1 @node Low-Level I/O, File System Interface, I/O on Streams, Top
2 @c %MENU% Low-level, less portable I/O
3 @chapter Low-Level Input/Output
5 This chapter describes functions for performing low-level input/output
6 operations on file descriptors. These functions include the primitives
7 for the higher-level I/O functions described in @ref{I/O on Streams}, as
8 well as functions for performing low-level control operations for which
9 there are no equivalents on streams.
11 Stream-level I/O is more flexible and usually more convenient;
12 therefore, programmers generally use the descriptor-level functions only
13 when necessary. These are some of the usual reasons:
17 For reading binary files in large chunks.
20 For reading an entire file into core before parsing it.
23 To perform operations other than data transfer, which can only be done
24 with a descriptor. (You can use @code{fileno} to get the descriptor
25 corresponding to a stream.)
28 To pass descriptors to a child process. (The child can create its own
29 stream to use a descriptor that it inherits, but cannot inherit a stream
34 * Opening and Closing Files:: How to open and close file
36 * I/O Primitives:: Reading and writing data.
37 * File Position Primitive:: Setting a descriptor's file
39 * Descriptors and Streams:: Converting descriptor to stream
41 * Stream/Descriptor Precautions:: Precautions needed if you use both
42 descriptors and streams.
43 * Scatter-Gather:: Fast I/O to discontinuous buffers.
44 * Memory-mapped I/O:: Using files like memory.
45 * Waiting for I/O:: How to check for input or output
46 on multiple file descriptors.
47 * Synchronizing I/O:: Making sure all I/O actions completed.
48 * Asynchronous I/O:: Perform I/O in parallel.
49 * Control Operations:: Various other operations on file
51 * Duplicating Descriptors:: Fcntl commands for duplicating
53 * Descriptor Flags:: Fcntl commands for manipulating
54 flags associated with file
56 * File Status Flags:: Fcntl commands for manipulating
57 flags associated with open files.
58 * File Locks:: Fcntl commands for implementing
60 * Interrupt Input:: Getting an asynchronous signal when
62 * IOCTLs:: Generic I/O Control operations.
66 @node Opening and Closing Files
67 @section Opening and Closing Files
69 @cindex opening a file descriptor
70 @cindex closing a file descriptor
71 This section describes the primitives for opening and closing files
72 using file descriptors. The @code{open} and @code{creat} functions are
73 declared in the header file @file{fcntl.h}, while @code{close} is
74 declared in @file{unistd.h}.
80 @deftypefun int open (const char *@var{filename}, int @var{flags}[, mode_t @var{mode}])
81 The @code{open} function creates and returns a new file descriptor
82 for the file named by @var{filename}. Initially, the file position
83 indicator for the file is at the beginning of the file. The argument
84 @var{mode} is used only when a file is created, but it doesn't hurt
85 to supply the argument in any case.
87 The @var{flags} argument controls how the file is to be opened. This is
88 a bit mask; you create the value by the bitwise OR of the appropriate
89 parameters (using the @samp{|} operator in C).
90 @xref{File Status Flags}, for the parameters available.
92 The normal return value from @code{open} is a non-negative integer file
93 descriptor. In the case of an error, a value of @math{-1} is returned
94 instead. In addition to the usual file name errors (@pxref{File
95 Name Errors}), the following @code{errno} error conditions are defined
100 The file exists but is not readable/writable as requested by the @var{flags}
101 argument, the file does not exist and the directory is unwritable so
102 it cannot be created.
105 Both @code{O_CREAT} and @code{O_EXCL} are set, and the named file already
109 The @code{open} operation was interrupted by a signal.
110 @xref{Interrupted Primitives}.
113 The @var{flags} argument specified write access, and the file is a directory.
116 The process has too many files open.
117 The maximum number of file descriptors is controlled by the
118 @code{RLIMIT_NOFILE} resource limit; @pxref{Limits on Resources}.
121 The entire system, or perhaps the file system which contains the
122 directory, cannot support any additional open files at the moment.
123 (This problem cannot happen on the GNU system.)
126 The named file does not exist, and @code{O_CREAT} is not specified.
129 The directory or file system that would contain the new file cannot be
130 extended, because there is no disk space left.
133 @code{O_NONBLOCK} and @code{O_WRONLY} are both set in the @var{flags}
134 argument, the file named by @var{filename} is a FIFO (@pxref{Pipes and
135 FIFOs}), and no process has the file open for reading.
138 The file resides on a read-only file system and any of @w{@code{O_WRONLY}},
139 @code{O_RDWR}, and @code{O_TRUNC} are set in the @var{flags} argument,
140 or @code{O_CREAT} is set and the file does not already exist.
145 If on a 32 bit machine the sources are translated with
146 @code{_FILE_OFFSET_BITS == 64} the function @code{open} returns a file
147 descriptor opened in the large file mode which enables the file handling
148 functions to use files up to @math{2^63} bytes in size and offset from
149 @math{-2^63} to @math{2^63}. This happens transparently for the user
150 since all of the lowlevel file handling functions are equally replaced.
152 This function is a cancellation point in multi-threaded programs. This
153 is a problem if the thread allocates some resources (like memory, file
154 descriptors, semaphores or whatever) at the time @code{open} is
155 called. If the thread gets canceled these resources stay allocated
156 until the program ends. To avoid this calls to @code{open} should be
157 protected using cancellation handlers.
158 @c ref pthread_cleanup_push / pthread_cleanup_pop
160 The @code{open} function is the underlying primitive for the @code{fopen}
161 and @code{freopen} functions, that create streams.
166 @deftypefun int open64 (const char *@var{filename}, int @var{flags}[, mode_t @var{mode}])
167 This function is similar to @code{open}. It returns a file descriptor
168 which can be used to access the file named by @var{filename}. The only
169 difference is that on 32 bit systems the file is opened in the
170 large file mode. I.e., file length and file offsets can exceed 31 bits.
172 When the sources are translated with @code{_FILE_OFFSET_BITS == 64} this
173 function is actually available under the name @code{open}. I.e., the
174 new, extended API using 64 bit file sizes and offsets transparently
175 replaces the old API.
180 @deftypefn {Obsolete function} int creat (const char *@var{filename}, mode_t @var{mode})
181 This function is obsolete. The call:
184 creat (@var{filename}, @var{mode})
191 open (@var{filename}, O_WRONLY | O_CREAT | O_TRUNC, @var{mode})
194 If on a 32 bit machine the sources are translated with
195 @code{_FILE_OFFSET_BITS == 64} the function @code{creat} returns a file
196 descriptor opened in the large file mode which enables the file handling
197 functions to use files up to @math{2^63} in size and offset from
198 @math{-2^63} to @math{2^63}. This happens transparently for the user
199 since all of the lowlevel file handling functions are equally replaced.
204 @deftypefn {Obsolete function} int creat64 (const char *@var{filename}, mode_t @var{mode})
205 This function is similar to @code{creat}. It returns a file descriptor
206 which can be used to access the file named by @var{filename}. The only
207 the difference is that on 32 bit systems the file is opened in the
208 large file mode. I.e., file length and file offsets can exceed 31 bits.
210 To use this file descriptor one must not use the normal operations but
211 instead the counterparts named @code{*64}, e.g., @code{read64}.
213 When the sources are translated with @code{_FILE_OFFSET_BITS == 64} this
214 function is actually available under the name @code{open}. I.e., the
215 new, extended API using 64 bit file sizes and offsets transparently
216 replaces the old API.
221 @deftypefun int close (int @var{filedes})
222 The function @code{close} closes the file descriptor @var{filedes}.
223 Closing a file has the following consequences:
227 The file descriptor is deallocated.
230 Any record locks owned by the process on the file are unlocked.
233 When all file descriptors associated with a pipe or FIFO have been closed,
234 any unread data is discarded.
237 This function is a cancellation point in multi-threaded programs. This
238 is a problem if the thread allocates some resources (like memory, file
239 descriptors, semaphores or whatever) at the time @code{close} is
240 called. If the thread gets canceled these resources stay allocated
241 until the program ends. To avoid this, calls to @code{close} should be
242 protected using cancellation handlers.
243 @c ref pthread_cleanup_push / pthread_cleanup_pop
245 The normal return value from @code{close} is @math{0}; a value of @math{-1}
246 is returned in case of failure. The following @code{errno} error
247 conditions are defined for this function:
251 The @var{filedes} argument is not a valid file descriptor.
254 The @code{close} call was interrupted by a signal.
255 @xref{Interrupted Primitives}.
256 Here is an example of how to handle @code{EINTR} properly:
259 TEMP_FAILURE_RETRY (close (desc));
265 When the file is accessed by NFS, these errors from @code{write} can sometimes
266 not be detected until @code{close}. @xref{I/O Primitives}, for details
270 Please note that there is @emph{no} separate @code{close64} function.
271 This is not necessary since this function does not determine nor depend
272 on the mode of the file. The kernel which performs the @code{close}
273 operation knows which mode the descriptor is used for and can handle
277 To close a stream, call @code{fclose} (@pxref{Closing Streams}) instead
278 of trying to close its underlying file descriptor with @code{close}.
279 This flushes any buffered output and updates the stream object to
280 indicate that it is closed.
283 @section Input and Output Primitives
285 This section describes the functions for performing primitive input and
286 output operations on file descriptors: @code{read}, @code{write}, and
287 @code{lseek}. These functions are declared in the header file
293 @deftp {Data Type} ssize_t
294 This data type is used to represent the sizes of blocks that can be
295 read or written in a single operation. It is similar to @code{size_t},
296 but must be a signed type.
299 @cindex reading from a file descriptor
302 @deftypefun ssize_t read (int @var{filedes}, void *@var{buffer}, size_t @var{size})
303 The @code{read} function reads up to @var{size} bytes from the file
304 with descriptor @var{filedes}, storing the results in the @var{buffer}.
305 (This is not necessarily a character string, and no terminating null
308 @cindex end-of-file, on a file descriptor
309 The return value is the number of bytes actually read. This might be
310 less than @var{size}; for example, if there aren't that many bytes left
311 in the file or if there aren't that many bytes immediately available.
312 The exact behavior depends on what kind of file it is. Note that
313 reading less than @var{size} bytes is not an error.
315 A value of zero indicates end-of-file (except if the value of the
316 @var{size} argument is also zero). This is not considered an error.
317 If you keep calling @code{read} while at end-of-file, it will keep
318 returning zero and doing nothing else.
320 If @code{read} returns at least one character, there is no way you can
321 tell whether end-of-file was reached. But if you did reach the end, the
322 next read will return zero.
324 In case of an error, @code{read} returns @math{-1}. The following
325 @code{errno} error conditions are defined for this function:
329 Normally, when no input is immediately available, @code{read} waits for
330 some input. But if the @code{O_NONBLOCK} flag is set for the file
331 (@pxref{File Status Flags}), @code{read} returns immediately without
332 reading any data, and reports this error.
334 @strong{Compatibility Note:} Most versions of BSD Unix use a different
335 error code for this: @code{EWOULDBLOCK}. In @theglibc{},
336 @code{EWOULDBLOCK} is an alias for @code{EAGAIN}, so it doesn't matter
339 On some systems, reading a large amount of data from a character special
340 file can also fail with @code{EAGAIN} if the kernel cannot find enough
341 physical memory to lock down the user's pages. This is limited to
342 devices that transfer with direct memory access into the user's memory,
343 which means it does not include terminals, since they always use
344 separate buffers inside the kernel. This problem never happens in the
347 Any condition that could result in @code{EAGAIN} can instead result in a
348 successful @code{read} which returns fewer bytes than requested.
349 Calling @code{read} again immediately would result in @code{EAGAIN}.
352 The @var{filedes} argument is not a valid file descriptor,
353 or is not open for reading.
356 @code{read} was interrupted by a signal while it was waiting for input.
357 @xref{Interrupted Primitives}. A signal will not necessary cause
358 @code{read} to return @code{EINTR}; it may instead result in a
359 successful @code{read} which returns fewer bytes than requested.
362 For many devices, and for disk files, this error code indicates
365 @code{EIO} also occurs when a background process tries to read from the
366 controlling terminal, and the normal action of stopping the process by
367 sending it a @code{SIGTTIN} signal isn't working. This might happen if
368 the signal is being blocked or ignored, or because the process group is
369 orphaned. @xref{Job Control}, for more information about job control,
370 and @ref{Signal Handling}, for information about signals.
373 In some systems, when reading from a character or block device, position
374 and size offsets must be aligned to a particular block size. This error
375 indicates that the offsets were not properly aligned.
378 Please note that there is no function named @code{read64}. This is not
379 necessary since this function does not directly modify or handle the
380 possibly wide file offset. Since the kernel handles this state
381 internally, the @code{read} function can be used for all cases.
383 This function is a cancellation point in multi-threaded programs. This
384 is a problem if the thread allocates some resources (like memory, file
385 descriptors, semaphores or whatever) at the time @code{read} is
386 called. If the thread gets canceled these resources stay allocated
387 until the program ends. To avoid this, calls to @code{read} should be
388 protected using cancellation handlers.
389 @c ref pthread_cleanup_push / pthread_cleanup_pop
391 The @code{read} function is the underlying primitive for all of the
392 functions that read from streams, such as @code{fgetc}.
397 @deftypefun ssize_t pread (int @var{filedes}, void *@var{buffer}, size_t @var{size}, off_t @var{offset})
398 The @code{pread} function is similar to the @code{read} function. The
399 first three arguments are identical, and the return values and error
400 codes also correspond.
402 The difference is the fourth argument and its handling. The data block
403 is not read from the current position of the file descriptor
404 @code{filedes}. Instead the data is read from the file starting at
405 position @var{offset}. The position of the file descriptor itself is
406 not affected by the operation. The value is the same as before the call.
408 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} the
409 @code{pread} function is in fact @code{pread64} and the type
410 @code{off_t} has 64 bits, which makes it possible to handle files up to
411 @math{2^63} bytes in length.
413 The return value of @code{pread} describes the number of bytes read.
414 In the error case it returns @math{-1} like @code{read} does and the
415 error codes are also the same, with these additions:
419 The value given for @var{offset} is negative and therefore illegal.
422 The file descriptor @var{filedes} is associate with a pipe or a FIFO and
423 this device does not allow positioning of the file pointer.
426 The function is an extension defined in the Unix Single Specification
432 @deftypefun ssize_t pread64 (int @var{filedes}, void *@var{buffer}, size_t @var{size}, off64_t @var{offset})
433 This function is similar to the @code{pread} function. The difference
434 is that the @var{offset} parameter is of type @code{off64_t} instead of
435 @code{off_t} which makes it possible on 32 bit machines to address
436 files larger than @math{2^31} bytes and up to @math{2^63} bytes. The
437 file descriptor @code{filedes} must be opened using @code{open64} since
438 otherwise the large offsets possible with @code{off64_t} will lead to
439 errors with a descriptor in small file mode.
441 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} on a
442 32 bit machine this function is actually available under the name
443 @code{pread} and so transparently replaces the 32 bit interface.
446 @cindex writing to a file descriptor
449 @deftypefun ssize_t write (int @var{filedes}, const void *@var{buffer}, size_t @var{size})
450 The @code{write} function writes up to @var{size} bytes from
451 @var{buffer} to the file with descriptor @var{filedes}. The data in
452 @var{buffer} is not necessarily a character string and a null character is
453 output like any other character.
455 The return value is the number of bytes actually written. This may be
456 @var{size}, but can always be smaller. Your program should always call
457 @code{write} in a loop, iterating until all the data is written.
