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 the GNU C library's functions for manipulating
6 files. Unlike the input and output functions described in
7 @ref{I/O on Streams} and @ref{Low-Level I/O}, these
8 functions are concerned with operating on the files themselves, rather
9 than on their contents.
11 Among the facilities described in this chapter are functions for
12 examining or modifying directories, functions for renaming and deleting
13 files, and functions for examining and setting file attributes such as
14 access permissions and modification times.
17 * Working Directory:: This is used to resolve relative
19 * Accessing Directories:: Finding out what files a directory
21 * Working on Directory Trees:: Apply actions to all files or a selectable
22 subset of a directory hierarchy.
23 * Hard Links:: Adding alternate names to a file.
24 * Symbolic Links:: A file that ``points to'' a file name.
25 * Deleting Files:: How to delete a file, and what that means.
26 * Renaming Files:: Changing a file's name.
27 * Creating Directories:: A system call just for creating a directory.
28 * File Attributes:: Attributes of individual files.
29 * Making Special Files:: How to create special files.
30 * Temporary Files:: Naming and creating temporary files.
33 @node Working Directory
34 @section Working Directory
36 @cindex current working directory
37 @cindex working directory
38 @cindex change working directory
39 Each process has associated with it a directory, called its @dfn{current
40 working directory} or simply @dfn{working directory}, that is used in
41 the resolution of relative file names (@pxref{File Name Resolution}).
43 When you log in and begin a new session, your working directory is
44 initially set to the home directory associated with your login account
45 in the system user database. You can find any user's home directory
46 using the @code{getpwuid} or @code{getpwnam} functions; see @ref{User
49 Users can change the working directory using shell commands like
50 @code{cd}. The functions described in this section are the primitives
51 used by those commands and by other programs for examining and changing
52 the working directory.
55 Prototypes for these functions are declared in the header file
61 @deftypefun {char *} getcwd (char *@var{buffer}, size_t @var{size})
62 The @code{getcwd} function returns an absolute file name representing
63 the current working directory, storing it in the character array
64 @var{buffer} that you provide. The @var{size} argument is how you tell
65 the system the allocation size of @var{buffer}.
67 The GNU library version of this function also permits you to specify a
68 null pointer for the @var{buffer} argument. Then @code{getcwd}
69 allocates a buffer automatically, as with @code{malloc}
70 (@pxref{Unconstrained Allocation}). If the @var{size} is greater than
71 zero, then the buffer is that large; otherwise, the buffer is as large
72 as necessary to hold the result.
74 The return value is @var{buffer} on success and a null pointer on failure.
75 The following @code{errno} error conditions are defined for this function:
79 The @var{size} argument is zero and @var{buffer} is not a null pointer.
82 The @var{size} argument is less than the length of the working directory
83 name. You need to allocate a bigger array and try again.
86 Permission to read or search a component of the file name was denied.
90 You could implement the behavior of GNU's @w{@code{getcwd (NULL, 0)}}
91 using only the standard behavior of @code{getcwd}:
98 char *buffer = (char *) xmalloc (size);
102 char *value = getcwd (buffer, size);
107 buffer = (char *) xmalloc (size);
113 @xref{Malloc Examples}, for information about @code{xmalloc}, which is
114 not a library function but is a customary name used in most GNU
119 @deftypefun {char *} getwd (char *@var{buffer})
120 This is similar to @code{getcwd}, but has no way to specify the size of
121 the buffer. The GNU library provides @code{getwd} only
122 for backwards compatibility with BSD.
124 The @var{buffer} argument should be a pointer to an array at least
125 @code{PATH_MAX} bytes long (@pxref{Limits for Files}). In the GNU
126 system there is no limit to the size of a file name, so this is not
127 necessarily enough space to contain the directory name. That is why
128 this function is deprecated.
133 @deftypefun int chdir (const char *@var{filename})
134 This function is used to set the process's working directory to
137 The normal, successful return value from @code{chdir} is @code{0}. A
138 value of @code{-1} is returned to indicate an error. The @code{errno}
139 error conditions defined for this function are the usual file name
140 syntax errors (@pxref{File Name Errors}), plus @code{ENOTDIR} if the
141 file @var{filename} is not a directory.
145 @node Accessing Directories
146 @section Accessing Directories
147 @cindex accessing directories
148 @cindex reading from a directory
149 @cindex directories, accessing
151 The facilities described in this section let you read the contents of a
152 directory file. This is useful if you want your program to list all the
153 files in a directory, perhaps as part of a menu.
155 @cindex directory stream
156 The @code{opendir} function opens a @dfn{directory stream} whose
157 elements are directory entries. You use the @code{readdir} function on
158 the directory stream to retrieve these entries, represented as
159 @w{@code{struct dirent}} objects. The name of the file for each entry is
160 stored in the @code{d_name} member of this structure. There are obvious
161 parallels here to the stream facilities for ordinary files, described in
162 @ref{I/O on Streams}.
165 * Directory Entries:: Format of one directory entry.
166 * Opening a Directory:: How to open a directory stream.
167 * Reading/Closing Directory:: How to read directory entries from the stream.
168 * Simple Directory Lister:: A very simple directory listing program.
169 * Random Access Directory:: Rereading part of the directory
170 already read with the same stream.
171 * Scanning Directory Content:: Get entries for user selected subset of
172 contents in given directory.
173 * Simple Directory Lister Mark II:: Revised version of the program.
176 @node Directory Entries
177 @subsection Format of a Directory Entry
180 This section describes what you find in a single directory entry, as you
181 might obtain it from a directory stream. All the symbols are declared
182 in the header file @file{dirent.h}.
186 @deftp {Data Type} {struct dirent}
187 This is a structure type used to return information about directory
188 entries. It contains the following fields:
192 This is the null-terminated file name component. This is the only
193 field you can count on in all POSIX systems.
196 This is the file serial number. For BSD compatibility, you can also
197 refer to this member as @code{d_ino}. In the GNU system and most POSIX
198 systems, for most files this the same as the @code{st_ino} member that
199 @code{stat} will return for the file. @xref{File Attributes}.
201 @item unsigned char d_namlen
202 This is the length of the file name, not including the terminating null
203 character. Its type is @code{unsigned char} because that is the integer
204 type of the appropriate size
206 @item unsigned char d_type
207 This is the type of the file, possibly unknown. The following constants
208 are defined for its value:
212 The type is unknown. On some systems this is the only value returned.
221 A named pipe, or FIFO. @xref{FIFO Special Files}.
224 A local-domain socket. @c !!! @xref{Local Domain}.
233 This member is a BSD extension. On systems where it is used, it
234 corresponds to the file type bits in the @code{st_mode} member of
235 @code{struct statbuf}. On other systems it will always be DT_UNKNOWN.
236 These two macros convert between @code{d_type} values and @code{st_mode}
239 @deftypefun int IFTODT (mode_t @var{mode})
240 This returns the @code{d_type} value corresponding to @var{mode}.
243 @deftypefun mode_t DTTOIF (int @var{dtype})
244 This returns the @code{st_mode} value corresponding to @var{dtype}.
248 This structure may contain additional members in the future.
250 When a file has multiple names, each name has its own directory entry.
251 The only way you can tell that the directory entries belong to a
252 single file is that they have the same value for the @code{d_fileno}
255 File attributes such as size, modification times, and the like are part
256 of the file itself, not any particular directory entry. @xref{File
260 @node Opening a Directory
261 @subsection Opening a Directory Stream
264 This section describes how to open a directory stream. All the symbols
265 are declared in the header file @file{dirent.h}.
269 @deftp {Data Type} DIR
270 The @code{DIR} data type represents a directory stream.
273 You shouldn't ever allocate objects of the @code{struct dirent} or
274 @code{DIR} data types, since the directory access functions do that for
275 you. Instead, you refer to these objects using the pointers returned by
276 the following functions.
280 @deftypefun {DIR *} opendir (const char *@var{dirname})
281 The @code{opendir} function opens and returns a directory stream for
282 reading the directory whose file name is @var{dirname}. The stream has
285 If unsuccessful, @code{opendir} returns a null pointer. In addition to
286 the usual file name errors (@pxref{File Name Errors}), the
287 following @code{errno} error conditions are defined for this function:
291 Read permission is denied for the directory named by @code{dirname}.
294 The process has too many files open.
297 The entire system, or perhaps the file system which contains the
298 directory, cannot support any additional open files at the moment.
299 (This problem cannot happen on the GNU system.)
302 The @code{DIR} type is typically implemented using a file descriptor,
303 and the @code{opendir} function in terms of the @code{open} function.
304 @xref{Low-Level I/O}. Directory streams and the underlying
305 file descriptors are closed on @code{exec} (@pxref{Executing a File}).
308 @node Reading/Closing Directory
309 @subsection Reading and Closing a Directory Stream
312 This section describes how to read directory entries from a directory
313 stream, and how to close the stream when you are done with it. All the
314 symbols are declared in the header file @file{dirent.h}.
318 @deftypefun {struct dirent *} readdir (DIR *@var{dirstream})
319 This function reads the next entry from the directory. It normally
320 returns a pointer to a structure containing information about the file.
321 This structure is statically allocated and can be rewritten by a
324 @strong{Portability Note:} On some systems, @code{readdir} may not
325 return entries for @file{.} and @file{..}, even though these are always
326 valid file names in any directory. @xref{File Name Resolution}.
328 If there are no more entries in the directory or an error is detected,
329 @code{readdir} returns a null pointer. The following @code{errno} error
330 conditions are defined for this function:
334 The @var{dirstream} argument is not valid.
337 @code{readdir} is not thread safe. Multiple threads using
338 @code{readdir} on the same @var{dirstream} may overwrite the return
339 value. Use @code{readdir_r} when this is critical.
344 @deftypefun int readdir_r (DIR *@var{dirstream}, struct dirent *@var{entry}, struct dirent **@var{result})
345 This function is the reentrant version of @code{readdir}. Like
346 @code{readdir} it returns the next entry from the directory. But to
347 prevent conflicts for simultaneously running threads the result is not
348 stored in some internal memory. Instead the argument @var{entry} has to
349 point to a place where the result is stored.
351 The return value is @code{0} in case the next entry was read
352 successfully. In this case a pointer to the result is returned in
353 *@var{result}. It is not required that *@var{result} is the same as
354 @var{entry}. If something goes wrong while executing @code{readdir_r}
355 the function returns a value indicating the error (as described for
358 If there are no more directory entries, @code{readdir_r}'s return value is
359 @code{0}, and *@var{result} is set to @code{NULL}.
361 @strong{Portability Note:} On some systems, @code{readdir_r} may not
362 return a terminated string as the file name even if no @code{d_reclen}
363 element is available in @code{struct dirent} and the file name as the
364 maximal allowed size. Modern systems all have the @code{d_reclen} field
365 and on old systems multi threading is not critical. In any case, there
366 is no such problem with the @code{readdir} function so that even on
367 systems without @code{d_reclen} field one could use multiple threads by
368 using external locking.
