3 POSIX - Perl interface to IEEE Std 1003.1
9 use POSIX qw(:errno_h :fcntl_h);
11 printf "EINTR is %d\n", EINTR;
13 $sess_id = POSIX::setsid();
15 $fd = POSIX::open($path, O_CREAT|O_EXCL|O_WRONLY, 0644);
16 # note: that's a filedescriptor, *NOT* a filehandle
20 The POSIX module permits you to access all (or nearly all) the standard
21 POSIX 1003.1 identifiers. Many of these identifiers have been given Perl-ish
24 I<Everything is exported by default> with the exception of any POSIX
25 functions with the same name as a built-in Perl function, such as
26 C<abs>, C<alarm>, C<rmdir>, C<write>, etc.., which will be exported
27 only if you ask for them explicitly. This is an unfortunate backwards
28 compatibility feature. You can stop the exporting by saying C<use
29 POSIX ()> and then use the fully qualified names (ie. C<POSIX::SEEK_END>).
31 This document gives a condensed list of the features available in the POSIX
32 module. Consult your operating system's manpages for general information on
33 most features. Consult L<perlfunc> for functions which are noted as being
34 identical to Perl's builtin functions.
36 The first section describes POSIX functions from the 1003.1 specification.
37 The second section describes some classes for signal objects, TTY objects,
38 and other miscellaneous objects. The remaining sections list various
39 constants and macros in an organization which roughly follows IEEE Std
44 The POSIX module is probably the most complex Perl module supplied with
45 the standard distribution. It incorporates autoloading, namespace games,
46 and dynamic loading of code that's in Perl, C, or both. It's a great
51 A few functions are not implemented because they are C specific. If you
52 attempt to call these, they will print a message telling you that they
53 aren't implemented, and suggest using the Perl equivalent should one
54 exist. For example, trying to access the setjmp() call will elicit the
55 message "setjmp() is C-specific: use eval {} instead".
57 Furthermore, some evil vendors will claim 1003.1 compliance, but in fact
58 are not so: they will not pass the PCTS (POSIX Compliance Test Suites).
59 For example, one vendor may not define EDEADLK, or the semantics of the
60 errno values set by open(2) might not be quite right. Perl does not
61 attempt to verify POSIX compliance. That means you can currently
62 successfully say "use POSIX", and then later in your program you find
63 that your vendor has been lax and there's no usable ICANON macro after
64 all. This could be construed to be a bug.
72 This is identical to the C function C<_exit()>. It exits the program
73 immediately which means among other things buffered I/O is B<not> flushed.
75 Note that when using threads and in Linux this is B<not> a good way to
76 exit a thread because in Linux processes and threads are kind of the
77 same thing (Note: while this is the situation in early 2003 there are
78 projects under way to have threads with more POSIXly semantics in Linux).
79 If you want not to return from a thread, detach the thread.
83 This is identical to the C function C<abort()>. It terminates the
84 process with a C<SIGABRT> signal unless caught by a signal handler or
85 if the handler does not return normally (it e.g. does a C<longjmp>).
89 This is identical to Perl's builtin C<abs()> function, returning
90 the absolute value of its numerical argument.
94 Determines the accessibility of a file.
96 if( POSIX::access( "/", &POSIX::R_OK ) ){
97 print "have read permission\n";
100 Returns C<undef> on failure. Note: do not use C<access()> for
101 security purposes. Between the C<access()> call and the operation
102 you are preparing for the permissions might change: a classic
107 This is identical to the C function C<acos()>, returning
108 the arcus cosine of its numerical argument. See also L<Math::Trig>.
112 This is identical to Perl's builtin C<alarm()> function,
113 either for arming or disarming the C<SIGARLM> timer.
117 This is identical to the C function C<asctime()>. It returns
120 "Fri Jun 2 18:22:13 2000\n\0"
122 and it is called thusly
124 $asctime = asctime($sec, $min, $hour, $mday, $mon, $year,
125 $wday, $yday, $isdst);
127 The C<$mon> is zero-based: January equals C<0>. The C<$year> is
128 1900-based: 2001 equals C<101>. The C<$wday>, C<$yday>, and C<$isdst>
129 default to zero (and the first two are usually ignored anyway).
133 This is identical to the C function C<asin()>, returning
134 the arcus sine of its numerical argument. See also L<Math::Trig>.
138 Unimplemented, but you can use L<perlfunc/die> and the L<Carp> module
139 to achieve similar things.
143 This is identical to the C function C<atan()>, returning the
144 arcus tangent of its numerical argument. See also L<Math::Trig>.
148 This is identical to Perl's builtin C<atan2()> function, returning
149 the arcus tangent defined by its two numerical arguments, the I<y>
150 coordinate and the I<x> coordinate. See also L<Math::Trig>.
154 atexit() is C-specific: use C<END {}> instead, see L<perlsub>.
158 atof() is C-specific. Perl converts strings to numbers transparently.
159 If you need to force a scalar to a number, add a zero to it.
163 atoi() is C-specific. Perl converts strings to numbers transparently.
164 If you need to force a scalar to a number, add a zero to it.
165 If you need to have just the integer part, see L<perlfunc/int>.
169 atol() is C-specific. Perl converts strings to numbers transparently.
170 If you need to force a scalar to a number, add a zero to it.
171 If you need to have just the integer part, see L<perlfunc/int>.
175 bsearch() not supplied. For doing binary search on wordlists,
180 calloc() is C-specific. Perl does memory management transparently.
184 This is identical to the C function C<ceil()>, returning the smallest
185 integer value greater than or equal to the given numerical argument.
189 This is identical to Perl's builtin C<chdir()> function, allowing
190 one to change the working (default) directory, see L<perlfunc/chdir>.
194 This is identical to Perl's builtin C<chmod()> function, allowing
195 one to change file and directory permissions, see L<perlfunc/chmod>.
199 This is identical to Perl's builtin C<chown()> function, allowing one
200 to change file and directory owners and groups, see L<perlfunc/chown>.
204 Use the method C<IO::Handle::clearerr()> instead, to reset the error
205 state (if any) and EOF state (if any) of the given stream.
209 This is identical to the C function C<clock()>, returning the
210 amount of spent processor time in microseconds.
214 Close the file. This uses file descriptors such as those obtained by calling
217 $fd = POSIX::open( "foo", &POSIX::O_RDONLY );
220 Returns C<undef> on failure.
222 See also L<perlfunc/close>.
226 This is identical to Perl's builtin C<closedir()> function for closing
227 a directory handle, see L<perlfunc/closedir>.
231 This is identical to Perl's builtin C<cos()> function, for returning
232 the cosine of its numerical argument, see L<perlfunc/cos>.
233 See also L<Math::Trig>.
237 This is identical to the C function C<cosh()>, for returning
238 the hyperbolic cosine of its numeric argument. See also L<Math::Trig>.
242 Create a new file. This returns a file descriptor like the ones returned by
243 C<POSIX::open>. Use C<POSIX::close> to close the file.
245 $fd = POSIX::creat( "foo", 0611 );
248 See also L<perlfunc/sysopen> and its C<O_CREAT> flag.
252 Generates the path name for the controlling terminal.
254 $path = POSIX::ctermid();
258 This is identical to the C function C<ctime()> and equivalent
259 to C<asctime(localtime(...))>, see L</asctime> and L</localtime>.
263 Get the login name of the owner of the current process.
265 $name = POSIX::cuserid();
269 This is identical to the C function C<difftime()>, for returning
270 the time difference (in seconds) between two times (as returned
271 by C<time()>), see L</time>.