459 Once @code{write} returns, the data is enqueued to be written and can be
460 read back right away, but it is not necessarily written out to permanent
461 storage immediately. You can use @code{fsync} when you need to be sure
462 your data has been permanently stored before continuing. (It is more
463 efficient for the system to batch up consecutive writes and do them all
464 at once when convenient. Normally they will always be written to disk
465 within a minute or less.) Modern systems provide another function
466 @code{fdatasync} which guarantees integrity only for the file data and
468 @c !!! xref fsync, fdatasync
469 You can use the @code{O_FSYNC} open mode to make @code{write} always
470 store the data to disk before returning; @pxref{Operating Modes}.
472 In the case of an error, @code{write} returns @math{-1}. The following
473 @code{errno} error conditions are defined for this function:
477 Normally, @code{write} blocks until the write operation is complete.
478 But if the @code{O_NONBLOCK} flag is set for the file (@pxref{Control
479 Operations}), it returns immediately without writing any data and
480 reports this error. An example of a situation that might cause the
481 process to block on output is writing to a terminal device that supports
482 flow control, where output has been suspended by receipt of a STOP
485 @strong{Compatibility Note:} Most versions of BSD Unix use a different
486 error code for this: @code{EWOULDBLOCK}. In @theglibc{},
487 @code{EWOULDBLOCK} is an alias for @code{EAGAIN}, so it doesn't matter
490 On some systems, writing a large amount of data from a character special
491 file can also fail with @code{EAGAIN} if the kernel cannot find enough
492 physical memory to lock down the user's pages. This is limited to
493 devices that transfer with direct memory access into the user's memory,
494 which means it does not include terminals, since they always use
495 separate buffers inside the kernel. This problem does not arise in the
499 The @var{filedes} argument is not a valid file descriptor,
500 or is not open for writing.
503 The size of the file would become larger than the implementation can support.
506 The @code{write} operation was interrupted by a signal while it was
507 blocked waiting for completion. A signal will not necessarily cause
508 @code{write} to return @code{EINTR}; it may instead result in a
509 successful @code{write} which writes fewer bytes than requested.
510 @xref{Interrupted Primitives}.
513 For many devices, and for disk files, this error code indicates
517 The device containing the file is full.
520 This error is returned when you try to write to a pipe or FIFO that
521 isn't open for reading by any process. When this happens, a @code{SIGPIPE}
522 signal is also sent to the process; see @ref{Signal Handling}.
525 In some systems, when writing to a character or block device, position
526 and size offsets must be aligned to a particular block size. This error
527 indicates that the offsets were not properly aligned.
530 Unless you have arranged to prevent @code{EINTR} failures, you should
531 check @code{errno} after each failing call to @code{write}, and if the
532 error was @code{EINTR}, you should simply repeat the call.
533 @xref{Interrupted Primitives}. The easy way to do this is with the
534 macro @code{TEMP_FAILURE_RETRY}, as follows:
537 nbytes = TEMP_FAILURE_RETRY (write (desc, buffer, count));
540 Please note that there is no function named @code{write64}. This is not
541 necessary since this function does not directly modify or handle the
542 possibly wide file offset. Since the kernel handles this state
543 internally the @code{write} function can be used for all cases.
545 This function is a cancellation point in multi-threaded programs. This
546 is a problem if the thread allocates some resources (like memory, file
547 descriptors, semaphores or whatever) at the time @code{write} is
548 called. If the thread gets canceled these resources stay allocated
549 until the program ends. To avoid this, calls to @code{write} should be
550 protected using cancellation handlers.
551 @c ref pthread_cleanup_push / pthread_cleanup_pop
553 The @code{write} function is the underlying primitive for all of the
554 functions that write to streams, such as @code{fputc}.
559 @deftypefun ssize_t pwrite (int @var{filedes}, const void *@var{buffer}, size_t @var{size}, off_t @var{offset})
560 The @code{pwrite} function is similar to the @code{write} function. The
561 first three arguments are identical, and the return values and error codes
564 The difference is the fourth argument and its handling. The data block
565 is not written to the current position of the file descriptor
566 @code{filedes}. Instead the data is written to the file starting at
567 position @var{offset}. The position of the file descriptor itself is
568 not affected by the operation. The value is the same as before the call.
570 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} the
571 @code{pwrite} function is in fact @code{pwrite64} and the type
572 @code{off_t} has 64 bits, which makes it possible to handle files up to
573 @math{2^63} bytes in length.
575 The return value of @code{pwrite} describes the number of written bytes.
576 In the error case it returns @math{-1} like @code{write} does and the
577 error codes are also the same, with these additions:
581 The value given for @var{offset} is negative and therefore illegal.
584 The file descriptor @var{filedes} is associated with a pipe or a FIFO and
585 this device does not allow positioning of the file pointer.
588 The function is an extension defined in the Unix Single Specification
594 @deftypefun ssize_t pwrite64 (int @var{filedes}, const void *@var{buffer}, size_t @var{size}, off64_t @var{offset})
595 This function is similar to the @code{pwrite} function. The difference
596 is that the @var{offset} parameter is of type @code{off64_t} instead of
597 @code{off_t} which makes it possible on 32 bit machines to address
598 files larger than @math{2^31} bytes and up to @math{2^63} bytes. The
599 file descriptor @code{filedes} must be opened using @code{open64} since
600 otherwise the large offsets possible with @code{off64_t} will lead to
601 errors with a descriptor in small file mode.
603 When the source file is compiled using @code{_FILE_OFFSET_BITS == 64} on a
604 32 bit machine this function is actually available under the name
605 @code{pwrite} and so transparently replaces the 32 bit interface.
609 @node File Position Primitive
610 @section Setting the File Position of a Descriptor
612 Just as you can set the file position of a stream with @code{fseek}, you
613 can set the file position of a descriptor with @code{lseek}. This
614 specifies the position in the file for the next @code{read} or
615 @code{write} operation. @xref{File Positioning}, for more information
616 on the file position and what it means.
618 To read the current file position value from a descriptor, use
619 @code{lseek (@var{desc}, 0, SEEK_CUR)}.
621 @cindex file positioning on a file descriptor
622 @cindex positioning a file descriptor
623 @cindex seeking on a file descriptor
626 @deftypefun off_t lseek (int @var{filedes}, off_t @var{offset}, int @var{whence})
627 The @code{lseek} function is used to change the file position of the
628 file with descriptor @var{filedes}.
630 The @var{whence} argument specifies how the @var{offset} should be
631 interpreted, in the same way as for the @code{fseek} function, and it must
632 be one of the symbolic constants @code{SEEK_SET}, @code{SEEK_CUR}, or
637 Specifies that @var{whence} is a count of characters from the beginning
641 Specifies that @var{whence} is a count of characters from the current
642 file position. This count may be positive or negative.
645 Specifies that @var{whence} is a count of characters from the end of
646 the file. A negative count specifies a position within the current
647 extent of the file; a positive count specifies a position past the
648 current end. If you set the position past the current end, and
649 actually write data, you will extend the file with zeros up to that
653 The return value from @code{lseek} is normally the resulting file
654 position, measured in bytes from the beginning of the file.
655 You can use this feature together with @code{SEEK_CUR} to read the
656 current file position.
658 If you want to append to the file, setting the file position to the
659 current end of file with @code{SEEK_END} is not sufficient. Another
660 process may write more data after you seek but before you write,
661 extending the file so the position you write onto clobbers their data.
662 Instead, use the @code{O_APPEND} operating mode; @pxref{Operating Modes}.
664 You can set the file position past the current end of the file. This
665 does not by itself make the file longer; @code{lseek} never changes the
666 file. But subsequent output at that position will extend the file.
667 Characters between the previous end of file and the new position are
668 filled with zeros. Extending the file in this way can create a
669 ``hole'': the blocks of zeros are not actually allocated on disk, so the
670 file takes up less space than it appears to; it is then called a
673 @cindex holes in files
675 If the file position cannot be changed, or the operation is in some way
676 invalid, @code{lseek} returns a value of @math{-1}. The following
677 @code{errno} error conditions are defined for this function:
681 The @var{filedes} is not a valid file descriptor.
684 The @var{whence} argument value is not valid, or the resulting
685 file offset is not valid. A file offset is invalid.
688 The @var{filedes} corresponds to an object that cannot be positioned,
689 such as a pipe, FIFO or terminal device. (POSIX.1 specifies this error
690 only for pipes and FIFOs, but in the GNU system, you always get
691 @code{ESPIPE} if the object is not seekable.)
694 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} the
695 @code{lseek} function is in fact @code{lseek64} and the type
696 @code{off_t} has 64 bits which makes it possible to handle files up to
697 @math{2^63} bytes in length.
699 This function is a cancellation point in multi-threaded programs. This
700 is a problem if the thread allocates some resources (like memory, file
701 descriptors, semaphores or whatever) at the time @code{lseek} is
702 called. If the thread gets canceled these resources stay allocated
703 until the program ends. To avoid this calls to @code{lseek} should be
704 protected using cancellation handlers.
705 @c ref pthread_cleanup_push / pthread_cleanup_pop
707 The @code{lseek} function is the underlying primitive for the
708 @code{fseek}, @code{fseeko}, @code{ftell}, @code{ftello} and
709 @code{rewind} functions, which operate on streams instead of file
715 @deftypefun off64_t lseek64 (int @var{filedes}, off64_t @var{offset}, int @var{whence})
716 This function is similar to the @code{lseek} function. The difference
717 is that the @var{offset} parameter is of type @code{off64_t} instead of
718 @code{off_t} which makes it possible on 32 bit machines to address
719 files larger than @math{2^31} bytes and up to @math{2^63} bytes. The
720 file descriptor @code{filedes} must be opened using @code{open64} since
721 otherwise the large offsets possible with @code{off64_t} will lead to
722 errors with a descriptor in small file mode.
724 When the source file is compiled with @code{_FILE_OFFSET_BITS == 64} on a
725 32 bits machine this function is actually available under the name
726 @code{lseek} and so transparently replaces the 32 bit interface.
729 You can have multiple descriptors for the same file if you open the file
730 more than once, or if you duplicate a descriptor with @code{dup}.
731 Descriptors that come from separate calls to @code{open} have independent
732 file positions; using @code{lseek} on one descriptor has no effect on the
740 d1 = open ("foo", O_RDONLY);
741 d2 = open ("foo", O_RDONLY);
742 lseek (d1, 1024, SEEK_SET);
749 will read the first four characters of the file @file{foo}. (The
750 error-checking code necessary for a real program has been omitted here
753 By contrast, descriptors made by duplication share a common file
754 position with the original descriptor that was duplicated. Anything
755 which alters the file position of one of the duplicates, including
756 reading or writing data, affects all of them alike. Thus, for example,
761 char buf1[4], buf2[4];
762 d1 = open ("foo", O_RDONLY);
765 lseek (d3, 1024, SEEK_SET);
772 will read four characters starting with the 1024'th character of
773 @file{foo}, and then four more characters starting with the 1028'th
778 @deftp {Data Type} off_t
779 This is an arithmetic data type used to represent file sizes.
780 In the GNU system, this is equivalent to @code{fpos_t} or @code{long int}.
782 If the source is compiled with @code{_FILE_OFFSET_BITS == 64} this type
783 is transparently replaced by @code{off64_t}.
788 @deftp {Data Type} off64_t
789 This type is used similar to @code{off_t}. The difference is that even
790 on 32 bit machines, where the @code{off_t} type would have 32 bits,
791 @code{off64_t} has 64 bits and so is able to address files up to
792 @math{2^63} bytes in length.
794 When compiling with @code{_FILE_OFFSET_BITS == 64} this type is
795 available under the name @code{off_t}.
798 These aliases for the @samp{SEEK_@dots{}} constants exist for the sake
799 of compatibility with older BSD systems. They are defined in two
800 different header files: @file{fcntl.h} and @file{sys/file.h}.
804 An alias for @code{SEEK_SET}.
807 An alias for @code{SEEK_CUR}.
810 An alias for @code{SEEK_END}.
813 @node Descriptors and Streams
814 @section Descriptors and Streams
815 @cindex streams, and file descriptors
816 @cindex converting file descriptor to stream
817 @cindex extracting file descriptor from stream
819 Given an open file descriptor, you can create a stream for it with the
820 @code{fdopen} function. You can get the underlying file descriptor for
821 an existing stream with the @code{fileno} function. These functions are
822 declared in the header file @file{stdio.h}.
827 @deftypefun {FILE *} fdopen (int @var{filedes}, const char *@var{opentype})
828 The @code{fdopen} function returns a new stream for the file descriptor
831 The @var{opentype} argument is interpreted in the same way as for the
832 @code{fopen} function (@pxref{Opening Streams}), except that
833 the @samp{b} option is not permitted; this is because GNU makes no
834 distinction between text and binary files. Also, @code{"w"} and
835 @code{"w+"} do not cause truncation of the file; these have an effect only
836 when opening a file, and in this case the file has already been opened.
837 You must make sure that the @var{opentype} argument matches the actual
838 mode of the open file descriptor.
840 The return value is the new stream. If the stream cannot be created
841 (for example, if the modes for the file indicated by the file descriptor
842 do not permit the access specified by the @var{opentype} argument), a
843 null pointer is returned instead.
845 In some other systems, @code{fdopen} may fail to detect that the modes
846 for file descriptor do not permit the access specified by
847 @code{opentype}. @Theglibc{} always checks for this.
850 For an example showing the use of the @code{fdopen} function,
851 see @ref{Creating a Pipe}.
855 @deftypefun int fileno (FILE *@var{stream})
856 This function returns the file descriptor associated with the stream
857 @var{stream}. If an error is detected (for example, if the @var{stream}
858 is not valid) or if @var{stream} does not do I/O to a file,
859 @code{fileno} returns @math{-1}.
864 @deftypefun int fileno_unlocked (FILE *@var{stream})
865 The @code{fileno_unlocked} function is equivalent to the @code{fileno}
866 function except that it does not implicitly lock the stream if the state
867 is @code{FSETLOCKING_INTERNAL}.
869 This function is a GNU extension.
872 @cindex standard file descriptors
873 @cindex file descriptors, standard
874 There are also symbolic constants defined in @file{unistd.h} for the
875 file descriptors belonging to the standard streams @code{stdin},
876 @code{stdout}, and @code{stderr}; see @ref{Standard Streams}.
884 This macro has value @code{0}, which is the file descriptor for
886 @cindex standard input file descriptor
891 @vindex STDOUT_FILENO
892 This macro has value @code{1}, which is the file descriptor for
894 @cindex standard output file descriptor
899 @vindex STDERR_FILENO
900 This macro has value @code{2}, which is the file descriptor for
901 standard error output.
903 @cindex standard error file descriptor
905 @node Stream/Descriptor Precautions
906 @section Dangers of Mixing Streams and Descriptors
908 @cindex streams and descriptors
909 @cindex descriptors and streams
910 @cindex mixing descriptors and streams
912 You can have multiple file descriptors and streams (let's call both
913 streams and descriptors ``channels'' for short) connected to the same
914 file, but you must take care to avoid confusion between channels. There
915 are two cases to consider: @dfn{linked} channels that share a single
916 file position value, and @dfn{independent} channels that have their own
919 It's best to use just one channel in your program for actual data
920 transfer to any given file, except when all the access is for input.
921 For example, if you open a pipe (something you can only do at the file
922 descriptor level), either do all I/O with the descriptor, or construct a
923 stream from the descriptor with @code{fdopen} and then do all I/O with
927 * Linked Channels:: Dealing with channels sharing a file position.
928 * Independent Channels:: Dealing with separately opened, unlinked channels.