373 @deftypefun int closedir (DIR *@var{dirstream})
374 This function closes the directory stream @var{dirstream}. It returns
375 @code{0} on success and @code{-1} on failure.
377 The following @code{errno} error conditions are defined for this
382 The @var{dirstream} argument is not valid.
386 @node Simple Directory Lister
387 @subsection Simple Program to List a Directory
389 Here's a simple program that prints the names of the files in
390 the current working directory:
396 The order in which files appear in a directory tends to be fairly
397 random. A more useful program would sort the entries (perhaps by
398 alphabetizing them) before printing them; see
399 @ref{Scanning Directory Content} and @ref{Array Sort Function}.
402 @node Random Access Directory
403 @subsection Random Access in a Directory Stream
406 This section describes how to reread parts of a directory that you have
407 already read from an open directory stream. All the symbols are
408 declared in the header file @file{dirent.h}.
412 @deftypefun void rewinddir (DIR *@var{dirstream})
413 The @code{rewinddir} function is used to reinitialize the directory
414 stream @var{dirstream}, so that if you call @code{readdir} it
415 returns information about the first entry in the directory again. This
416 function also notices if files have been added or removed to the
417 directory since it was opened with @code{opendir}. (Entries for these
418 files might or might not be returned by @code{readdir} if they were
419 added or removed since you last called @code{opendir} or
425 @deftypefun off_t telldir (DIR *@var{dirstream})
426 The @code{telldir} function returns the file position of the directory
427 stream @var{dirstream}. You can use this value with @code{seekdir} to
428 restore the directory stream to that position.
433 @deftypefun void seekdir (DIR *@var{dirstream}, off_t @var{pos})
434 The @code{seekdir} function sets the file position of the directory
435 stream @var{dirstream} to @var{pos}. The value @var{pos} must be the
436 result of a previous call to @code{telldir} on this particular stream;
437 closing and reopening the directory can invalidate values returned by
442 @node Scanning Directory Content
443 @subsection Scanning the Content of a Directory
445 A higher-level interface to the directory handling functions is the
446 @code{scandir} function. With its help one can select a subset of the
447 entries in a directory, possibly sort them and get as the result a list
452 @deftypefun int scandir (const char *@var{dir}, struct dirent ***@var{namelist}, int (*@var{selector}) (const struct dirent *), int (*@var{cmp}) (const void *, const void *))
454 The @code{scandir} function scans the contents of the directory selected
455 by @var{dir}. The result in @var{namelist} is an array of pointers to
456 structure of type @code{struct dirent} which describe all selected
457 directory entries and which is allocated using @code{malloc}. Instead
458 of always getting all directory entries returned, the user supplied
459 function @var{selector} can be used to decide which entries are in the
460 result. Only the entries for which @var{selector} returns a nonzero
463 Finally the entries in the @var{namelist} are sorted using the user
464 supplied function @var{cmp}. The arguments of the @var{cmp} function
465 are of type @code{struct dirent **}. I.e., one cannot directly use the
466 @code{strcmp} or @code{strcoll} function; see the functions
467 @code{alphasort} and @code{versionsort} below.
469 The return value of the function gives the number of entries placed in
470 @var{namelist}. If it is @code{-1} an error occurred (either the
471 directory could not be opened for reading or the malloc call failed) and
472 the global variable @code{errno} contains more information on the error.
475 As said above the fourth argument to the @code{scandir} function must be
476 a pointer to a sorting function. For the convenience of the programmer
477 the GNU C library contains implementations of functions which are very
478 helpful for this purpose.
482 @deftypefun int alphasort (const void *@var{a}, const void *@var{b})
483 The @code{alphasort} function behaves like the @code{strcoll} function
484 (@pxref{String/Array Comparison}). The difference is that the arguments
485 are not string pointers but instead they are of type
486 @code{struct dirent **}.
488 Return value of @code{alphasort} is less than, equal to, or greater than
489 zero depending on the order of the two entries @var{a} and @var{b}.
494 @deftypefun int versionsort (const void *@var{a}, const void *@var{b})
495 The @code{versionsort} function is like @code{alphasort}, excepted that it
496 uses the @code{strverscmp} function internally.
499 If the filesystem supports large files we cannot use the @code{scandir}
500 anymore since the @code{dirent} structure might not able to contain all
501 the information. The LFS provides the new type @w{@code{struct
502 dirent64}}. To use this we need a new function.
506 @deftypefun int scandir64 (const char *@var{dir}, struct dirent64 ***@var{namelist}, int (*@var{selector}) (const struct dirent64 *), int (*@var{cmp}) (const void *, const void *))
507 The @code{scandir64} function works like the @code{scandir} function
508 only that the directory entries it returns are described by elements of
509 type @w{@code{struct dirent64}}. The function pointed to by
510 @var{selector} is again used to select the wanted entries only that
511 @var{selector} now must point to a function which takes a
512 @w{@code{struct dirent64 *}} parameter.
514 The @var{cmp} now must be a function which expects its two arguments to
515 be of type @code{struct dirent64 **}.
518 As just said the function expected as the fourth is different from the
519 function expected in @code{scandir}. Therefore we cannot use the
520 @code{alphasort} and @code{versionsort} functions anymore. Instead we
521 have two similar functions available.
525 @deftypefun int alphasort64 (const void *@var{a}, const void *@var{b})
526 The @code{alphasort64} function behaves like the @code{strcoll} function
527 (@pxref{String/Array Comparison}). The difference is that the arguments
528 are not string pointers but instead they are of type
529 @code{struct dirent64 **}.
531 Return value of @code{alphasort64} is less than, equal to, or greater
532 than zero depending on the order of the two entries @var{a} and @var{b}.
537 @deftypefun int versionsort64 (const void *@var{a}, const void *@var{b})
538 The @code{versionsort64} function is like @code{alphasort64}, excepted that it
539 uses the @code{strverscmp} function internally.
542 It is important not to mix the use of @code{scandir} and the 64 bits
543 comparison functions or vice versa. There are systems on which this
544 works but on others it will fail miserably.
546 @node Simple Directory Lister Mark II
547 @subsection Simple Program to List a Directory, Mark II
549 Here is a revised version of the directory lister found above
550 (@pxref{Simple Directory Lister}). Using the @code{scandir} function we
551 can avoid using the functions which directly work with the directory
552 contents. After the call the found entries are available for direct
559 Please note the simple selector function for this example. Since
560 we want to see all directory entries we always return @code{1}.
563 @node Working on Directory Trees
564 @section Working on Directory Trees
565 @cindex directory hierarchy
566 @cindex hierarchy, directory
567 @cindex tree, directory
569 The functions to handle files in directories described so far allowed to
570 retrieve all the information in small pieces or process all files in a
571 directory (see @code{scandir}). Sometimes it is useful to process whole
572 hierarchies of directories and the contained files. The X/Open
573 specification define two functions to do this. The simpler form is
574 derived from an early definition in @w{System V} systems and therefore
575 this function is available on SVID derived systems. The prototypes and
576 required definitions can be found in the @file{ftw.h} header.
578 Both functions of this @code{ftw} family take as one of the arguments a
579 reference to a callback function. The functions must be of these types.
583 @deftp {Data Type} __ftw_func_t
586 int (*) (const char *, const struct stat *, int)
589 Type for callback functions given to the @code{ftw} function. The first
590 parameter will contain a pointer to the filename, the second parameter
591 will point to an object of type @code{struct stat} which will be filled
592 for the file named by the first parameter.
595 The last parameter is a flag given more information about the current
596 file. It can have the following values:
600 The current item is a normal file or files which do not fit into one of
601 the following categories. This means especially special files, sockets
604 The current item is a directory.
606 The @code{stat} call to fill the object pointed to by the second
607 parameter failed and so the information is invalid.
609 The item is a directory which cannot be read.
611 The item is a symbolic link. Since symbolic links are normally followed
612 seeing this value in a @code{ftw} callback function means the referenced
613 file does not exist. The situation for @code{nftw} is different.
615 This value is only available if the program is compiled with
616 @code{_BSD_SOURCE} or @code{_XOPEN_EXTENDED} defined before including
617 the first header. The original SVID systems do not have symbolic links.
620 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
621 type is in fact @code{__ftw64_func_t} since this mode also changes
622 @code{struct stat} to be @code{struct stat64}.
625 For the LFS interface and the use in the function @code{ftw64} the
626 header @file{ftw.h} defines another function type.
630 @deftp {Data Type} __ftw64_func_t
633 int (*) (const char *, const struct stat64 *, int)
636 This type is used just like @code{__ftw_func_t} for the callback
637 function, but this time called from @code{ftw64}. The second parameter
638 to the function is this time a pointer to a variable of type
639 @code{struct stat64} which is able to represent the larger values.
644 @deftp {Data Type} __nftw_func_t
647 int (*) (const char *, const struct stat *, int, struct FTW *)
652 The first three arguments have the same as for the @code{__ftw_func_t}
653 type. A difference is that for the third argument some additional
654 values are defined to allow finer differentiation:
657 The current item is a directory and all subdirectories have already been
658 visited and reported. This flag is returned instead of @code{FTW_D} if
659 the @code{FTW_DEPTH} flag is given to @code{nftw} (see below).
661 The current item is a stale symbolic link. The file it points to does
665 The last parameter of the callback function is a pointer to a structure
666 with some extra information as described below.
668 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
669 type is in fact @code{__nftw64_func_t} since this mode also changes
670 @code{struct stat} to be @code{struct stat64}.
673 For the LFS interface there is also a variant of this data type
674 available which has to be used with the @code{nftw64} function.
678 @deftp {Data Type} __nftw64_func_t
681 int (*) (const char *, const struct stat64 *, int, struct FTW *)
684 This type is used just like @code{__nftw_func_t} for the callback
685 function, but this time called from @code{nftw64}. The second parameter
686 to the function is this time a pointer to a variable of type
687 @code{struct stat64} which is able to represent the larger values.
692 @deftp {Data Type} {struct FTW}
693 The contained information helps to interpret the name parameter and
694 gives some information about current state of the traversal of the
699 The value specifies which part of the filename argument given in the
700 first parameter to the callback function is the name of the file. The
701 rest of the string is the path to locate the file. This information is
702 especially important if the @code{FTW_CHDIR} flag for @code{nftw} was
703 set since then the current directory is the one the current item is
706 While processing the directory the functions tracks how many directories
707 have been examine to find the current item. This nesting level is
708 @math{0} for the item given starting item (file or directory) and is
709 incremented by one for each entered directory.
716 @deftypefun int ftw (const char *@var{filename}, __ftw_func_t @var{func}, int @var{descriptors})
717 The @code{ftw} function calls the callback function given in the
718 parameter @var{func} for every item which is found in the directory
719 specified by @var{filename} and all directories below. The function
720 follows symbolic links if necessary but does not process an item twice.
