}
2944 @deftypefun int futimes (int @var{fd}, const struct timeval @var{tvp}@t{[2]})
2945 @standards{BSD, sys/time.h}
2946 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
2947 @c Since there's no futimes syscall, it non-atomically converts tvp
2948 @c to struct timespec array and issues a utimensat syscall, falling back
2949 @c to utimes on a /proc/self/fd symlink.
2950 This function is like @code{utimes}, except that it takes an open file
2951 descriptor as an argument instead of a file name. @xref{Low-Level
2952 I/O}. This function comes from FreeBSD, and is not available on all
2953 platforms (if not available, it will fail with @code{ENOSYS}).
2955 Like @code{utimes}, @code{futimes} returns @code{0} on success and @code{-1}
2956 on failure. The following @code{errno} error conditions are defined for
2961 There is a permission problem in the case where a null pointer was
2962 passed as the @var{times} argument. In order to update the time stamp on
2963 the file, you must either be the owner of the file, have write
2964 permission for the file, or be a privileged user.
2967 The @var{filedes} argument is not a valid file descriptor.
2970 If the @var{times} argument is not a null pointer, you must either be
2971 the owner of the file or be a privileged user.
2974 The file lives on a read-only file system.
2979 @subsection File Size
2981 Normally file sizes are maintained automatically. A file begins with a
2982 size of @math{0} and is automatically extended when data is written past
2983 its end. It is also possible to empty a file completely by an
2984 @code{open} or @code{fopen} call.
2986 However, sometimes it is necessary to @emph{reduce} the size of a file.
2987 This can be done with the @code{truncate} and @code{ftruncate} functions.
2988 They were introduced in BSD Unix. @code{ftruncate} was later added to
2991 Some systems allow you to extend a file (creating holes) with these
2992 functions. This is useful when using memory-mapped I/O
2993 (@pxref{Memory-mapped I/O}), where files are not automatically extended.
2994 However, it is not portable but must be implemented if @code{mmap}
2995 allows mapping of files (i.e., @code{_POSIX_MAPPED_FILES} is defined).
2997 Using these functions on anything other than a regular file gives
2998 @emph{undefined} results. On many systems, such a call will appear to
2999 succeed, without actually accomplishing anything.
3001 @deftypefun int truncate (const char *@var{filename}, off_t @var{length})
3002 @standards{X/Open, unistd.h}
3003 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3004 @c In the absence of a truncate syscall, we use open and ftruncate.
3006 The @code{truncate} function changes the size of @var{filename} to
3007 @var{length}. If @var{length} is shorter than the previous length, data
3008 at the end will be lost. The file must be writable by the user to
3009 perform this operation.
3011 If @var{length} is longer, holes will be added to the end. However, some
3012 systems do not support this feature and will leave the file unchanged.
3014 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} the
3015 @code{truncate} function is in fact @code{truncate64} and the type
3016 @code{off_t} has 64 bits which makes it possible to handle files up to
3017 @twoexp{63} bytes in length.
3019 The return value is @math{0} for success, or @math{-1} for an error. In
3020 addition to the usual file name errors, the following errors may occur:
3025 The file is a directory or not writable.
3028 @var{length} is negative.
3031 The operation would extend the file beyond the limits of the operating system.
3034 A hardware I/O error occurred.
3037 The file is "append-only" or "immutable".
3040 The operation was interrupted by a signal.
3046 @deftypefun int truncate64 (const char *@var{name}, off64_t @var{length})
3047 @standards{Unix98, unistd.h}
3048 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3049 @c In the absence of a syscall, try truncate if length fits.
3050 This function is similar to the @code{truncate} function. The
3051 difference is that the @var{length} argument is 64 bits wide even on 32
3052 bits machines, which allows the handling of files with sizes up to
3055 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} on a
3056 32 bits machine this function is actually available under the name
3057 @code{truncate} and so transparently replaces the 32 bits interface.
3060 @deftypefun int ftruncate (int @var{fd}, off_t @var{length})
3061 @standards{POSIX, unistd.h}
3062 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3064 This is like @code{truncate}, but it works on a file descriptor @var{fd}
3065 for an opened file instead of a file name to identify the object. The
3066 file must be opened for writing to successfully carry out the operation.