929 * Cleaning Streams:: Cleaning a stream makes it safe to use
933 @node Linked Channels
934 @subsection Linked Channels
935 @cindex linked channels
937 Channels that come from a single opening share the same file position;
938 we call them @dfn{linked} channels. Linked channels result when you
939 make a stream from a descriptor using @code{fdopen}, when you get a
940 descriptor from a stream with @code{fileno}, when you copy a descriptor
941 with @code{dup} or @code{dup2}, and when descriptors are inherited
942 during @code{fork}. For files that don't support random access, such as
943 terminals and pipes, @emph{all} channels are effectively linked. On
944 random-access files, all append-type output streams are effectively
945 linked to each other.
947 @cindex cleaning up a stream
948 If you have been using a stream for I/O (or have just opened the stream),
949 and you want to do I/O using
950 another channel (either a stream or a descriptor) that is linked to it,
951 you must first @dfn{clean up} the stream that you have been using.
952 @xref{Cleaning Streams}.
954 Terminating a process, or executing a new program in the process,
955 destroys all the streams in the process. If descriptors linked to these
956 streams persist in other processes, their file positions become
957 undefined as a result. To prevent this, you must clean up the streams
958 before destroying them.
960 @node Independent Channels
961 @subsection Independent Channels
962 @cindex independent channels
964 When you open channels (streams or descriptors) separately on a seekable
965 file, each channel has its own file position. These are called
966 @dfn{independent channels}.
968 The system handles each channel independently. Most of the time, this
969 is quite predictable and natural (especially for input): each channel
970 can read or write sequentially at its own place in the file. However,
971 if some of the channels are streams, you must take these precautions:
975 You should clean an output stream after use, before doing anything else
976 that might read or write from the same part of the file.
979 You should clean an input stream before reading data that may have been
980 modified using an independent channel. Otherwise, you might read
981 obsolete data that had been in the stream's buffer.
984 If you do output to one channel at the end of the file, this will
985 certainly leave the other independent channels positioned somewhere
986 before the new end. You cannot reliably set their file positions to the
987 new end of file before writing, because the file can always be extended
988 by another process between when you set the file position and when you
989 write the data. Instead, use an append-type descriptor or stream; they
990 always output at the current end of the file. In order to make the
991 end-of-file position accurate, you must clean the output channel you
992 were using, if it is a stream.
994 It's impossible for two channels to have separate file pointers for a
995 file that doesn't support random access. Thus, channels for reading or
996 writing such files are always linked, never independent. Append-type
997 channels are also always linked. For these channels, follow the rules
998 for linked channels; see @ref{Linked Channels}.
1000 @node Cleaning Streams
1001 @subsection Cleaning Streams
1003 You can use @code{fflush} to clean a stream in most
1006 You can skip the @code{fflush} if you know the stream
1007 is already clean. A stream is clean whenever its buffer is empty. For
1008 example, an unbuffered stream is always clean. An input stream that is
1009 at end-of-file is clean. A line-buffered stream is clean when the last
1010 character output was a newline. However, a just-opened input stream
1011 might not be clean, as its input buffer might not be empty.
1013 There is one case in which cleaning a stream is impossible on most
1014 systems. This is when the stream is doing input from a file that is not
1015 random-access. Such streams typically read ahead, and when the file is
1016 not random access, there is no way to give back the excess data already
1017 read. When an input stream reads from a random-access file,
1018 @code{fflush} does clean the stream, but leaves the file pointer at an
1019 unpredictable place; you must set the file pointer before doing any
1022 Closing an output-only stream also does @code{fflush}, so this is a
1023 valid way of cleaning an output stream.
1025 You need not clean a stream before using its descriptor for control
1026 operations such as setting terminal modes; these operations don't affect
1027 the file position and are not affected by it. You can use any
1028 descriptor for these operations, and all channels are affected
1029 simultaneously. However, text already ``output'' to a stream but still
1030 buffered by the stream will be subject to the new terminal modes when
1031 subsequently flushed. To make sure ``past'' output is covered by the
1032 terminal settings that were in effect at the time, flush the output
1033 streams for that terminal before setting the modes. @xref{Terminal
1036 @node Scatter-Gather
1037 @section Fast Scatter-Gather I/O
1038 @cindex scatter-gather
1040 Some applications may need to read or write data to multiple buffers,
1041 which are separated in memory. Although this can be done easily enough
1042 with multiple calls to @code{read} and @code{write}, it is inefficient
1043 because there is overhead associated with each kernel call.
1045 Instead, many platforms provide special high-speed primitives to perform
1046 these @dfn{scatter-gather} operations in a single kernel call. @Theglibc{}
1047 will provide an emulation on any system that lacks these
1048 primitives, so they are not a portability threat. They are defined in
1051 These functions are controlled with arrays of @code{iovec} structures,
1052 which describe the location and size of each buffer.
1056 @deftp {Data Type} {struct iovec}
1058 The @code{iovec} structure describes a buffer. It contains two fields:
1062 @item void *iov_base
1063 Contains the address of a buffer.
1065 @item size_t iov_len
1066 Contains the length of the buffer.
1073 @deftypefun ssize_t readv (int @var{filedes}, const struct iovec *@var{vector}, int @var{count})
1075 The @code{readv} function reads data from @var{filedes} and scatters it
1076 into the buffers described in @var{vector}, which is taken to be
1077 @var{count} structures long. As each buffer is filled, data is sent to the
1080 Note that @code{readv} is not guaranteed to fill all the buffers.
1081 It may stop at any point, for the same reasons @code{read} would.
1083 The return value is a count of bytes (@emph{not} buffers) read, @math{0}
1084 indicating end-of-file, or @math{-1} indicating an error. The possible
1085 errors are the same as in @code{read}.
1091 @deftypefun ssize_t writev (int @var{filedes}, const struct iovec *@var{vector}, int @var{count})
1093 The @code{writev} function gathers data from the buffers described in
1094 @var{vector}, which is taken to be @var{count} structures long, and writes
1095 them to @code{filedes}. As each buffer is written, it moves on to the
1098 Like @code{readv}, @code{writev} may stop midstream under the same
1099 conditions @code{write} would.
1101 The return value is a count of bytes written, or @math{-1} indicating an
1102 error. The possible errors are the same as in @code{write}.
1106 @c Note - I haven't read this anywhere. I surmised it from my knowledge
1107 @c of computer science. Thus, there could be subtleties I'm missing.
1109 Note that if the buffers are small (under about 1kB), high-level streams
1110 may be easier to use than these functions. However, @code{readv} and
1111 @code{writev} are more efficient when the individual buffers themselves
1112 (as opposed to the total output), are large. In that case, a high-level
1113 stream would not be able to cache the data effectively.
1115 @node Memory-mapped I/O
1116 @section Memory-mapped I/O
1118 On modern operating systems, it is possible to @dfn{mmap} (pronounced
1119 ``em-map'') a file to a region of memory. When this is done, the file can
1120 be accessed just like an array in the program.
1122 This is more efficient than @code{read} or @code{write}, as only the regions
1123 of the file that a program actually accesses are loaded. Accesses to
1124 not-yet-loaded parts of the mmapped region are handled in the same way as
1127 Since mmapped pages can be stored back to their file when physical
1128 memory is low, it is possible to mmap files orders of magnitude larger
1129 than both the physical memory @emph{and} swap space. The only limit is
1130 address space. The theoretical limit is 4GB on a 32-bit machine -
1131 however, the actual limit will be smaller since some areas will be
1132 reserved for other purposes. If the LFS interface is used the file size
1133 on 32-bit systems is not limited to 2GB (offsets are signed which
1134 reduces the addressable area of 4GB by half); the full 64-bit are
1137 Memory mapping only works on entire pages of memory. Thus, addresses
1138 for mapping must be page-aligned, and length values will be rounded up.
1139 To determine the size of a page the machine uses one should use
1141 @vindex _SC_PAGESIZE
1143 size_t page_size = (size_t) sysconf (_SC_PAGESIZE);
1147 These functions are declared in @file{sys/mman.h}.
1151 @deftypefun {void *} mmap (void *@var{address}, size_t @var{length}, int @var{protect}, int @var{flags}, int @var{filedes}, off_t @var{offset})
1153 The @code{mmap} function creates a new mapping, connected to bytes
1154 (@var{offset}) to (@var{offset} + @var{length} - 1) in the file open on
1155 @var{filedes}. A new reference for the file specified by @var{filedes}
1156 is created, which is not removed by closing the file.
1158 @var{address} gives a preferred starting address for the mapping.
1159 @code{NULL} expresses no preference. Any previous mapping at that
1160 address is automatically removed. The address you give may still be
1161 changed, unless you use the @code{MAP_FIXED} flag.
1166 @var{protect} contains flags that control what kind of access is
1167 permitted. They include @code{PROT_READ}, @code{PROT_WRITE}, and
1168 @code{PROT_EXEC}, which permit reading, writing, and execution,
1169 respectively. Inappropriate access will cause a segfault (@pxref{Program
1172 Note that most hardware designs cannot support write permission without
1173 read permission, and many do not distinguish read and execute permission.
1174 Thus, you may receive wider permissions than you ask for, and mappings of
1175 write-only files may be denied even if you do not use @code{PROT_READ}.
1177 @var{flags} contains flags that control the nature of the map.
1178 One of @code{MAP_SHARED} or @code{MAP_PRIVATE} must be specified.
1184 This specifies that writes to the region should never be written back
1185 to the attached file. Instead, a copy is made for the process, and the
1186 region will be swapped normally if memory runs low. No other process will
1189 Since private mappings effectively revert to ordinary memory
1190 when written to, you must have enough virtual memory for a copy of
1191 the entire mmapped region if you use this mode with @code{PROT_WRITE}.
1194 This specifies that writes to the region will be written back to the
1195 file. Changes made will be shared immediately with other processes
1196 mmaping the same file.
1198 Note that actual writing may take place at any time. You need to use
1199 @code{msync}, described below, if it is important that other processes
1200 using conventional I/O get a consistent view of the file.
1203 This forces the system to use the exact mapping address specified in
1204 @var{address} and fail if it can't.
1206 @c One of these is official - the other is obviously an obsolete synonym
1210 This flag tells the system to create an anonymous mapping, not connected
1211 to a file. @var{filedes} and @var{off} are ignored, and the region is
1212 initialized with zeros.
1214 Anonymous maps are used as the basic primitive to extend the heap on some
1215 systems. They are also useful to share data between multiple tasks
1216 without creating a file.
1218 On some systems using private anonymous mmaps is more efficient than using
1219 @code{malloc} for large blocks. This is not an issue with @theglibc{},
1220 as the included @code{malloc} automatically uses @code{mmap} where appropriate.
1222 @c Linux has some other MAP_ options, which I have not discussed here.
1223 @c MAP_DENYWRITE, MAP_EXECUTABLE and MAP_GROWSDOWN don't seem applicable to
1224 @c user programs (and I don't understand the last two). MAP_LOCKED does
1225 @c not appear to be implemented.
1229 @code{mmap} returns the address of the new mapping, or @math{-1} for an
1232 Possible errors include:
1238 Either @var{address} was unusable, or inconsistent @var{flags} were
1243 @var{filedes} was not open for the type of access specified in @var{protect}.
1247 Either there is not enough memory for the operation, or the process is
1248 out of address space.
1252 This file is of a type that doesn't support mapping.
1256 The file is on a filesystem that doesn't support mapping.
1258 @c On Linux, EAGAIN will appear if the file has a conflicting mandatory lock.
1259 @c However mandatory locks are not discussed in this manual.
1261 @c Similarly, ETXTBSY will occur if the MAP_DENYWRITE flag (not documented
1262 @c here) is used and the file is already open for writing.
1270 @deftypefun {void *} mmap64 (void *@var{address}, size_t @var{length}, int @var{protect}, int @var{flags}, int @var{filedes}, off64_t @var{offset})
1271 The @code{mmap64} function is equivalent to the @code{mmap} function but
1272 the @var{offset} parameter is of type @code{off64_t}. On 32-bit systems
1273 this allows the file associated with the @var{filedes} descriptor to be
1274 larger than 2GB. @var{filedes} must be a descriptor returned from a
1275 call to @code{open64} or @code{fopen64} and @code{freopen64} where the
1276 descriptor is retrieved with @code{fileno}.
1278 When the sources are translated with @code{_FILE_OFFSET_BITS == 64} this
1279 function is actually available under the name @code{mmap}. I.e., the
1280 new, extended API using 64 bit file sizes and offsets transparently
1281 replaces the old API.
1286 @deftypefun int munmap (void *@var{addr}, size_t @var{length})
1288 @code{munmap} removes any memory maps from (@var{addr}) to (@var{addr} +
1289 @var{length}). @var{length} should be the length of the mapping.
1291 It is safe to unmap multiple mappings in one command, or include unmapped
1292 space in the range. It is also possible to unmap only part of an existing
1293 mapping. However, only entire pages can be removed. If @var{length} is not
1294 an even number of pages, it will be rounded up.
1296 It returns @math{0} for success and @math{-1} for an error.
1298 One error is possible:
1303 The memory range given was outside the user mmap range or wasn't page
1312 @deftypefun int msync (void *@var{address}, size_t @var{length}, int @var{flags})
1314 When using shared mappings, the kernel can write the file at any time
1315 before the mapping is removed. To be certain data has actually been
1316 written to the file and will be accessible to non-memory-mapped I/O, it
1317 is necessary to use this function.
1319 It operates on the region @var{address} to (@var{address} + @var{length}).
1320 It may be used on part of a mapping or multiple mappings, however the
1321 region given should not contain any unmapped space.
1323 @var{flags} can contain some options:
1329 This flag makes sure the data is actually written @emph{to disk}.
1330 Normally @code{msync} only makes sure that accesses to a file with
1331 conventional I/O reflect the recent changes.
1335 This tells @code{msync} to begin the synchronization, but not to wait for
1338 @c Linux also has MS_INVALIDATE, which I don't understand.
1342 @code{msync} returns @math{0} for success and @math{-1} for
1343 error. Errors include:
1348 An invalid region was given, or the @var{flags} were invalid.
1351 There is no existing mapping in at least part of the given region.
1359 @deftypefun {void *} mremap (void *@var{address}, size_t @var{length}, size_t @var{new_length}, int @var{flag})
1361 This function can be used to change the size of an existing memory
1362 area. @var{address} and @var{length} must cover a region entirely mapped
1363 in the same @code{mmap} statement. A new mapping with the same
1364 characteristics will be returned with the length @var{new_length}.
1366 One option is possible, @code{MREMAP_MAYMOVE}. If it is given in
1367 @var{flags}, the system may remove the existing mapping and create a new
1368 one of the desired length in another location.
1370 The address of the resulting mapping is returned, or @math{-1}. Possible
1371 error codes include:
1376 There is no existing mapping in at least part of the original region, or
1377 the region covers two or more distinct mappings.
1380 The address given is misaligned or inappropriate.
1383 The region has pages locked, and if extended it would exceed the
1384 process's resource limit for locked pages. @xref{Limits on Resources}.
1387 The region is private writable, and insufficient virtual memory is
1388 available to extend it. Also, this error will occur if
1389 @code{MREMAP_MAYMOVE} is not given and the extension would collide with
1390 another mapped region.
1395 This function is only available on a few systems. Except for performing
1396 optional optimizations one should not rely on this function.
1398 Not all file descriptors may be mapped. Sockets, pipes, and most devices
1399 only allow sequential access and do not fit into the mapping abstraction.
