-/* Various functions of utilitarian nature.
- Copyright (C) 1995, 1996, 1997, 1998, 2000 Free Software Foundation, Inc.
+/* Various utility functions.
+ Copyright (C) 2005 Free Software Foundation, Inc.
-This file is part of Wget.
+This file is part of GNU Wget.
-This program is free software; you can redistribute it and/or modify
+GNU Wget is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
-This program is distributed in the hope that it will be useful,
+GNU Wget 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, write to the Free Software
-Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */
+along with Wget; if not, write to the Free Software
+Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
+
+In addition, as a special exception, the Free Software Foundation
+gives permission to link the code of its release of Wget with the
+OpenSSL project's "OpenSSL" library (or with modified versions of it
+that use the same license as the "OpenSSL" library), and distribute
+the linked executables. You must obey the GNU General Public License
+in all respects for all of the code used other than "OpenSSL". If you
+modify this file, you may extend this exception to your version of the
+file, but you are not obligated to do so. If you do not wish to do
+so, delete this exception statement from your version. */
#include <config.h>
#else /* not HAVE_STRING_H */
# include <strings.h>
#endif /* not HAVE_STRING_H */
-#include <ctype.h>
#include <sys/types.h>
#ifdef HAVE_UNISTD_H
# include <unistd.h>
#ifdef HAVE_PWD_H
# include <pwd.h>
#endif
-#include <limits.h>
+#ifdef HAVE_LIMITS_H
+# include <limits.h>
+#endif
#ifdef HAVE_UTIME_H
# include <utime.h>
#endif
#endif
#include <fcntl.h>
#include <assert.h>
+#ifdef WGET_USE_STDARG
+# include <stdarg.h>
+#else
+# include <varargs.h>
+#endif
+
+/* For TIOCGWINSZ and friends: */
+#ifdef HAVE_SYS_IOCTL_H
+# include <sys/ioctl.h>
+#endif
+#ifdef HAVE_TERMIOS_H
+# include <termios.h>
+#endif
+
+/* Needed for run_with_timeout. */
+#undef USE_SIGNAL_TIMEOUT
+#ifdef HAVE_SIGNAL_H
+# include <signal.h>
+#endif
+#ifdef HAVE_SETJMP_H
+# include <setjmp.h>
+#endif
+
+#ifndef HAVE_SIGSETJMP
+/* If sigsetjmp is a macro, configure won't pick it up. */
+# ifdef sigsetjmp
+# define HAVE_SIGSETJMP
+# endif
+#endif
+
+#ifdef HAVE_SIGNAL
+# ifdef HAVE_SIGSETJMP
+# define USE_SIGNAL_TIMEOUT
+# endif
+# ifdef HAVE_SIGBLOCK
+# define USE_SIGNAL_TIMEOUT
+# endif
+#endif
#include "wget.h"
#include "utils.h"
-#include "fnmatch.h"
#include "hash.h"
#ifndef errno
extern int errno;
#endif
-
-/* Croak the fatal memory error and bail out with non-zero exit
- status. */
-static void
-memfatal (const char *s)
-{
- /* HACK: expose save_log_p from log.c, so we can turn it off in
- order to prevent saving the log. Saving the log is dangerous
- because logprintf() and logputs() can call malloc(), so this
- could infloop. When logging is turned off, infloop can no longer
- happen. */
- extern int save_log_p;
-
- save_log_p = 0;
- logprintf (LOG_ALWAYS, _("%s: %s: Not enough memory.\n"), exec_name, s);
- exit (1);
-}
-
-/* xmalloc, xrealloc and xstrdup exit the program if there is not
- enough memory. xstrdup also implements strdup on systems that do
- not have it. */
-void *
-xmalloc (size_t size)
-{
- void *res;
-
- res = malloc (size);
- if (!res)
- memfatal ("malloc");
- return res;
-}
-
-void *
-xrealloc (void *obj, size_t size)
-{
- void *res;
-
- /* Not all Un*xes have the feature of realloc() that calling it with
- a NULL-pointer is the same as malloc(), but it is easy to
- simulate. */
- if (obj)
- res = realloc (obj, size);
- else
- res = malloc (size);
- if (!res)
- memfatal ("realloc");
- return res;
-}
+/* Utility function: like xstrdup(), but also lowercases S. */
char *
-xstrdup (const char *s)
+xstrdup_lower (const char *s)
{
-#ifndef HAVE_STRDUP
- int l = strlen (s);
- char *s1 = malloc (l + 1);
- if (!s1)
- memfatal ("strdup");
- memcpy (s1, s, l + 1);
- return s1;
-#else /* HAVE_STRDUP */
- char *s1 = strdup (s);
- if (!s1)
- memfatal ("strdup");
- return s1;
-#endif /* HAVE_STRDUP */
+ char *copy = xstrdup (s);
+ char *p = copy;
+ for (; *p; p++)
+ *p = TOLOWER (*p);
+ return copy;
}
-\f
+
/* Copy the string formed by two pointers (one on the beginning, other
on the char after the last char) to a new, malloc-ed location.