721 If @var{filename} names no directory this item is the only object
722 reported by calling the callback function.
724 The filename given to the callback function is constructed by taking the
725 @var{filename} parameter and appending the names of all passed
726 directories and then the local file name. So the callback function can
727 use this parameter to access the file. Before the callback function is
728 called @code{ftw} calls @code{stat} for this file and passes the
729 information up to the callback function. If this @code{stat} call was
730 not successful the failure is indicated by setting the falg argument of
731 the callback function to @code{FTW_NS}. Otherwise the flag is set
732 according to the description given in the description of
733 @code{__ftw_func_t} above.
735 The callback function is expected to return @math{0} to indicate that no
736 error occurred and the processing should be continued. If an error
737 occurred in the callback function or the call to @code{ftw} shall return
738 immediately the callback function can return a value other than
739 @math{0}. This is the only correct way to stop the function. The
740 program must not use @code{setjmp} or similar techniques to continue the
741 program in another place. This would leave the resources allocated in
742 the @code{ftw} function allocated.
744 The @var{descriptors} parameter to the @code{ftw} function specifies how
745 many file descriptors the @code{ftw} function is allowed to consume.
746 The more descriptors can be used the faster the function can run. For
747 each level of directories at most one descriptor is used so that for
748 very deep directory hierarchies the limit on open file descriptors for
749 the process or the system can be exceeded. Beside this the limit on
750 file descriptors is counted together for all threads in a multi-threaded
751 program and therefore it is always good too limit the maximal number of
752 open descriptors to a reasonable number.
754 The return value of the @code{ftw} function is @math{0} if all callback
755 function calls returned @math{0} and all actions performed by the
756 @code{ftw} succeeded. If some function call failed (other than calling
757 @code{stat} on an item) the function return @math{-1}. If a callback
758 function returns a value other than @math{0} this value is returned as
759 the return value of @code{ftw}.
761 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
762 32 bits system this function is in fact @code{ftw64}. I.e., the LFS
763 interface transparently replaces the old interface.
768 @deftypefun int ftw64 (const char *@var{filename}, __ftw64_func_t @var{func}, int @var{descriptors})
769 This function is similar to @code{ftw} but it can work on filesystems
770 with large files since the information about the files is reported using
771 a variable of type @code{struct stat64} which is passed by reference to
772 the callback function.
774 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
775 32 bits system this function is available under the name @code{ftw} and
776 transparently replaces the old implementation.
781 @deftypefun int nftw (const char *@var{filename}, __nftw_func_t @var{func}, int @var{descriptors}, int @var{flag})
782 The @code{nftw} functions works like the @code{ftw} functions. It calls
783 the callback function @var{func} for all items it finds in the directory
784 @var{filename} and below. At most @var{descriptors} file descriptors
785 are consumed during the @code{nftw} call.
787 The differences are that for one the callback function is of a different
788 type. It is of type @w{@code{struct FTW *}} and provides the callback
789 functions the information described above.
791 The second difference is that @code{nftw} takes an additional fourth
792 argument which is @math{0} or a combination of any of the following
793 values, combined using bitwise OR.
797 While traversing the directory symbolic links are not followed. I.e.,
798 if this flag is given symbolic links are reported using the
799 @code{FTW_SL} value for the type parameter to the callback function.
800 Please note that if this flag is used the appearance of @code{FTW_SL} in
801 a callback function does not mean the referenced file does not exist.
802 To indicate this the extra value @code{FTW_SLN} exists.
804 The callback function is only called for items which are on the same
805 mounted filesystem as the directory given as the @var{filename}
806 parameter to @code{nftw}.
808 If this flag is given the current working directory is changed to the
809 directory containing the reported object before the callback function is
812 If this option is given the function visits first all files and
813 subdirectories before the callback function is called for the directory
814 itself (depth-first processing). This also means the type flag given to
815 the callback function is @code{FTW_DP} and not @code{FTW_D}.
818 The return value is computed in the same way as for @code{ftw}.
819 @code{nftw} return @math{0} if no failure occurred in @code{nftw} and
820 all callback function call return values are also @math{0}. For
821 internal errors such as memory problems @math{-1} is returned and
822 @var{errno} is set accordingly. If the return value of a callback
823 invocation is nonzero this very same value is returned.
825 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
826 32 bits system this function is in fact @code{nftw64}. I.e., the LFS
827 interface transparently replaces the old interface.
832 @deftypefun int nftw64 (const char *@var{filename}, __nftw64_func_t @var{func}, int @var{descriptors}, int @var{flag})
833 This function is similar to @code{nftw} but it can work on filesystems
834 with large files since the information about the files is reported using
835 a variable of type @code{struct stat64} which is passed by reference to
836 the callback function.
838 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
839 32 bits system this function is available under the name @code{nftw} and
840 transparently replaces the old implementation.
848 @cindex multiple names for one file
849 @cindex file names, multiple
851 In POSIX systems, one file can have many names at the same time. All of
852 the names are equally real, and no one of them is preferred to the
855 To add a name to a file, use the @code{link} function. (The new name is
856 also called a @dfn{hard link} to the file.) Creating a new link to a
857 file does not copy the contents of the file; it simply makes a new name
858 by which the file can be known, in addition to the file's existing name
861 One file can have names in several directories, so the organization
862 of the file system is not a strict hierarchy or tree.
864 In most implementations, it is not possible to have hard links to the
865 same file in multiple file systems. @code{link} reports an error if you
866 try to make a hard link to the file from another file system when this
869 The prototype for the @code{link} function is declared in the header
870 file @file{unistd.h}.
875 @deftypefun int link (const char *@var{oldname}, const char *@var{newname})
876 The @code{link} function makes a new link to the existing file named by
877 @var{oldname}, under the new name @var{newname}.
879 This function returns a value of @code{0} if it is successful and
880 @code{-1} on failure. In addition to the usual file name errors
881 (@pxref{File Name Errors}) for both @var{oldname} and @var{newname}, the
882 following @code{errno} error conditions are defined for this function:
886 You are not allowed to write the directory in which the new link is to
889 Some implementations also require that the existing file be accessible
890 by the caller, and use this error to report failure for that reason.
894 There is already a file named @var{newname}. If you want to replace
895 this link with a new link, you must remove the old link explicitly first.
898 There are already too many links to the file named by @var{oldname}.
899 (The maximum number of links to a file is @w{@code{LINK_MAX}}; see
900 @ref{Limits for Files}.)
903 The file named by @var{oldname} doesn't exist. You can't make a link to
904 a file that doesn't exist.
907 The directory or file system that would contain the new link is full
908 and cannot be extended.
911 In the GNU system and some others, you cannot make links to directories.
912 Many systems allow only privileged users to do so. This error
913 is used to report the problem.
916 The directory containing the new link can't be modified because it's on
917 a read-only file system.
920 The directory specified in @var{newname} is on a different file system
921 than the existing file.
924 A hardware error occurred while trying to read or write the to filesystem.
929 @section Symbolic Links
932 @cindex symbolic link
933 @cindex link, symbolic
935 The GNU system supports @dfn{soft links} or @dfn{symbolic links}. This
936 is a kind of ``file'' that is essentially a pointer to another file
937 name. Unlike hard links, symbolic links can be made to directories or
938 across file systems with no restrictions. You can also make a symbolic
939 link to a name which is not the name of any file. (Opening this link
940 will fail until a file by that name is created.) Likewise, if the
941 symbolic link points to an existing file which is later deleted, the
942 symbolic link continues to point to the same file name even though the
943 name no longer names any file.
945 The reason symbolic links work the way they do is that special things
946 happen when you try to open the link. The @code{open} function realizes
947 you have specified the name of a link, reads the file name contained in
948 the link, and opens that file name instead. The @code{stat} function
949 likewise operates on the file that the symbolic link points to, instead
950 of on the link itself.
952 By contrast, other operations such as deleting or renaming the file
953 operate on the link itself. The functions @code{readlink} and
954 @code{lstat} also refrain from following symbolic links, because their
955 purpose is to obtain information about the link. So does @code{link},
956 the function that makes a hard link---it makes a hard link to the
957 symbolic link, which one rarely wants.
959 Prototypes for the functions listed in this section are in
965 @deftypefun int symlink (const char *@var{oldname}, const char *@var{newname})
966 The @code{symlink} function makes a symbolic link to @var{oldname} named
969 The normal return value from @code{symlink} is @code{0}. A return value
970 of @code{-1} indicates an error. In addition to the usual file name
971 syntax errors (@pxref{File Name Errors}), the following @code{errno}
972 error conditions are defined for this function:
976 There is already an existing file named @var{newname}.
979 The file @var{newname} would exist on a read-only file system.
982 The directory or file system cannot be extended to make the new link.
985 A hardware error occurred while reading or writing data on the disk.
988 @comment not sure about these
990 There are too many levels of indirection. This can be the result of
991 circular symbolic links to directories.
994 The new link can't be created because the user's disk quota has been
1002 @deftypefun int readlink (const char *@var{filename}, char *@var{buffer}, size_t @var{size})
1003 The @code{readlink} function gets the value of the symbolic link
1004 @var{filename}. The file name that the link points to is copied into
1005 @var{buffer}. This file name string is @emph{not} null-terminated;
1006 @code{readlink} normally returns the number of characters copied. The
1007 @var{size} argument specifies the maximum number of characters to copy,
1008 usually the allocation size of @var{buffer}.
1010 If the return value equals @var{size}, you cannot tell whether or not
1011 there was room to return the entire name. So make a bigger buffer and
1012 call @code{readlink} again. Here is an example:
1016 readlink_malloc (char *filename)
1022 char *buffer = (char *) xmalloc (size);
1023 int nchars = readlink (filename, buffer, size);
1032 @c @group Invalid outside example.
1033 A value of @code{-1} is returned in case of error. In addition to the
1034 usual file name errors (@pxref{File Name Errors}), the following
1035 @code{errno} error conditions are defined for this function:
1039 The named file is not a symbolic link.
1042 A hardware error occurred while reading or writing data on the disk.
1047 @node Deleting Files
1048 @section Deleting Files
1049 @cindex deleting a file
1050 @cindex removing a file
1051 @cindex unlinking a file
1053 You can delete a file with the functions @code{unlink} or @code{remove}.
1055 Deletion actually deletes a file name. If this is the file's only name,
1056 then the file is deleted as well. If the file has other names as well
1057 (@pxref{Hard Links}), it remains accessible under its other names.
1061 @deftypefun int unlink (const char *@var{filename})
1062 The @code{unlink} function deletes the file name @var{filename}. If
1063 this is a file's sole name, the file itself is also deleted. (Actually,
1064 if any process has the file open when this happens, deletion is
1065 postponed until all processes have closed the file.)
1068 The function @code{unlink} is declared in the header file @file{unistd.h}.
1070 This function returns @code{0} on successful completion, and @code{-1}
1071 on error. In addition to the usual file name errors
1072 (@pxref{File Name Errors}), the following @code{errno} error conditions are
1073 defined for this function:
1077 Write permission is denied for the directory from which the file is to be
1078 removed, or the directory has the sticky bit set and you do not own the file.