3068 The POSIX standard leaves it implementation defined what happens if the
3069 specified new @var{length} of the file is bigger than the original size.
3070 The @code{ftruncate} function might simply leave the file alone and do
3071 nothing or it can increase the size to the desired size. In this later
3072 case the extended area should be zero-filled. So using @code{ftruncate}
3073 is no reliable way to increase the file size but if it is possible it is
3074 probably the fastest way. The function also operates on POSIX shared
3075 memory segments if these are implemented by the system.
3077 @code{ftruncate} is especially useful in combination with @code{mmap}.
3078 Since the mapped region must have a fixed size one cannot enlarge the
3079 file by writing something beyond the last mapped page. Instead one has
3080 to enlarge the file itself and then remap the file with the new size.
3081 The example below shows how this works.
3083 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} the
3084 @code{ftruncate} function is in fact @code{ftruncate64} and the type
3085 @code{off_t} has 64 bits which makes it possible to handle files up to
3086 @twoexp{63} bytes in length.
3088 The return value is @math{0} for success, or @math{-1} for an error. The
3089 following errors may occur:
3094 @var{fd} does not correspond to an open file.
3097 @var{fd} is a directory or not open for writing.
3100 @var{length} is negative.
3103 The operation would extend the file beyond the limits of the operating system.
3104 @c or the open() call -- with the not-yet-discussed feature of opening
3105 @c files with extra-large offsets.
3108 A hardware I/O error occurred.
3111 The file is "append-only" or "immutable".
3114 The operation was interrupted by a signal.
3116 @c ENOENT is also possible on Linux --- however it only occurs if the file
3117 @c descriptor has a `file' structure but no `inode' structure. I'm not
3118 @c sure how such an fd could be created. Perhaps it's a bug.
3124 @deftypefun int ftruncate64 (int @var{id}, off64_t @var{length})
3125 @standards{Unix98, unistd.h}
3126 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3127 @c In the absence of a syscall, try ftruncate if length fits.
3128 This function is similar to the @code{ftruncate} function. The
3129 difference is that the @var{length} argument is 64 bits wide even on 32
3130 bits machines which allows the handling of files with sizes up to
3133 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} on a
3134 32 bits machine this function is actually available under the name
3135 @code{ftruncate} and so transparently replaces the 32 bits interface.
3138 As announced here is a little example of how to use @code{ftruncate} in
3139 combination with @code{mmap}:
3147 add (off_t at, void *block, size_t size)
3149 if (at + size > len)
3151 /* Resize the file and remap. */
3152 size_t ps = sysconf (_SC_PAGESIZE);
3153 size_t ns = (at + size + ps - 1) & ~(ps - 1);
3155 if (ftruncate (fd, ns) < 0)
3157 np = mmap (NULL, ns, PROT_READ|PROT_WRITE, MAP_SHARED, fd, 0);
3158 if (np == MAP_FAILED)
3163 memcpy ((char *) start + at, block, size);
3168 The function @code{add} writes a block of memory at an arbitrary
3169 position in the file. If the current size of the file is too small it
3170 is extended. Note that it is extended by a whole number of pages. This
3171 is a requirement of @code{mmap}. The program has to keep track of the
3172 real size, and when it has finished a final @code{ftruncate} call should
3173 set the real size of the file.
3175 @node Storage Allocation
3176 @subsection Storage Allocation
3177 @cindex allocating file storage
3178 @cindex file allocation
3179 @cindex storage allocating
3181 @cindex file fragmentation
3182 @cindex fragmentation of files
3183 @cindex sparse files
3184 @cindex files, sparse
3185 Most file systems support allocating large files in a non-contiguous
3186 fashion: the file is split into @emph{fragments} which are allocated
3187 sequentially, but the fragments themselves can be scattered across the
3188 disk. File systems generally try to avoid such fragmentation because it
3189 decreases performance, but if a file gradually increases in size, there
3190 might be no other option than to fragment it. In addition, many file
3191 systems support @emph{sparse files} with @emph{holes}: regions of null
3192 bytes for which no backing storage has been allocated by the file
3193 system. When the holes are finally overwritten with data, fragmentation
3196 Explicit allocation of storage for yet-unwritten parts of the file can
3197 help the system to avoid fragmentation. Additionally, if storage
3198 pre-allocation fails, it is possible to report the out-of-disk error
3199 early, often without filling up the entire disk. However, due to
3200 deduplication, copy-on-write semantics, and file compression, such
3201 pre-allocation may not reliably prevent the out-of-disk-space error from
3202 occurring later. Checking for write errors is still required, and
3203 writes to memory-mapped regions created with @code{mmap} can still
3204 result in @code{SIGBUS}.
