/* Getopt for GNU.
NOTE: getopt is part of the C library, so if you don't know what
"Keep this file name-space clean" means, talk to drepper@gnu.org
before changing it!
Copyright (C) 1987-1996, 1998-2004, 2006, 2008-2010 Free Software
Foundation, Inc.
This file is part of the GNU C Library.
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>. */
#ifndef _LIBC
# include <config.h>
#endif
#include "getopt.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#ifdef _LIBC
# include <libintl.h>
#else
# include "gettext.h"
#endif
#if defined _LIBC && defined USE_IN_LIBIO
# include <wchar.h>
#endif
/* This version of `getopt' appears to the caller like standard Unix `getopt'
but it behaves differently for the user, since it allows the user
to intersperse the options with the other arguments.
As `getopt_long' works, it permutes the elements of ARGV so that,
when it is done, all the options precede everything else. Thus
all application programs are extended to handle flexible argument order.
Using `getopt' or setting the environment variable POSIXLY_CORRECT
disables permutation.
Then the behavior is completely standard.
GNU application programs can use a third alternative mode in which
they can distinguish the relative order of options and other arguments. */
#include "getopt_int.h"
/* For communication from `getopt' to the caller.
When `getopt' finds an option that takes an argument,
the argument value is returned here.
Also, when `ordering' is RETURN_IN_ORDER,
each non-option ARGV-element is returned here. */
char *optarg;
/* Index in ARGV of the next element to be scanned.
This is used for communication to and from the caller
and for communication between successive calls to `getopt'.
On entry to `getopt', zero means this is the first call; initialize.
When `getopt' returns -1, this is the index of the first of the
non-option elements that the caller should itself scan.
Otherwise, `optind' communicates from one call to the next
how much of ARGV has been scanned so far. */
/* 1003.2 says this must be 1 before any call. */
/* Callers store zero here to inhibit the error message
for unrecognized options. */
/* Set to an option character which was unrecognized.
This must be initialized on some systems to avoid linking in the
system's own getopt implementation. */
/* Keep a global copy of all internal members of getopt_data. */
#if defined HAVE_DECL_GETENV && !HAVE_DECL_GETENV
extern char *getenv ();
#endif
#ifdef _LIBC
/* Stored original parameters.
XXX This is no good solution. We should rather copy the args so
that we can compare them later. But we must not use malloc(3). */
extern int __libc_argc;
extern char **__libc_argv;
/* Bash 2.0 gives us an environment variable containing flags
indicating ARGV elements that should not be considered arguments. */
# ifdef USE_NONOPTION_FLAGS
/* Defined in getopt_init.c */
extern char *__getopt_nonoption_flags;
# endif
# ifdef USE_NONOPTION_FLAGS
if (d->__nonoption_flags_len > 0) \
{ \
}
# else
# endif
#else /* !_LIBC */
#endif /* _LIBC */
/* Exchange two adjacent subsequences of ARGV.
One subsequence is elements [first_nonopt,last_nonopt)
which contains all the non-options that have been skipped so far.
The other is elements [last_nonopt,optind), which contains all
the options processed since those non-options were skipped.
`first_nonopt' and `last_nonopt' are relocated so that they describe
the new indices of the non-options in ARGV after they are moved. */
static void
{
char *tem;
/* Exchange the shorter segment with the far end of the longer segment.
That puts the shorter segment into the right place.