1081 This error indicates that the file is being used by the system in such a
1082 way that it can't be unlinked. For example, you might see this error if
1083 the file name specifies the root directory or a mount point for a file
1087 The file name to be deleted doesn't exist.
1090 On some systems, @code{unlink} cannot be used to delete the name of a
1091 directory, or can only be used this way by a privileged user.
1092 To avoid such problems, use @code{rmdir} to delete directories.
1093 (In the GNU system @code{unlink} can never delete the name of a directory.)
1096 The directory in which the file name is to be deleted is on a read-only
1097 file system, and can't be modified.
1103 @deftypefun int rmdir (const char *@var{filename})
1104 @cindex directories, deleting
1105 @cindex deleting a directory
1106 The @code{rmdir} function deletes a directory. The directory must be
1107 empty before it can be removed; in other words, it can only contain
1108 entries for @file{.} and @file{..}.
1110 In most other respects, @code{rmdir} behaves like @code{unlink}. There
1111 are two additional @code{errno} error conditions defined for
1117 The directory to be deleted is not empty.
1120 These two error codes are synonymous; some systems use one, and some use
1121 the other. The GNU system always uses @code{ENOTEMPTY}.
1123 The prototype for this function is declared in the header file
1130 @deftypefun int remove (const char *@var{filename})
1131 This is the @w{ISO C} function to remove a file. It works like
1132 @code{unlink} for files and like @code{rmdir} for directories.
1133 @code{remove} is declared in @file{stdio.h}.
1137 @node Renaming Files
1138 @section Renaming Files
1140 The @code{rename} function is used to change a file's name.
1142 @cindex renaming a file
1145 @deftypefun int rename (const char *@var{oldname}, const char *@var{newname})
1146 The @code{rename} function renames the file name @var{oldname} with
1147 @var{newname}. The file formerly accessible under the name
1148 @var{oldname} is afterward accessible as @var{newname} instead. (If the
1149 file had any other names aside from @var{oldname}, it continues to have
1152 The directory containing the name @var{newname} must be on the same
1153 file system as the file (as indicated by the name @var{oldname}).
1155 One special case for @code{rename} is when @var{oldname} and
1156 @var{newname} are two names for the same file. The consistent way to
1157 handle this case is to delete @var{oldname}. However, POSIX requires
1158 that in this case @code{rename} do nothing and report success---which is
1159 inconsistent. We don't know what your operating system will do.
1161 If the @var{oldname} is not a directory, then any existing file named
1162 @var{newname} is removed during the renaming operation. However, if
1163 @var{newname} is the name of a directory, @code{rename} fails in this
1166 If the @var{oldname} is a directory, then either @var{newname} must not
1167 exist or it must name a directory that is empty. In the latter case,
1168 the existing directory named @var{newname} is deleted first. The name
1169 @var{newname} must not specify a subdirectory of the directory
1170 @code{oldname} which is being renamed.
1172 One useful feature of @code{rename} is that the meaning of the name
1173 @var{newname} changes ``atomically'' from any previously existing file
1174 by that name to its new meaning (the file that was called
1175 @var{oldname}). There is no instant at which @var{newname} is
1176 nonexistent ``in between'' the old meaning and the new meaning. If
1177 there is a system crash during the operation, it is possible for both
1178 names to still exist; but @var{newname} will always be intact if it
1181 If @code{rename} fails, it returns @code{-1}. In addition to the usual
1182 file name errors (@pxref{File Name Errors}), the following
1183 @code{errno} error conditions are defined for this function:
1187 One of the directories containing @var{newname} or @var{oldname}
1188 refuses write permission; or @var{newname} and @var{oldname} are
1189 directories and write permission is refused for one of them.
1192 A directory named by @var{oldname} or @var{newname} is being used by
1193 the system in a way that prevents the renaming from working. This includes
1194 directories that are mount points for filesystems, and directories
1195 that are the current working directories of processes.
1199 The directory @var{newname} isn't empty. The GNU system always returns
1200 @code{ENOTEMPTY} for this, but some other systems return @code{EEXIST}.
1203 The @var{oldname} is a directory that contains @var{newname}.
1206 The @var{newname} names a directory, but the @var{oldname} doesn't.
1209 The parent directory of @var{newname} would have too many links.
1212 The file named by @var{oldname} doesn't exist.
1215 The directory that would contain @var{newname} has no room for another
1216 entry, and there is no space left in the file system to expand it.
1219 The operation would involve writing to a directory on a read-only file
1223 The two file names @var{newname} and @var{oldnames} are on different
1228 @node Creating Directories
1229 @section Creating Directories
1230 @cindex creating a directory
1231 @cindex directories, creating
1234 Directories are created with the @code{mkdir} function. (There is also
1235 a shell command @code{mkdir} which does the same thing.)
1240 @deftypefun int mkdir (const char *@var{filename}, mode_t @var{mode})
1241 The @code{mkdir} function creates a new, empty directory whose name is
1244 The argument @var{mode} specifies the file permissions for the new
1245 directory file. @xref{Permission Bits}, for more information about
1248 A return value of @code{0} indicates successful completion, and
1249 @code{-1} indicates failure. In addition to the usual file name syntax
1250 errors (@pxref{File Name Errors}), the following @code{errno} error
1251 conditions are defined for this function:
1255 Write permission is denied for the parent directory in which the new
1256 directory is to be added.
1259 A file named @var{filename} already exists.
1262 The parent directory has too many links.
1264 Well-designed file systems never report this error, because they permit
1265 more links than your disk could possibly hold. However, you must still
1266 take account of the possibility of this error, as it could result from
1267 network access to a file system on another machine.
1270 The file system doesn't have enough room to create the new directory.
1273 The parent directory of the directory being created is on a read-only
1274 file system, and cannot be modified.
1277 To use this function, your program should include the header file
1282 @node File Attributes
1283 @section File Attributes
1286 When you issue an @samp{ls -l} shell command on a file, it gives you
1287 information about the size of the file, who owns it, when it was last
1288 modified, and the like. This kind of information is called the
1289 @dfn{file attributes}; it is associated with the file itself and not a
1290 particular one of its names.
1292 This section contains information about how you can inquire about and
1293 modify these attributes of files.
1296 * Attribute Meanings:: The names of the file attributes,
1297 and what their values mean.
1298 * Reading Attributes:: How to read the attributes of a file.
1299 * Testing File Type:: Distinguishing ordinary files,
1300 directories, links...
1301 * File Owner:: How ownership for new files is determined,
1302 and how to change it.
1303 * Permission Bits:: How information about a file's access
1305 * Access Permission:: How the system decides who can access a file.
1306 * Setting Permissions:: How permissions for new files are assigned,
1307 and how to change them.
1308 * Testing File Access:: How to find out if your process can
1310 * File Times:: About the time attributes of a file.
1311 * File Size:: Manually changing the size of a file.
1314 @node Attribute Meanings
1315 @subsection What the File Attribute Values Mean
1316 @cindex status of a file
1317 @cindex attributes of a file
1318 @cindex file attributes
1320 When you read the attributes of a file, they come back in a structure
1321 called @code{struct stat}. This section describes the names of the
1322 attributes, their data types, and what they mean. For the functions
1323 to read the attributes of a file, see @ref{Reading Attributes}.
1325 The header file @file{sys/stat.h} declares all the symbols defined
1331 @deftp {Data Type} {struct stat}
1332 The @code{stat} structure type is used to return information about the
1333 attributes of a file. It contains at least the following members:
1336 @item mode_t st_mode
1337 Specifies the mode of the file. This includes file type information
1338 (@pxref{Testing File Type}) and the file permission bits
1339 (@pxref{Permission Bits}).
1342 The file serial number, which distinguishes this file from all other
1343 files on the same device.
1346 Identifies the device containing the file. The @code{st_ino} and
1347 @code{st_dev}, taken together, uniquely identify the file. The
1348 @code{st_dev} value is not necessarily consistent across reboots or
1349 system crashes, however.
1351 @item nlink_t st_nlink
1352 The number of hard links to the file. This count keeps track of how
1353 many directories have entries for this file. If the count is ever
1354 decremented to zero, then the file itself is discarded as soon as no
1355 process still holds it open. Symbolic links are not counted in the
1359 The user ID of the file's owner. @xref{File Owner}.
1362 The group ID of the file. @xref{File Owner}.
1365 This specifies the size of a regular file in bytes. For files that
1366 are really devices and the like, this field isn't usually meaningful.
1367 For symbolic links, this specifies the length of the file name the link
1370 @item time_t st_atime
1371 This is the last access time for the file. @xref{File Times}.
1373 @item unsigned long int st_atime_usec
1374 This is the fractional part of the last access time for the file.
1377 @item time_t st_mtime
1378 This is the time of the last modification to the contents of the file.
1381 @item unsigned long int st_mtime_usec
1382 This is the fractional part of the time of last modification to the
1383 contents of the file. @xref{File Times}.
1385 @item time_t st_ctime
1386 This is the time of the last modification to the attributes of the file.
1389 @item unsigned long int st_ctime_usec
1390 This is the fractional part of the time of last modification to the
1391 attributes of the file. @xref{File Times}.
1394 @item blkcnt_t st_blocks
1395 This is the amount of disk space that the file occupies, measured in
1396 units of 512-byte blocks.
1398 The number of disk blocks is not strictly proportional to the size of
1399 the file, for two reasons: the file system may use some blocks for
1400 internal record keeping; and the file may be sparse---it may have
1401 ``holes'' which contain zeros but do not actually take up space on the
1404 You can tell (approximately) whether a file is sparse by comparing this
1405 value with @code{st_size}, like this:
1408 (st.st_blocks * 512 < st.st_size)
1411 This test is not perfect because a file that is just slightly sparse
1412 might not be detected as sparse at all. For practical applications,
1413 this is not a problem.
1415 @item unsigned int st_blksize
1416 The optimal block size for reading of writing this file, in bytes. You
1417 might use this size for allocating the buffer space for reading of
1418 writing the file. (This is unrelated to @code{st_blocks}.)
1422 Some of the file attributes have special data type names which exist
1423 specifically for those attributes. (They are all aliases for well-known
1424 integer types that you know and love.) These typedef names are defined
1425 in the header file @file{sys/types.h} as well as in @file{sys/stat.h}.
1426 Here is a list of them.
1428 The extensions for the Large File Support (LFS) require even on 32 bits
1429 machine types which can handle file sizes up to @math{2^63}. Therefore
1430 a new definition of @code{struct stat} is necessary.
1434 @deftp {Data Type} {struct stat64}
1435 The members of this type are the same and have the same names as those
1436 in @code{struct stat}. The only difference is that the members
1437 @code{st_ino}, @code{st_size}, and @code{st_blocks} have a different
1438 type to support larger values.