3206 @deftypefun int posix_fallocate (int @var{fd}, off_t @var{offset}, off_t @var{length})
3207 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3208 @c If the file system does not support allocation,
3209 @c @code{posix_fallocate} has a race with file extension (if
3210 @c @var{length} is zero) or with concurrent writes of non-NUL bytes (if
3211 @c @var{length} is positive).
3213 Allocate backing store for the region of @var{length} bytes starting at
3214 byte @var{offset} in the file for the descriptor @var{fd}. The file
3215 length is increased to @samp{@var{length} + @var{offset}} if necessary.
3217 @var{fd} must be a regular file opened for writing, or @code{EBADF} is
3218 returned. If there is insufficient disk space to fulfill the allocation
3219 request, @code{ENOSPC} is returned.
3221 @strong{Note:} If @code{fallocate} is not available (because the file
3222 system does not support it), @code{posix_fallocate} is emulated, which
3223 has the following drawbacks:
3227 It is very inefficient because all file system blocks in the requested
3228 range need to be examined (even if they have been allocated before) and
3229 potentially rewritten. In contrast, with proper @code{fallocate}
3230 support (see below), the file system can examine the internal file
3231 allocation data structures and eliminate holes directly, maybe even
3232 using unwritten extents (which are pre-allocated but uninitialized on
3236 There is a race condition if another thread or process modifies the
3237 underlying file in the to-be-allocated area. Non-null bytes could be
3238 overwritten with null bytes.
3241 If @var{fd} has been opened with the @code{O_WRONLY} flag, the function
3242 will fail with an @code{errno} value of @code{EBADF}.
3245 If @var{fd} has been opened with the @code{O_APPEND} flag, the function
3246 will fail with an @code{errno} value of @code{EBADF}.
3249 If @var{length} is zero, @code{ftruncate} is used to increase the file
3250 size as requested, without allocating file system blocks. There is a
3251 race condition which means that @code{ftruncate} can accidentally
3252 truncate the file if it has been extended concurrently.
3255 On Linux, if an application does not benefit from emulation or if the
3256 emulation is harmful due to its inherent race conditions, the
3257 application can use the Linux-specific @code{fallocate} function, with a
3258 zero flag argument. For the @code{fallocate} function, @theglibc{} does
3259 not perform allocation emulation if the file system does not support
3260 allocation. Instead, an @code{EOPNOTSUPP} is returned to the caller.
3264 @deftypefun int posix_fallocate64 (int @var{fd}, off64_t @var{offset}, off64_t @var{length})
3265 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3267 This function is a variant of @code{posix_fallocate64} which accepts
3268 64-bit file offsets on all platforms.
3272 @node Making Special Files
3273 @section Making Special Files
3274 @cindex creating special files
3275 @cindex special files
3277 The @code{mknod} function is the primitive for making special files,
3278 such as files that correspond to devices. @Theglibc{} includes
3279 this function for compatibility with BSD.
3281 The prototype for @code{mknod} is declared in @file{sys/stat.h}.
3284 @deftypefun int mknod (const char *@var{filename}, mode_t @var{mode}, dev_t @var{dev})
3285 @standards{BSD, sys/stat.h}
3286 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3287 @c Instead of issuing the syscall directly, we go through xmknod.
3288 @c Although the internal xmknod takes a dev_t*, that could lead to
3289 @c @mtsrace races, it's passed a pointer to mknod's dev.
3290 The @code{mknod} function makes a special file with name @var{filename}.
3291 The @var{mode} specifies the mode of the file, and may include the various
3292 special file bits, such as @code{S_IFCHR} (for a character special file)
3293 or @code{S_IFBLK} (for a block special file). @xref{Testing File Type}.