1400 In addition, some regular files may not be mmapable, and older kernels may
1401 not support mapping at all. Thus, programs using @code{mmap} should
1402 have a fallback method to use should it fail. @xref{Mmap,,,standards,GNU
1407 @deftypefun int madvise (void *@var{addr}, size_t @var{length}, int @var{advice})
1409 This function can be used to provide the system with @var{advice} about
1410 the intended usage patterns of the memory region starting at @var{addr}
1411 and extending @var{length} bytes.
1413 The valid BSD values for @var{advice} are:
1418 The region should receive no further special treatment.
1421 The region will be accessed via random page references. The kernel
1422 should page-in the minimal number of pages for each page fault.
1424 @item MADV_SEQUENTIAL
1425 The region will be accessed via sequential page references. This
1426 may cause the kernel to aggressively read-ahead, expecting further
1427 sequential references after any page fault within this region.
1430 The region will be needed. The pages within this region may
1431 be pre-faulted in by the kernel.
1434 The region is no longer needed. The kernel may free these pages,
1435 causing any changes to the pages to be lost, as well as swapped
1436 out pages to be discarded.
1440 The POSIX names are slightly different, but with the same meanings:
1444 @item POSIX_MADV_NORMAL
1445 This corresponds with BSD's @code{MADV_NORMAL}.
1447 @item POSIX_MADV_RANDOM
1448 This corresponds with BSD's @code{MADV_RANDOM}.
1450 @item POSIX_MADV_SEQUENTIAL
1451 This corresponds with BSD's @code{MADV_SEQUENTIAL}.
1453 @item POSIX_MADV_WILLNEED
1454 This corresponds with BSD's @code{MADV_WILLNEED}.
1456 @item POSIX_MADV_DONTNEED
1457 This corresponds with BSD's @code{MADV_DONTNEED}.
1461 @code{msync} returns @math{0} for success and @math{-1} for
1462 error. Errors include:
1466 An invalid region was given, or the @var{advice} was invalid.
1469 There is no existing mapping in at least part of the given region.
1474 @node Waiting for I/O
1475 @section Waiting for Input or Output
1476 @cindex waiting for input or output
1477 @cindex multiplexing input
1478 @cindex input from multiple files
1480 Sometimes a program needs to accept input on multiple input channels
1481 whenever input arrives. For example, some workstations may have devices
1482 such as a digitizing tablet, function button box, or dial box that are
1483 connected via normal asynchronous serial interfaces; good user interface
1484 style requires responding immediately to input on any device. Another
1485 example is a program that acts as a server to several other processes
1486 via pipes or sockets.
1488 You cannot normally use @code{read} for this purpose, because this
1489 blocks the program until input is available on one particular file
1490 descriptor; input on other channels won't wake it up. You could set
1491 nonblocking mode and poll each file descriptor in turn, but this is very
1494 A better solution is to use the @code{select} function. This blocks the
1495 program until input or output is ready on a specified set of file
1496 descriptors, or until a timer expires, whichever comes first. This
1497 facility is declared in the header file @file{sys/types.h}.
1500 In the case of a server socket (@pxref{Listening}), we say that
1501 ``input'' is available when there are pending connections that could be
1502 accepted (@pxref{Accepting Connections}). @code{accept} for server
1503 sockets blocks and interacts with @code{select} just as @code{read} does
1506 @cindex file descriptor sets, for @code{select}
1507 The file descriptor sets for the @code{select} function are specified
1508 as @code{fd_set} objects. Here is the description of the data type
1509 and some macros for manipulating these objects.
1511 @comment sys/types.h
1513 @deftp {Data Type} fd_set
1514 The @code{fd_set} data type represents file descriptor sets for the
1515 @code{select} function. It is actually a bit array.
1518 @comment sys/types.h
1520 @deftypevr Macro int FD_SETSIZE
1521 The value of this macro is the maximum number of file descriptors that a
1522 @code{fd_set} object can hold information about. On systems with a
1523 fixed maximum number, @code{FD_SETSIZE} is at least that number. On
1524 some systems, including GNU, there is no absolute limit on the number of
1525 descriptors open, but this macro still has a constant value which
1526 controls the number of bits in an @code{fd_set}; if you get a file
1527 descriptor with a value as high as @code{FD_SETSIZE}, you cannot put
1528 that descriptor into an @code{fd_set}.
1531 @comment sys/types.h
1533 @deftypefn Macro void FD_ZERO (fd_set *@var{set})
1534 This macro initializes the file descriptor set @var{set} to be the
1538 @comment sys/types.h
1540 @deftypefn Macro void FD_SET (int @var{filedes}, fd_set *@var{set})
1541 This macro adds @var{filedes} to the file descriptor set @var{set}.
1543 The @var{filedes} parameter must not have side effects since it is
1544 evaluated more than once.
1547 @comment sys/types.h
1549 @deftypefn Macro void FD_CLR (int @var{filedes}, fd_set *@var{set})
1550 This macro removes @var{filedes} from the file descriptor set @var{set}.
1552 The @var{filedes} parameter must not have side effects since it is
1553 evaluated more than once.
1556 @comment sys/types.h
1558 @deftypefn Macro int FD_ISSET (int @var{filedes}, const fd_set *@var{set})
1559 This macro returns a nonzero value (true) if @var{filedes} is a member
1560 of the file descriptor set @var{set}, and zero (false) otherwise.
1562 The @var{filedes} parameter must not have side effects since it is
1563 evaluated more than once.
1566 Next, here is the description of the @code{select} function itself.
1568 @comment sys/types.h
1570 @deftypefun int select (int @var{nfds}, fd_set *@var{read-fds}, fd_set *@var{write-fds}, fd_set *@var{except-fds}, struct timeval *@var{timeout})
1571 The @code{select} function blocks the calling process until there is
1572 activity on any of the specified sets of file descriptors, or until the
1573 timeout period has expired.
1575 The file descriptors specified by the @var{read-fds} argument are
1576 checked to see if they are ready for reading; the @var{write-fds} file
1577 descriptors are checked to see if they are ready for writing; and the
1578 @var{except-fds} file descriptors are checked for exceptional
1579 conditions. You can pass a null pointer for any of these arguments if
1580 you are not interested in checking for that kind of condition.
1582 A file descriptor is considered ready for reading if a @code{read}
1583 call will not block. This usually includes the read offset being at
1584 the end of the file or there is an error to report. A server socket
1585 is considered ready for reading if there is a pending connection which
1586 can be accepted with @code{accept}; @pxref{Accepting Connections}. A
1587 client socket is ready for writing when its connection is fully
1588 established; @pxref{Connecting}.
1590 ``Exceptional conditions'' does not mean errors---errors are reported
1591 immediately when an erroneous system call is executed, and do not
1592 constitute a state of the descriptor. Rather, they include conditions
1593 such as the presence of an urgent message on a socket. (@xref{Sockets},
1594 for information on urgent messages.)
1596 The @code{select} function checks only the first @var{nfds} file
1597 descriptors. The usual thing is to pass @code{FD_SETSIZE} as the value
1600 The @var{timeout} specifies the maximum time to wait. If you pass a
1601 null pointer for this argument, it means to block indefinitely until one
1602 of the file descriptors is ready. Otherwise, you should provide the
1603 time in @code{struct timeval} format; see @ref{High-Resolution
1604 Calendar}. Specify zero as the time (a @code{struct timeval} containing
1605 all zeros) if you want to find out which descriptors are ready without
1606 waiting if none are ready.
1608 The normal return value from @code{select} is the total number of ready file
1609 descriptors in all of the sets. Each of the argument sets is overwritten
1610 with information about the descriptors that are ready for the corresponding
1611 operation. Thus, to see if a particular descriptor @var{desc} has input,
1612 use @code{FD_ISSET (@var{desc}, @var{read-fds})} after @code{select} returns.
1614 If @code{select} returns because the timeout period expires, it returns
1617 Any signal will cause @code{select} to return immediately. So if your
1618 program uses signals, you can't rely on @code{select} to keep waiting
1619 for the full time specified. If you want to be sure of waiting for a
1620 particular amount of time, you must check for @code{EINTR} and repeat
1621 the @code{select} with a newly calculated timeout based on the current
1622 time. See the example below. See also @ref{Interrupted Primitives}.
1624 If an error occurs, @code{select} returns @code{-1} and does not modify
1625 the argument file descriptor sets. The following @code{errno} error
1626 conditions are defined for this function:
1630 One of the file descriptor sets specified an invalid file descriptor.
1633 The operation was interrupted by a signal. @xref{Interrupted Primitives}.
1636 The @var{timeout} argument is invalid; one of the components is negative
1641 @strong{Portability Note:} The @code{select} function is a BSD Unix
1644 Here is an example showing how you can use @code{select} to establish a
1645 timeout period for reading from a file descriptor. The @code{input_timeout}
1646 function blocks the calling process until input is available on the
1647 file descriptor, or until the timeout period expires.
1650 @include select.c.texi
1653 There is another example showing the use of @code{select} to multiplex
1654 input from multiple sockets in @ref{Server Example}.
1657 @node Synchronizing I/O
1658 @section Synchronizing I/O operations
1660 @cindex synchronizing
1661 In most modern operating systems, the normal I/O operations are not
1662 executed synchronously. I.e., even if a @code{write} system call
1663 returns, this does not mean the data is actually written to the media,
1666 In situations where synchronization points are necessary, you can use
1667 special functions which ensure that all operations finish before
1672 @deftypefun int sync (void)
1673 A call to this function will not return as long as there is data which
1674 has not been written to the device. All dirty buffers in the kernel will
1675 be written and so an overall consistent system can be achieved (if no
1676 other process in parallel writes data).
1678 A prototype for @code{sync} can be found in @file{unistd.h}.
1680 The return value is zero to indicate no error.
1683 Programs more often want to ensure that data written to a given file is
1684 committed, rather than all data in the system. For this, @code{sync} is overkill.
1689 @deftypefun int fsync (int @var{fildes})
1690 The @code{fsync} function can be used to make sure all data associated with
1691 the open file @var{fildes} is written to the device associated with the
1692 descriptor. The function call does not return unless all actions have
1695 A prototype for @code{fsync} can be found in @file{unistd.h}.
1697 This function is a cancellation point in multi-threaded programs. This
1698 is a problem if the thread allocates some resources (like memory, file
1699 descriptors, semaphores or whatever) at the time @code{fsync} is
1700 called. If the thread gets canceled these resources stay allocated
1701 until the program ends. To avoid this, calls to @code{fsync} should be
1702 protected using cancellation handlers.
1703 @c ref pthread_cleanup_push / pthread_cleanup_pop
1705 The return value of the function is zero if no error occurred. Otherwise
1706 it is @math{-1} and the global variable @var{errno} is set to the
1710 The descriptor @var{fildes} is not valid.
1713 No synchronization is possible since the system does not implement this.
1717 Sometimes it is not even necessary to write all data associated with a
1718 file descriptor. E.g., in database files which do not change in size it
1719 is enough to write all the file content data to the device.
1720 Meta-information, like the modification time etc., are not that important
1721 and leaving such information uncommitted does not prevent a successful
1722 recovering of the file in case of a problem.
1726 @deftypefun int fdatasync (int @var{fildes})
1727 When a call to the @code{fdatasync} function returns, it is ensured
1728 that all of the file data is written to the device. For all pending I/O
1729 operations, the parts guaranteeing data integrity finished.
1731 Not all systems implement the @code{fdatasync} operation. On systems
1732 missing this functionality @code{fdatasync} is emulated by a call to
1733 @code{fsync} since the performed actions are a superset of those
1734 required by @code{fdatasync}.
1736 The prototype for @code{fdatasync} is in @file{unistd.h}.
1738 The return value of the function is zero if no error occurred. Otherwise
1739 it is @math{-1} and the global variable @var{errno} is set to the
1743 The descriptor @var{fildes} is not valid.
1746 No synchronization is possible since the system does not implement this.
1751 @node Asynchronous I/O
1752 @section Perform I/O Operations in Parallel
1754 The POSIX.1b standard defines a new set of I/O operations which can
1755 significantly reduce the time an application spends waiting at I/O. The
1756 new functions allow a program to initiate one or more I/O operations and
1757 then immediately resume normal work while the I/O operations are
1758 executed in parallel. This functionality is available if the
1759 @file{unistd.h} file defines the symbol @code{_POSIX_ASYNCHRONOUS_IO}.
1761 These functions are part of the library with realtime functions named
1762 @file{librt}. They are not actually part of the @file{libc} binary.
1763 The implementation of these functions can be done using support in the
1764 kernel (if available) or using an implementation based on threads at
1765 userlevel. In the latter case it might be necessary to link applications
1766 with the thread library @file{libpthread} in addition to @file{librt}.
1768 All AIO operations operate on files which were opened previously. There
1769 might be arbitrarily many operations running for one file. The
1770 asynchronous I/O operations are controlled using a data structure named
1771 @code{struct aiocb} (@dfn{AIO control block}). It is defined in
1772 @file{aio.h} as follows.
1776 @deftp {Data Type} {struct aiocb}
1777 The POSIX.1b standard mandates that the @code{struct aiocb} structure
1778 contains at least the members described in the following table. There
1779 might be more elements which are used by the implementation, but
1780 depending upon these elements is not portable and is highly deprecated.
1783 @item int aio_fildes
1784 This element specifies the file descriptor to be used for the
1785 operation. It must be a legal descriptor, otherwise the operation will
1788 The device on which the file is opened must allow the seek operation.
1789 I.e., it is not possible to use any of the AIO operations on devices
1790 like terminals where an @code{lseek} call would lead to an error.
1792 @item off_t aio_offset
1793 This element specifies the offset in the file at which the operation (input
1794 or output) is performed. Since the operations are carried out in arbitrary
1795 order and more than one operation for one file descriptor can be
1796 started, one cannot expect a current read/write position of the file
1799 @item volatile void *aio_buf
1800 This is a pointer to the buffer with the data to be written or the place
1801 where the read data is stored.
1803 @item size_t aio_nbytes
1804 This element specifies the length of the buffer pointed to by @code{aio_buf}.
1806 @item int aio_reqprio
1807 If the platform has defined @code{_POSIX_PRIORITIZED_IO} and
1808 @code{_POSIX_PRIORITY_SCHEDULING}, the AIO requests are
1809 processed based on the current scheduling priority. The
1810 @code{aio_reqprio} element can then be used to lower the priority of the
1813 @item struct sigevent aio_sigevent
1814 This element specifies how the calling process is notified once the
1815 operation terminates. If the @code{sigev_notify} element is
1816 @code{SIGEV_NONE}, no notification is sent. If it is @code{SIGEV_SIGNAL},
1817 the signal determined by @code{sigev_signo} is sent. Otherwise,
1818 @code{sigev_notify} must be @code{SIGEV_THREAD}. In this case, a thread
1819 is created which starts executing the function pointed to by
1820 @code{sigev_notify_function}.
1822 @item int aio_lio_opcode
1823 This element is only used by the @code{lio_listio} and
1824 @code{lio_listio64} functions. Since these functions allow an
1825 arbitrary number of operations to start at once, and each operation can be
1826 input or output (or nothing), the information must be stored in the
1827 control block. The possible values are:
1831 Start a read operation. Read from the file at position
1832 @code{aio_offset} and store the next @code{aio_nbytes} bytes in the
1833 buffer pointed to by @code{aio_buf}.
1836 Start a write operation. Write @code{aio_nbytes} bytes starting at
1837 @code{aio_buf} into the file starting at position @code{aio_offset}.
1840 Do nothing for this control block. This value is useful sometimes when
1841 an array of @code{struct aiocb} values contains holes, i.e., some of the
1842 values must not be handled although the whole array is presented to the
1843 @code{lio_listio} function.