275 div() is C-specific, use L<perlfunc/int> on the usual C</> division and
280 This is similar to the C function C<dup()>, for duplicating a file
283 This uses file descriptors such as those obtained by calling
286 Returns C<undef> on failure.
290 This is similar to the C function C<dup2()>, for duplicating a file
291 descriptor to an another known file descriptor.
293 This uses file descriptors such as those obtained by calling
296 Returns C<undef> on failure.
300 Returns the value of errno.
302 $errno = POSIX::errno();
304 This identical to the numerical values of the C<$!>, see L<perlvar/$ERRNO>.
308 execl() is C-specific, see L<perlfunc/exec>.
312 execle() is C-specific, see L<perlfunc/exec>.
316 execlp() is C-specific, see L<perlfunc/exec>.
320 execv() is C-specific, see L<perlfunc/exec>.
324 execve() is C-specific, see L<perlfunc/exec>.
328 execvp() is C-specific, see L<perlfunc/exec>.
332 This is identical to Perl's builtin C<exit()> function for exiting the
333 program, see L<perlfunc/exit>.
337 This is identical to Perl's builtin C<exp()> function for
338 returning the exponent (I<e>-based) of the numerical argument,
343 This is identical to Perl's builtin C<abs()> function for returning
344 the absolute value of the numerical argument, see L<perlfunc/abs>.
348 Use method C<IO::Handle::close()> instead, or see L<perlfunc/close>.
352 This is identical to Perl's builtin C<fcntl()> function,
353 see L<perlfunc/fcntl>.
357 Use method C<IO::Handle::new_from_fd()> instead, or see L<perlfunc/open>.
361 Use method C<IO::Handle::eof()> instead, or see L<perlfunc/eof>.
365 Use method C<IO::Handle::error()> instead.
369 Use method C<IO::Handle::flush()> instead.
370 See also L<perlvar/$OUTPUT_AUTOFLUSH>.
374 Use method C<IO::Handle::getc()> instead, or see L<perlfunc/read>.
378 Use method C<IO::Seekable::getpos()> instead, or see L<L/seek>.
382 Use method C<IO::Handle::gets()> instead. Similar to E<lt>E<gt>, also known
383 as L<perlfunc/readline>.
387 Use method C<IO::Handle::fileno()> instead, or see L<perlfunc/fileno>.
391 This is identical to the C function C<floor()>, returning the largest
392 integer value less than or equal to the numerical argument.
396 This is identical to the C function C<fmod()>.
400 It returns the remainder C<$r = $x - $n*$y>, where C<$n = trunc($x/$y)>.
401 The C<$r> has the same sign as C<$x> and magnitude (absolute value)
402 less than the magnitude of C<$y>.
406 Use method C<IO::File::open()> instead, or see L<perlfunc/open>.
410 This is identical to Perl's builtin C<fork()> function
411 for duplicating the current process, see L<perlfunc/fork>
412 and L<perlfork> if you are in Windows.
416 Retrieves the value of a configurable limit on a file or directory. This
417 uses file descriptors such as those obtained by calling C<POSIX::open>.
419 The following will determine the maximum length of the longest allowable
420 pathname on the filesystem which holds C</var/foo>.
422 $fd = POSIX::open( "/var/foo", &POSIX::O_RDONLY );
423 $path_max = POSIX::fpathconf( $fd, &POSIX::_PC_PATH_MAX );
425 Returns C<undef> on failure.
429 fprintf() is C-specific, see L<perlfunc/printf> instead.
433 fputc() is C-specific, see L<perlfunc/print> instead.
437 fputs() is C-specific, see L<perlfunc/print> instead.
441 fread() is C-specific, see L<perlfunc/read> instead.
445 free() is C-specific. Perl does memory management transparently.
449 freopen() is C-specific, see L<perlfunc/open> instead.
453 Return the mantissa and exponent of a floating-point number.
455 ($mantissa, $exponent) = POSIX::frexp( 1.234e56 );
459 fscanf() is C-specific, use E<lt>E<gt> and regular expressions instead.
463 Use method C<IO::Seekable::seek()> instead, or see L<perlfunc/seek>.
467 Use method C<IO::Seekable::setpos()> instead, or seek L<perlfunc/seek>.
471 Get file status. This uses file descriptors such as those obtained by
472 calling C<POSIX::open>. The data returned is identical to the data from
473 Perl's builtin C<stat> function.
475 $fd = POSIX::open( "foo", &POSIX::O_RDONLY );
476 @stats = POSIX::fstat( $fd );
480 Use method C<IO::Handle::sync()> instead.
484 Use method C<IO::Seekable::tell()> instead, or see L<perlfunc/tell>.
488 fwrite() is C-specific, see L<perlfunc/print> instead.
492 This is identical to Perl's builtin C<getc()> function,
493 see L<perlfunc/getc>.
497 Returns one character from STDIN. Identical to Perl's C<getc()>,
498 see L<perlfunc/getc>.
502 Returns the name of the current working directory.
507 Returns the effective group identifier. Similar to Perl' s builtin
508 variable C<$(>, see L<perlvar/$EGID>.
512 Returns the value of the specified environment variable.
513 The same information is available through the C<%ENV> array.
517 Returns the effective user identifier. Identical to Perl's builtin C<$E<gt>>
518 variable, see L<perlvar/$EUID>.
522 Returns the user's real group identifier. Similar to Perl's builtin
523 variable C<$)>, see L<perlvar/$GID>.
527 This is identical to Perl's builtin C<getgrgid()> function for
528 returning group entries by group identifiers, see
529 L<perlfunc/getgrgid>.
533 This is identical to Perl's builtin C<getgrnam()> function for
534 returning group entries by group names, see L<perlfunc/getgrnam>.
538 Returns the ids of the user's supplementary groups. Similar to Perl's
539 builtin variable C<$)>, see L<perlvar/$GID>.
543 This is identical to Perl's builtin C<getlogin()> function for
544 returning the user name associated with the current session, see
545 L<perlfunc/getlogin>.
549 This is identical to Perl's builtin C<getpgrp()> function for
550 returning the process group identifier of the current process, see
555 Returns the process identifier. Identical to Perl's builtin
556 variable C<$$>, see L<perlvar/$PID>.
560 This is identical to Perl's builtin C<getppid()> function for
561 returning the process identifier of the parent process of the current
562 process , see L<perlfunc/getppid>.
566 This is identical to Perl's builtin C<getpwnam()> function for
567 returning user entries by user names, see L<perlfunc/getpwnam>.
571 This is identical to Perl's builtin C<getpwuid()> function for
572 returning user entries by user identifiers, see L<perlfunc/getpwuid>.
576 Returns one line from C<STDIN>, similar to E<lt>E<gt>, also known
577 as the C<readline()> function, see L<perlfunc/readline>.
579 B<NOTE>: if you have C programs that still use C<gets()>, be very
580 afraid. The C<gets()> function is a source of endless grief because
581 it has no buffer overrun checks. It should B<never> be used. The
582 C<fgets()> function should be preferred instead.
586 Returns the user's identifier. Identical to Perl's builtin C<$E<lt>> variable,
591 This is identical to Perl's builtin C<gmtime()> function for
592 converting seconds since the epoch to a date in Greenwich Mean Time,
593 see L<perlfunc/gmtime>.
597 This is identical to the C function, except that it can apply to a
598 single character or to a whole string. Note that locale settings may
599 affect what characters are considered C<isalnum>. Does not work on
600 Unicode characters code point 256 or higher. Consider using regular
601 expressions and the C</[[:alnum:]]/> construct instead, or possibly
602 the C</\w/> construct.