1441 @item mode_t st_mode
1442 Specifies the mode of the file. This includes file type information
1443 (@pxref{Testing File Type}) and the file permission bits
1444 (@pxref{Permission Bits}).
1446 @item ino64_t st_ino
1447 The file serial number, which distinguishes this file from all other
1448 files on the same device.
1451 Identifies the device containing the file. The @code{st_ino} and
1452 @code{st_dev}, taken together, uniquely identify the file. The
1453 @code{st_dev} value is not necessarily consistent across reboots or
1454 system crashes, however.
1456 @item nlink_t st_nlink
1457 The number of hard links to the file. This count keeps track of how
1458 many directories have entries for this file. If the count is ever
1459 decremented to zero, then the file itself is discarded as soon as no
1460 process still holds it open. Symbolic links are not counted in the
1464 The user ID of the file's owner. @xref{File Owner}.
1467 The group ID of the file. @xref{File Owner}.
1469 @item off64_t st_size
1470 This specifies the size of a regular file in bytes. For files that
1471 are really devices and the like, this field isn't usually meaningful.
1472 For symbolic links, this specifies the length of the file name the link
1475 @item time_t st_atime
1476 This is the last access time for the file. @xref{File Times}.
1478 @item unsigned long int st_atime_usec
1479 This is the fractional part of the last access time for the file.
1482 @item time_t st_mtime
1483 This is the time of the last modification to the contents of the file.
1486 @item unsigned long int st_mtime_usec
1487 This is the fractional part of the time of last modification to the
1488 contents of the file. @xref{File Times}.
1490 @item time_t st_ctime
1491 This is the time of the last modification to the attributes of the file.
1494 @item unsigned long int st_ctime_usec
1495 This is the fractional part of the time of last modification to the
1496 attributes of the file. @xref{File Times}.
1499 @item blkcnt64_t st_blocks
1500 This is the amount of disk space that the file occupies, measured in
1501 units of 512-byte blocks.
1503 @item unsigned int st_blksize
1504 The optimal block size for reading of writing this file, in bytes. You
1505 might use this size for allocating the buffer space for reading of
1506 writing the file. (This is unrelated to @code{st_blocks}.)
1510 @comment sys/types.h
1512 @deftp {Data Type} mode_t
1513 This is an integer data type used to represent file modes. In the
1514 GNU system, this is equivalent to @code{unsigned int}.
1517 @cindex inode number
1518 @comment sys/types.h
1520 @deftp {Data Type} ino_t
1521 This is an arithmetic data type used to represent file serial numbers.
1522 (In Unix jargon, these are sometimes called @dfn{inode numbers}.)
1523 In the GNU system, this type is equivalent to @code{unsigned long int}.
1525 If the source is compiled with @code{_FILE_OFFSET_BITS == 64} this type
1526 is transparently replaced by @code{ino64_t}.
1529 @comment sys/types.h
1531 @deftp {Data Type} ino64_t
1532 This is an arithmetic data type used to represent file serial numbers
1533 for the use in LFS. In the GNU system, this type is equivalent to
1534 @code{unsigned long longint}.
1536 When compiling with @code{_FILE_OFFSET_BITS == 64} this type is
1537 available under the name @code{ino_t}.
1540 @comment sys/types.h
1542 @deftp {Data Type} dev_t
1543 This is an arithmetic data type used to represent file device numbers.
1544 In the GNU system, this is equivalent to @code{int}.
1547 @comment sys/types.h
1549 @deftp {Data Type} nlink_t
1550 This is an arithmetic data type used to represent file link counts.
1551 In the GNU system, this is equivalent to @code{unsigned short int}.
1554 @comment sys/types.h
1556 @deftp {Data Type} blkcnt_t
1557 This is an arithmetic data type used to represent block counts.
1558 In the GNU system, this is equivalent to @code{unsigned long int}.
1560 If the source is compiled with @code{_FILE_OFFSET_BITS == 64} this type
1561 is transparently replaced by @code{blkcnt64_t}.
1564 @comment sys/types.h
1566 @deftp {Data Type} blkcnt64_t
1567 This is an arithmetic data type used to represent block counts for the
1568 use in LFS. In the GNU system, this is equivalent to @code{unsigned
1571 When compiling with @code{_FILE_OFFSET_BITS == 64} this type is
1572 available under the name @code{blkcnt_t}.
1575 @node Reading Attributes
1576 @subsection Reading the Attributes of a File
1578 To examine the attributes of files, use the functions @code{stat},
1579 @code{fstat} and @code{lstat}. They return the attribute information in
1580 a @code{struct stat} object. All three functions are declared in the
1581 header file @file{sys/stat.h}.
1585 @deftypefun int stat (const char *@var{filename}, struct stat *@var{buf})
1586 The @code{stat} function returns information about the attributes of the
1587 file named by @w{@var{filename}} in the structure pointed at by @var{buf}.
1589 If @var{filename} is the name of a symbolic link, the attributes you get
1590 describe the file that the link points to. If the link points to a
1591 nonexistent file name, then @code{stat} fails, reporting a nonexistent
1594 The return value is @code{0} if the operation is successful, and @code{-1}
1595 on failure. In addition to the usual file name errors
1596 (@pxref{File Name Errors}, the following @code{errno} error conditions
1597 are defined for this function:
1601 The file named by @var{filename} doesn't exist.
1604 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
1605 function is in fact @code{stat64} since the LFS interface transparently
1606 replaces the normal implementation.
1611 @deftypefun int stat64 (const char *@var{filename}, struct stat64 *@var{buf})
1612 This function is similar to @code{stat} but it is also able to work on
1613 file larger then @math{2^31} bytes on 32 bits systems. To be able to do
1614 this the result is stored in a variable of type @code{struct stat64} to
1615 which @var{buf} must point.
1617 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
1618 function is available under the name @code{stat} and so transparently
1619 replaces the interface for small fiels on 32 bits machines.
1624 @deftypefun int fstat (int @var{filedes}, struct stat *@var{buf})
1625 The @code{fstat} function is like @code{stat}, except that it takes an
1626 open file descriptor as an argument instead of a file name.
1627 @xref{Low-Level I/O}.
1629 Like @code{stat}, @code{fstat} returns @code{0} on success and @code{-1}
1630 on failure. The following @code{errno} error conditions are defined for
1635 The @var{filedes} argument is not a valid file descriptor.
1638 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
1639 function is in fact @code{fstat64} since the LFS interface transparently
1640 replaces the normal implementation.
1645 @deftypefun int fstat64 (int @var{filedes}, struct stat64 *@var{buf})
1646 This function is similar to @code{fstat} but it is prepared to work on
1647 large files on 32 bits platforms. For large files the file descriptor
1648 @var{filedes} should be returned by @code{open64} or @code{creat64}.
1649 The @var{buf} pointer points to a variable of type @code{struct stat64}
1650 which is able to represent the larger values.
1652 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
1653 function is available under the name @code{fstat} and so transparently
1654 replaces the interface for small fiels on 32 bits machines.
1659 @deftypefun int lstat (const char *@var{filename}, struct stat *@var{buf})
1660 The @code{lstat} function is like @code{stat}, except that it does not
1661 follow symbolic links. If @var{filename} is the name of a symbolic
1662 link, @code{lstat} returns information about the link itself; otherwise,
1663 @code{lstat} works like @code{stat}. @xref{Symbolic Links}.
1665 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
1666 function is in fact @code{lstat64} since the LFS interface transparently
1667 replaces the normal implementation.
1672 @deftypefun int lstat64 (const char *@var{filename}, struct stat64 *@var{buf})
1673 This function is similar to @code{lstat} but it is also able to work on
1674 file larger then @math{2^31} bytes on 32 bits systems. To be able to do
1675 this the result is stored in a variable of type @code{struct stat64} to
1676 which @var{buf} must point.
1678 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
1679 function is available under the name @code{lstat} and so transparently
1680 replaces the interface for small fiels on 32 bits machines.
1683 @node Testing File Type
1684 @subsection Testing the Type of a File
1686 The @dfn{file mode}, stored in the @code{st_mode} field of the file
1687 attributes, contains two kinds of information: the file type code, and
1688 the access permission bits. This section discusses only the type code,
1689 which you can use to tell whether the file is a directory, whether it is
1690 a socket, and so on. For information about the access permission,
1691 @ref{Permission Bits}.
1693 There are two predefined ways you can access the file type portion of
1694 the file mode. First of all, for each type of file, there is a
1695 @dfn{predicate macro} which examines a file mode value and returns
1696 true or false---is the file of that type, or not. Secondly, you can
1697 mask out the rest of the file mode to get just a file type code.
1698 You can compare this against various constants for the supported file
1701 All of the symbols listed in this section are defined in the header file
1705 The following predicate macros test the type of a file, given the value
1706 @var{m} which is the @code{st_mode} field returned by @code{stat} on
1711 @deftypefn Macro int S_ISDIR (mode_t @var{m})
1712 This macro returns nonzero if the file is a directory.
1717 @deftypefn Macro int S_ISCHR (mode_t @var{m})
1718 This macro returns nonzero if the file is a character special file (a
1719 device like a terminal).
1724 @deftypefn Macro int S_ISBLK (mode_t @var{m})
1725 This macro returns nonzero if the file is a block special file (a device
1731 @deftypefn Macro int S_ISREG (mode_t @var{m})
1732 This macro returns nonzero if the file is a regular file.
1737 @deftypefn Macro int S_ISFIFO (mode_t @var{m})
1738 This macro returns nonzero if the file is a FIFO special file, or a
1739 pipe. @xref{Pipes and FIFOs}.
1744 @deftypefn Macro int S_ISLNK (mode_t @var{m})
1745 This macro returns nonzero if the file is a symbolic link.
1746 @xref{Symbolic Links}.
1751 @deftypefn Macro int S_ISSOCK (mode_t @var{m})
1752 This macro returns nonzero if the file is a socket. @xref{Sockets}.
1755 An alternate non-POSIX method of testing the file type is supported for
1756 compatibility with BSD. The mode can be bitwise ANDed with
1757 @code{S_IFMT} to extract the file type code, and compared to the
1758 appropriate type code constant. For example,
1761 S_ISCHR (@var{mode})
1768 ((@var{mode} & S_IFMT) == S_IFCHR)
1773 @deftypevr Macro int S_IFMT
1774 This is a bit mask used to extract the file type code portion of a mode
1778 These are the symbolic names for the different file type codes:
1785 This macro represents the value of the file type code for a directory file.
1791 This macro represents the value of the file type code for a
1792 character-oriented device file.
1798 This macro represents the value of the file type code for a block-oriented
1805 This macro represents the value of the file type code for a regular file.
1811 This macro represents the value of the file type code for a symbolic link.
1817 This macro represents the value of the file type code for a socket.
1823 This macro represents the value of the file type code for a FIFO or pipe.
1827 @subsection File Owner
1829 @cindex owner of a file
1830 @cindex group owner of a file
1832 Every file has an @dfn{owner} which is one of the registered user names
1833 defined on the system. Each file also has a @dfn{group}, which is one
1834 of the defined groups. The file owner can often be useful for showing
1835 you who edited the file (especially when you edit with GNU Emacs), but
1836 its main purpose is for access control.