It leaves the longer segment in the right place overall,
but it consists of two parts that need to be swapped next. */
#if defined _LIBC && defined USE_NONOPTION_FLAGS
/* First make sure the handling of the `__getopt_nonoption_flags'
string can work normally. Our top argument must be in the range
of the string. */
{
/* We must extend the array. The user plays games with us and
presents new arguments. */
d->__nonoption_flags_len = d->__nonoption_flags_max_len = 0;
else
{
}
}
#endif
{
{
/* Bottom segment is the short one. */
register int i;
/* Swap it with the top part of the top segment. */
for (i = 0; i < len; i++)
{
}
/* Exclude the moved bottom segment from further swapping. */
}
else
{
/* Top segment is the short one. */
register int i;
/* Swap it with the bottom part of the bottom segment. */
for (i = 0; i < len; i++)
{
}
/* Exclude the moved top segment from further swapping. */
}
}
/* Update records for the slots the non-options now occupy. */
d->__last_nonopt = d->optind;
}
/* Initialize the internal data when the first call is made. */
static const char *
struct _getopt_data *d, int posixly_correct)
{
/* Start processing options with ARGV-element 1 (since ARGV-element 0
is the program name); the sequence of previously skipped
non-option ARGV-elements is empty. */
d->__nextchar = NULL;
/* Determine how to handle the ordering of options and nonoptions. */
if (optstring[0] == '-')
{
d->__ordering = RETURN_IN_ORDER;
++optstring;
}
else if (optstring[0] == '+')
{
d->__ordering = REQUIRE_ORDER;
++optstring;
}
else if (d->__posixly_correct)
d->__ordering = REQUIRE_ORDER;
else
d->__ordering = PERMUTE;
#if defined _LIBC && defined USE_NONOPTION_FLAGS
if (!d->__posixly_correct
{
if (d->__nonoption_flags_max_len == 0)
{
if (__getopt_nonoption_flags == NULL
|| __getopt_nonoption_flags[0] == '\0')
d->__nonoption_flags_max_len = -1;
else
{
if (d->__nonoption_flags_max_len < argc)
(char *) malloc (d->__nonoption_flags_max_len);
if (__getopt_nonoption_flags == NULL)
d->__nonoption_flags_max_len = -1;
else
}
}
}
else
d->__nonoption_flags_len = 0;
#endif
return optstring;
}
/* Scan elements of ARGV (whose length is ARGC) for option characters
given in OPTSTRING.
If an element of ARGV starts with '-', and is not exactly "-" or "--",
then it is an option element. The characters of this element
(aside from the initial '-') are option characters. If `getopt'
is called repeatedly, it returns successively each of the option characters
from each of the option elements.
If `getopt' finds another option character, it returns that character,
updating `optind' and `nextchar' so that the next call to `getopt' can
resume the scan with the following option character or ARGV-element.
If there are no more option characters, `getopt' returns -1.
Then `optind' is the index in ARGV of the first ARGV-element
that is not an option. (The ARGV-elements have been permuted
so that those that are not options now come last.)
OPTSTRING is a string containing the legitimate option characters.
If an option character is seen that is not listed in OPTSTRING,
return '?' after printing an error message. If you set `opterr' to
zero, the error message is suppressed but we still return '?'.
If a char in OPTSTRING is followed by a colon, that means it wants an arg,
so the following text in the same ARGV-element, or the text of the following
ARGV-element, is returned in `optarg'. Two colons mean an option that
wants an optional arg; if there is text in the current ARGV-element,
it is returned in `optarg', otherwise `optarg' is set to zero.
If OPTSTRING starts with `-' or `+', it requests different methods of
handling the non-option ARGV-elements.
See the comments about RETURN_IN_ORDER and REQUIRE_ORDER, above.
Long-named options begin with `--' instead of `-'.
Their names may be abbreviated as long as the abbreviation is unique
or is an exact match for some defined option. If they have an
argument, it follows the option name in the same ARGV-element, separated
from the option name by a `=', or else the in next ARGV-element.
When `getopt' finds a long-named option, it returns 0 if that option's
`flag' field is nonzero, the value of the option's `val' field
if the `flag' field is zero.
The elements of ARGV aren't really const, because we permute them.
But we pretend they're const in the prototype to be compatible
with other systems.
LONGOPTS is a vector of `struct option' terminated by an
element containing a name which is zero.
LONGIND returns the index in LONGOPT of the long-named option found.
It is only valid when a long-named option has been found by the most
recent call.
If LONG_ONLY is nonzero, '-' as well as '--' can introduce
long-named options. */
int
{
if (argc < 1)
return -1;
if (d->optind == 0 || !d->__initialized)
{
if (d->optind == 0)
d->__initialized = 1;
}
optstring++;
if (optstring[0] == ':')
print_errors = 0;
/* Test whether ARGV[optind] points to a non-option argument.
Either it does not have option syntax, or there is an environment flag
from the shell indicating it is not an option. The later information
is only used when the used in the GNU libc. */
#if defined _LIBC && defined USE_NONOPTION_FLAGS
|| (d->optind < d->__nonoption_flags_len \
#else
#endif
{
/* Advance to the next ARGV-element. */
/* Give FIRST_NONOPT & LAST_NONOPT rational values if OPTIND has been
moved back by the user (who may also have changed the arguments). */
if (d->__last_nonopt > d->optind)
d->__last_nonopt = d->optind;
if (d->__first_nonopt > d->optind)
d->__first_nonopt = d->optind;
if (d->__ordering == PERMUTE)
{
/* If we have just processed some options following some non-options,
exchange them so that the options come first. */
if (d->__first_nonopt != d->__last_nonopt
&& d->__last_nonopt != d->optind)
else if (d->__last_nonopt != d->optind)
d->__first_nonopt = d->optind;
/* Skip any additional non-options
and extend the range of non-options previously skipped. */
d->optind++;
d->__last_nonopt = d->optind;
}
/* The special ARGV-element `--' means premature end of options.