606 This is identical to the C function, except that it can apply to
607 a single character or to a whole string. Note that locale settings
608 may affect what characters are considered C<isalpha>. Does not work
609 on Unicode characters code point 256 or higher. Consider using regular
610 expressions and the C</[[:alpha:]]/> construct instead.
614 Returns a boolean indicating whether the specified filehandle is connected
615 to a tty. Similar to the C<-t> operator, see L<perlfunc/-X>.
619 This is identical to the C function, except that it can apply to
620 a single character or to a whole string. Note that locale settings
621 may affect what characters are considered C<iscntrl>. Does not work
622 on Unicode characters code point 256 or higher. Consider using regular
623 expressions and the C</[[:cntrl:]]/> construct instead.
627 This is identical to the C function, except that it can apply to
628 a single character or to a whole string. Note that locale settings
629 may affect what characters are considered C<isdigit> (unlikely, but
630 still possible). Does not work on Unicode characters code point 256
631 or higher. Consider using regular expressions and the C</[[:digit:]]/>
632 construct instead, or the C</\d/> construct.
636 This is identical to the C function, except that it can apply to
637 a single character or to a whole string. Note that locale settings
638 may affect what characters are considered C<isgraph>. Does not work
639 on Unicode characters code point 256 or higher. Consider using regular
640 expressions and the C</[[:graph:]]/> construct instead.
644 This is identical to the C function, except that it can apply to
645 a single character or to a whole string. Note that locale settings
646 may affect what characters are considered C<islower>. Does not work
647 on Unicode characters code point 256 or higher. Consider using regular
648 expressions and the C</[[:lower:]]/> construct instead. Do B<not> use
653 This is identical to the C function, except that it can apply to
654 a single character or to a whole string. Note that locale settings
655 may affect what characters are considered C<isprint>. Does not work
656 on Unicode characters code point 256 or higher. Consider using regular
657 expressions and the C</[[:print:]]/> construct instead.
661 This is identical to the C function, except that it can apply to
662 a single character or to a whole string. Note that locale settings
663 may affect what characters are considered C<ispunct>. Does not work
664 on Unicode characters code point 256 or higher. Consider using regular
665 expressions and the C</[[:punct:]]/> construct instead.
669 This is identical to the C function, except that it can apply to
670 a single character or to a whole string. Note that locale settings
671 may affect what characters are considered C<isspace>. Does not work
672 on Unicode characters code point 256 or higher. Consider using regular
673 expressions and the C</[[:space:]]/> construct instead, or the C</\s/>
674 construct. (Note that C</\s/> and C</[[:space:]]/> are slightly
675 different in that C</[[:space:]]/> can normally match a vertical tab,
676 while C</\s/> does not.)
680 This is identical to the C function, except that it can apply to
681 a single character or to a whole string. Note that locale settings
682 may affect what characters are considered C<isupper>. Does not work
683 on Unicode characters code point 256 or higher. Consider using regular
684 expressions and the C</[[:upper:]]/> construct instead. Do B<not> use
689 This is identical to the C function, except that it can apply to a single
690 character or to a whole string. Note that locale settings may affect what
691 characters are considered C<isxdigit> (unlikely, but still possible).
692 Does not work on Unicode characters code point 256 or higher.
693 Consider using regular expressions and the C</[[:xdigit:]]/>
694 construct instead, or simply C</[0-9a-f]/i>.
698 This is identical to Perl's builtin C<kill()> function for sending
699 signals to processes (often to terminate them), see L<perlfunc/kill>.
703 (For returning absolute values of long integers.)
704 labs() is C-specific, see L<perlfunc/abs> instead.
708 This is identical to the C function C<ldexp()>
709 for multiplying floating point numbers with powers of two.
711 $x_quadrupled = POSIX::ldexp($x, 2);
715 (For computing dividends of long integers.)
716 ldiv() is C-specific, use C</> and C<int()> instead.
720 This is identical to Perl's builtin C<link()> function
721 for creating hard links into files, see L<perlfunc/link>.
725 Get numeric formatting information. Returns a reference to a hash
726 containing the current locale formatting values.
728 Here is how to query the database for the B<de> (Deutsch or German) locale.
730 $loc = POSIX::setlocale( &POSIX::LC_ALL, "de" );
731 print "Locale = $loc\n";
732 $lconv = POSIX::localeconv();
733 print "decimal_point = ", $lconv->{decimal_point}, "\n";
734 print "thousands_sep = ", $lconv->{thousands_sep}, "\n";
735 print "grouping = ", $lconv->{grouping}, "\n";
736 print "int_curr_symbol = ", $lconv->{int_curr_symbol}, "\n";
737 print "currency_symbol = ", $lconv->{currency_symbol}, "\n";
738 print "mon_decimal_point = ", $lconv->{mon_decimal_point}, "\n";
739 print "mon_thousands_sep = ", $lconv->{mon_thousands_sep}, "\n";
740 print "mon_grouping = ", $lconv->{mon_grouping}, "\n";
741 print "positive_sign = ", $lconv->{positive_sign}, "\n";
742 print "negative_sign = ", $lconv->{negative_sign}, "\n";
743 print "int_frac_digits = ", $lconv->{int_frac_digits}, "\n";
744 print "frac_digits = ", $lconv->{frac_digits}, "\n";
745 print "p_cs_precedes = ", $lconv->{p_cs_precedes}, "\n";
746 print "p_sep_by_space = ", $lconv->{p_sep_by_space}, "\n";
747 print "n_cs_precedes = ", $lconv->{n_cs_precedes}, "\n";
748 print "n_sep_by_space = ", $lconv->{n_sep_by_space}, "\n";
749 print "p_sign_posn = ", $lconv->{p_sign_posn}, "\n";
750 print "n_sign_posn = ", $lconv->{n_sign_posn}, "\n";
754 This is identical to Perl's builtin C<localtime()> function for
755 converting seconds since the epoch to a date see L<perlfunc/localtime>.
759 This is identical to Perl's builtin C<log()> function,
760 returning the natural (I<e>-based) logarithm of the numerical argument,
765 This is identical to the C function C<log10()>,
766 returning the 10-base logarithm of the numerical argument.
769 sub log10 { log($_[0]) / log(10) }
773 sub log10 { log($_[0]) / 2.30258509299405 }
777 sub log10 { log($_[0]) * 0.434294481903252 }
781 longjmp() is C-specific: use L<perlfunc/die> instead.
785 Move the file's read/write position. This uses file descriptors such as
786 those obtained by calling C<POSIX::open>.
788 $fd = POSIX::open( "foo", &POSIX::O_RDONLY );
789 $off_t = POSIX::lseek( $fd, 0, &POSIX::SEEK_SET );
791 Returns C<undef> on failure.
795 malloc() is C-specific. Perl does memory management transparently.
799 This is identical to the C function C<mblen()>.
800 Perl does not have any support for the wide and multibyte
801 characters of the C standards, so this might be a rather
806 This is identical to the C function C<mbstowcs()>.
807 Perl does not have any support for the wide and multibyte
808 characters of the C standards, so this might be a rather
813 This is identical to the C function C<mbtowc()>.
814 Perl does not have any support for the wide and multibyte
815 characters of the C standards, so this might be a rather
820 memchr() is C-specific, see L<perlfunc/index> instead.
824 memcmp() is C-specific, use C<eq> instead, see L<perlop>.