1847 When the sources are compiled using @code{_FILE_OFFSET_BITS == 64} on a
1848 32 bit machine, this type is in fact @code{struct aiocb64}, since the LFS
1849 interface transparently replaces the @code{struct aiocb} definition.
1852 For use with the AIO functions defined in the LFS, there is a similar type
1853 defined which replaces the types of the appropriate members with larger
1854 types but otherwise is equivalent to @code{struct aiocb}. Particularly,
1855 all member names are the same.
1859 @deftp {Data Type} {struct aiocb64}
1861 @item int aio_fildes
1862 This element specifies the file descriptor which is used for the
1863 operation. It must be a legal descriptor since otherwise the operation
1864 fails for obvious reasons.
1866 The device on which the file is opened must allow the seek operation.
1867 I.e., it is not possible to use any of the AIO operations on devices
1868 like terminals where an @code{lseek} call would lead to an error.
1870 @item off64_t aio_offset
1871 This element specifies at which offset in the file the operation (input
1872 or output) is performed. Since the operation are carried in arbitrary
1873 order and more than one operation for one file descriptor can be
1874 started, one cannot expect a current read/write position of the file
1877 @item volatile void *aio_buf
1878 This is a pointer to the buffer with the data to be written or the place
1879 where the read data is stored.
1881 @item size_t aio_nbytes
1882 This element specifies the length of the buffer pointed to by @code{aio_buf}.
1884 @item int aio_reqprio
1885 If for the platform @code{_POSIX_PRIORITIZED_IO} and
1886 @code{_POSIX_PRIORITY_SCHEDULING} are defined the AIO requests are
1887 processed based on the current scheduling priority. The
1888 @code{aio_reqprio} element can then be used to lower the priority of the
1891 @item struct sigevent aio_sigevent
1892 This element specifies how the calling process is notified once the
1893 operation terminates. If the @code{sigev_notify}, element is
1894 @code{SIGEV_NONE} no notification is sent. If it is @code{SIGEV_SIGNAL},
1895 the signal determined by @code{sigev_signo} is sent. Otherwise,
1896 @code{sigev_notify} must be @code{SIGEV_THREAD} in which case a thread
1897 which starts executing the function pointed to by
1898 @code{sigev_notify_function}.
1900 @item int aio_lio_opcode
1901 This element is only used by the @code{lio_listio} and
1902 @code{[lio_listio64} functions. Since these functions allow an
1903 arbitrary number of operations to start at once, and since each operation can be
1904 input or output (or nothing), the information must be stored in the
1905 control block. See the description of @code{struct aiocb} for a description
1906 of the possible values.
1909 When the sources are compiled using @code{_FILE_OFFSET_BITS == 64} on a
1910 32 bit machine, this type is available under the name @code{struct
1911 aiocb64}, since the LFS transparently replaces the old interface.
1915 * Asynchronous Reads/Writes:: Asynchronous Read and Write Operations.
1916 * Status of AIO Operations:: Getting the Status of AIO Operations.
1917 * Synchronizing AIO Operations:: Getting into a consistent state.
1918 * Cancel AIO Operations:: Cancellation of AIO Operations.
1919 * Configuration of AIO:: How to optimize the AIO implementation.
1922 @node Asynchronous Reads/Writes
1923 @subsection Asynchronous Read and Write Operations
1927 @deftypefun int aio_read (struct aiocb *@var{aiocbp})
1928 This function initiates an asynchronous read operation. It
1929 immediately returns after the operation was enqueued or when an
1930 error was encountered.
1932 The first @code{aiocbp->aio_nbytes} bytes of the file for which
1933 @code{aiocbp->aio_fildes} is a descriptor are written to the buffer
1934 starting at @code{aiocbp->aio_buf}. Reading starts at the absolute
1935 position @code{aiocbp->aio_offset} in the file.
1937 If prioritized I/O is supported by the platform the
1938 @code{aiocbp->aio_reqprio} value is used to adjust the priority before
1939 the request is actually enqueued.
1941 The calling process is notified about the termination of the read
1942 request according to the @code{aiocbp->aio_sigevent} value.
1944 When @code{aio_read} returns, the return value is zero if no error
1945 occurred that can be found before the process is enqueued. If such an
1946 early error is found, the function returns @math{-1} and sets
1947 @code{errno} to one of the following values:
1951 The request was not enqueued due to (temporarily) exceeded resource
1954 The @code{aio_read} function is not implemented.
1956 The @code{aiocbp->aio_fildes} descriptor is not valid. This condition
1957 need not be recognized before enqueueing the request and so this error
1958 might also be signaled asynchronously.
1960 The @code{aiocbp->aio_offset} or @code{aiocbp->aio_reqpiro} value is
1961 invalid. This condition need not be recognized before enqueueing the
1962 request and so this error might also be signaled asynchronously.
1965 If @code{aio_read} returns zero, the current status of the request
1966 can be queried using @code{aio_error} and @code{aio_return} functions.
1967 As long as the value returned by @code{aio_error} is @code{EINPROGRESS}
1968 the operation has not yet completed. If @code{aio_error} returns zero,
1969 the operation successfully terminated, otherwise the value is to be
1970 interpreted as an error code. If the function terminated, the result of
1971 the operation can be obtained using a call to @code{aio_return}. The
1972 returned value is the same as an equivalent call to @code{read} would
1973 have returned. Possible error codes returned by @code{aio_error} are:
1977 The @code{aiocbp->aio_fildes} descriptor is not valid.
1979 The operation was canceled before the operation was finished
1980 (@pxref{Cancel AIO Operations})
1982 The @code{aiocbp->aio_offset} value is invalid.
1985 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
1986 function is in fact @code{aio_read64} since the LFS interface transparently
1987 replaces the normal implementation.
1992 @deftypefun int aio_read64 (struct aiocb *@var{aiocbp})
1993 This function is similar to the @code{aio_read} function. The only
1994 difference is that on @w{32 bit} machines, the file descriptor should
1995 be opened in the large file mode. Internally, @code{aio_read64} uses
1996 functionality equivalent to @code{lseek64} (@pxref{File Position
1997 Primitive}) to position the file descriptor correctly for the reading,
1998 as opposed to @code{lseek} functionality used in @code{aio_read}.
2000 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64}, this
2001 function is available under the name @code{aio_read} and so transparently
2002 replaces the interface for small files on 32 bit machines.
2005 To write data asynchronously to a file, there exists an equivalent pair
2006 of functions with a very similar interface.
2010 @deftypefun int aio_write (struct aiocb *@var{aiocbp})
2011 This function initiates an asynchronous write operation. The function
2012 call immediately returns after the operation was enqueued or if before
2013 this happens an error was encountered.
2015 The first @code{aiocbp->aio_nbytes} bytes from the buffer starting at
2016 @code{aiocbp->aio_buf} are written to the file for which
2017 @code{aiocbp->aio_fildes} is an descriptor, starting at the absolute
2018 position @code{aiocbp->aio_offset} in the file.
2020 If prioritized I/O is supported by the platform, the
2021 @code{aiocbp->aio_reqprio} value is used to adjust the priority before
2022 the request is actually enqueued.
2024 The calling process is notified about the termination of the read
2025 request according to the @code{aiocbp->aio_sigevent} value.
2027 When @code{aio_write} returns, the return value is zero if no error
2028 occurred that can be found before the process is enqueued. If such an
2029 early error is found the function returns @math{-1} and sets
2030 @code{errno} to one of the following values.
2034 The request was not enqueued due to (temporarily) exceeded resource
2037 The @code{aio_write} function is not implemented.
2039 The @code{aiocbp->aio_fildes} descriptor is not valid. This condition
2040 may not be recognized before enqueueing the request, and so this error
2041 might also be signaled asynchronously.
2043 The @code{aiocbp->aio_offset} or @code{aiocbp->aio_reqprio} value is
2044 invalid. This condition may not be recognized before enqueueing the
2045 request and so this error might also be signaled asynchronously.
2048 In the case @code{aio_write} returns zero, the current status of the
2049 request can be queried using @code{aio_error} and @code{aio_return}
2050 functions. As long as the value returned by @code{aio_error} is
2051 @code{EINPROGRESS} the operation has not yet completed. If
2052 @code{aio_error} returns zero, the operation successfully terminated,
2053 otherwise the value is to be interpreted as an error code. If the
2054 function terminated, the result of the operation can be get using a call
2055 to @code{aio_return}. The returned value is the same as an equivalent
2056 call to @code{read} would have returned. Possible error codes returned
2057 by @code{aio_error} are:
2061 The @code{aiocbp->aio_fildes} descriptor is not valid.
2063 The operation was canceled before the operation was finished.
2064 (@pxref{Cancel AIO Operations})
2066 The @code{aiocbp->aio_offset} value is invalid.
2069 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64}, this
2070 function is in fact @code{aio_write64} since the LFS interface transparently
2071 replaces the normal implementation.
2076 @deftypefun int aio_write64 (struct aiocb *@var{aiocbp})
2077 This function is similar to the @code{aio_write} function. The only
2078 difference is that on @w{32 bit} machines the file descriptor should
2079 be opened in the large file mode. Internally @code{aio_write64} uses
2080 functionality equivalent to @code{lseek64} (@pxref{File Position
2081 Primitive}) to position the file descriptor correctly for the writing,
2082 as opposed to @code{lseek} functionality used in @code{aio_write}.
2084 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64}, this
2085 function is available under the name @code{aio_write} and so transparently
2086 replaces the interface for small files on 32 bit machines.
2089 Besides these functions with the more or less traditional interface,
2090 POSIX.1b also defines a function which can initiate more than one
2091 operation at a time, and which can handle freely mixed read and write
2092 operations. It is therefore similar to a combination of @code{readv} and
2097 @deftypefun int lio_listio (int @var{mode}, struct aiocb *const @var{list}[], int @var{nent}, struct sigevent *@var{sig})
2098 The @code{lio_listio} function can be used to enqueue an arbitrary
2099 number of read and write requests at one time. The requests can all be
2100 meant for the same file, all for different files or every solution in
2103 @code{lio_listio} gets the @var{nent} requests from the array pointed to
2104 by @var{list}. The operation to be performed is determined by the
2105 @code{aio_lio_opcode} member in each element of @var{list}. If this
2106 field is @code{LIO_READ} a read operation is enqueued, similar to a call
2107 of @code{aio_read} for this element of the array (except that the way
2108 the termination is signalled is different, as we will see below). If
2109 the @code{aio_lio_opcode} member is @code{LIO_WRITE} a write operation
2110 is enqueued. Otherwise the @code{aio_lio_opcode} must be @code{LIO_NOP}
2111 in which case this element of @var{list} is simply ignored. This
2112 ``operation'' is useful in situations where one has a fixed array of
2113 @code{struct aiocb} elements from which only a few need to be handled at
2114 a time. Another situation is where the @code{lio_listio} call was
2115 canceled before all requests are processed (@pxref{Cancel AIO
2116 Operations}) and the remaining requests have to be reissued.
2118 The other members of each element of the array pointed to by
2119 @code{list} must have values suitable for the operation as described in
2120 the documentation for @code{aio_read} and @code{aio_write} above.
2122 The @var{mode} argument determines how @code{lio_listio} behaves after
2123 having enqueued all the requests. If @var{mode} is @code{LIO_WAIT} it
2124 waits until all requests terminated. Otherwise @var{mode} must be
2125 @code{LIO_NOWAIT} and in this case the function returns immediately after
2126 having enqueued all the requests. In this case the caller gets a
2127 notification of the termination of all requests according to the
2128 @var{sig} parameter. If @var{sig} is @code{NULL} no notification is
2129 send. Otherwise a signal is sent or a thread is started, just as
2130 described in the description for @code{aio_read} or @code{aio_write}.
2132 If @var{mode} is @code{LIO_WAIT}, the return value of @code{lio_listio}
2133 is @math{0} when all requests completed successfully. Otherwise the
2134 function return @math{-1} and @code{errno} is set accordingly. To find
2135 out which request or requests failed one has to use the @code{aio_error}
2136 function on all the elements of the array @var{list}.
2138 In case @var{mode} is @code{LIO_NOWAIT}, the function returns @math{0} if
2139 all requests were enqueued correctly. The current state of the requests
2140 can be found using @code{aio_error} and @code{aio_return} as described
2141 above. If @code{lio_listio} returns @math{-1} in this mode, the
2142 global variable @code{errno} is set accordingly. If a request did not
2143 yet terminate, a call to @code{aio_error} returns @code{EINPROGRESS}. If
2144 the value is different, the request is finished and the error value (or
2145 @math{0}) is returned and the result of the operation can be retrieved
2146 using @code{aio_return}.
2148 Possible values for @code{errno} are:
2152 The resources necessary to queue all the requests are not available at
2153 the moment. The error status for each element of @var{list} must be
2154 checked to determine which request failed.
2156 Another reason could be that the system wide limit of AIO requests is
2157 exceeded. This cannot be the case for the implementation on GNU systems
2158 since no arbitrary limits exist.
2160 The @var{mode} parameter is invalid or @var{nent} is larger than
2161 @code{AIO_LISTIO_MAX}.
2163 One or more of the request's I/O operations failed. The error status of
2164 each request should be checked to determine which one failed.
2166 The @code{lio_listio} function is not supported.
2169 If the @var{mode} parameter is @code{LIO_NOWAIT} and the caller cancels
2170 a request, the error status for this request returned by
2171 @code{aio_error} is @code{ECANCELED}.
2173 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64}, this
2174 function is in fact @code{lio_listio64} since the LFS interface
2175 transparently replaces the normal implementation.
2180 @deftypefun int lio_listio64 (int @var{mode}, struct aiocb *const @var{list}, int @var{nent}, struct sigevent *@var{sig})
2181 This function is similar to the @code{lio_listio} function. The only
2182 difference is that on @w{32 bit} machines, the file descriptor should
2183 be opened in the large file mode. Internally, @code{lio_listio64} uses
2184 functionality equivalent to @code{lseek64} (@pxref{File Position
2185 Primitive}) to position the file descriptor correctly for the reading or
2186 writing, as opposed to @code{lseek} functionality used in
2189 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64}, this
2190 function is available under the name @code{lio_listio} and so
2191 transparently replaces the interface for small files on 32 bit
2195 @node Status of AIO Operations
2196 @subsection Getting the Status of AIO Operations
2198 As already described in the documentation of the functions in the last
2199 section, it must be possible to get information about the status of an I/O
2200 request. When the operation is performed truly asynchronously (as with
2201 @code{aio_read} and @code{aio_write} and with @code{lio_listio} when the
2202 mode is @code{LIO_NOWAIT}), one sometimes needs to know whether a
2203 specific request already terminated and if so, what the result was.
2204 The following two functions allow you to get this kind of information.
2208 @deftypefun int aio_error (const struct aiocb *@var{aiocbp})
2209 This function determines the error state of the request described by the
2210 @code{struct aiocb} variable pointed to by @var{aiocbp}. If the
2211 request has not yet terminated the value returned is always
2212 @code{EINPROGRESS}. Once the request has terminated the value
2213 @code{aio_error} returns is either @math{0} if the request completed
2214 successfully or it returns the value which would be stored in the
2215 @code{errno} variable if the request would have been done using
2216 @code{read}, @code{write}, or @code{fsync}.
2218 The function can return @code{ENOSYS} if it is not implemented. It
2219 could also return @code{EINVAL} if the @var{aiocbp} parameter does not
2220 refer to an asynchronous operation whose return status is not yet known.
2222 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2223 function is in fact @code{aio_error64} since the LFS interface
2224 transparently replaces the normal implementation.