0-terminate it. */
return res;
}
\f
-/* Return pointer to a static char[] buffer in which zero-terminated
- string-representation of TM (in form hh:mm:ss) is printed. It is
- shamelessly non-reentrant, but it doesn't matter, really.
+#ifdef WGET_USE_STDARG
+# define VA_START(args, arg1) va_start (args, arg1)
+#else
+# define VA_START(args, ignored) va_start (args)
+#endif
+
+/* Like sprintf, but allocates a string of sufficient size with malloc
+ and returns it. GNU libc has a similar function named asprintf,
+ which requires the pointer to the string to be passed. */
- If TM is non-NULL, the time_t of the current time will be stored
- there. */
char *
-time_str (time_t *tm)
+aprintf (const char *fmt, ...)
{
- static char tms[15];
- struct tm *ptm;
- time_t tim;
+ /* This function is implemented using vsnprintf, which we provide
+ for the systems that don't have it. Therefore, it should be 100%
+ portable. */
+
+ int size = 32;
+ char *str = xmalloc (size);
+
+ while (1)
+ {
+ int n;
+ va_list args;
+
+ /* See log_vprintf_internal for explanation why it's OK to rely
+ on the return value of vsnprintf. */
+
+ VA_START (args, fmt);
+ n = vsnprintf (str, size, fmt, args);
+ va_end (args);
- *tms = '\0';
- tim = time (tm);
- if (tim == -1)
- return tms;
- ptm = localtime (&tim);
- sprintf (tms, "%02d:%02d:%02d", ptm->tm_hour, ptm->tm_min, ptm->tm_sec);
- return tms;
+ /* If the printing worked, return the string. */
+ if (n > -1 && n < size)
+ return str;
+
+ /* Else try again with a larger buffer. */
+ if (n > -1) /* C99 */
+ size = n + 1; /* precisely what is needed */
+ else
+ size <<= 1; /* twice the old size */
+ str = xrealloc (str, size);
+ }
+ return NULL; /* unreached */
}
-/* Returns an error message for ERRNUM. #### This requires more work.
- This function, as well as the whole error system, is very
- ill-conceived. */
-const char *
-uerrmsg (uerr_t errnum)
+/* Concatenate the NULL-terminated list of string arguments into
+ freshly allocated space. */
+
+char *
+concat_strings (const char *str0, ...)
{
- switch (errnum)
+ va_list args;
+ int saved_lengths[5]; /* inspired by Apache's apr_pstrcat */
+ char *ret, *p;
+
+ const char *next_str;
+ int total_length = 0;
+ int argcount;
+
+ /* Calculate the length of and allocate the resulting string. */
+
+ argcount = 0;
+ VA_START (args, str0);
+ for (next_str = str0; next_str != NULL; next_str = va_arg (args, char *))
{
- case URLUNKNOWN:
- return _("Unknown/unsupported protocol");
- break;
- case URLBADPORT:
- return _("Invalid port specification");
- break;
- case URLBADHOST:
- return _("Invalid host name");
- break;
- default:
- abort ();
- /* $@#@#$ compiler. */
- return NULL;
+ int len = strlen (next_str);
+ if (argcount < countof (saved_lengths))
+ saved_lengths[argcount++] = len;
+ total_length += len;
+ }
+ va_end (args);
+ p = ret = xmalloc (total_length + 1);
+
+ /* Copy the strings into the allocated space. */
+
+ argcount = 0;
+ VA_START (args, str0);
+ for (next_str = str0; next_str != NULL; next_str = va_arg (args, char *))
+ {
+ int len;
+ if (argcount < countof (saved_lengths))
+ len = saved_lengths[argcount++];
+ else
+ len = strlen (next_str);
+ memcpy (p, next_str, len);
+ p += len;
}
+ va_end (args);
+ *p = '\0';
+
+ return ret;
}
\f
-/* The Windows versions of the following two functions are defined in
- mswindows.c. */
+/* Return pointer to a static char[] buffer in which zero-terminated
+ string-representation of TM (in form hh:mm:ss) is printed.