828 memcpy() is C-specific, use C<=>, see L<perlop>, or see L<perlfunc/substr>.
832 memmove() is C-specific, use C<=>, see L<perlop>, or see L<perlfunc/substr>.
836 memset() is C-specific, use C<x> instead, see L<perlop>.
840 This is identical to Perl's builtin C<mkdir()> function
841 for creating directories, see L<perlfunc/mkdir>.
845 This is similar to the C function C<mkfifo()> for creating
848 if (mkfifo($path, $mode)) { ....
850 Returns C<undef> on failure. The C<$mode> is similar to the
851 mode of C<mkdir()>, see L<perlfunc/mkdir>.
855 Convert date/time info to a calendar time.
859 mktime(sec, min, hour, mday, mon, year, wday = 0, yday = 0, isdst = 0)
861 The month (C<mon>), weekday (C<wday>), and yearday (C<yday>) begin at zero.
862 I.e. January is 0, not 1; Sunday is 0, not 1; January 1st is 0, not 1. The
863 year (C<year>) is given in years since 1900. I.e. The year 1995 is 95; the
864 year 2001 is 101. Consult your system's C<mktime()> manpage for details
865 about these and the other arguments.
867 Calendar time for December 12, 1995, at 10:30 am.
869 $time_t = POSIX::mktime( 0, 30, 10, 12, 11, 95 );
870 print "Date = ", POSIX::ctime($time_t);
872 Returns C<undef> on failure.
876 Return the integral and fractional parts of a floating-point number.
878 ($fractional, $integral) = POSIX::modf( 3.14 );
882 This is similar to the C function C<nice()>, for changing
883 the scheduling preference of the current process. Positive
884 arguments mean more polite process, negative values more
885 needy process. Normal user processes can only be more polite.
887 Returns C<undef> on failure.
891 offsetof() is C-specific, you probably want to see L<perlfunc/pack> instead.
895 Open a file for reading for writing. This returns file descriptors, not
896 Perl filehandles. Use C<POSIX::close> to close the file.
898 Open a file read-only with mode 0666.
900 $fd = POSIX::open( "foo" );
902 Open a file for read and write.
904 $fd = POSIX::open( "foo", &POSIX::O_RDWR );
906 Open a file for write, with truncation.
908 $fd = POSIX::open( "foo", &POSIX::O_WRONLY | &POSIX::O_TRUNC );
910 Create a new file with mode 0640. Set up the file for writing.
912 $fd = POSIX::open( "foo", &POSIX::O_CREAT | &POSIX::O_WRONLY, 0640 );
914 Returns C<undef> on failure.
916 See also L<perlfunc/sysopen>.
920 Open a directory for reading.
922 $dir = POSIX::opendir( "/var" );
923 @files = POSIX::readdir( $dir );
924 POSIX::closedir( $dir );
926 Returns C<undef> on failure.
930 Retrieves the value of a configurable limit on a file or directory.
932 The following will determine the maximum length of the longest allowable
933 pathname on the filesystem which holds C</var>.
935 $path_max = POSIX::pathconf( "/var", &POSIX::_PC_PATH_MAX );
937 Returns C<undef> on failure.
941 This is similar to the C function C<pause()>, which suspends
942 the execution of the current process until a signal is received.
944 Returns C<undef> on failure.
948 This is identical to the C function C<perror()>, which outputs to the
949 standard error stream the specified message followed by ": " and the
950 current error string. Use the C<warn()> function and the C<$!>
951 variable instead, see L<perlfunc/warn> and L<perlvar/$ERRNO>.
955 Create an interprocess channel. This returns file descriptors like those
956 returned by C<POSIX::open>.
958 my ($read, $write) = POSIX::pipe();
959 POSIX::write( $write, "hello", 5 );
960 POSIX::read( $read, $buf, 5 );
962 See also L<perlfunc/pipe>.
966 Computes C<$x> raised to the power C<$exponent>.
968 $ret = POSIX::pow( $x, $exponent );
970 You can also use the C<**> operator, see L<perlop>.
974 Formats and prints the specified arguments to STDOUT.
975 See also L<perlfunc/printf>.
979 putc() is C-specific, see L<perlfunc/print> instead.
983 putchar() is C-specific, see L<perlfunc/print> instead.
987 puts() is C-specific, see L<perlfunc/print> instead.
991 qsort() is C-specific, see L<perlfunc/sort> instead.
995 Sends the specified signal to the current process.
996 See also L<perlfunc/kill> and the C<$$> in L<perlvar/$PID>.
1000 C<rand()> is non-portable, see L<perlfunc/rand> instead.
1004 Read from a file. This uses file descriptors such as those obtained by
1005 calling C<POSIX::open>. If the buffer C<$buf> is not large enough for the
1006 read then Perl will extend it to make room for the request.
1008 $fd = POSIX::open( "foo", &POSIX::O_RDONLY );
1009 $bytes = POSIX::read( $fd, $buf, 3 );
1011 Returns C<undef> on failure.
1013 See also L<perlfunc/sysread>.
1017 This is identical to Perl's builtin C<readdir()> function
1018 for reading directory entries, see L<perlfunc/readdir>.
1022 realloc() is C-specific. Perl does memory management transparently.
1026 This is identical to Perl's builtin C<unlink()> function
1027 for removing files, see L<perlfunc/unlink>.
1031 This is identical to Perl's builtin C<rename()> function
1032 for renaming files, see L<perlfunc/rename>.
1036 Seeks to the beginning of the file.
1040 This is identical to Perl's builtin C<rewinddir()> function for
1041 rewinding directory entry streams, see L<perlfunc/rewinddir>.
1045 This is identical to Perl's builtin C<rmdir()> function
1046 for removing (empty) directories, see L<perlfunc/rmdir>.
1050 scanf() is C-specific, use E<lt>E<gt> and regular expressions instead,
1055 Sets the real group identifier and the effective group identifier for
1056 this process. Similar to assigning a value to the Perl's builtin
1057 C<$)> variable, see L<perlvar/$GID>, except that the latter
1058 will change only the real user identifier, and that the setgid()
1059 uses only a single numeric argument, as opposed to a space-separated
1064 C<setjmp()> is C-specific: use C<eval {}> instead,
1065 see L<perlfunc/eval>.
1069 Modifies and queries program's locale. The following examples assume
1071 use POSIX qw(setlocale LC_ALL LC_CTYPE);
1075 The following will set the traditional UNIX system locale behavior
1076 (the second argument C<"C">).
1078 $loc = setlocale( LC_ALL, "C" );
1080 The following will query the current LC_CTYPE category. (No second
1081 argument means 'query'.)
1083 $loc = setlocale( LC_CTYPE );
1085 The following will set the LC_CTYPE behaviour according to the locale
1086 environment variables (the second argument C<"">).
1087 Please see your systems C<setlocale(3)> documentation for the locale
1088 environment variables' meaning or consult L<perllocale>.
1090 $loc = setlocale( LC_CTYPE, "" );
1092 The following will set the LC_COLLATE behaviour to Argentinian
1093 Spanish. B<NOTE>: The naming and availability of locales depends on
1094 your operating system. Please consult L<perllocale> for how to find
1095 out which locales are available in your system.
1097 $loc = setlocale( LC_ALL, "es_AR.ISO8859-1" );
1101 This is similar to the C function C<setpgid()> for
1102 setting the process group identifier of the current process.
1104 Returns C<undef> on failure.
1108 This is identical to the C function C<setsid()> for
1109 setting the session identifier of the current process.