3295 The @var{dev} argument specifies which device the special file refers to.
3296 Its exact interpretation depends on the kind of special file being created.
3298 The return value is @code{0} on success and @code{-1} on error. In addition
3299 to the usual file name errors (@pxref{File Name Errors}), the
3300 following @code{errno} error conditions are defined for this function:
3304 The calling process is not privileged. Only the superuser can create
3308 The directory or file system that would contain the new file is full
3309 and cannot be extended.
3312 The directory containing the new file can't be modified because it's on
3313 a read-only file system.
3316 There is already a file named @var{filename}. If you want to replace
3317 this file, you must remove the old file explicitly first.
3321 @node Temporary Files
3322 @section Temporary Files
3324 If you need to use a temporary file in your program, you can use the
3325 @code{tmpfile} function to open it. Or you can use the @code{tmpnam}
3326 (better: @code{tmpnam_r}) function to provide a name for a temporary
3327 file and then you can open it in the usual way with @code{fopen}.
3329 The @code{tempnam} function is like @code{tmpnam} but lets you choose
3330 what directory temporary files will go in, and something about what
3331 their file names will look like. Important for multi-threaded programs
3332 is that @code{tempnam} is reentrant, while @code{tmpnam} is not since it
3333 returns a pointer to a static buffer.
3335 These facilities are declared in the header file @file{stdio.h}.
3338 @deftypefun {FILE *} tmpfile (void)
3339 @standards{ISO, stdio.h}
3340 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{} @asulock{}}@acunsafe{@acsmem{} @acsfd{} @aculock{}}}
3341 @c The unsafety issues are those of fdopen, plus @acsfd because of the
3343 @c __path_search (internal buf, !dir, const pfx, !try_tmpdir) ok
3344 @c libc_secure_genenv only if try_tmpdir
3345 @c xstat64, strlen, strcmp, sprintf
3346 @c __gen_tempname (internal tmpl, __GT_FILE) ok
3347 @c strlen, memcmp, getpid, open/mkdir/lxstat64 ok
3348 @c HP_TIMING_NOW if available ok
3349 @c gettimeofday (!tz) first time, or every time if no HP_TIMING_NOW ok
3350 @c static value is used and modified without synchronization ok
3351 @c but the use is as a source of non-cryptographic randomness
3352 @c with retries in case of collision, so it should be safe
3354 This function creates a temporary binary file for update mode, as if by
3355 calling @code{fopen} with mode @code{"wb+"}. The file is deleted
3356 automatically when it is closed or when the program terminates. (On
3357 some other @w{ISO C} systems the file may fail to be deleted if the program
3358 terminates abnormally).
3360 This function is reentrant.
3362 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
3363 32-bit system this function is in fact @code{tmpfile64}, i.e., the LFS
3364 interface transparently replaces the old interface.
3367 @deftypefun {FILE *} tmpfile64 (void)
3368 @standards{Unix98, stdio.h}
3369 @safety{@prelim{}@mtsafe{}@asunsafe{@ascuheap{} @asulock{}}@acunsafe{@acsmem{} @acsfd{} @aculock{}}}
3370 This function is similar to @code{tmpfile}, but the stream it returns a
3371 pointer to was opened using @code{tmpfile64}. Therefore this stream can
3372 be used for files larger than @twoexp{31} bytes on 32-bit machines.
3374 Please note that the return type is still @code{FILE *}. There is no
3375 special @code{FILE} type for the LFS interface.
3377 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32
3378 bits machine this function is available under the name @code{tmpfile}
3379 and so transparently replaces the old interface.
3382 @deftypefun {char *} tmpnam (char *@var{result})
3383 @standards{ISO, stdio.h}
3384 @safety{@prelim{}@mtunsafe{@mtasurace{:tmpnam/!result}}@asunsafe{}@acsafe{}}
3385 @c The passed-in buffer should not be modified concurrently with the
3387 @c __path_search (static or passed-in buf, !dir, !pfx, !try_tmpdir) ok
3388 @c __gen_tempname (internal tmpl, __GT_NOCREATE) ok
3389 This function constructs and returns a valid file name that does not
3390 refer to any existing file. If the @var{result} argument is a null
3391 pointer, the return value is a pointer to an internal static string,
3392 which might be modified by subsequent calls and therefore makes this
3393 function non-reentrant. Otherwise, the @var{result} argument should be
3394 a pointer to an array of at least @code{L_tmpnam} characters, and the
3395 result is written into that array.