-/* A cuserid() immitation using getpwuid(), to avoid hassling with
- utmp. Besides, not all systems have cuesrid(). Under Windows, it
- is defined in mswindows.c.
+ If TM is NULL, the current time will be used. */
- If WHERE is non-NULL, the username will be stored there.
- Otherwise, it will be returned as a static buffer (as returned by
- getpwuid()). In the latter case, the buffer should be copied
- before calling getpwuid() or pwd_cuserid() again. */
-#ifndef WINDOWS
char *
-pwd_cuserid (char *where)
+time_str (time_t *tm)
{
- struct passwd *pwd;
+ static char output[15];
+ struct tm *ptm;
+ time_t secs = tm ? *tm : time (NULL);
- if (!(pwd = getpwuid (getuid ())) || !pwd->pw_name)
- return NULL;
- if (where)
+ if (secs == -1)
{
- strcpy (where, pwd->pw_name);
- return where;
+ /* In case of error, return the empty string. Maybe we should
+ just abort if this happens? */
+ *output = '\0';
+ return output;
}
- else
- return pwd->pw_name;
+ ptm = localtime (&secs);
+ sprintf (output, "%02d:%02d:%02d", ptm->tm_hour, ptm->tm_min, ptm->tm_sec);
+ return output;
+}
+
+/* Like the above, but include the date: YYYY-MM-DD hh:mm:ss. */
+
+char *
+datetime_str (time_t *tm)
+{
+ static char output[20]; /* "YYYY-MM-DD hh:mm:ss" + \0 */
+ struct tm *ptm;
+ time_t secs = tm ? *tm : time (NULL);
+
+ if (secs == -1)
+ {
+ /* In case of error, return the empty string. Maybe we should
+ just abort if this happens? */
+ *output = '\0';
+ return output;
+ }
+ ptm = localtime (&secs);
+ sprintf (output, "%04d-%02d-%02d %02d:%02d:%02d",
+ ptm->tm_year + 1900, ptm->tm_mon + 1, ptm->tm_mday,
+ ptm->tm_hour, ptm->tm_min, ptm->tm_sec);
+ return output;
}
+\f
+/* The Windows versions of the following two functions are defined in
+ mswindows.c. */
+#ifndef WINDOWS
void
fork_to_background (void)
{
pid_t pid;
/* Whether we arrange our own version of opt.lfilename here. */
- int changedp = 0;
+ int logfile_changed = 0;
if (!opt.lfilename)
{
- opt.lfilename = unique_name (DEFAULT_LOGFILE);
- changedp = 1;
+ /* We must create the file immediately to avoid either a race
+ condition (which arises from using unique_name and failing to
+ use fopen_excl) or lying to the user about the log file name
+ (which arises from using unique_name, printing the name, and
+ using fopen_excl later on.) */
+ FILE *new_log_fp = unique_create (DEFAULT_LOGFILE, 0, &opt.lfilename);
+ if (new_log_fp)
+ {
+ logfile_changed = 1;
+ fclose (new_log_fp);
+ }
}
pid = fork ();
if (pid < 0)
else if (pid != 0)
{
/* parent, no error */
- printf (_("Continuing in background.\n"));
- if (changedp)
+ printf (_("Continuing in background, pid %d.\n"), (int)pid);
+ if (logfile_changed)
printf (_("Output will be written to `%s'.\n"), opt.lfilename);
- exit (0);
- }
- /* child: keep running */
-}
-#endif /* not WINDOWS */
-\f
-/* Canonicalize PATH, and return a new path. The new path differs from PATH
- in that:
- Multple `/'s are collapsed to a single `/'.
- Leading `./'s and trailing `/.'s are removed.
- Trailing `/'s are removed.
- Non-leading `../'s and trailing `..'s are handled by removing
- portions of the path.
-
- E.g. "a/b/c/./../d/.." will yield "a/b". This function originates
- from GNU Bash.
-
- Changes for Wget:
- Always use '/' as stub_char.