1113 Sets the real user identifier and the effective user identifier for
1114 this process. Similar to assigning a value to the Perl's builtin
1115 C<$E<lt>> variable, see L<perlvar/$UID>, except that the latter
1116 will change only the real user identifier.
1120 Detailed signal management. This uses C<POSIX::SigAction> objects for
1121 the C<action> and C<oldaction> arguments (the oldaction can also be
1122 just a hash reference). Consult your system's C<sigaction> manpage
1123 for details, see also C<POSIX::SigRt>.
1127 sigaction(signal, action, oldaction = 0)
1129 Returns C<undef> on failure. The C<signal> must be a number (like
1130 SIGHUP), not a string (like "SIGHUP"), though Perl does try hard
1133 If you use the SA_SIGINFO flag, the signal handler will in addition to
1134 the first argument, the signal name, also receive a second argument, a
1135 hash reference, inside which are the following keys with the following
1136 semantics, as defined by POSIX/SUSv3:
1138 signo the signal number
1139 errno the error number
1140 code if this is zero or less, the signal was sent by
1141 a user process and the uid and pid make sense,
1142 otherwise the signal was sent by the kernel
1144 The following are also defined by POSIX/SUSv3, but unfortunately
1145 not very widely implemented:
1147 pid the process id generating the signal
1148 uid the uid of the process id generating the signal
1149 status exit value or signal for SIGCHLD
1150 band band event for SIGPOLL
1152 A third argument is also passed to the handler, which contains a copy
1153 of the raw binary contents of the siginfo structure: if a system has
1154 some non-POSIX fields, this third argument is where to unpack() them
1157 Note that not all siginfo values make sense simultaneously (some are
1158 valid only for certain signals, for example), and not all values make
1159 sense from Perl perspective, you should to consult your system's
1160 C<sigaction> and possibly also C<siginfo> documentation.
1164 siglongjmp() is C-specific: use L<perlfunc/die> instead.
1168 Examine signals that are blocked and pending. This uses C<POSIX::SigSet>
1169 objects for the C<sigset> argument. Consult your system's C<sigpending>
1170 manpage for details.
1176 Returns C<undef> on failure.
1180 Change and/or examine calling process's signal mask. This uses
1181 C<POSIX::SigSet> objects for the C<sigset> and C<oldsigset> arguments.
1182 Consult your system's C<sigprocmask> manpage for details.
1186 sigprocmask(how, sigset, oldsigset = 0)
1188 Returns C<undef> on failure.
1192 C<sigsetjmp()> is C-specific: use C<eval {}> instead,
1193 see L<perlfunc/eval>.
1197 Install a signal mask and suspend process until signal arrives. This uses
1198 C<POSIX::SigSet> objects for the C<signal_mask> argument. Consult your
1199 system's C<sigsuspend> manpage for details.
1203 sigsuspend(signal_mask)
1205 Returns C<undef> on failure.
1209 This is identical to Perl's builtin C<sin()> function
1210 for returning the sine of the numerical argument,
1211 see L<perlfunc/sin>. See also L<Math::Trig>.
1215 This is identical to the C function C<sinh()>
1216 for returning the hyperbolic sine of the numerical argument.
1217 See also L<Math::Trig>.
1221 This is functionally identical to Perl's builtin C<sleep()> function
1222 for suspending the execution of the current for process for certain
1223 number of seconds, see L<perlfunc/sleep>. There is one significant
1224 difference, however: C<POSIX::sleep()> returns the number of
1225 B<unslept> seconds, while the C<CORE::sleep()> returns the
1226 number of slept seconds.
1230 This is similar to Perl's builtin C<sprintf()> function
1231 for returning a string that has the arguments formatted as requested,
1232 see L<perlfunc/sprintf>.
1236 This is identical to Perl's builtin C<sqrt()> function.
1237 for returning the square root of the numerical argument,
1238 see L<perlfunc/sqrt>.
1242 Give a seed the pseudorandom number generator, see L<perlfunc/srand>.
1246 sscanf() is C-specific, use regular expressions instead,
1251 This is identical to Perl's builtin C<stat()> function
1252 for returning information about files and directories.
1256 strcat() is C-specific, use C<.=> instead, see L<perlop>.
1260 strchr() is C-specific, see L<perlfunc/index> instead.
1264 strcmp() is C-specific, use C<eq> or C<cmp> instead, see L<perlop>.
1268 This is identical to the C function C<strcoll()>
1269 for collating (comparing) strings transformed using
1270 the C<strxfrm()> function. Not really needed since
1271 Perl can do this transparently, see L<perllocale>.
1275 strcpy() is C-specific, use C<=> instead, see L<perlop>.
1279 strcspn() is C-specific, use regular expressions instead,
1284 Returns the error string for the specified errno.
1285 Identical to the string form of the C<$!>, see L<perlvar/$ERRNO>.
1289 Convert date and time information to string. Returns the string.
1293 strftime(fmt, sec, min, hour, mday, mon, year, wday = -1, yday = -1, isdst = -1)
1295 The month (C<mon>), weekday (C<wday>), and yearday (C<yday>) begin at zero.
1296 I.e. January is 0, not 1; Sunday is 0, not 1; January 1st is 0, not 1. The
1297 year (C<year>) is given in years since 1900. I.e., the year 1995 is 95; the
1298 year 2001 is 101. Consult your system's C<strftime()> manpage for details
1299 about these and the other arguments.
1301 If you want your code to be portable, your format (C<fmt>) argument
1302 should use only the conversion specifiers defined by the ANSI C
1303 standard (C89, to play safe). These are C<aAbBcdHIjmMpSUwWxXyYZ%>.
1304 But even then, the B<results> of some of the conversion specifiers are
1305 non-portable. For example, the specifiers C<aAbBcpZ> change according
1306 to the locale settings of the user, and both how to set locales (the
1307 locale names) and what output to expect are non-standard.
1308 The specifier C<c> changes according to the timezone settings of the
1309 user and the timezone computation rules of the operating system.
1310 The C<Z> specifier is notoriously unportable since the names of
1311 timezones are non-standard. Sticking to the numeric specifiers is the
1314 The given arguments are made consistent as though by calling
1315 C<mktime()> before calling your system's C<strftime()> function,
1316 except that the C<isdst> value is not affected.
1318 The string for Tuesday, December 12, 1995.
1320 $str = POSIX::strftime( "%A, %B %d, %Y", 0, 0, 0, 12, 11, 95, 2 );
1325 strlen() is C-specific, use C<length()> instead, see L<perlfunc/length>.
1329 strncat() is C-specific, use C<.=> instead, see L<perlop>.
1333 strncmp() is C-specific, use C<eq> instead, see L<perlop>.
1337 strncpy() is C-specific, use C<=> instead, see L<perlop>.
1341 strpbrk() is C-specific, use regular expressions instead,
1346 strrchr() is C-specific, see L<perlfunc/rindex> instead.
1350 strspn() is C-specific, use regular expressions instead,
1355 This is identical to Perl's builtin C<index()> function,
1356 see L<perlfunc/index>.
1360 String to double translation. Returns the parsed number and the number
1361 of characters in the unparsed portion of the string. Truly
1362 POSIX-compliant systems set $! ($ERRNO) to indicate a translation
1363 error, so clear $! before calling strtod. However, non-POSIX systems
1364 may not check for overflow, and therefore will never set $!.
1366 strtod should respect any POSIX I<setlocale()> settings.