1838 The file owner and group play a role in determining access because the
1839 file has one set of access permission bits for the user that is the
1840 owner, another set that apply to users who belong to the file's group,
1841 and a third set of bits that apply to everyone else. @xref{Access
1842 Permission}, for the details of how access is decided based on this
1845 When a file is created, its owner is set from the effective user ID of
1846 the process that creates it (@pxref{Process Persona}). The file's group
1847 ID may be set from either effective group ID of the process, or the
1848 group ID of the directory that contains the file, depending on the
1849 system where the file is stored. When you access a remote file system,
1850 it behaves according to its own rule, not according to the system your
1851 program is running on. Thus, your program must be prepared to encounter
1852 either kind of behavior, no matter what kind of system you run it on.
1856 You can change the owner and/or group owner of an existing file using
1857 the @code{chown} function. This is the primitive for the @code{chown}
1858 and @code{chgrp} shell commands.
1861 The prototype for this function is declared in @file{unistd.h}.
1865 @deftypefun int chown (const char *@var{filename}, uid_t @var{owner}, gid_t @var{group})
1866 The @code{chown} function changes the owner of the file @var{filename} to
1867 @var{owner}, and its group owner to @var{group}.
1869 Changing the owner of the file on certain systems clears the set-user-ID
1870 and set-group-ID bits of the file's permissions. (This is because those
1871 bits may not be appropriate for the new owner.) The other file
1872 permission bits are not changed.
1874 The return value is @code{0} on success and @code{-1} on failure.
1875 In addition to the usual file name errors (@pxref{File Name Errors}),
1876 the following @code{errno} error conditions are defined for this function:
1880 This process lacks permission to make the requested change.
1882 Only privileged users or the file's owner can change the file's group.
1883 On most file systems, only privileged users can change the file owner;
1884 some file systems allow you to change the owner if you are currently the
1885 owner. When you access a remote file system, the behavior you encounter
1886 is determined by the system that actually holds the file, not by the
1887 system your program is running on.
1889 @xref{Options for Files}, for information about the
1890 @code{_POSIX_CHOWN_RESTRICTED} macro.
1893 The file is on a read-only file system.
1899 @deftypefun int fchown (int @var{filedes}, int @var{owner}, int @var{group})
1900 This is like @code{chown}, except that it changes the owner of the file
1901 with open file descriptor @var{filedes}.
1903 The return value from @code{fchown} is @code{0} on success and @code{-1}
1904 on failure. The following @code{errno} error codes are defined for this
1909 The @var{filedes} argument is not a valid file descriptor.
1912 The @var{filedes} argument corresponds to a pipe or socket, not an ordinary
1916 This process lacks permission to make the requested change. For
1917 details, see @code{chmod}, above.
1920 The file resides on a read-only file system.
1924 @node Permission Bits
1925 @subsection The Mode Bits for Access Permission
1927 The @dfn{file mode}, stored in the @code{st_mode} field of the file
1928 attributes, contains two kinds of information: the file type code, and
1929 the access permission bits. This section discusses only the access
1930 permission bits, which control who can read or write the file.
1931 @xref{Testing File Type}, for information about the file type code.
1933 All of the symbols listed in this section are defined in the header file
1937 @cindex file permission bits
1938 These symbolic constants are defined for the file mode bits that control
1939 access permission for the file:
1950 Read permission bit for the owner of the file. On many systems, this
1951 bit is 0400. @code{S_IREAD} is an obsolete synonym provided for BSD
1962 Write permission bit for the owner of the file. Usually 0200.
1963 @w{@code{S_IWRITE}} is an obsolete synonym provided for BSD compatibility.
1973 Execute (for ordinary files) or search (for directories) permission bit
1974 for the owner of the file. Usually 0100. @code{S_IEXEC} is an obsolete
1975 synonym provided for BSD compatibility.
1981 This is equivalent to @samp{(S_IRUSR | S_IWUSR | S_IXUSR)}.
1987 Read permission bit for the group owner of the file. Usually 040.
1993 Write permission bit for the group owner of the file. Usually 020.
1999 Execute or search permission bit for the group owner of the file.
2006 This is equivalent to @samp{(S_IRGRP | S_IWGRP | S_IXGRP)}.
2012 Read permission bit for other users. Usually 04.
2018 Write permission bit for other users. Usually 02.
2024 Execute or search permission bit for other users. Usually 01.
2030 This is equivalent to @samp{(S_IROTH | S_IWOTH | S_IXOTH)}.
2036 This is the set-user-ID on execute bit, usually 04000.
2037 @xref{How Change Persona}.
2043 This is the set-group-ID on execute bit, usually 02000.
2044 @xref{How Change Persona}.
2051 This is the @dfn{sticky} bit, usually 01000.
2053 On a directory, it gives permission to delete a file in the directory
2054 only if you own that file. Ordinarily, a user either can delete all the
2055 files in the directory or cannot delete any of them (based on whether
2056 the user has write permission for the directory). The same restriction
2057 applies---you must both have write permission for the directory and own
2058 the file you want to delete. The one exception is that the owner of the
2059 directory can delete any file in the directory, no matter who owns it
2060 (provided the owner has given himself write permission for the
2061 directory). This is commonly used for the @file{/tmp} directory, where
2062 anyone may create files, but not delete files created by other users.
2064 Originally the sticky bit on an executable file modified the swapping
2065 policies of the system. Normally, when a program terminated, its pages
2066 in core were immediately freed and reused. If the sticky bit was set on
2067 the executable file, the system kept the pages in core for a while as if
2068 the program were still running. This was advantageous for a program
2069 likely to be run many times in succession. This usage is obsolete in
2070 modern systems. When a program terminates, its pages always remain in
2071 core as long as there is no shortage of memory in the system. When the
2072 program is next run, its pages will still be in core if no shortage
2073 arose since the last run.
2075 On some modern systems where the sticky bit has no useful meaning for an
2076 executable file, you cannot set the bit at all for a non-directory.
2077 If you try, @code{chmod} fails with @code{EFTYPE};
2078 @pxref{Setting Permissions}.
2080 Some systems (particularly SunOS) have yet another use for the sticky
2081 bit. If the sticky bit is set on a file that is @emph{not} executable,
2082 it means the opposite: never cache the pages of this file at all. The
2083 main use of this is for the files on an NFS server machine which are
2084 used as the swap area of diskless client machines. The idea is that the
2085 pages of the file will be cached in the client's memory, so it is a
2086 waste of the server's memory to cache them a second time. In this use
2087 the sticky bit also says that the filesystem may fail to record the
2088 file's modification time onto disk reliably (the idea being that no-one
2089 cares for a swap file).
2091 This bit is only available on BSD systems (and those derived from
2092 them). Therefore one has to use the @code{_BSD_SOURCE} feature select
2093 macro to get the definition (@pxref{Feature Test Macros}).
2096 The actual bit values of the symbols are listed in the table above
2097 so you can decode file mode values when debugging your programs.
2098 These bit values are correct for most systems, but they are not
2101 @strong{Warning:} Writing explicit numbers for file permissions is bad
2102 practice. It is not only non-portable, it also requires everyone who
2103 reads your program to remember what the bits mean. To make your
2104 program clean, use the symbolic names.
2106 @node Access Permission
2107 @subsection How Your Access to a File is Decided
2108 @cindex permission to access a file
2109 @cindex access permission for a file
2110 @cindex file access permission
2112 Recall that the operating system normally decides access permission for
2113 a file based on the effective user and group IDs of the process, and its
2114 supplementary group IDs, together with the file's owner, group and
2115 permission bits. These concepts are discussed in detail in
2116 @ref{Process Persona}.
2118 If the effective user ID of the process matches the owner user ID of the
2119 file, then permissions for read, write, and execute/search are
2120 controlled by the corresponding ``user'' (or ``owner'') bits. Likewise,
2121 if any of the effective group ID or supplementary group IDs of the
2122 process matches the group owner ID of the file, then permissions are
2123 controlled by the ``group'' bits. Otherwise, permissions are controlled
2124 by the ``other'' bits.
2126 Privileged users, like @samp{root}, can access any file, regardless of
2127 its file permission bits. As a special case, for a file to be
2128 executable even for a privileged user, at least one of its execute bits
2131 @node Setting Permissions
2132 @subsection Assigning File Permissions
2134 @cindex file creation mask
2136 The primitive functions for creating files (for example, @code{open} or
2137 @code{mkdir}) take a @var{mode} argument, which specifies the file
2138 permissions for the newly created file. But the specified mode is
2139 modified by the process's @dfn{file creation mask}, or @dfn{umask},
2142 The bits that are set in the file creation mask identify permissions
2143 that are always to be disabled for newly created files. For example, if
2144 you set all the ``other'' access bits in the mask, then newly created
2145 files are not accessible at all to processes in the ``other''
2146 category, even if the @var{mode} argument specified to the creation
2147 function would permit such access. In other words, the file creation
2148 mask is the complement of the ordinary access permissions you want to
2151 Programs that create files typically specify a @var{mode} argument that
2152 includes all the permissions that make sense for the particular file.
2153 For an ordinary file, this is typically read and write permission for
2154 all classes of users. These permissions are then restricted as
2155 specified by the individual user's own file creation mask.
2158 To change the permission of an existing file given its name, call
2159 @code{chmod}. This function ignores the file creation mask; it uses
2160 exactly the specified permission bits.
2163 In normal use, the file creation mask is initialized in the user's login
2164 shell (using the @code{umask} shell command), and inherited by all
2165 subprocesses. Application programs normally don't need to worry about
2166 the file creation mask. It will do automatically what it is supposed to
2169 When your program should create a file and bypass the umask for its
2170 access permissions, the easiest way to do this is to use @code{fchmod}
2171 after opening the file, rather than changing the umask.
2173 In fact, changing the umask is usually done only by shells. They use
2174 the @code{umask} function.
2176 The functions in this section are declared in @file{sys/stat.h}.
2181 @deftypefun mode_t umask (mode_t @var{mask})
2182 The @code{umask} function sets the file creation mask of the current
2183 process to @var{mask}, and returns the previous value of the file
2186 Here is an example showing how to read the mask with @code{umask}
2187 without changing it permanently:
2199 However, it is better to use @code{getumask} if you just want to read
2200 the mask value, because that is reentrant (at least if you use the GNU
2206 @deftypefun mode_t getumask (void)
2207 Return the current value of the file creation mask for the current
2208 process. This function is a GNU extension.
2213 @deftypefun int chmod (const char *@var{filename}, mode_t @var{mode})
2214 The @code{chmod} function sets the access permission bits for the file
2215 named by @var{filename} to @var{mode}.