- Don't check for local things using canon_stat.
- Change the original string instead of strdup-ing.
- React correctly when beginning with `./' and `../'. */
-void
-path_simplify (char *path)
-{
- register int i, start, ddot;
- char stub_char;
-
- if (!*path)
- return;
-
- /*stub_char = (*path == '/') ? '/' : '.';*/
- stub_char = '/';
-
- /* Addition: Remove all `./'-s preceding the string. If `../'-s
- precede, put `/' in front and remove them too. */
- i = 0;
- ddot = 0;
- while (1)
- {
- if (path[i] == '.' && path[i + 1] == '/')
- i += 2;
- else if (path[i] == '.' && path[i + 1] == '.' && path[i + 2] == '/')
- {
- i += 3;
- ddot = 1;
- }
- else
- break;
- }
- if (i)
- strcpy (path, path + i - ddot);
-
- /* Replace single `.' or `..' with `/'. */
- if ((path[0] == '.' && path[1] == '\0')
- || (path[0] == '.' && path[1] == '.' && path[2] == '\0'))
- {
- path[0] = stub_char;
- path[1] = '\0';
- return;
+ exit (0); /* #### should we use _exit()? */
}
- /* Walk along PATH looking for things to compact. */
- i = 0;
- while (1)
- {
- if (!path[i])
- break;
-
- while (path[i] && path[i] != '/')
- i++;
-
- start = i++;
-
- /* If we didn't find any slashes, then there is nothing left to do. */
- if (!path[start])
- break;
-
- /* Handle multiple `/'s in a row. */
- while (path[i] == '/')
- i++;
-
- if ((start + 1) != i)
- {
- strcpy (path + start + 1, path + i);
- i = start + 1;
- }
-
- /* Check for trailing `/'. */
- if (start && !path[i])
- {
- zero_last:
- path[--i] = '\0';
- break;
- }
-
- /* Check for `../', `./' or trailing `.' by itself. */
- if (path[i] == '.')
- {
- /* Handle trailing `.' by itself. */
- if (!path[i + 1])
- goto zero_last;
-
- /* Handle `./'. */
- if (path[i + 1] == '/')
- {
- strcpy (path + i, path + i + 1);
- i = (start < 0) ? 0 : start;
- continue;
- }
-
- /* Handle `../' or trailing `..' by itself. */
- if (path[i + 1] == '.' &&
- (path[i + 2] == '/' || !path[i + 2]))
- {
- while (--start > -1 && path[start] != '/');
- strcpy (path + start + 1, path + i + 2);
- i = (start < 0) ? 0 : start;
- continue;
- }
- } /* path == '.' */
- } /* while */
- if (!*path)
- {
- *path = stub_char;
- path[1] = '\0';
- }
+ /* child: give up the privileges and keep running. */
+ setsid ();
+ freopen ("/dev/null", "r", stdin);
+ freopen ("/dev/null", "w", stdout);
+ freopen ("/dev/null", "w", stderr);
}
+#endif /* not WINDOWS */
\f
/* "Touch" FILE, i.e. make its atime and mtime equal to the time
specified with TM. */
remove_link (const char *file)
{
int err = 0;
- struct stat st;
+ struct_stat st;
if (lstat (file, &st) == 0 && S_ISLNK (st.st_mode))
{
#ifdef HAVE_ACCESS
return access (filename, F_OK) >= 0;
#else
- struct stat buf;
+ struct_stat buf;
return stat (filename, &buf) >= 0;
#endif
}
int
file_non_directory_p (const char *path)
{
- struct stat buf;
+ struct_stat buf;
/* Use lstat() rather than stat() so that symbolic links pointing to
directories can be identified correctly. */
if (lstat (path, &buf) != 0)
return S_ISDIR (buf.st_mode) ? 0 : 1;
}
-/* Return a unique filename, given a prefix and count */
+/* Return the size of file named by FILENAME, or -1 if it cannot be
+ opened or seeked into. */
+wgint
+file_size (const char *filename)
+{
+#if defined(HAVE_FSEEKO) && defined(HAVE_FTELLO)
+ wgint size;
+ /* We use fseek rather than stat to determine the file size because
+ that way we can also verify that the file is readable without
+ explicitly checking for permissions. Inspired by the POST patch
+ by Arnaud Wylie. */
+ FILE *fp = fopen (filename, "rb");
+ if (!fp)
+ return -1;
+ fseeko (fp, 0, SEEK_END);
+ size = ftello (fp);
+ fclose (fp);
+ return size;
+#else
+ struct_stat st;
+ if (stat (filename, &st) < 0)
+ return -1;
+ return st.st_size;
+#endif
+}
+
+/* stat file names named PREFIX.1, PREFIX.2, etc., until one that
+ doesn't exist is found. Return a freshly allocated copy of the
+ unused file name. */
+
static char *
-unique_name_1 (const char *fileprefix, int count)
+unique_name_1 (const char *prefix)
+{
+ int count = 1;
+ int plen = strlen (prefix);
+ char *template = (char *)alloca (plen + 1 + 24);
+ char *template_tail = template + plen;
+
+ memcpy (template, prefix, plen);
+ *template_tail++ = '.';
+
+ do
+ number_to_string (template_tail, count++);
+ while (file_exists_p (template));
+
+ return xstrdup (template);
+}
+
+/* Return a unique file name, based on FILE.