1368 To parse a string $str as a floating point number use
1371 ($num, $n_unparsed) = POSIX::strtod($str);
1373 The second returned item and $! can be used to check for valid input:
1375 if (($str eq '') || ($n_unparsed != 0) || $!) {
1376 die "Non-numeric input $str" . ($! ? ": $!\n" : "\n");
1379 When called in a scalar context strtod returns the parsed number.
1383 strtok() is C-specific, use regular expressions instead, see
1384 L<perlre>, or L<perlfunc/split>.
1388 String to (long) integer translation. Returns the parsed number and
1389 the number of characters in the unparsed portion of the string. Truly
1390 POSIX-compliant systems set $! ($ERRNO) to indicate a translation
1391 error, so clear $! before calling strtol. However, non-POSIX systems
1392 may not check for overflow, and therefore will never set $!.
1394 strtol should respect any POSIX I<setlocale()> settings.
1396 To parse a string $str as a number in some base $base use
1399 ($num, $n_unparsed) = POSIX::strtol($str, $base);
1401 The base should be zero or between 2 and 36, inclusive. When the base
1402 is zero or omitted strtol will use the string itself to determine the
1403 base: a leading "0x" or "0X" means hexadecimal; a leading "0" means
1404 octal; any other leading characters mean decimal. Thus, "1234" is
1405 parsed as a decimal number, "01234" as an octal number, and "0x1234"
1406 as a hexadecimal number.
1408 The second returned item and $! can be used to check for valid input:
1410 if (($str eq '') || ($n_unparsed != 0) || !$!) {
1411 die "Non-numeric input $str" . $! ? ": $!\n" : "\n";
1414 When called in a scalar context strtol returns the parsed number.
1418 String to unsigned (long) integer translation. strtoul() is identical
1419 to strtol() except that strtoul() only parses unsigned integers. See
1420 L</strtol> for details.
1422 Note: Some vendors supply strtod() and strtol() but not strtoul().
1423 Other vendors that do supply strtoul() parse "-1" as a valid value.
1427 String transformation. Returns the transformed string.
1429 $dst = POSIX::strxfrm( $src );
1431 Used in conjunction with the C<strcoll()> function, see L</strcoll>.
1433 Not really needed since Perl can do this transparently, see
1438 Retrieves values of system configurable variables.
1440 The following will get the machine's clock speed.
1442 $clock_ticks = POSIX::sysconf( &POSIX::_SC_CLK_TCK );
1444 Returns C<undef> on failure.
1448 This is identical to Perl's builtin C<system()> function, see
1453 This is identical to the C function C<tan()>, returning the
1454 tangent of the numerical argument. See also L<Math::Trig>.
1458 This is identical to the C function C<tanh()>, returning the
1459 hyperbolic tangent of the numerical argument. See also L<Math::Trig>.
1463 This is similar to the C function C<tcdrain()> for draining
1464 the output queue of its argument stream.
1466 Returns C<undef> on failure.
1470 This is similar to the C function C<tcflow()> for controlling
1471 the flow of its argument stream.
1473 Returns C<undef> on failure.
1477 This is similar to the C function C<tcflush()> for flushing
1478 the I/O buffers of its argument stream.
1480 Returns C<undef> on failure.
1484 This is identical to the C function C<tcgetpgrp()> for returning the
1485 process group identifier of the foreground process group of the controlling
1490 This is similar to the C function C<tcsendbreak()> for sending
1491 a break on its argument stream.
1493 Returns C<undef> on failure.
1497 This is similar to the C function C<tcsetpgrp()> for setting the
1498 process group identifier of the foreground process group of the controlling
1501 Returns C<undef> on failure.
1505 This is identical to Perl's builtin C<time()> function
1506 for returning the number of seconds since the epoch
1507 (whatever it is for the system), see L<perlfunc/time>.
1511 The times() function returns elapsed realtime since some point in the past
1512 (such as system startup), user and system times for this process, and user
1513 and system times used by child processes. All times are returned in clock
1516 ($realtime, $user, $system, $cuser, $csystem) = POSIX::times();
1518 Note: Perl's builtin C<times()> function returns four values, measured in
1523 Use method C<IO::File::new_tmpfile()> instead, or see L<File::Temp>.
1527 Returns a name for a temporary file.
1529 $tmpfile = POSIX::tmpnam();
1531 For security reasons, which are probably detailed in your system's
1532 documentation for the C library tmpnam() function, this interface
1533 should not be used; instead see L<File::Temp>.
1537 This is identical to the C function, except that it can apply to a single
1538 character or to a whole string. Consider using the C<lc()> function,
1539 see L<perlfunc/lc>, or the equivalent C<\L> operator inside doublequotish
1544 This is identical to the C function, except that it can apply to a single
1545 character or to a whole string. Consider using the C<uc()> function,
1546 see L<perlfunc/uc>, or the equivalent C<\U> operator inside doublequotish
1551 This is identical to the C function C<ttyname()> for returning the
1552 name of the current terminal.
1556 Retrieves the time conversion information from the C<tzname> variable.
1559 ($std, $dst) = POSIX::tzname();
1563 This is identical to the C function C<tzset()> for setting
1564 the current timezone based on the environment variable C<TZ>,
1565 to be used by C<ctime()>, C<localtime()>, C<mktime()>, and C<strftime()>
1570 This is identical to Perl's builtin C<umask()> function
1571 for setting (and querying) the file creation permission mask,
1572 see L<perlfunc/umask>.
1576 Get name of current operating system.
1578 ($sysname, $nodename, $release, $version, $machine) = POSIX::uname();
1580 Note that the actual meanings of the various fields are not
1581 that well standardized, do not expect any great portability.
1582 The C<$sysname> might be the name of the operating system,
1583 the C<$nodename> might be the name of the host, the C<$release>
1584 might be the (major) release number of the operating system,
1585 the C<$version> might be the (minor) release number of the
1586 operating system, and the C<$machine> might be a hardware identifier.
1591 Use method C<IO::Handle::ungetc()> instead.
1595 This is identical to Perl's builtin C<unlink()> function
1596 for removing files, see L<perlfunc/unlink>.
1600 This is identical to Perl's builtin C<utime()> function
1601 for changing the time stamps of files and directories,
1602 see L<perlfunc/utime>.
1606 vfprintf() is C-specific, see L<perlfunc/printf> instead.
1610 vprintf() is C-specific, see L<perlfunc/printf> instead.
1614 vsprintf() is C-specific, see L<perlfunc/sprintf> instead.
1618 This is identical to Perl's builtin C<wait()> function,
1619 see L<perlfunc/wait>.
1623 Wait for a child process to change state. This is identical to Perl's
1624 builtin C<waitpid()> function, see L<perlfunc/waitpid>.
1626 $pid = POSIX::waitpid( -1, POSIX::WNOHANG );
1627 print "status = ", ($? / 256), "\n";
1631 This is identical to the C function C<wcstombs()>.
1632 Perl does not have any support for the wide and multibyte
1633 characters of the C standards, so this might be a rather
1638 This is identical to the C function C<wctomb()>.
1639 Perl does not have any support for the wide and multibyte
1640 characters of the C standards, so this might be a rather
1645 Write to a file. This uses file descriptors such as those obtained by
1646 calling C<POSIX::open>.