2217 If the @var{filename} names a symbolic link, @code{chmod} changes the
2218 permission of the file pointed to by the link, not those of the link
2221 This function returns @code{0} if successful and @code{-1} if not. In
2222 addition to the usual file name errors (@pxref{File Name
2223 Errors}), the following @code{errno} error conditions are defined for
2228 The named file doesn't exist.
2231 This process does not have permission to change the access permission of
2232 this file. Only the file's owner (as judged by the effective user ID of
2233 the process) or a privileged user can change them.
2236 The file resides on a read-only file system.
2239 @var{mode} has the @code{S_ISVTX} bit (the ``sticky bit'') set,
2240 and the named file is not a directory. Some systems do not allow setting the
2241 sticky bit on non-directory files, and some do (and only some of those
2242 assign a useful meaning to the bit for non-directory files).
2244 You only get @code{EFTYPE} on systems where the sticky bit has no useful
2245 meaning for non-directory files, so it is always safe to just clear the
2246 bit in @var{mode} and call @code{chmod} again. @xref{Permission Bits},
2247 for full details on the sticky bit.
2253 @deftypefun int fchmod (int @var{filedes}, int @var{mode})
2254 This is like @code{chmod}, except that it changes the permissions of
2255 the file currently open via descriptor @var{filedes}.
2257 The return value from @code{fchmod} is @code{0} on success and @code{-1}
2258 on failure. The following @code{errno} error codes are defined for this
2263 The @var{filedes} argument is not a valid file descriptor.
2266 The @var{filedes} argument corresponds to a pipe or socket, or something
2267 else that doesn't really have access permissions.
2270 This process does not have permission to change the access permission of
2271 this file. Only the file's owner (as judged by the effective user ID of
2272 the process) or a privileged user can change them.
2275 The file resides on a read-only file system.
2279 @node Testing File Access
2280 @subsection Testing Permission to Access a File
2281 @cindex testing access permission
2282 @cindex access, testing for
2283 @cindex setuid programs and file access
2285 When a program runs as a privileged user, this permits it to access
2286 files off-limits to ordinary users---for example, to modify
2287 @file{/etc/passwd}. Programs designed to be run by ordinary users but
2288 access such files use the setuid bit feature so that they always run
2289 with @code{root} as the effective user ID.
2291 Such a program may also access files specified by the user, files which
2292 conceptually are being accessed explicitly by the user. Since the
2293 program runs as @code{root}, it has permission to access whatever file
2294 the user specifies---but usually the desired behavior is to permit only
2295 those files which the user could ordinarily access.
2297 The program therefore must explicitly check whether @emph{the user}
2298 would have the necessary access to a file, before it reads or writes the
2301 To do this, use the function @code{access}, which checks for access
2302 permission based on the process's @emph{real} user ID rather than the
2303 effective user ID. (The setuid feature does not alter the real user ID,
2304 so it reflects the user who actually ran the program.)
2306 There is another way you could check this access, which is easy to
2307 describe, but very hard to use. This is to examine the file mode bits
2308 and mimic the system's own access computation. This method is
2309 undesirable because many systems have additional access control
2310 features; your program cannot portably mimic them, and you would not
2311 want to try to keep track of the diverse features that different systems
2312 have. Using @code{access} is simple and automatically does whatever is
2313 appropriate for the system you are using.
2315 @code{access} is @emph{only} only appropriate to use in setuid programs.
2316 A non-setuid program will always use the effective ID rather than the
2320 The symbols in this section are declared in @file{unistd.h}.
2324 @deftypefun int access (const char *@var{filename}, int @var{how})
2325 The @code{access} function checks to see whether the file named by
2326 @var{filename} can be accessed in the way specified by the @var{how}
2327 argument. The @var{how} argument either can be the bitwise OR of the
2328 flags @code{R_OK}, @code{W_OK}, @code{X_OK}, or the existence test
2331 This function uses the @emph{real} user and group ID's of the calling
2332 process, rather than the @emph{effective} ID's, to check for access
2333 permission. As a result, if you use the function from a @code{setuid}
2334 or @code{setgid} program (@pxref{How Change Persona}), it gives
2335 information relative to the user who actually ran the program.
2337 The return value is @code{0} if the access is permitted, and @code{-1}
2338 otherwise. (In other words, treated as a predicate function,
2339 @code{access} returns true if the requested access is @emph{denied}.)
2341 In addition to the usual file name errors (@pxref{File Name
2342 Errors}), the following @code{errno} error conditions are defined for
2347 The access specified by @var{how} is denied.
2350 The file doesn't exist.
2353 Write permission was requested for a file on a read-only file system.
2357 These macros are defined in the header file @file{unistd.h} for use
2358 as the @var{how} argument to the @code{access} function. The values
2359 are integer constants.
2364 @deftypevr Macro int R_OK
2365 Argument that means, test for read permission.
2370 @deftypevr Macro int W_OK
2371 Argument that means, test for write permission.
2376 @deftypevr Macro int X_OK
2377 Argument that means, test for execute/search permission.
2382 @deftypevr Macro int F_OK
2383 Argument that means, test for existence of the file.
2387 @subsection File Times
2389 @cindex file access time
2390 @cindex file modification time
2391 @cindex file attribute modification time
2392 Each file has three time stamps associated with it: its access time,
2393 its modification time, and its attribute modification time. These
2394 correspond to the @code{st_atime}, @code{st_mtime}, and @code{st_ctime}
2395 members of the @code{stat} structure; see @ref{File Attributes}.
2397 All of these times are represented in calendar time format, as
2398 @code{time_t} objects. This data type is defined in @file{time.h}.
2399 For more information about representation and manipulation of time
2400 values, see @ref{Calendar Time}.
2403 Reading from a file updates its access time attribute, and writing
2404 updates its modification time. When a file is created, all three
2405 time stamps for that file are set to the current time. In addition, the
2406 attribute change time and modification time fields of the directory that
2407 contains the new entry are updated.
2409 Adding a new name for a file with the @code{link} function updates the
2410 attribute change time field of the file being linked, and both the
2411 attribute change time and modification time fields of the directory
2412 containing the new name. These same fields are affected if a file name
2413 is deleted with @code{unlink}, @code{remove}, or @code{rmdir}. Renaming
2414 a file with @code{rename} affects only the attribute change time and
2415 modification time fields of the two parent directories involved, and not
2416 the times for the file being renamed.
2418 Changing attributes of a file (for example, with @code{chmod}) updates
2419 its attribute change time field.
2421 You can also change some of the time stamps of a file explicitly using
2422 the @code{utime} function---all except the attribute change time. You
2423 need to include the header file @file{utime.h} to use this facility.
2428 @deftp {Data Type} {struct utimbuf}
2429 The @code{utimbuf} structure is used with the @code{utime} function to
2430 specify new access and modification times for a file. It contains the
2435 This is the access time for the file.
2437 @item time_t modtime
2438 This is the modification time for the file.
2444 @deftypefun int utime (const char *@var{filename}, const struct utimbuf *@var{times})
2445 This function is used to modify the file times associated with the file
2446 named @var{filename}.
2448 If @var{times} is a null pointer, then the access and modification times
2449 of the file are set to the current time. Otherwise, they are set to the
2450 values from the @code{actime} and @code{modtime} members (respectively)
2451 of the @code{utimbuf} structure pointed at by @var{times}.
2453 The attribute modification time for the file is set to the current time
2454 in either case (since changing the time stamps is itself a modification
2455 of the file attributes).
2457 The @code{utime} function returns @code{0} if successful and @code{-1}
2458 on failure. In addition to the usual file name errors
2459 (@pxref{File Name Errors}), the following @code{errno} error conditions
2460 are defined for this function:
2464 There is a permission problem in the case where a null pointer was
2465 passed as the @var{times} argument. In order to update the time stamp on
2466 the file, you must either be the owner of the file, have write
2467 permission on the file, or be a privileged user.
2470 The file doesn't exist.
2473 If the @var{times} argument is not a null pointer, you must either be
2474 the owner of the file or be a privileged user. This error is used to
2478 The file lives on a read-only file system.
2482 Each of the three time stamps has a corresponding microsecond part,
2483 which extends its resolution. These fields are called
2484 @code{st_atime_usec}, @code{st_mtime_usec}, and @code{st_ctime_usec};
2485 each has a value between 0 and 999,999, which indicates the time in
2486 microseconds. They correspond to the @code{tv_usec} field of a
2487 @code{timeval} structure; see @ref{High-Resolution Calendar}.
2489 The @code{utimes} function is like @code{utime}, but also lets you specify
2490 the fractional part of the file times. The prototype for this function is
2491 in the header file @file{sys/time.h}.
2496 @deftypefun int utimes (const char *@var{filename}, struct timeval @var{tvp}@t{[2]})
2497 This function sets the file access and modification times for the file
2498 named by @var{filename}. The new file access time is specified by
2499 @code{@var{tvp}[0]}, and the new modification time by
2500 @code{@var{tvp}[1]}. This function comes from BSD.
2502 The return values and error conditions are the same as for the @code{utime}
2507 @subsection File Size
2509 Normally file sizes are maintained automatically. A file begins with a
2510 size of @math{0} and is automatically extended when data is written
2511 past its end. It is also possible to empty a file completely in an
2512 @code{open} or @code{fopen} call.
2514 However, sometimes it is neccessary to @emph{reduce} the size of a file.
2515 This can be done with the @code{truncate} and @code{ftruncate} functions.
2516 They were introduced in BSD Unix. @code{ftruncate} was later added to
2519 Some systems allow you to extend a file (creating holes) with these
2520 functions. This is useful when using memory-mapped I/O
2521 (@pxref{Memory-mapped I/O}), where files are not automatically extended.
2522 However it is not portable but must be implemented if @code{mmap} allows
2523 mapping of files (i.e., @code{_POSIX_MAPPED_FILES} is defined).
2525 Using these functions on anything other than a regular file gives
2526 @emph{undefined} results. On many systems, such a call will appear to
2527 succeed, without actually accomplishing anything.
2529 @deftypefun int truncate (const char *@var{filename}, off_t @var{length})
2531 The @code{truncate} function changes the size of @var{filename} to
2532 @var{length}. If @var{length} is shorter than the previous length, data at
2533 the end will be lost.
2535 If @var{length} is longer, holes will be added to the end. However, some
2536 systems do not support this feature and will leave the file unchanged.
2538 The return value is @math{0} for success, or @math{-1} for an error. In
2539 addition to the usual file name errors, the following errors may occur:
2544 The file is a directory or not writable.
2547 @var{length} is negative.
2550 The operation would extend the file beyond the limits of the operating system.
2553 A hardware I/O error occured.
2556 The file is "append-only" or "immutable".
2559 The operation was interrupted by a signal.
2565 @deftypefun int ftruncate (int @var{fd}, off_t @var{length})
2567 This is like @code{truncate}, but it works on a file descriptor @var{fd}.
2569 @code{ftruncate} is especially useful in combination with @code{mmap}.