+
+ More precisely, if FILE doesn't exist, it is returned unmodified.
+ If not, FILE.1 is tried, then FILE.2, etc. The first FILE.<number>
+ file name that doesn't exist is returned.
+
+ The resulting file is not created, only verified that it didn't
+ exist at the point in time when the function was called.
+ Therefore, where security matters, don't rely that the file created
+ by this function exists until you open it with O_EXCL or
+ equivalent.
+
+ If ALLOW_PASSTHROUGH is 0, it always returns a freshly allocated
+ string. Otherwise, it may return FILE if the file doesn't exist
+ (and therefore doesn't need changing). */
+
+char *
+unique_name (const char *file, int allow_passthrough)
{
- char *filename;
+ /* If the FILE itself doesn't exist, return it without
+ modification. */
+ if (!file_exists_p (file))
+ return allow_passthrough ? (char *)file : xstrdup (file);
+
+ /* Otherwise, find a numeric suffix that results in unused file name
+ and return it. */
+ return unique_name_1 (file);
+}
- if (count)
+/* Create a file based on NAME, except without overwriting an existing
+ file with that name. Providing O_EXCL is correctly implemented,
+ this function does not have the race condition associated with
+ opening the file returned by unique_name. */
+
+FILE *
+unique_create (const char *name, int binary, char **opened_name)
+{
+ /* unique file name, based on NAME */
+ char *uname = unique_name (name, 0);
+ FILE *fp;
+ while ((fp = fopen_excl (uname, binary)) == NULL && errno == EEXIST)
{
- filename = (char *)xmalloc (strlen (fileprefix) + numdigit (count) + 2);
- sprintf (filename, "%s.%d", fileprefix, count);
+ xfree (uname);
+ uname = unique_name (name, 0);
}
- else
- filename = xstrdup (fileprefix);
-
- if (!file_exists_p (filename))
- return filename;
- else
+ if (opened_name && fp != NULL)
{
- free (filename);
- return NULL;
+ if (fp)
+ *opened_name = uname;
+ else
+ {
+ *opened_name = NULL;
+ xfree (uname);
+ }
}
+ else
+ xfree (uname);
+ return fp;
}
-/* Return a unique file name, based on PREFIX. */
-char *
-unique_name (const char *prefix)
+/* Open the file for writing, with the addition that the file is
+ opened "exclusively". This means that, if the file already exists,
+ this function will *fail* and errno will be set to EEXIST. If
+ BINARY is set, the file will be opened in binary mode, equivalent
+ to fopen's "wb".