3397 It is possible for @code{tmpnam} to fail if you call it too many times
3398 without removing previously-created files. This is because the limited
3399 length of the temporary file names gives room for only a finite number
3400 of different names. If @code{tmpnam} fails it returns a null pointer.
3402 @strong{Warning:} Between the time the pathname is constructed and the
3403 file is created another process might have created a file with the same
3404 name using @code{tmpnam}, leading to a possible security hole. The
3405 implementation generates names which can hardly be predicted, but when
3406 opening the file you should use the @code{O_EXCL} flag. Using
3407 @code{tmpfile} or @code{mkstemp} is a safe way to avoid this problem.
3410 @deftypefun {char *} tmpnam_r (char *@var{result})
3411 @standards{GNU, stdio.h}
3412 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3413 This function is nearly identical to the @code{tmpnam} function, except
3414 that if @var{result} is a null pointer it returns a null pointer.
3416 This guarantees reentrancy because the non-reentrant situation of
3417 @code{tmpnam} cannot happen here.
3419 @strong{Warning}: This function has the same security problems as
3423 @deftypevr Macro int L_tmpnam
3424 @standards{ISO, stdio.h}
3425 The value of this macro is an integer constant expression that
3426 represents the minimum size of a string large enough to hold a file name
3427 generated by the @code{tmpnam} function.
3430 @deftypevr Macro int TMP_MAX
3431 @standards{ISO, stdio.h}
3432 The macro @code{TMP_MAX} is a lower bound for how many temporary names
3433 you can create with @code{tmpnam}. You can rely on being able to call
3434 @code{tmpnam} at least this many times before it might fail saying you
3435 have made too many temporary file names.
3437 With @theglibc{}, you can create a very large number of temporary
3438 file names. If you actually created the files, you would probably run
3439 out of disk space before you ran out of names. Some other systems have
3440 a fixed, small limit on the number of temporary files. The limit is
3441 never less than @code{25}.
3444 @deftypefun {char *} tempnam (const char *@var{dir}, const char *@var{prefix})
3445 @standards{SVID, stdio.h}
3446 @safety{@prelim{}@mtsafe{@mtsenv{}}@asunsafe{@ascuheap{}}@acunsafe{@acsmem{}}}
3447 @c There's no way (short of being setuid) to avoid getenv("TMPDIR"),
3448 @c even with a non-NULL dir.
3450 @c __path_search (internal buf, dir, pfx, try_tmpdir) unsafe getenv
3451 @c __gen_tempname (internal tmpl, __GT_NOCREATE) ok
3453 This function generates a unique temporary file name. If @var{prefix}
3454 is not a null pointer, up to five characters of this string are used as
3455 a prefix for the file name. The return value is a string newly
3456 allocated with @code{malloc}, so you should release its storage with
3457 @code{free} when it is no longer needed.
3459 Because the string is dynamically allocated this function is reentrant.
3461 The directory prefix for the temporary file name is determined by
3462 testing each of the following in sequence. The directory must exist and
3467 The environment variable @code{TMPDIR}, if it is defined. For security
3468 reasons this only happens if the program is not SUID or SGID enabled.
3471 The @var{dir} argument, if it is not a null pointer.
3474 The value of the @code{P_tmpdir} macro.
3477 The directory @file{/tmp}.
3480 This function is defined for SVID compatibility.
3482 @strong{Warning:} Between the time the pathname is constructed and the
3483 file is created another process might have created a file with the same
3484 name using @code{tempnam}, leading to a possible security hole. The
3485 implementation generates names which can hardly be predicted, but when
3486 opening the file you should use the @code{O_EXCL} flag. Using
3487 @code{tmpfile} or @code{mkstemp} is a safe way to avoid this problem.
3489 @cindex TMPDIR environment variable
3491 @c !!! are we putting SVID/GNU/POSIX.1/BSD in here or not??