1648 $fd = POSIX::open( "foo", &POSIX::O_WRONLY );
1650 $bytes = POSIX::write( $b, $buf, 5 );
1652 Returns C<undef> on failure.
1654 See also L<perlfunc/syswrite>.
1660 =head2 POSIX::SigAction
1666 Creates a new C<POSIX::SigAction> object which corresponds to the C
1667 C<struct sigaction>. This object will be destroyed automatically when
1668 it is no longer needed. The first parameter is the handler, a sub
1669 reference. The second parameter is a C<POSIX::SigSet> object, it
1670 defaults to the empty set. The third parameter contains the
1671 C<sa_flags>, it defaults to 0.
1673 $sigset = POSIX::SigSet->new(SIGINT, SIGQUIT);
1674 $sigaction = POSIX::SigAction->new( \&handler, $sigset, &POSIX::SA_NOCLDSTOP );
1676 This C<POSIX::SigAction> object is intended for use with the C<POSIX::sigaction()>
1689 accessor functions to get/set the values of a SigAction object.
1691 $sigset = $sigaction->mask;
1692 $sigaction->flags(&POSIX::SA_RESTART);
1696 accessor function for the "safe signals" flag of a SigAction object; see
1697 L<perlipc> for general information on safe (a.k.a. "deferred") signals. If
1698 you wish to handle a signal safely, use this accessor to set the "safe" flag
1699 in the C<POSIX::SigAction> object:
1701 $sigaction->safe(1);
1703 You may also examine the "safe" flag on the output action object which is
1704 filled in when given as the third parameter to C<POSIX::sigaction()>:
1706 sigaction(SIGINT, $new_action, $old_action);
1707 if ($old_action->safe) {
1708 # previous SIGINT handler used safe signals
1719 A hash of the POSIX realtime signal handlers. It is an extension of
1720 the standard %SIG, the $POSIX::SIGRT{SIGRTMIN} is roughly equivalent
1721 to $SIG{SIGRTMIN}, but the right POSIX moves (see below) are made with
1722 the POSIX::SigSet and POSIX::sigaction instead of accessing the %SIG.
1724 You can set the %POSIX::SIGRT elements to set the POSIX realtime
1725 signal handlers, use C<delete> and C<exists> on the elements, and use
1726 C<scalar> on the C<%POSIX::SIGRT> to find out how many POSIX realtime
1727 signals there are available (SIGRTMAX - SIGRTMIN + 1, the SIGRTMAX is
1728 a valid POSIX realtime signal).
1730 Setting the %SIGRT elements is equivalent to calling this:
1733 my ($rtsig, $handler, $flags) = @_;
1734 my $sigset = POSIX:SigSet($rtsig);
1735 my $sigact = POSIX::SigAction->new($handler, $sigset, $flags);
1736 sigaction($rtsig, $sigact);
1739 The flags default to zero, if you want something different you can
1740 either use C<local> on $POSIX::RtSig::SIGACTION_FLAGS, or you can
1741 derive from POSIX::SigRt and define your own C<new()> (the tied hash
1742 STORE method of the %SIGRT calls C<new($rtsig, $handler, $SIGACTION_FLAGS)>,
1743 where the $rtsig ranges from zero to SIGRTMAX - SIGRTMIN + 1).
1745 Just as with any signal, you can use sigaction($rtsig, undef, $oa) to
1746 retrieve the installed signal handler (or, rather, the signal action).
1748 B<NOTE:> whether POSIX realtime signals really work in your system, or
1749 whether Perl has been compiled so that it works with them, is outside
1754 Return the minimum POSIX realtime signal number available, or C<undef>
1755 if no POSIX realtime signals are available.
1759 Return the maximum POSIX realtime signal number available, or C<undef>
1760 if no POSIX realtime signals are available.
1764 =head2 POSIX::SigSet
1770 Create a new SigSet object. This object will be destroyed automatically
1771 when it is no longer needed. Arguments may be supplied to initialize the
1774 Create an empty set.
1776 $sigset = POSIX::SigSet->new;
1778 Create a set with SIGUSR1.
1780 $sigset = POSIX::SigSet->new( &POSIX::SIGUSR1 );
1784 Add a signal to a SigSet object.
1786 $sigset->addset( &POSIX::SIGUSR2 );
1788 Returns C<undef> on failure.
1792 Remove a signal from the SigSet object.
1794 $sigset->delset( &POSIX::SIGUSR2 );
1796 Returns C<undef> on failure.
1800 Initialize the SigSet object to be empty.
1802 $sigset->emptyset();
1804 Returns C<undef> on failure.
1808 Initialize the SigSet object to include all signals.
1812 Returns C<undef> on failure.
1816 Tests the SigSet object to see if it contains a specific signal.
1818 if( $sigset->ismember( &POSIX::SIGUSR1 ) ){
1819 print "contains SIGUSR1\n";
1824 =head2 POSIX::Termios
1830 Create a new Termios object. This object will be destroyed automatically
1831 when it is no longer needed. A Termios object corresponds to the termios
1832 C struct. new() mallocs a new one, getattr() fills it from a file descriptor,
1833 and setattr() sets a file descriptor's parameters to match Termios' contents.
1835 $termios = POSIX::Termios->new;
1839 Get terminal control attributes.
1841 Obtain the attributes for stdin.
1845 Obtain the attributes for stdout.
1847 $termios->getattr( 1 )
1849 Returns C<undef> on failure.
1853 Retrieve a value from the c_cc field of a termios object. The c_cc field is
1854 an array so an index must be specified.
1856 $c_cc[1] = $termios->getcc(1);
1860 Retrieve the c_cflag field of a termios object.
1862 $c_cflag = $termios->getcflag;
1866 Retrieve the c_iflag field of a termios object.
1868 $c_iflag = $termios->getiflag;
1872 Retrieve the input baud rate.
1874 $ispeed = $termios->getispeed;
1878 Retrieve the c_lflag field of a termios object.
1880 $c_lflag = $termios->getlflag;
1884 Retrieve the c_oflag field of a termios object.
1886 $c_oflag = $termios->getoflag;
1890 Retrieve the output baud rate.
1892 $ospeed = $termios->getospeed;
1896 Set terminal control attributes.
1898 Set attributes immediately for stdout.
1900 $termios->setattr( 1, &POSIX::TCSANOW );
1902 Returns C<undef> on failure.
1906 Set a value in the c_cc field of a termios object. The c_cc field is an
1907 array so an index must be specified.
1909 $termios->setcc( &POSIX::VEOF, 1 );
1913 Set the c_cflag field of a termios object.
1915 $termios->setcflag( $c_cflag | &POSIX::CLOCAL );
1919 Set the c_iflag field of a termios object.
1921 $termios->setiflag( $c_iflag | &POSIX::BRKINT );
1925 Set the input baud rate.
1927 $termios->setispeed( &POSIX::B9600 );
1929 Returns C<undef> on failure.
1933 Set the c_lflag field of a termios object.
1935 $termios->setlflag( $c_lflag | &POSIX::ECHO );
1939 Set the c_oflag field of a termios object.
1941 $termios->setoflag( $c_oflag | &POSIX::OPOST );
1945 Set the output baud rate.
1947 $termios->setospeed( &POSIX::B9600 );