+
+ If opening the file fails for any reason, including the file having
+ previously existed, this function returns NULL and sets errno
+ appropriately. */
+
+FILE *
+fopen_excl (const char *fname, int binary)
{
- char *file = NULL;
- int count = 0;
-
- while (!file)
- file = unique_name_1 (prefix, count++);
- return file;
+ int fd;
+#ifdef O_EXCL
+ int flags = O_WRONLY | O_CREAT | O_EXCL;
+# ifdef O_BINARY
+ if (binary)
+ flags |= O_BINARY;
+# endif
+ fd = open (fname, flags, 0666);
+ if (fd < 0)
+ return NULL;
+ return fdopen (fd, binary ? "wb" : "w");
+#else /* not O_EXCL */
+ /* Manually check whether the file exists. This is prone to race
+ conditions, but systems without O_EXCL haven't deserved
+ better. */
+ if (file_exists_p (fname))
+ {
+ errno = EEXIST;
+ return NULL;
+ }
+ return fopen (fname, binary ? "wb" : "w");
+#endif /* not O_EXCL */
}
\f
/* Create DIRECTORY. If some of the pathname components of DIRECTORY
int
make_directory (const char *directory)
{
- int quit = 0;
- int i;
+ int i, ret, quit = 0;
char *dir;
/* Make a copy of dir, to be able to write to it. Otherwise, the
if (!dir[i])
quit = 1;
dir[i] = '\0';
- /* Check whether the directory already exists. */
+ /* Check whether the directory already exists. Allow creation of
+ of intermediate directories to fail, as the initial path components
+ are not necessarily directories! */
if (!file_exists_p (dir))
- {
- if (mkdir (dir, 0777) < 0)
- return -1;
- }
+ ret = mkdir (dir, 0777);
+ else
+ ret = 0;
if (quit)
break;
else
dir[i] = '/';
}
- return 0;
+ return ret;
+}
+
+/* Merge BASE with FILE. BASE can be a directory or a file name, FILE
+ should be a file name.
+
+ file_merge("/foo/bar", "baz") => "/foo/baz"
+ file_merge("/foo/bar/", "baz") => "/foo/bar/baz"
+ file_merge("foo", "bar") => "bar"
+
+ In other words, it's a simpler and gentler version of uri_merge_1. */
+
+char *
+file_merge (const char *base, const char *file)
+{
+ char *result;
+ const char *cut = (const char *)strrchr (base, '/');
+
+ if (!cut)
+ return xstrdup (file);
+
+ result = (char *)xmalloc (cut - base + 1 + strlen (file) + 1);
+ memcpy (result, base, cut - base);
+ result[cut - base] = '/';
+ strcpy (result + (cut - base) + 1, file);
+
+ return result;
}
\f
static int in_acclist PARAMS ((const char *const *, const char *, int));
return 1;
}
-/* Match the end of STRING against PATTERN. For instance:
+/* Return non-zero if STRING ends with TAIL. For instance:
- match_backwards ("abc", "bc") -> 1
- match_backwards ("abc", "ab") -> 0
- match_backwards ("abc", "abc") -> 1 */
-static int
-match_backwards (const char *string, const char *pattern)
+ match_tail ("abc", "bc", 0) -> 1
+ match_tail ("abc", "ab", 0) -> 0
+ match_tail ("abc", "abc", 0) -> 1
+
+ If FOLD_CASE_P is non-zero, the comparison will be
+ case-insensitive. */
+
+int
+match_tail (const char *string, const char *tail, int fold_case_p)
{
int i, j;
- for (i = strlen (string), j = strlen (pattern); i >= 0 && j >= 0; i--, j--)
- if (string[i] != pattern[j])
- break;
- /* If the pattern was exhausted, the match was succesful. */
+ /* We want this to be fast, so we code two loops, one with
+ case-folding, one without. */
+
+ if (!fold_case_p)
+ {
+ for (i = strlen (string), j = strlen (tail); i >= 0 && j >= 0; i--, j--)
+ if (string[i] != tail[j])
+ break;
+ }
+ else
+ {
+ for (i = strlen (string), j = strlen (tail); i >= 0 && j >= 0; i--, j--)
+ if (TOLOWER (string[i]) != TOLOWER (tail[j]))
+ break;
+ }
+
+ /* If the tail was exhausted, the match was succesful. */
if (j == -1)
return 1;
else
}
/* Checks whether string S matches each element of ACCEPTS. A list
- element are matched either with fnmatch() or match_backwards(),
+ element are matched either with fnmatch() or match_tail(),
according to whether the element contains wildcards or not.
If the BACKWARD is 0, don't do backward comparison -- just compare
{
if (backward)
{
- if (match_backwards (s, *accepts))
+ if (match_tail (s, *accepts, 0))
return 1;
}
else
return 0;
}
-/* Return the malloc-ed suffix of STR. For instance:
+/* Return the location of STR's suffix (file extension). Examples:
suffix ("foo.bar") -> "bar"
suffix ("foo.bar.baz") -> "baz"
suffix ("/foo/bar") -> NULL
{
int i;
- for (i = strlen (str); i && str[i] != '/' && str[i] != '.'; i--);
+ for (i = strlen (str); i && str[i] != '/' && str[i] != '.'; i--)
+ ;
+
if (str[i++] == '.')