3492 @deftypevr {SVID Macro} {char *} P_tmpdir
3493 @standards{SVID, stdio.h}
3494 This macro is the name of the default directory for temporary files.
3497 Older Unix systems did not have the functions just described. Instead
3498 they used @code{mktemp} and @code{mkstemp}. Both of these functions
3499 work by modifying a file name template string you pass. The last six
3500 characters of this string must be @samp{XXXXXX}. These six @samp{X}s
3501 are replaced with six characters which make the whole string a unique
3502 file name. Usually the template string is something like
3503 @samp{/tmp/@var{prefix}XXXXXX}, and each program uses a unique @var{prefix}.
3505 @strong{NB:} Because @code{mktemp} and @code{mkstemp} modify the
3506 template string, you @emph{must not} pass string constants to them.
3507 String constants are normally in read-only storage, so your program
3508 would crash when @code{mktemp} or @code{mkstemp} tried to modify the
3509 string. These functions are declared in the header file @file{stdlib.h}.
3512 @deftypefun {char *} mktemp (char *@var{template})
3513 @standards{Unix, stdlib.h}
3514 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3515 @c __gen_tempname (caller tmpl, __GT_NOCREATE) ok
3516 The @code{mktemp} function generates a unique file name by modifying
3517 @var{template} as described above. If successful, it returns
3518 @var{template} as modified. If @code{mktemp} cannot find a unique file
3519 name, it makes @var{template} an empty string and returns that. If
3520 @var{template} does not end with @samp{XXXXXX}, @code{mktemp} returns a
3523 @strong{Warning:} Between the time the pathname is constructed and the
3524 file is created another process might have created a file with the same
3525 name using @code{mktemp}, leading to a possible security hole. The
3526 implementation generates names which can hardly be predicted, but when
3527 opening the file you should use the @code{O_EXCL} flag. Using
3528 @code{mkstemp} is a safe way to avoid this problem.
3531 @deftypefun int mkstemp (char *@var{template})
3532 @standards{BSD, stdlib.h}
3533 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{@acsfd{}}}
3534 @c __gen_tempname (caller tmpl, __GT_FILE) ok
3535 The @code{mkstemp} function generates a unique file name just as
3536 @code{mktemp} does, but it also opens the file for you with @code{open}
3537 (@pxref{Opening and Closing Files}). If successful, it modifies
3538 @var{template} in place and returns a file descriptor for that file open
3539 for reading and writing. If @code{mkstemp} cannot create a
3540 uniquely-named file, it returns @code{-1}. If @var{template} does not
3541 end with @samp{XXXXXX}, @code{mkstemp} returns @code{-1} and does not
3542 modify @var{template}.
3544 The file is opened using mode @code{0600}. If the file is meant to be
3545 used by other users this mode must be changed explicitly.
3548 Unlike @code{mktemp}, @code{mkstemp} is actually guaranteed to create a
3549 unique file that cannot possibly clash with any other program trying to
3550 create a temporary file. This is because it works by calling
3551 @code{open} with the @code{O_EXCL} flag, which says you want to create a
3552 new file and get an error if the file already exists.
3554 @deftypefun {char *} mkdtemp (char *@var{template})
3555 @standards{BSD, stdlib.h}
3556 @safety{@prelim{}@mtsafe{}@assafe{}@acsafe{}}
3557 @c __gen_tempname (caller tmpl, __GT_DIR) ok
3558 The @code{mkdtemp} function creates a directory with a unique name. If
3559 it succeeds, it overwrites @var{template} with the name of the
3560 directory, and returns @var{template}. As with @code{mktemp} and
3561 @code{mkstemp}, @var{template} should be a string ending with
3564 If @code{mkdtemp} cannot create an uniquely named directory, it returns
3565 @code{NULL} and sets @code{errno} appropriately. If @var{template} does
3566 not end with @samp{XXXXXX}, @code{mkdtemp} returns @code{NULL} and does
3567 not modify @var{template}. @code{errno} will be set to @code{EINVAL} in
3570 The directory is created using mode @code{0700}.
3573 The directory created by @code{mkdtemp} cannot clash with temporary
3574 files or directories created by other users. This is because directory
3575 creation always works like @code{open} with @code{O_EXCL}.
3576 @xref{Creating Directories}.
3578 The @code{mkdtemp} function comes from OpenBSD.
3580 @c FIXME these are undocumented:
3585 @c fstatat (there's a commented-out safety assessment for this one)
3589 @c name_to_handle_at
3591 @c open_by_handle_at