2229 @deftypefun int aio_error64 (const struct aiocb64 *@var{aiocbp})
2230 This function is similar to @code{aio_error} with the only difference
2231 that the argument is a reference to a variable of type @code{struct
2234 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2235 function is available under the name @code{aio_error} and so
2236 transparently replaces the interface for small files on 32 bit
2242 @deftypefun ssize_t aio_return (const struct aiocb *@var{aiocbp})
2243 This function can be used to retrieve the return status of the operation
2244 carried out by the request described in the variable pointed to by
2245 @var{aiocbp}. As long as the error status of this request as returned
2246 by @code{aio_error} is @code{EINPROGRESS} the return of this function is
2249 Once the request is finished this function can be used exactly once to
2250 retrieve the return value. Following calls might lead to undefined
2251 behavior. The return value itself is the value which would have been
2252 returned by the @code{read}, @code{write}, or @code{fsync} call.
2254 The function can return @code{ENOSYS} if it is not implemented. It
2255 could also return @code{EINVAL} if the @var{aiocbp} parameter does not
2256 refer to an asynchronous operation whose return status is not yet known.
2258 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2259 function is in fact @code{aio_return64} since the LFS interface
2260 transparently replaces the normal implementation.
2265 @deftypefun int aio_return64 (const struct aiocb64 *@var{aiocbp})
2266 This function is similar to @code{aio_return} with the only difference
2267 that the argument is a reference to a variable of type @code{struct
2270 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2271 function is available under the name @code{aio_return} and so
2272 transparently replaces the interface for small files on 32 bit
2276 @node Synchronizing AIO Operations
2277 @subsection Getting into a Consistent State
2279 When dealing with asynchronous operations it is sometimes necessary to
2280 get into a consistent state. This would mean for AIO that one wants to
2281 know whether a certain request or a group of request were processed.
2282 This could be done by waiting for the notification sent by the system
2283 after the operation terminated, but this sometimes would mean wasting
2284 resources (mainly computation time). Instead POSIX.1b defines two
2285 functions which will help with most kinds of consistency.
2287 The @code{aio_fsync} and @code{aio_fsync64} functions are only available
2288 if the symbol @code{_POSIX_SYNCHRONIZED_IO} is defined in @file{unistd.h}.
2290 @cindex synchronizing
2293 @deftypefun int aio_fsync (int @var{op}, struct aiocb *@var{aiocbp})
2294 Calling this function forces all I/O operations operating queued at the
2295 time of the function call operating on the file descriptor
2296 @code{aiocbp->aio_fildes} into the synchronized I/O completion state
2297 (@pxref{Synchronizing I/O}). The @code{aio_fsync} function returns
2298 immediately but the notification through the method described in
2299 @code{aiocbp->aio_sigevent} will happen only after all requests for this
2300 file descriptor have terminated and the file is synchronized. This also
2301 means that requests for this very same file descriptor which are queued
2302 after the synchronization request are not affected.
2304 If @var{op} is @code{O_DSYNC} the synchronization happens as with a call
2305 to @code{fdatasync}. Otherwise @var{op} should be @code{O_SYNC} and
2306 the synchronization happens as with @code{fsync}.
2308 As long as the synchronization has not happened, a call to
2309 @code{aio_error} with the reference to the object pointed to by
2310 @var{aiocbp} returns @code{EINPROGRESS}. Once the synchronization is
2311 done @code{aio_error} return @math{0} if the synchronization was not
2312 successful. Otherwise the value returned is the value to which the
2313 @code{fsync} or @code{fdatasync} function would have set the
2314 @code{errno} variable. In this case nothing can be assumed about the
2315 consistency for the data written to this file descriptor.
2317 The return value of this function is @math{0} if the request was
2318 successfully enqueued. Otherwise the return value is @math{-1} and
2319 @code{errno} is set to one of the following values:
2323 The request could not be enqueued due to temporary lack of resources.
2325 The file descriptor @code{aiocbp->aio_fildes} is not valid or not open
2328 The implementation does not support I/O synchronization or the @var{op}
2329 parameter is other than @code{O_DSYNC} and @code{O_SYNC}.
2331 This function is not implemented.
2334 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2335 function is in fact @code{aio_fsync64} since the LFS interface
2336 transparently replaces the normal implementation.
2341 @deftypefun int aio_fsync64 (int @var{op}, struct aiocb64 *@var{aiocbp})
2342 This function is similar to @code{aio_fsync} with the only difference
2343 that the argument is a reference to a variable of type @code{struct
2346 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2347 function is available under the name @code{aio_fsync} and so
2348 transparently replaces the interface for small files on 32 bit
2352 Another method of synchronization is to wait until one or more requests of a
2353 specific set terminated. This could be achieved by the @code{aio_*}
2354 functions to notify the initiating process about the termination but in
2355 some situations this is not the ideal solution. In a program which
2356 constantly updates clients somehow connected to the server it is not
2357 always the best solution to go round robin since some connections might
2358 be slow. On the other hand letting the @code{aio_*} function notify the
2359 caller might also be not the best solution since whenever the process
2360 works on preparing data for on client it makes no sense to be
2361 interrupted by a notification since the new client will not be handled
2362 before the current client is served. For situations like this
2363 @code{aio_suspend} should be used.
2367 @deftypefun int aio_suspend (const struct aiocb *const @var{list}[], int @var{nent}, const struct timespec *@var{timeout})
2368 When calling this function, the calling thread is suspended until at
2369 least one of the requests pointed to by the @var{nent} elements of the
2370 array @var{list} has completed. If any of the requests has already
2371 completed at the time @code{aio_suspend} is called, the function returns
2372 immediately. Whether a request has terminated or not is determined by
2373 comparing the error status of the request with @code{EINPROGRESS}. If
2374 an element of @var{list} is @code{NULL}, the entry is simply ignored.
2376 If no request has finished, the calling process is suspended. If
2377 @var{timeout} is @code{NULL}, the process is not woken until a request
2378 has finished. If @var{timeout} is not @code{NULL}, the process remains
2379 suspended at least as long as specified in @var{timeout}. In this case,
2380 @code{aio_suspend} returns with an error.
2382 The return value of the function is @math{0} if one or more requests
2383 from the @var{list} have terminated. Otherwise the function returns
2384 @math{-1} and @code{errno} is set to one of the following values:
2388 None of the requests from the @var{list} completed in the time specified
2391 A signal interrupted the @code{aio_suspend} function. This signal might
2392 also be sent by the AIO implementation while signalling the termination
2393 of one of the requests.
2395 The @code{aio_suspend} function is not implemented.
2398 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2399 function is in fact @code{aio_suspend64} since the LFS interface
2400 transparently replaces the normal implementation.
2405 @deftypefun int aio_suspend64 (const struct aiocb64 *const @var{list}[], int @var{nent}, const struct timespec *@var{timeout})
2406 This function is similar to @code{aio_suspend} with the only difference
2407 that the argument is a reference to a variable of type @code{struct
2410 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64} this
2411 function is available under the name @code{aio_suspend} and so
2412 transparently replaces the interface for small files on 32 bit
2416 @node Cancel AIO Operations
2417 @subsection Cancellation of AIO Operations
2419 When one or more requests are asynchronously processed, it might be
2420 useful in some situations to cancel a selected operation, e.g., if it
2421 becomes obvious that the written data is no longer accurate and would
2422 have to be overwritten soon. As an example, assume an application, which
2423 writes data in files in a situation where new incoming data would have
2424 to be written in a file which will be updated by an enqueued request.
2425 The POSIX AIO implementation provides such a function, but this function
2426 is not capable of forcing the cancellation of the request. It is up to the
2427 implementation to decide whether it is possible to cancel the operation
2428 or not. Therefore using this function is merely a hint.
2432 @deftypefun int aio_cancel (int @var{fildes}, struct aiocb *@var{aiocbp})
2433 The @code{aio_cancel} function can be used to cancel one or more
2434 outstanding requests. If the @var{aiocbp} parameter is @code{NULL}, the
2435 function tries to cancel all of the outstanding requests which would process
2436 the file descriptor @var{fildes} (i.e., whose @code{aio_fildes} member
2437 is @var{fildes}). If @var{aiocbp} is not @code{NULL}, @code{aio_cancel}
2438 attempts to cancel the specific request pointed to by @var{aiocbp}.
2440 For requests which were successfully canceled, the normal notification
2441 about the termination of the request should take place. I.e., depending
2442 on the @code{struct sigevent} object which controls this, nothing
2443 happens, a signal is sent or a thread is started. If the request cannot
2444 be canceled, it terminates the usual way after performing the operation.
2446 After a request is successfully canceled, a call to @code{aio_error} with
2447 a reference to this request as the parameter will return
2448 @code{ECANCELED} and a call to @code{aio_return} will return @math{-1}.
2449 If the request wasn't canceled and is still running the error status is
2450 still @code{EINPROGRESS}.
2452 The return value of the function is @code{AIO_CANCELED} if there were
2453 requests which haven't terminated and which were successfully canceled.
2454 If there is one or more requests left which couldn't be canceled, the
2455 return value is @code{AIO_NOTCANCELED}. In this case @code{aio_error}
2456 must be used to find out which of the, perhaps multiple, requests (in
2457 @var{aiocbp} is @code{NULL}) weren't successfully canceled. If all
2458 requests already terminated at the time @code{aio_cancel} is called the
2459 return value is @code{AIO_ALLDONE}.
2461 If an error occurred during the execution of @code{aio_cancel} the
2462 function returns @math{-1} and sets @code{errno} to one of the following
2467 The file descriptor @var{fildes} is not valid.
2469 @code{aio_cancel} is not implemented.
2472 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64}, this
2473 function is in fact @code{aio_cancel64} since the LFS interface
2474 transparently replaces the normal implementation.
2479 @deftypefun int aio_cancel64 (int @var{fildes}, struct aiocb64 *@var{aiocbp})
2480 This function is similar to @code{aio_cancel} with the only difference
2481 that the argument is a reference to a variable of type @code{struct
2484 When the sources are compiled with @code{_FILE_OFFSET_BITS == 64}, this
2485 function is available under the name @code{aio_cancel} and so
2486 transparently replaces the interface for small files on 32 bit
2490 @node Configuration of AIO
2491 @subsection How to optimize the AIO implementation
2493 The POSIX standard does not specify how the AIO functions are
2494 implemented. They could be system calls, but it is also possible to
2495 emulate them at userlevel.
2497 At the point of this writing, the available implementation is a userlevel
2498 implementation which uses threads for handling the enqueued requests.
2499 While this implementation requires making some decisions about
2500 limitations, hard limitations are something which is best avoided
2501 in @theglibc{}. Therefore, @theglibc{} provides a means
2502 for tuning the AIO implementation according to the individual use.
2506 @deftp {Data Type} {struct aioinit}
2507 This data type is used to pass the configuration or tunable parameters
2508 to the implementation. The program has to initialize the members of
2509 this struct and pass it to the implementation using the @code{aio_init}
2513 @item int aio_threads
2514 This member specifies the maximal number of threads which may be used
2517 This number provides an estimate on the maximal number of simultaneously
2521 @item int aio_usedba
2525 @item int aio_numusers
2527 @item int aio_reserved[2]
2534 @deftypefun void aio_init (const struct aioinit *@var{init})
2535 This function must be called before any other AIO function. Calling it
2536 is completely voluntary, as it is only meant to help the AIO
2537 implementation perform better.
2539 Before calling the @code{aio_init}, function the members of a variable of
2540 type @code{struct aioinit} must be initialized. Then a reference to
2541 this variable is passed as the parameter to @code{aio_init} which itself
2542 may or may not pay attention to the hints.
2544 The function has no return value and no error cases are defined. It is
2545 a extension which follows a proposal from the SGI implementation in
2546 @w{Irix 6}. It is not covered by POSIX.1b or Unix98.
2549 @node Control Operations
2550 @section Control Operations on Files
2552 @cindex control operations on files
2553 @cindex @code{fcntl} function
2554 This section describes how you can perform various other operations on
2555 file descriptors, such as inquiring about or setting flags describing
2556 the status of the file descriptor, manipulating record locks, and the
2557 like. All of these operations are performed by the function @code{fcntl}.
2559 The second argument to the @code{fcntl} function is a command that
2560 specifies which operation to perform. The function and macros that name
2561 various flags that are used with it are declared in the header file
2562 @file{fcntl.h}. Many of these flags are also used by the @code{open}
2563 function; see @ref{Opening and Closing Files}.
2568 @deftypefun int fcntl (int @var{filedes}, int @var{command}, @dots{})
2569 The @code{fcntl} function performs the operation specified by
2570 @var{command} on the file descriptor @var{filedes}. Some commands
2571 require additional arguments to be supplied. These additional arguments
2572 and the return value and error conditions are given in the detailed
2573 descriptions of the individual commands.
2575 Briefly, here is a list of what the various commands are.
2579 Duplicate the file descriptor (return another file descriptor pointing
2580 to the same open file). @xref{Duplicating Descriptors}.
2583 Get flags associated with the file descriptor. @xref{Descriptor Flags}.
2586 Set flags associated with the file descriptor. @xref{Descriptor Flags}.
2589 Get flags associated with the open file. @xref{File Status Flags}.
2592 Set flags associated with the open file. @xref{File Status Flags}.
2595 Get a file lock. @xref{File Locks}.
2598 Set or clear a file lock. @xref{File Locks}.
2601 Like @code{F_SETLK}, but wait for completion. @xref{File Locks}.
2604 Get process or process group ID to receive @code{SIGIO} signals.
2605 @xref{Interrupt Input}.
2608 Set process or process group ID to receive @code{SIGIO} signals.
2609 @xref{Interrupt Input}.
2612 This function is a cancellation point in multi-threaded programs. This
2613 is a problem if the thread allocates some resources (like memory, file
2614 descriptors, semaphores or whatever) at the time @code{fcntl} is
2615 called. If the thread gets canceled these resources stay allocated
2616 until the program ends. To avoid this calls to @code{fcntl} should be
2617 protected using cancellation handlers.
2618 @c ref pthread_cleanup_push / pthread_cleanup_pop
2622 @node Duplicating Descriptors
2623 @section Duplicating Descriptors
2625 @cindex duplicating file descriptors
2626 @cindex redirecting input and output
2628 You can @dfn{duplicate} a file descriptor, or allocate another file
2629 descriptor that refers to the same open file as the original. Duplicate
2630 descriptors share one file position and one set of file status flags
2631 (@pxref{File Status Flags}), but each has its own set of file descriptor
2632 flags (@pxref{Descriptor Flags}).
2634 The major use of duplicating a file descriptor is to implement
2635 @dfn{redirection} of input or output: that is, to change the
2636 file or pipe that a particular file descriptor corresponds to.
2638 You can perform this operation using the @code{fcntl} function with the
2639 @code{F_DUPFD} command, but there are also convenient functions
2640 @code{dup} and @code{dup2} for duplicating descriptors.
2644 The @code{fcntl} function and flags are declared in @file{fcntl.h},
2645 while prototypes for @code{dup} and @code{dup2} are in the header file
2650 @deftypefun int dup (int @var{old})
2651 This function copies descriptor @var{old} to the first available
2652 descriptor number (the first number not currently open). It is
2653 equivalent to @code{fcntl (@var{old}, F_DUPFD, 0)}.
2658 @deftypefun int dup2 (int @var{old}, int @var{new})
2659 This function copies the descriptor @var{old} to descriptor number
2662 If @var{old} is an invalid descriptor, then @code{dup2} does nothing; it
2663 does not close @var{new}. Otherwise, the new duplicate of @var{old}
2664 replaces any previous meaning of descriptor @var{new}, as if @var{new}
2667 If @var{old} and @var{new} are different numbers, and @var{old} is a
2668 valid descriptor number, then @code{dup2} is equivalent to:
2672 fcntl (@var{old}, F_DUPFD, @var{new})
2675 However, @code{dup2} does this atomically; there is no instant in the
2676 middle of calling @code{dup2} at which @var{new} is closed and not yet a
2677 duplicate of @var{old}.