- return xstrdup (str + i);
+ return (char *)str + i;
else
return NULL;
}
-/* Read a line from FP. The function reallocs the storage as needed
- to accomodate for any length of the line. Reallocs are done
- storage exponentially, doubling the storage after each overflow to
- minimize the number of calls to realloc() and fgets(). The newline
- character at the end of line is retained.
+/* Return non-zero if S contains globbing wildcards (`*', `?', `[' or
+ `]'). */
+
+int
+has_wildcards_p (const char *s)
+{
+ for (; *s; s++)
+ if (*s == '*' || *s == '?' || *s == '[' || *s == ']')
+ return 1;
+ return 0;
+}
+
+/* Return non-zero if FNAME ends with a typical HTML suffix. The
+ following (case-insensitive) suffixes are presumed to be HTML files:
+
+ html
+ htm
+ ?html (`?' matches one character)
+
+ #### CAVEAT. This is not necessarily a good indication that FNAME
+ refers to a file that contains HTML! */
+int
+has_html_suffix_p (const char *fname)
+{
+ char *suf;
+
+ if ((suf = suffix (fname)) == NULL)
+ return 0;
+ if (!strcasecmp (suf, "html"))
+ return 1;
+ if (!strcasecmp (suf, "htm"))
+ return 1;
+ if (suf[0] && !strcasecmp (suf + 1, "html"))
+ return 1;
+ return 0;
+}
+
+/* Read a line from FP and return the pointer to freshly allocated
+ storage. The storage space is obtained through malloc() and should
+ be freed with free() when it is no longer needed.
+
+ The length of the line is not limited, except by available memory.
+ The newline character at the end of line is retained. The line is
+ terminated with a zero character.
After end-of-file is encountered without anything being read, NULL
is returned. NULL is also returned on error. To distinguish
read_whole_line (FILE *fp)
{
int length = 0;
- int bufsize = 81;
+ int bufsize = 82;
char *line = (char *)xmalloc (bufsize);
while (fgets (line + length, bufsize - length, fp))
{
length += strlen (line + length);
- assert (length > 0);
+ if (length == 0)
+ /* Possible for example when reading from a binary file where
+ a line begins with \0. */
+ continue;
+
if (line[length - 1] == '\n')
break;
+
/* fgets() guarantees to read the whole line, or to use up the
space we've given it. We can double the buffer
unconditionally. */
}
if (length == 0 || ferror (fp))
{
- free (line);
+ xfree (line);
return NULL;
}
if (length + 1 < bufsize)
fd = open (file, O_RDONLY);
if (fd < 0)
return NULL;
- fm = xmalloc (sizeof (struct file_memory));
+ fm = xnew (struct file_memory);
#ifdef HAVE_MMAP
{
- struct stat buf;
+ struct_stat buf;
if (fstat (fd, &buf) < 0)
goto mmap_lose;
fm->length = buf.st_size;
efficiency, but at some cost to generality. */
fm->content = mmap (NULL, fm->length, PROT_READ | PROT_WRITE,
MAP_PRIVATE, fd, 0);
- if (fm->content == MAP_FAILED)
+ if (fm->content == (char *)MAP_FAILED)
goto mmap_lose;
if (!inhibit_close)
close (fd);
fm->content = xmalloc (size);
while (1)
{
- long nread;
+ wgint nread;
if (fm->length > size / 2)
{
/* #### I'm not sure whether the whole exponential-growth
/* Normally, we grow SIZE exponentially to make the number
of calls to read() and realloc() logarithmic in relation
to file size. However, read() can read an amount of data
- smaller than requested, and it would be unreasonably to
+ smaller than requested, and it would be unreasonable to
double SIZE every time *something* was read. Therefore,
we double SIZE only when the length exceeds half of the
entire allocated size. */
lose:
if (!inhibit_close)
close (fd);
- free (fm->content);
- free (fm);
+ xfree (fm->content);
+ xfree (fm);
return NULL;
}
/* Release the resources held by FM. Specifically, this calls
- munmap() or free() on fm->content, depending whether mmap or
+ munmap() or xfree() on fm->content, depending whether mmap or
malloc/read were used to read in the file. It also frees the
memory needed to hold the FM structure itself. */
else
#endif
{
- free (fm->content);
+ xfree (fm->content);
}
- free (fm);
+ xfree (fm);
}
\f
/* Free the pointers in a NULL-terminated vector of pointers, then
{
char **p = vec;
while (*p)
- free (*p++);
- free (vec);
+ xfree (*p++);
+ xfree (vec);
}
}
if (!*v2)
{
/* To avoid j == 0 */
- free (v2);
+ xfree (v2);
return v1;
}
/* Count v1. */
/* Reallocate v1. */
v1 = (char **)xrealloc (v1, (i + j + 1) * sizeof (char **));
memcpy (v1 + i, v2, (j + 1) * sizeof (char *));
- free (v2);
+ xfree (v2);
return v1;
}
-
-/* A set of simple-minded routines to store strings in a linked list.