1949 Returns C<undef> on failure.
1951 =item Baud rate values
1953 B38400 B75 B200 B134 B300 B1800 B150 B0 B19200 B1200 B9600 B600 B4800 B50 B2400 B110
1955 =item Terminal interface values
1957 TCSADRAIN TCSANOW TCOON TCIOFLUSH TCOFLUSH TCION TCIFLUSH TCSAFLUSH TCIOFF TCOOFF
1959 =item c_cc field values
1961 VEOF VEOL VERASE VINTR VKILL VQUIT VSUSP VSTART VSTOP VMIN VTIME NCCS
1963 =item c_cflag field values
1965 CLOCAL CREAD CSIZE CS5 CS6 CS7 CS8 CSTOPB HUPCL PARENB PARODD
1967 =item c_iflag field values
1969 BRKINT ICRNL IGNBRK IGNCR IGNPAR INLCR INPCK ISTRIP IXOFF IXON PARMRK
1971 =item c_lflag field values
1973 ECHO ECHOE ECHOK ECHONL ICANON IEXTEN ISIG NOFLSH TOSTOP
1975 =item c_oflag field values
1981 =head1 PATHNAME CONSTANTS
1987 _PC_CHOWN_RESTRICTED _PC_LINK_MAX _PC_MAX_CANON _PC_MAX_INPUT _PC_NAME_MAX _PC_NO_TRUNC _PC_PATH_MAX _PC_PIPE_BUF _PC_VDISABLE
1991 =head1 POSIX CONSTANTS
1997 _POSIX_ARG_MAX _POSIX_CHILD_MAX _POSIX_CHOWN_RESTRICTED _POSIX_JOB_CONTROL _POSIX_LINK_MAX _POSIX_MAX_CANON _POSIX_MAX_INPUT _POSIX_NAME_MAX _POSIX_NGROUPS_MAX _POSIX_NO_TRUNC _POSIX_OPEN_MAX _POSIX_PATH_MAX _POSIX_PIPE_BUF _POSIX_SAVED_IDS _POSIX_SSIZE_MAX _POSIX_STREAM_MAX _POSIX_TZNAME_MAX _POSIX_VDISABLE _POSIX_VERSION
2001 =head1 SYSTEM CONFIGURATION
2007 _SC_ARG_MAX _SC_CHILD_MAX _SC_CLK_TCK _SC_JOB_CONTROL _SC_NGROUPS_MAX _SC_OPEN_MAX _SC_PAGESIZE _SC_SAVED_IDS _SC_STREAM_MAX _SC_TZNAME_MAX _SC_VERSION
2017 E2BIG EACCES EADDRINUSE EADDRNOTAVAIL EAFNOSUPPORT EAGAIN EALREADY EBADF
2018 EBUSY ECHILD ECONNABORTED ECONNREFUSED ECONNRESET EDEADLK EDESTADDRREQ
2019 EDOM EDQUOT EEXIST EFAULT EFBIG EHOSTDOWN EHOSTUNREACH EINPROGRESS EINTR
2020 EINVAL EIO EISCONN EISDIR ELOOP EMFILE EMLINK EMSGSIZE ENAMETOOLONG
2021 ENETDOWN ENETRESET ENETUNREACH ENFILE ENOBUFS ENODEV ENOENT ENOEXEC
2022 ENOLCK ENOMEM ENOPROTOOPT ENOSPC ENOSYS ENOTBLK ENOTCONN ENOTDIR
2023 ENOTEMPTY ENOTSOCK ENOTTY ENXIO EOPNOTSUPP EPERM EPFNOSUPPORT EPIPE
2024 EPROCLIM EPROTONOSUPPORT EPROTOTYPE ERANGE EREMOTE ERESTART EROFS
2025 ESHUTDOWN ESOCKTNOSUPPORT ESPIPE ESRCH ESTALE ETIMEDOUT ETOOMANYREFS
2026 ETXTBSY EUSERS EWOULDBLOCK EXDEV
2036 FD_CLOEXEC F_DUPFD F_GETFD F_GETFL F_GETLK F_OK F_RDLCK F_SETFD F_SETFL F_SETLK F_SETLKW F_UNLCK F_WRLCK O_ACCMODE O_APPEND O_CREAT O_EXCL O_NOCTTY O_NONBLOCK O_RDONLY O_RDWR O_TRUNC O_WRONLY
2046 DBL_DIG DBL_EPSILON DBL_MANT_DIG DBL_MAX DBL_MAX_10_EXP DBL_MAX_EXP DBL_MIN DBL_MIN_10_EXP DBL_MIN_EXP FLT_DIG FLT_EPSILON FLT_MANT_DIG FLT_MAX FLT_MAX_10_EXP FLT_MAX_EXP FLT_MIN FLT_MIN_10_EXP FLT_MIN_EXP FLT_RADIX FLT_ROUNDS LDBL_DIG LDBL_EPSILON LDBL_MANT_DIG LDBL_MAX LDBL_MAX_10_EXP LDBL_MAX_EXP LDBL_MIN LDBL_MIN_10_EXP LDBL_MIN_EXP
2056 ARG_MAX CHAR_BIT CHAR_MAX CHAR_MIN CHILD_MAX INT_MAX INT_MIN LINK_MAX LONG_MAX LONG_MIN MAX_CANON MAX_INPUT MB_LEN_MAX NAME_MAX NGROUPS_MAX OPEN_MAX PATH_MAX PIPE_BUF SCHAR_MAX SCHAR_MIN SHRT_MAX SHRT_MIN SSIZE_MAX STREAM_MAX TZNAME_MAX UCHAR_MAX UINT_MAX ULONG_MAX USHRT_MAX
2066 LC_ALL LC_COLLATE LC_CTYPE LC_MONETARY LC_NUMERIC LC_TIME
2086 SA_NOCLDSTOP SA_NOCLDWAIT SA_NODEFER SA_ONSTACK SA_RESETHAND SA_RESTART
2087 SA_SIGINFO SIGABRT SIGALRM SIGCHLD SIGCONT SIGFPE SIGHUP SIGILL SIGINT
2088 SIGKILL SIGPIPE SIGQUIT SIGSEGV SIGSTOP SIGTERM SIGTSTP SIGTTIN SIGTTOU
2089 SIGUSR1 SIGUSR2 SIG_BLOCK SIG_DFL SIG_ERR SIG_IGN SIG_SETMASK
2100 S_IRGRP S_IROTH S_IRUSR S_IRWXG S_IRWXO S_IRWXU S_ISGID S_ISUID S_IWGRP S_IWOTH S_IWUSR S_IXGRP S_IXOTH S_IXUSR
2104 S_ISBLK S_ISCHR S_ISDIR S_ISFIFO S_ISREG
2114 EXIT_FAILURE EXIT_SUCCESS MB_CUR_MAX RAND_MAX
2124 BUFSIZ EOF FILENAME_MAX L_ctermid L_cuserid L_tmpname TMP_MAX
2134 CLK_TCK CLOCKS_PER_SEC
2144 R_OK SEEK_CUR SEEK_END SEEK_SET STDIN_FILENO STDOUT_FILENO STDERR_FILENO W_OK X_OK
2160 Do not suspend the calling process until a child process
2161 changes state but instead return immediately.
2165 Catch stopped child processes.
2171 WIFEXITED WEXITSTATUS WIFSIGNALED WTERMSIG WIFSTOPPED WSTOPSIG
2177 WIFEXITED($?) returns true if the child process exited normally
2178 (C<exit()> or by falling off the end of C<main()>)
2182 WEXITSTATUS($?) returns the normal exit status of the child process
2183 (only meaningful if WIFEXITED($?) is true)
2187 WIFSIGNALED($?) returns true if the child process terminated because
2192 WTERMSIG($?) returns the signal the child process terminated for
2193 (only meaningful if WIFSIGNALED($?) is true)
2197 WIFSTOPPED($?) returns true if the child process is currently stopped
2198 (can happen only if you specified the WUNTRACED flag to waitpid())
2202 WSTOPSIG($?) returns the signal the child process was stopped for
2203 (only meaningful if WIFSTOPPED($?) is true)