2682 @deftypevr Macro int F_DUPFD
2683 This macro is used as the @var{command} argument to @code{fcntl}, to
2684 copy the file descriptor given as the first argument.
2686 The form of the call in this case is:
2689 fcntl (@var{old}, F_DUPFD, @var{next-filedes})
2692 The @var{next-filedes} argument is of type @code{int} and specifies that
2693 the file descriptor returned should be the next available one greater
2694 than or equal to this value.
2696 The return value from @code{fcntl} with this command is normally the value
2697 of the new file descriptor. A return value of @math{-1} indicates an
2698 error. The following @code{errno} error conditions are defined for
2703 The @var{old} argument is invalid.
2706 The @var{next-filedes} argument is invalid.
2709 There are no more file descriptors available---your program is already
2710 using the maximum. In BSD and GNU, the maximum is controlled by a
2711 resource limit that can be changed; @pxref{Limits on Resources}, for
2712 more information about the @code{RLIMIT_NOFILE} limit.
2715 @code{ENFILE} is not a possible error code for @code{dup2} because
2716 @code{dup2} does not create a new opening of a file; duplicate
2717 descriptors do not count toward the limit which @code{ENFILE}
2718 indicates. @code{EMFILE} is possible because it refers to the limit on
2719 distinct descriptor numbers in use in one process.
2722 Here is an example showing how to use @code{dup2} to do redirection.
2723 Typically, redirection of the standard streams (like @code{stdin}) is
2724 done by a shell or shell-like program before calling one of the
2725 @code{exec} functions (@pxref{Executing a File}) to execute a new
2726 program in a child process. When the new program is executed, it
2727 creates and initializes the standard streams to point to the
2728 corresponding file descriptors, before its @code{main} function is
2731 So, to redirect standard input to a file, the shell could do something
2742 file = TEMP_FAILURE_RETRY (open (filename, O_RDONLY));
2743 dup2 (file, STDIN_FILENO);
2744 TEMP_FAILURE_RETRY (close (file));
2745 execv (program, NULL);
2749 There is also a more detailed example showing how to implement redirection
2750 in the context of a pipeline of processes in @ref{Launching Jobs}.
2753 @node Descriptor Flags
2754 @section File Descriptor Flags
2755 @cindex file descriptor flags
2757 @dfn{File descriptor flags} are miscellaneous attributes of a file
2758 descriptor. These flags are associated with particular file
2759 descriptors, so that if you have created duplicate file descriptors
2760 from a single opening of a file, each descriptor has its own set of flags.
2762 Currently there is just one file descriptor flag: @code{FD_CLOEXEC},
2763 which causes the descriptor to be closed if you use any of the
2764 @code{exec@dots{}} functions (@pxref{Executing a File}).
2766 The symbols in this section are defined in the header file
2772 @deftypevr Macro int F_GETFD
2773 This macro is used as the @var{command} argument to @code{fcntl}, to
2774 specify that it should return the file descriptor flags associated
2775 with the @var{filedes} argument.
2777 The normal return value from @code{fcntl} with this command is a
2778 nonnegative number which can be interpreted as the bitwise OR of the
2779 individual flags (except that currently there is only one flag to use).
2781 In case of an error, @code{fcntl} returns @math{-1}. The following
2782 @code{errno} error conditions are defined for this command:
2786 The @var{filedes} argument is invalid.
2793 @deftypevr Macro int F_SETFD
2794 This macro is used as the @var{command} argument to @code{fcntl}, to
2795 specify that it should set the file descriptor flags associated with the
2796 @var{filedes} argument. This requires a third @code{int} argument to
2797 specify the new flags, so the form of the call is:
2800 fcntl (@var{filedes}, F_SETFD, @var{new-flags})
2803 The normal return value from @code{fcntl} with this command is an
2804 unspecified value other than @math{-1}, which indicates an error.
2805 The flags and error conditions are the same as for the @code{F_GETFD}
2809 The following macro is defined for use as a file descriptor flag with
2810 the @code{fcntl} function. The value is an integer constant usable
2811 as a bit mask value.
2815 @deftypevr Macro int FD_CLOEXEC
2816 @cindex close-on-exec (file descriptor flag)
2817 This flag specifies that the file descriptor should be closed when
2818 an @code{exec} function is invoked; see @ref{Executing a File}. When
2819 a file descriptor is allocated (as with @code{open} or @code{dup}),
2820 this bit is initially cleared on the new file descriptor, meaning that
2821 descriptor will survive into the new program after @code{exec}.
2824 If you want to modify the file descriptor flags, you should get the
2825 current flags with @code{F_GETFD} and modify the value. Don't assume
2826 that the flags listed here are the only ones that are implemented; your
2827 program may be run years from now and more flags may exist then. For
2828 example, here is a function to set or clear the flag @code{FD_CLOEXEC}
2829 without altering any other flags:
2832 /* @r{Set the @code{FD_CLOEXEC} flag of @var{desc} if @var{value} is nonzero,}
2833 @r{or clear the flag if @var{value} is 0.}
2834 @r{Return 0 on success, or -1 on error with @code{errno} set.} */
2837 set_cloexec_flag (int desc, int value)
2839 int oldflags = fcntl (desc, F_GETFD, 0);
2840 /* @r{If reading the flags failed, return error indication now.} */
2843 /* @r{Set just the flag we want to set.} */
2845 oldflags |= FD_CLOEXEC;
2847 oldflags &= ~FD_CLOEXEC;
2848 /* @r{Store modified flag word in the descriptor.} */
2849 return fcntl (desc, F_SETFD, oldflags);
2853 @node File Status Flags
2854 @section File Status Flags
2855 @cindex file status flags
2857 @dfn{File status flags} are used to specify attributes of the opening of a
2858 file. Unlike the file descriptor flags discussed in @ref{Descriptor
2859 Flags}, the file status flags are shared by duplicated file descriptors
2860 resulting from a single opening of the file. The file status flags are
2861 specified with the @var{flags} argument to @code{open};
2862 @pxref{Opening and Closing Files}.
2864 File status flags fall into three categories, which are described in the
2869 @ref{Access Modes}, specify what type of access is allowed to the
2870 file: reading, writing, or both. They are set by @code{open} and are
2871 returned by @code{fcntl}, but cannot be changed.
2874 @ref{Open-time Flags}, control details of what @code{open} will do.
2875 These flags are not preserved after the @code{open} call.
2878 @ref{Operating Modes}, affect how operations such as @code{read} and
2879 @code{write} are done. They are set by @code{open}, and can be fetched or
2880 changed with @code{fcntl}.
2883 The symbols in this section are defined in the header file
2888 * Access Modes:: Whether the descriptor can read or write.
2889 * Open-time Flags:: Details of @code{open}.
2890 * Operating Modes:: Special modes to control I/O operations.
2891 * Getting File Status Flags:: Fetching and changing these flags.
2895 @subsection File Access Modes
2897 The file access modes allow a file descriptor to be used for reading,
2898 writing, or both. (In the GNU system, they can also allow none of these,
2899 and allow execution of the file as a program.) The access modes are chosen
2900 when the file is opened, and never change.
2904 @deftypevr Macro int O_RDONLY
2905 Open the file for read access.
2910 @deftypevr Macro int O_WRONLY
2911 Open the file for write access.
2916 @deftypevr Macro int O_RDWR
2917 Open the file for both reading and writing.
2920 In the GNU system (and not in other systems), @code{O_RDONLY} and
2921 @code{O_WRONLY} are independent bits that can be bitwise-ORed together,
2922 and it is valid for either bit to be set or clear. This means that
2923 @code{O_RDWR} is the same as @code{O_RDONLY|O_WRONLY}. A file access
2924 mode of zero is permissible; it allows no operations that do input or
2925 output to the file, but does allow other operations such as
2926 @code{fchmod}. On the GNU system, since ``read-only'' or ``write-only''
2927 is a misnomer, @file{fcntl.h} defines additional names for the file
2928 access modes. These names are preferred when writing GNU-specific code.
2929 But most programs will want to be portable to other POSIX.1 systems and
2930 should use the POSIX.1 names above instead.
2934 @deftypevr Macro int O_READ
2935 Open the file for reading. Same as @code{O_RDONLY}; only defined on GNU.
2940 @deftypevr Macro int O_WRITE
2941 Open the file for writing. Same as @code{O_WRONLY}; only defined on GNU.
2946 @deftypevr Macro int O_EXEC
2947 Open the file for executing. Only defined on GNU.
2950 To determine the file access mode with @code{fcntl}, you must extract
2951 the access mode bits from the retrieved file status flags. In the GNU
2952 system, you can just test the @code{O_READ} and @code{O_WRITE} bits in
2953 the flags word. But in other POSIX.1 systems, reading and writing
2954 access modes are not stored as distinct bit flags. The portable way to
2955 extract the file access mode bits is with @code{O_ACCMODE}.
2959 @deftypevr Macro int O_ACCMODE
2960 This macro stands for a mask that can be bitwise-ANDed with the file
2961 status flag value to produce a value representing the file access mode.
2962 The mode will be @code{O_RDONLY}, @code{O_WRONLY}, or @code{O_RDWR}.
2963 (In the GNU system it could also be zero, and it never includes the
2967 @node Open-time Flags
2968 @subsection Open-time Flags
2970 The open-time flags specify options affecting how @code{open} will behave.
2971 These options are not preserved once the file is open. The exception to
2972 this is @code{O_NONBLOCK}, which is also an I/O operating mode and so it
2973 @emph{is} saved. @xref{Opening and Closing Files}, for how to call
2976 There are two sorts of options specified by open-time flags.
2980 @dfn{File name translation flags} affect how @code{open} looks up the
2981 file name to locate the file, and whether the file can be created.
2982 @cindex file name translation flags
2983 @cindex flags, file name translation
2986 @dfn{Open-time action flags} specify extra operations that @code{open} will
2987 perform on the file once it is open.
2988 @cindex open-time action flags
2989 @cindex flags, open-time action
2992 Here are the file name translation flags.
2996 @deftypevr Macro int O_CREAT
2997 If set, the file will be created if it doesn't already exist.
2998 @c !!! mode arg, umask
2999 @cindex create on open (file status flag)
3004 @deftypevr Macro int O_EXCL
3005 If both @code{O_CREAT} and @code{O_EXCL} are set, then @code{open} fails
3006 if the specified file already exists. This is guaranteed to never
3007 clobber an existing file.
3012 @deftypevr Macro int O_NONBLOCK
3013 @cindex non-blocking open
3014 This prevents @code{open} from blocking for a ``long time'' to open the
3015 file. This is only meaningful for some kinds of files, usually devices
3016 such as serial ports; when it is not meaningful, it is harmless and
3017 ignored. Often opening a port to a modem blocks until the modem reports
3018 carrier detection; if @code{O_NONBLOCK} is specified, @code{open} will
3019 return immediately without a carrier.
3021 Note that the @code{O_NONBLOCK} flag is overloaded as both an I/O operating
3022 mode and a file name translation flag. This means that specifying
3023 @code{O_NONBLOCK} in @code{open} also sets nonblocking I/O mode;
3024 @pxref{Operating Modes}. To open the file without blocking but do normal
3025 I/O that blocks, you must call @code{open} with @code{O_NONBLOCK} set and
3026 then call @code{fcntl} to turn the bit off.
3031 @deftypevr Macro int O_NOCTTY
3032 If the named file is a terminal device, don't make it the controlling
3033 terminal for the process. @xref{Job Control}, for information about
3034 what it means to be the controlling terminal.
3036 In the GNU system and 4.4 BSD, opening a file never makes it the
3037 controlling terminal and @code{O_NOCTTY} is zero. However, other
3038 systems may use a nonzero value for @code{O_NOCTTY} and set the
3039 controlling terminal when you open a file that is a terminal device; so
3040 to be portable, use @code{O_NOCTTY} when it is important to avoid this.
3041 @cindex controlling terminal, setting
3044 The following three file name translation flags exist only in the GNU system.
3048 @deftypevr Macro int O_IGNORE_CTTY
3049 Do not recognize the named file as the controlling terminal, even if it
3050 refers to the process's existing controlling terminal device. Operations
3051 on the new file descriptor will never induce job control signals.
3057 @deftypevr Macro int O_NOLINK
3058 If the named file is a symbolic link, open the link itself instead of
3059 the file it refers to. (@code{fstat} on the new file descriptor will
3060 return the information returned by @code{lstat} on the link's name.)
3061 @cindex symbolic link, opening
3066 @deftypevr Macro int O_NOTRANS
3067 If the named file is specially translated, do not invoke the translator.
3068 Open the bare file the translator itself sees.
3072 The open-time action flags tell @code{open} to do additional operations
3073 which are not really related to opening the file. The reason to do them
3074 as part of @code{open} instead of in separate calls is that @code{open}
3075 can do them @i{atomically}.
3079 @deftypevr Macro int O_TRUNC
3080 Truncate the file to zero length. This option is only useful for
3081 regular files, not special files such as directories or FIFOs. POSIX.1
3082 requires that you open the file for writing to use @code{O_TRUNC}. In
3083 BSD and GNU you must have permission to write the file to truncate it,
3084 but you need not open for write access.
3086 This is the only open-time action flag specified by POSIX.1. There is
3087 no good reason for truncation to be done by @code{open}, instead of by
3088 calling @code{ftruncate} afterwards. The @code{O_TRUNC} flag existed in
3089 Unix before @code{ftruncate} was invented, and is retained for backward
3093 The remaining operating modes are BSD extensions. They exist only
3094 on some systems. On other systems, these macros are not defined.
3098 @deftypevr Macro int O_SHLOCK
3099 Acquire a shared lock on the file, as with @code{flock}.
3102 If @code{O_CREAT} is specified, the locking is done atomically when
3103 creating the file. You are guaranteed that no other process will get
3104 the lock on the new file first.
3109 @deftypevr Macro int O_EXLOCK
3110 Acquire an exclusive lock on the file, as with @code{flock}.
3111 @xref{File Locks}. This is atomic like @code{O_SHLOCK}.
3114 @node Operating Modes
3115 @subsection I/O Operating Modes
3117 The operating modes affect how input and output operations using a file
3118 descriptor work. These flags are set by @code{open} and can be fetched
3119 and changed with @code{fcntl}.
3123 @deftypevr Macro int O_APPEND
3124 The bit that enables append mode for the file. If set, then all
3125 @code{write} operations write the data at the end of the file, extending
3126 it, regardless of the current file position. This is the only reliable
3127 way to append to a file. In append mode, you are guaranteed that the
3128 data you write will always go to the current end of the file, regardless
3129 of other processes writing to the file. Conversely, if you simply set
3130 the file position to the end of file and write, then another process can
3131 extend the file after you set the file position but before you write,
3132 resulting in your data appearing someplace before the real end of file.
3137 @deftypevr Macro int O_NONBLOCK
3138 The bit that enables nonblocking mode for the file. If this bit is set,
3139 @code{read} requests on the file can return immediately with a failure
3140 status if there is no input immediately available, instead of blocking.
3141 Likewise, @code{write} requests can also return immediately with a
3142 failure status if the output can't be written immediately.
3144 Note that the @code{O_NONBLOCK} flag is overloaded as both an I/O
3145 operating mode and a file name translation flag; @pxref{Open-time Flags}.