2570 Since the mapped region must have a fixed size one cannot enlarge the
2571 file by writing something beyond the last mapped page. Instead one has
2572 to enlarge the file itself and then remap the file with the new size.
2573 The example below shows how this works.
2575 The return value is @math{0} for success, or @math{-1} for an error. The
2576 following errors may occur:
2581 @var{fd} does not correspond to an open file.
2584 @var{fd} is a directory or not open for write.
2587 @var{length} is negative.
2590 The operation would extend the file beyond the limits of the operating system.
2591 @c or the open() call -- with the not-yet-discussed feature of opening
2592 @c files with extra-large offsets.
2595 A hardware I/O error occured.
2598 The file is "append-only" or "immutable".
2601 The operation was interrupted by a signal.
2603 @c ENOENT is also possible on Linux --- however it only occurs if the file
2604 @c descriptor has a `file' structure but no `inode' structure. I'm not
2605 @c sure how such an fd could be created. Perhaps it's a bug.
2611 As announced here is a little example how to use @code{ftruncate} in
2612 combination with @code{mmap}:
2620 add (off_t at, void *block, size_t size)
2622 if (at + size > len)
2624 /* Resize the file and remap. */
2625 size_t ps = sysconf (_SC_PAGESIZE);
2626 size_t ns = (at + size + ps - 1) & ~(ps - 1);
2628 if (ftruncate (fd, ns) < 0)
2630 np = mmap (NULL, ns, PROT_READ|PROT_WRITE, MAP_SHARED, fd, 0);
2631 if (np == MAP_FAILED)
2636 memcpy ((char *) start + at, block, size);
2641 The function @code{add} allows to add at arbitrary positions in the file
2642 given blocks of memory. If the current size of the file is too small it
2643 is extended. Please note the it is extended in multiples of a pagesize.
2644 This is a requirement of @code{mmap}. The program has to track the real
2645 size and once the program finished to work a final @code{ftruncate} call
2646 should set the real size of the file.
2648 @node Making Special Files
2649 @section Making Special Files
2650 @cindex creating special files
2651 @cindex special files
2653 The @code{mknod} function is the primitive for making special files,
2654 such as files that correspond to devices. The GNU library includes
2655 this function for compatibility with BSD.
2657 The prototype for @code{mknod} is declared in @file{sys/stat.h}.
2662 @deftypefun int mknod (const char *@var{filename}, int @var{mode}, int @var{dev})
2663 The @code{mknod} function makes a special file with name @var{filename}.
2664 The @var{mode} specifies the mode of the file, and may include the various
2665 special file bits, such as @code{S_IFCHR} (for a character special file)
2666 or @code{S_IFBLK} (for a block special file). @xref{Testing File Type}.
2668 The @var{dev} argument specifies which device the special file refers to.
2669 Its exact interpretation depends on the kind of special file being created.
2671 The return value is @code{0} on success and @code{-1} on error. In addition
2672 to the usual file name errors (@pxref{File Name Errors}), the
2673 following @code{errno} error conditions are defined for this function:
2677 The calling process is not privileged. Only the superuser can create
2681 The directory or file system that would contain the new file is full
2682 and cannot be extended.
2685 The directory containing the new file can't be modified because it's on
2686 a read-only file system.
2689 There is already a file named @var{filename}. If you want to replace
2690 this file, you must remove the old file explicitly first.
2694 @node Temporary Files
2695 @section Temporary Files
2697 If you need to use a temporary file in your program, you can use the
2698 @code{tmpfile} function to open it. Or you can use the @code{tmpnam}
2699 (better: @code{tmpnam_r}) function make a name for a temporary file and
2700 then open it in the usual way with @code{fopen}.
2702 The @code{tempnam} function is like @code{tmpnam} but lets you choose
2703 what directory temporary files will go in, and something about what
2704 their file names will look like. Important for multi threaded programs
2705 is that @code{tempnam} is reentrant while @code{tmpnam} is not since it
2706 returns a pointer to a static buffer.
2708 These facilities are declared in the header file @file{stdio.h}.
2713 @deftypefun {FILE *} tmpfile (void)
2714 This function creates a temporary binary file for update mode, as if by
2715 calling @code{fopen} with mode @code{"wb+"}. The file is deleted
2716 automatically when it is closed or when the program terminates. (On
2717 some other @w{ISO C} systems the file may fail to be deleted if the program
2718 terminates abnormally).
2720 This function is reentrant.
2722 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a
2723 32 bits system this function is in fact @code{tmpfile64}. I.e., the
2724 LFS interface transparently replaces the old interface.
2729 @deftypefun {FILE *} tmpfile64 (void)
2730 This function is similar to @code{tmpfile} but the stream it returns a
2731 pointer for is opened using @code{tmpfile64}. Therefore this stream can be
2732 used even on files larger then @math{2^31} bytes on 32 bits machines.
2734 Please note that the return type is still @code{FILE *}. There is no
2735 special @code{FILE} type for the LFS interface.
2737 If the sources are compiled with @code{_FILE_OFFSET_BITS == 64} on a 32
2738 bits machine this function is available under the name @code{tmpfile}
2739 and so transparently replaces the old interface.
2744 @deftypefun {char *} tmpnam (char *@var{result})
2745 This function constructs and returns a file name that is a valid file
2746 name and that does not name any existing file. If the @var{result}
2747 argument is a null pointer, the return value is a pointer to an internal
2748 static string, which might be modified by subsequent calls and therefore
2749 makes this function non-reentrant. Otherwise, the @var{result} argument
2750 should be a pointer to an array of at least @code{L_tmpnam} characters,
2751 and the result is written into that array.
2753 It is possible for @code{tmpnam} to fail if you call it too many times
2754 without removing previously created files. This is because the fixed
2755 length of a temporary file name gives room for only a finite number of
2756 different names. If @code{tmpnam} fails, it returns a null pointer.
2758 @strong{Warning:} Since between the time the pathname is constructed and
2759 the file is created another process might have created a file with this
2760 name using @code{tmpnam} is a possible security hole. The
2761 implementation generates names which hardly can be predicted but opening
2762 the file in any case should use the @code{O_EXCL} flag. Using
2763 @code{tmpfile} is a safe way to avoid this problem.
2768 @deftypefun {char *} tmpnam_r (char *@var{result})
2769 This function is nearly identical to the @code{tmpnam} function. But it
2770 does not allow @var{result} to be a null pointer. In the later case a
2771 null pointer is returned.
2773 This function is reentrant because the non-reentrant situation of
2774 @code{tmpnam} cannot happen here.
2779 @deftypevr Macro int L_tmpnam
2780 The value of this macro is an integer constant expression that represents
2781 the minimum allocation size of a string large enough to hold the
2782 file name generated by the @code{tmpnam} function.
2787 @deftypevr Macro int TMP_MAX
2788 The macro @code{TMP_MAX} is a lower bound for how many temporary names
2789 you can create with @code{tmpnam}. You can rely on being able to call
2790 @code{tmpnam} at least this many times before it might fail saying you
2791 have made too many temporary file names.
2793 With the GNU library, you can create a very large number of temporary
2794 file names---if you actually create the files, you will probably run out
2795 of disk space before you run out of names. Some other systems have a
2796 fixed, small limit on the number of temporary files. The limit is never
2797 less than @code{25}.
2802 @deftypefun {char *} tempnam (const char *@var{dir}, const char *@var{prefix})
2803 This function generates a unique temporary filename. If @var{prefix} is
2804 not a null pointer, up to five characters of this string are used as a
2805 prefix for the file name. The return value is a string newly allocated
2806 with @code{malloc}; you should release its storage with @code{free} when
2807 it is no longer needed.
2809 Because the string is dynamically allocated this function is reentrant.
2811 The directory prefix for the temporary file name is determined by testing
2812 each of the following, in sequence. The directory must exist and be
2817 The environment variable @code{TMPDIR}, if it is defined. For security
2818 reasons this only happens if the program is not SUID or SGID enabled.
2821 The @var{dir} argument, if it is not a null pointer.
2824 The value of the @code{P_tmpdir} macro.
2827 The directory @file{/tmp}.
2830 This function is defined for SVID compatibility.
2832 @cindex TMPDIR environment variable
2836 @c !!! are we putting SVID/GNU/POSIX.1/BSD in here or not??
2837 @deftypevr {SVID Macro} {char *} P_tmpdir
2838 This macro is the name of the default directory for temporary files.
2841 Older Unix systems did not have the functions just described. Instead
2842 they used @code{mktemp} and @code{mkstemp}. Both of these functions
2843 work by modifying a file name template string you pass. The last six
2844 characters of this string must be @samp{XXXXXX}. These six @samp{X}s
2845 are replaced with six characters which make the whole string a unique
2846 file name. Usually the template string is something like
2847 @samp{/tmp/@var{prefix}XXXXXX}, and each program uses a unique @var{prefix}.
2849 @strong{Note:} Because @code{mktemp} and @code{mkstemp} modify the
2850 template string, you @emph{must not} pass string constants to them.
2851 String constants are normally in read-only storage, so your program
2852 would crash when @code{mktemp} or @code{mkstemp} tried to modify the
2857 @deftypefun {char *} mktemp (char *@var{template})
2858 The @code{mktemp} function generates a unique file name by modifying
2859 @var{template} as described above. If successful, it returns
2860 @var{template} as modified. If @code{mktemp} cannot find a unique file
2861 name, it makes @var{template} an empty string and returns that. If
2862 @var{template} does not end with @samp{XXXXXX}, @code{mktemp} returns a
2865 @strong{Warning:} Since between the time the pathname is constructed and
2866 the file is created another process might have created a file with this
2867 name using @code{mktemp} is a possible security hole. The
2868 implementation generates names which hardly can be predicted but opening
2869 the file in any case should use the @code{O_EXCL} flag. Using
2870 @code{mkstemp} is a safe way to avoid this problem.
2875 @deftypefun int mkstemp (char *@var{template})
2876 The @code{mkstemp} function generates a unique file name just as
2877 @code{mktemp} does, but it also opens the file for you with @code{open}
2878 (@pxref{Opening and Closing Files}). If successful, it modifies
2879 @var{template} in place and returns a file descriptor open on that file
2880 for reading and writing. If @code{mkstemp} cannot create a
2881 uniquely-named file, it makes @var{template} an empty string and returns
2882 @code{-1}. If @var{template} does not end with @samp{XXXXXX},
2883 @code{mkstemp} returns @code{-1} and does not modify @var{template}.
2885 The file is opened using mode @code{0600}. If the file is meant to be
2886 used by other users the mode must explicitly changed.
2889 Unlike @code{mktemp}, @code{mkstemp} is actually guaranteed to create a
2890 unique file that cannot possibly clash with any other program trying to
2891 create a temporary file. This is because it works by calling
2892 @code{open} with the @code{O_EXCL} flag bit, which says you want to
2893 always create a new file, and get an error if the file already exists.