Skip it like a null option,
then exchange with previous non-options as if it were an option,
then skip everything else like a non-option. */
{
d->optind++;
if (d->__first_nonopt != d->__last_nonopt
&& d->__last_nonopt != d->optind)
else if (d->__first_nonopt == d->__last_nonopt)
d->__first_nonopt = d->optind;
d->__last_nonopt = argc;
}
/* If we have done all the ARGV-elements, stop the scan
and back over any non-options that we skipped and permuted. */
{
/* Set the next-arg-index to point at the non-options
that we previously skipped, so the caller will digest them. */
if (d->__first_nonopt != d->__last_nonopt)
d->optind = d->__first_nonopt;
return -1;
}
/* If we have come to a non-option and did not permute it,
either stop the scan or describe it to the caller and pass it by. */
if (NONOPTION_P)
{
if (d->__ordering == REQUIRE_ORDER)
return -1;
return 1;
}
/* We have found another option-ARGV-element.
Skip the initial punctuation. */
}
/* Decode the current option-ARGV-element. */
/* Check whether the ARGV-element is a long option.
If long_only and the ARGV-element has the form "-f", where f is
a valid short option, don't consider it an abbreviated form of
a long option that starts with f. Otherwise there would be no
way to give the -f short option.
On the other hand, if there's a long option "fubar" and
the ARGV-element is "-fu", do consider that an abbreviation of
the long option, just like "--fu", and not "-f" with arg "u".
This distinction seems to be the most useful approach. */
{
char *nameend;
const struct option *p;
int exact = 0;
int ambig = 0;
int option_index;
/* Do nothing. */ ;
/* Test all long options for either exact match
or abbreviated matches. */
{
if ((unsigned int) (nameend - d->__nextchar)
{
/* Exact match found. */
pfound = p;
exact = 1;
break;
}
{
/* First nonexact match found. */
pfound = p;
}
else if (long_only
/* Second or later nonexact match found. */
ambig = 1;
}
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
{
}
#else
#endif
}
d->optind++;
d->optopt = 0;
return '?';
}
{
d->optind++;
if (*nameend)
{
/* Don't test has_arg with >, because some C compilers don't
allow it to be used on enums. */
else
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
int n;
#endif
{
/* --option */
#if defined _LIBC && defined USE_IN_LIBIO
%s: option '--%s' doesn't allow an argument\n"),
#else
%s: option '--%s' doesn't allow an argument\n"),
#endif
}
else
{
/* +option or -option */
#if defined _LIBC && defined USE_IN_LIBIO
%s: option '%c%s' doesn't allow an argument\n"),
#else
%s: option '%c%s' doesn't allow an argument\n"),
#endif
}
#if defined _LIBC && defined USE_IN_LIBIO
if (n >= 0)
{
}
#endif
}
return '?';
}
}
{
else
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
%s: option '--%s' requires an argument\n"),
{
}
#else
_("%s: option '--%s' requires an argument\n"),
#endif
}
}
}
*longind = option_index;
{
return 0;
}
}
/* Can't find it as a long option. If this is not getopt_long_only,
or the option starts with '--' or is not a valid short
option, then it's an error.