3150 @deftypevr Macro int O_NDELAY
3151 This is an obsolete name for @code{O_NONBLOCK}, provided for
3152 compatibility with BSD. It is not defined by the POSIX.1 standard.
3155 The remaining operating modes are BSD and GNU extensions. They exist only
3156 on some systems. On other systems, these macros are not defined.
3160 @deftypevr Macro int O_ASYNC
3161 The bit that enables asynchronous input mode. If set, then @code{SIGIO}
3162 signals will be generated when input is available. @xref{Interrupt Input}.
3164 Asynchronous input mode is a BSD feature.
3169 @deftypevr Macro int O_FSYNC
3170 The bit that enables synchronous writing for the file. If set, each
3171 @code{write} call will make sure the data is reliably stored on disk before
3172 returning. @c !!! xref fsync
3174 Synchronous writing is a BSD feature.
3179 @deftypevr Macro int O_SYNC
3180 This is another name for @code{O_FSYNC}. They have the same value.
3185 @deftypevr Macro int O_NOATIME
3186 If this bit is set, @code{read} will not update the access time of the
3187 file. @xref{File Times}. This is used by programs that do backups, so
3188 that backing a file up does not count as reading it.
3189 Only the owner of the file or the superuser may use this bit.
3191 This is a GNU extension.
3194 @node Getting File Status Flags
3195 @subsection Getting and Setting File Status Flags
3197 The @code{fcntl} function can fetch or change file status flags.
3201 @deftypevr Macro int F_GETFL
3202 This macro is used as the @var{command} argument to @code{fcntl}, to
3203 read the file status flags for the open file with descriptor
3206 The normal return value from @code{fcntl} with this command is a
3207 nonnegative number which can be interpreted as the bitwise OR of the
3208 individual flags. Since the file access modes are not single-bit values,
3209 you can mask off other bits in the returned flags with @code{O_ACCMODE}
3212 In case of an error, @code{fcntl} returns @math{-1}. The following
3213 @code{errno} error conditions are defined for this command:
3217 The @var{filedes} argument is invalid.
3223 @deftypevr Macro int F_SETFL
3224 This macro is used as the @var{command} argument to @code{fcntl}, to set
3225 the file status flags for the open file corresponding to the
3226 @var{filedes} argument. This command requires a third @code{int}
3227 argument to specify the new flags, so the call looks like this:
3230 fcntl (@var{filedes}, F_SETFL, @var{new-flags})
3233 You can't change the access mode for the file in this way; that is,
3234 whether the file descriptor was opened for reading or writing.
3236 The normal return value from @code{fcntl} with this command is an
3237 unspecified value other than @math{-1}, which indicates an error. The
3238 error conditions are the same as for the @code{F_GETFL} command.
3241 If you want to modify the file status flags, you should get the current
3242 flags with @code{F_GETFL} and modify the value. Don't assume that the
3243 flags listed here are the only ones that are implemented; your program
3244 may be run years from now and more flags may exist then. For example,
3245 here is a function to set or clear the flag @code{O_NONBLOCK} without
3246 altering any other flags:
3250 /* @r{Set the @code{O_NONBLOCK} flag of @var{desc} if @var{value} is nonzero,}
3251 @r{or clear the flag if @var{value} is 0.}
3252 @r{Return 0 on success, or -1 on error with @code{errno} set.} */
3255 set_nonblock_flag (int desc, int value)
3257 int oldflags = fcntl (desc, F_GETFL, 0);
3258 /* @r{If reading the flags failed, return error indication now.} */
3261 /* @r{Set just the flag we want to set.} */
3263 oldflags |= O_NONBLOCK;
3265 oldflags &= ~O_NONBLOCK;
3266 /* @r{Store modified flag word in the descriptor.} */
3267 return fcntl (desc, F_SETFL, oldflags);
3276 @cindex record locking
3277 The remaining @code{fcntl} commands are used to support @dfn{record
3278 locking}, which permits multiple cooperating programs to prevent each
3279 other from simultaneously accessing parts of a file in error-prone
3282 @cindex exclusive lock
3284 An @dfn{exclusive} or @dfn{write} lock gives a process exclusive access
3285 for writing to the specified part of the file. While a write lock is in
3286 place, no other process can lock that part of the file.
3290 A @dfn{shared} or @dfn{read} lock prohibits any other process from
3291 requesting a write lock on the specified part of the file. However,
3292 other processes can request read locks.
3294 The @code{read} and @code{write} functions do not actually check to see
3295 whether there are any locks in place. If you want to implement a
3296 locking protocol for a file shared by multiple processes, your application
3297 must do explicit @code{fcntl} calls to request and clear locks at the
3300 Locks are associated with processes. A process can only have one kind
3301 of lock set for each byte of a given file. When any file descriptor for
3302 that file is closed by the process, all of the locks that process holds
3303 on that file are released, even if the locks were made using other
3304 descriptors that remain open. Likewise, locks are released when a
3305 process exits, and are not inherited by child processes created using
3306 @code{fork} (@pxref{Creating a Process}).
3308 When making a lock, use a @code{struct flock} to specify what kind of
3309 lock and where. This data type and the associated macros for the
3310 @code{fcntl} function are declared in the header file @file{fcntl.h}.
3315 @deftp {Data Type} {struct flock}
3316 This structure is used with the @code{fcntl} function to describe a file
3317 lock. It has these members:
3320 @item short int l_type
3321 Specifies the type of the lock; one of @code{F_RDLCK}, @code{F_WRLCK}, or
3324 @item short int l_whence
3325 This corresponds to the @var{whence} argument to @code{fseek} or
3326 @code{lseek}, and specifies what the offset is relative to. Its value
3327 can be one of @code{SEEK_SET}, @code{SEEK_CUR}, or @code{SEEK_END}.
3330 This specifies the offset of the start of the region to which the lock
3331 applies, and is given in bytes relative to the point specified by
3332 @code{l_whence} member.
3335 This specifies the length of the region to be locked. A value of
3336 @code{0} is treated specially; it means the region extends to the end of
3340 This field is the process ID (@pxref{Process Creation Concepts}) of the
3341 process holding the lock. It is filled in by calling @code{fcntl} with
3342 the @code{F_GETLK} command, but is ignored when making a lock.
3348 @deftypevr Macro int F_GETLK
3349 This macro is used as the @var{command} argument to @code{fcntl}, to
3350 specify that it should get information about a lock. This command
3351 requires a third argument of type @w{@code{struct flock *}} to be passed
3352 to @code{fcntl}, so that the form of the call is:
3355 fcntl (@var{filedes}, F_GETLK, @var{lockp})
3358 If there is a lock already in place that would block the lock described
3359 by the @var{lockp} argument, information about that lock overwrites
3360 @code{*@var{lockp}}. Existing locks are not reported if they are
3361 compatible with making a new lock as specified. Thus, you should
3362 specify a lock type of @code{F_WRLCK} if you want to find out about both
3363 read and write locks, or @code{F_RDLCK} if you want to find out about
3366 There might be more than one lock affecting the region specified by the
3367 @var{lockp} argument, but @code{fcntl} only returns information about
3368 one of them. The @code{l_whence} member of the @var{lockp} structure is
3369 set to @code{SEEK_SET} and the @code{l_start} and @code{l_len} fields
3370 set to identify the locked region.
3372 If no lock applies, the only change to the @var{lockp} structure is to
3373 update the @code{l_type} to a value of @code{F_UNLCK}.
3375 The normal return value from @code{fcntl} with this command is an
3376 unspecified value other than @math{-1}, which is reserved to indicate an
3377 error. The following @code{errno} error conditions are defined for
3382 The @var{filedes} argument is invalid.
3385 Either the @var{lockp} argument doesn't specify valid lock information,
3386 or the file associated with @var{filedes} doesn't support locks.
3392 @deftypevr Macro int F_SETLK
3393 This macro is used as the @var{command} argument to @code{fcntl}, to
3394 specify that it should set or clear a lock. This command requires a
3395 third argument of type @w{@code{struct flock *}} to be passed to
3396 @code{fcntl}, so that the form of the call is:
3399 fcntl (@var{filedes}, F_SETLK, @var{lockp})
3402 If the process already has a lock on any part of the region, the old lock
3403 on that part is replaced with the new lock. You can remove a lock
3404 by specifying a lock type of @code{F_UNLCK}.
3406 If the lock cannot be set, @code{fcntl} returns immediately with a value
3407 of @math{-1}. This function does not block waiting for other processes
3408 to release locks. If @code{fcntl} succeeds, it return a value other
3411 The following @code{errno} error conditions are defined for this
3417 The lock cannot be set because it is blocked by an existing lock on the
3418 file. Some systems use @code{EAGAIN} in this case, and other systems
3419 use @code{EACCES}; your program should treat them alike, after
3420 @code{F_SETLK}. (The GNU system always uses @code{EAGAIN}.)
3423 Either: the @var{filedes} argument is invalid; you requested a read lock
3424 but the @var{filedes} is not open for read access; or, you requested a
3425 write lock but the @var{filedes} is not open for write access.
3428 Either the @var{lockp} argument doesn't specify valid lock information,
3429 or the file associated with @var{filedes} doesn't support locks.
3432 The system has run out of file lock resources; there are already too
3433 many file locks in place.
3435 Well-designed file systems never report this error, because they have no
3436 limitation on the number of locks. However, you must still take account
3437 of the possibility of this error, as it could result from network access
3438 to a file system on another machine.
3444 @deftypevr Macro int F_SETLKW
3445 This macro is used as the @var{command} argument to @code{fcntl}, to
3446 specify that it should set or clear a lock. It is just like the
3447 @code{F_SETLK} command, but causes the process to block (or wait)
3448 until the request can be specified.
3450 This command requires a third argument of type @code{struct flock *}, as
3451 for the @code{F_SETLK} command.
3453 The @code{fcntl} return values and errors are the same as for the
3454 @code{F_SETLK} command, but these additional @code{errno} error conditions
3455 are defined for this command:
3459 The function was interrupted by a signal while it was waiting.
3460 @xref{Interrupted Primitives}.
3463 The specified region is being locked by another process. But that
3464 process is waiting to lock a region which the current process has
3465 locked, so waiting for the lock would result in deadlock. The system
3466 does not guarantee that it will detect all such conditions, but it lets
3467 you know if it notices one.
3472 The following macros are defined for use as values for the @code{l_type}
3473 member of the @code{flock} structure. The values are integer constants.
3480 This macro is used to specify a read (or shared) lock.
3486 This macro is used to specify a write (or exclusive) lock.
3492 This macro is used to specify that the region is unlocked.
3495 As an example of a situation where file locking is useful, consider a
3496 program that can be run simultaneously by several different users, that
3497 logs status information to a common file. One example of such a program
3498 might be a game that uses a file to keep track of high scores. Another
3499 example might be a program that records usage or accounting information
3500 for billing purposes.
3502 Having multiple copies of the program simultaneously writing to the
3503 file could cause the contents of the file to become mixed up. But
3504 you can prevent this kind of problem by setting a write lock on the
3505 file before actually writing to the file.
3507 If the program also needs to read the file and wants to make sure that
3508 the contents of the file are in a consistent state, then it can also use
3509 a read lock. While the read lock is set, no other process can lock
3510 that part of the file for writing.
3512 @c ??? This section could use an example program.
3514 Remember that file locks are only a @emph{voluntary} protocol for
3515 controlling access to a file. There is still potential for access to
3516 the file by programs that don't use the lock protocol.
3518 @node Interrupt Input
3519 @section Interrupt-Driven Input
3521 @cindex interrupt-driven input
3522 If you set the @code{O_ASYNC} status flag on a file descriptor
3523 (@pxref{File Status Flags}), a @code{SIGIO} signal is sent whenever
3524 input or output becomes possible on that file descriptor. The process
3525 or process group to receive the signal can be selected by using the
3526 @code{F_SETOWN} command to the @code{fcntl} function. If the file
3527 descriptor is a socket, this also selects the recipient of @code{SIGURG}
3528 signals that are delivered when out-of-band data arrives on that socket;
3529 see @ref{Out-of-Band Data}. (@code{SIGURG} is sent in any situation
3530 where @code{select} would report the socket as having an ``exceptional
3531 condition''. @xref{Waiting for I/O}.)
3533 If the file descriptor corresponds to a terminal device, then @code{SIGIO}
3534 signals are sent to the foreground process group of the terminal.
3538 The symbols in this section are defined in the header file
3543 @deftypevr Macro int F_GETOWN
3544 This macro is used as the @var{command} argument to @code{fcntl}, to
3545 specify that it should get information about the process or process
3546 group to which @code{SIGIO} signals are sent. (For a terminal, this is
3547 actually the foreground process group ID, which you can get using
3548 @code{tcgetpgrp}; see @ref{Terminal Access Functions}.)
3550 The return value is interpreted as a process ID; if negative, its
3551 absolute value is the process group ID.
3553 The following @code{errno} error condition is defined for this command:
3557 The @var{filedes} argument is invalid.
3563 @deftypevr Macro int F_SETOWN
3564 This macro is used as the @var{command} argument to @code{fcntl}, to
3565 specify that it should set the process or process group to which
3566 @code{SIGIO} signals are sent. This command requires a third argument
3567 of type @code{pid_t} to be passed to @code{fcntl}, so that the form of
3571 fcntl (@var{filedes}, F_SETOWN, @var{pid})
3574 The @var{pid} argument should be a process ID. You can also pass a
3575 negative number whose absolute value is a process group ID.
3577 The return value from @code{fcntl} with this command is @math{-1}
3578 in case of error and some other value if successful. The following
3579 @code{errno} error conditions are defined for this command:
3583 The @var{filedes} argument is invalid.
3586 There is no process or process group corresponding to @var{pid}.
3590 @c ??? This section could use an example program.
3593 @section Generic I/O Control operations
3594 @cindex generic i/o control operations
3597 The GNU system can handle most input/output operations on many different
3598 devices and objects in terms of a few file primitives - @code{read},
3599 @code{write} and @code{lseek}. However, most devices also have a few
3600 peculiar operations which do not fit into this model. Such as:
3605 Changing the character font used on a terminal.
3608 Telling a magnetic tape system to rewind or fast forward. (Since they
3609 cannot move in byte increments, @code{lseek} is inapplicable).
3612 Ejecting a disk from a drive.
3615 Playing an audio track from a CD-ROM drive.
3618 Maintaining routing tables for a network.
3622 Although some such objects such as sockets and terminals
3623 @footnote{Actually, the terminal-specific functions are implemented with
3624 IOCTLs on many platforms.} have special functions of their own, it would
3625 not be practical to create functions for all these cases.
3627 Instead these minor operations, known as @dfn{IOCTL}s, are assigned code
3628 numbers and multiplexed through the @code{ioctl} function, defined in
3629 @code{sys/ioctl.h}. The code numbers themselves are defined in many
3632 @comment sys/ioctl.h
3634 @deftypefun int ioctl (int @var{filedes}, int @var{command}, @dots{})
3636 The @code{ioctl} function performs the generic I/O operation
3637 @var{command} on @var{filedes}.
3639 A third argument is usually present, either a single number or a pointer
3640 to a structure. The meaning of this argument, the returned value, and
3641 any error codes depends upon the command used. Often @math{-1} is
3642 returned for a failure.
3646 On some systems, IOCTLs used by different devices share the same numbers.
3647 Thus, although use of an inappropriate IOCTL @emph{usually} only produces
3648 an error, you should not attempt to use device-specific IOCTLs on an
3651 Most IOCTLs are OS-specific and/or only used in special system utilities,
3652 and are thus beyond the scope of this document. For an example of the use
3653 of an IOCTL, see @ref{Out-of-Band Data}.