Otherwise interpret it as a short option. */
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
int n;
#endif
{
/* --option */
#if defined _LIBC && defined USE_IN_LIBIO
argv[0], d->__nextchar);
#else
argv[0], d->__nextchar);
#endif
}
else
{
/* +option or -option */
#if defined _LIBC && defined USE_IN_LIBIO
#else
#endif
}
#if defined _LIBC && defined USE_IN_LIBIO
if (n >= 0)
{
}
#endif
}
d->__nextchar = (char *) "";
d->optind++;
d->optopt = 0;
return '?';
}
}
/* Look at and handle the next short option-character. */
{
char c = *d->__nextchar++;
/* Increment `optind' when we start to process its last character. */
if (*d->__nextchar == '\0')
++d->optind;
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
int n;
#endif
#if defined _LIBC && defined USE_IN_LIBIO
argv[0], c);
#else
#endif
#if defined _LIBC && defined USE_IN_LIBIO
if (n >= 0)
{
}
#endif
}
d->optopt = c;
return '?';
}
/* Convenience. Treat POSIX -W foo same as long option --foo */
{
char *nameend;
const struct option *p;
int exact = 0;
int ambig = 0;
int indfound = 0;
int option_index;
/* This is an option that requires an argument. */
if (*d->__nextchar != '\0')
{
d->optarg = d->__nextchar;
/* If we end this ARGV-element by taking the rest as an arg,
we must advance to the next element now. */
d->optind++;
}
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
if (__asprintf (&buf,
_("%s: option requires an argument -- '%c'\n"),
argv[0], c) >= 0)
{
}
#else
_("%s: option requires an argument -- '%c'\n"),
argv[0], c);
#endif
}
d->optopt = c;
if (optstring[0] == ':')
c = ':';
else
c = '?';
return c;
}
else
/* We already incremented `d->optind' once;
increment it again when taking next ARGV-elt as argument. */
/* optarg is now the argument, see if it's in the
table of longopts. */
nameend++)
/* Do nothing. */ ;
/* Test all long options for either exact match
or abbreviated matches. */
{
{
/* Exact match found. */
pfound = p;
exact = 1;
break;
}
{
/* First nonexact match found. */
pfound = p;
}
else if (long_only
/* Second or later nonexact match found. */
ambig = 1;
}
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
{
}
#else
#endif
}
d->optind++;
return '?';
}
{
if (*nameend)
{
/* Don't test has_arg with >, because some C compilers don't
allow it to be used on enums. */
else
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
%s: option '-W %s' doesn't allow an argument\n"),
{
}
#else
%s: option '-W %s' doesn't allow an argument\n"),
#endif
}
return '?';
}
}
{
else
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
%s: option '-W %s' requires an argument\n"),
{
}
#else
%s: option '-W %s' requires an argument\n"),
#endif
}
}
}
else
*longind = option_index;
{
return 0;
}
}
d->__nextchar = NULL;
return 'W'; /* Let the application handle it. */
}
{
{
/* This is an option that accepts an argument optionally. */
if (*d->__nextchar != '\0')
{
d->optarg = d->__nextchar;
d->optind++;
}
else
d->__nextchar = NULL;
}
else
{
/* This is an option that requires an argument. */
if (*d->__nextchar != '\0')
{
d->optarg = d->__nextchar;
/* If we end this ARGV-element by taking the rest as an arg,
we must advance to the next element now. */
d->optind++;
}
{
if (print_errors)
{
#if defined _LIBC && defined USE_IN_LIBIO
char *buf;
%s: option requires an argument -- '%c'\n"),
argv[0], c) >= 0)
{
}
#else
_("%s: option requires an argument -- '%c'\n"),
argv[0], c);
#endif
}
d->optopt = c;
if (optstring[0] == ':')
c = ':';
else
c = '?';
}
else
/* We already incremented `optind' once;
increment it again when taking next ARGV-elt as argument. */
d->__nextchar = NULL;
}
}
return c;
}
}
int
int posixly_correct)
{
int result;
return result;
}
/* glibc gets a LSB-compliant getopt.
Standalone applications get a POSIX-compliant getopt. */
#if _LIBC
enum { POSIXLY_CORRECT = 0 };
#else
#endif
int
{
(const struct option *) 0,
(int *) 0,
0, POSIXLY_CORRECT);
}
#ifdef _LIBC
int
{
(const struct option *) 0,
(int *) 0,
0, 1);
}
#endif
#ifdef TEST
/* Compile with -DTEST to make an executable for use in testing
the above definition of `getopt'. */
int
{
int c;
int digit_optind = 0;
while (1)
{
if (c == -1)
break;
switch (c)
{
case '0':
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
printf ("digits occur in two different argv-elements.\n");
printf ("option %c\n", c);
break;
case 'a':
printf ("option a\n");
break;
case 'b':
printf ("option b\n");
break;
case 'c':
break;
case '?':
break;
default:
printf ("?? getopt returned character code 0%o ??\n", c);
}
}
{
printf ("non-option ARGV-elements: ");
printf ("\n");
}
exit (0);
}
#endif /* TEST */