- This used to also be used for searching, but now we have hash
- tables for that. */
-
-/* Append an element to the list. */
-slist *
-slist_append (slist *l, const char *s)
-{
- slist *newel = (slist *)xmalloc (sizeof (slist));
- slist *beg = l;
-
- newel->string = xstrdup (s);
- newel->next = NULL;
-
- if (!l)
- return newel;
- /* Find the last element. */
- while (l->next)
- l = l->next;
- l->next = newel;
- return beg;
-}
-
-/* Is there a specific entry in the list? */
-int
-slist_contains (slist *l, const char *s)
-{
- for (; l; l = l->next)
- if (!strcmp (l->string, s))
- return 1;
- return 0;
-}
-
-/* Free the whole slist. */
-void
-slist_free (slist *l)
-{
- slist *n;
-
- while (l)
- {
- n = l->next;
- free (l->string);
- free (l);
- l = n;
- }
-}
\f
/* Sometimes it's useful to create "sets" of strings, i.e. special
hash tables where you want to store strings as keys and merely
void
string_set_add (struct hash_table *ht, const char *s)
{
+ /* First check whether the set element already exists. If it does,
+ do nothing so that we don't have to free() the old element and
+ then strdup() a new one. */
+ if (hash_table_contains (ht, s))
+ return;
+
/* We use "1" as value. It provides us a useful and clear arbitrary
value, and it consumes no memory -- the pointers to the same
- string "1" will be shared by all the key-value pairs in the hash
- table. */
+ string "1" will be shared by all the key-value pairs in all `set'
+ hash tables. */
hash_table_put (ht, xstrdup (s), "1");
}
+/* Synonym for hash_table_contains... */
+
int
-string_set_exists (struct hash_table *ht, const char *s)
+string_set_contains (struct hash_table *ht, const char *s)
+{
+ return hash_table_contains (ht, s);
+}
+
+static int
+string_set_to_array_mapper (void *key, void *value_ignored, void *arg)
{
- return hash_table_exists (ht, s);
+ char ***arrayptr = (char ***) arg;
+ *(*arrayptr)++ = (char *) key;
+ return 0;
+}
+
+/* Convert the specified string set to array. ARRAY should be large
+ enough to hold hash_table_count(ht) char pointers. */
+
+void string_set_to_array (struct hash_table *ht, char **array)
+{
+ hash_table_map (ht, string_set_to_array_mapper, &array);
}
static int
string_set_free_mapper (void *key, void *value_ignored, void *arg_ignored)
{
- free (key);
+ xfree (key);
return 0;
}
static int
free_keys_and_values_mapper (void *key, void *value, void *arg_ignored)
{
- free (key);
- free (value);
+ xfree (key);
+ xfree (value);
return 0;
}
}
\f
-/* Engine for legible and legible_long_long; this function works on
- strings. */
+/* Add thousand separators to a number already in string form. Used
+ by with_thousand_seps and with_thousand_seps_large. */
static char *
-legible_1 (const char *repr)
+add_thousand_seps (const char *repr)
{
- static char outbuf[128];
+ static char outbuf[48];
int i, i1, mod;
char *outptr;
const char *inptr;
/* Reset the pointers. */
outptr = outbuf;
inptr = repr;
- /* If the number is negative, shift the pointers. */
+
+ /* Ignore the sign for the purpose of adding thousand
+ separators. */
if (*inptr == '-')
{
*outptr++ = '-';
return outbuf;
}
-/* Legible -- return a static pointer to the legibly printed long. */
+/* Return a static pointer to the number printed with thousand
+ separators inserted at the right places. */
+
char *
-legible (long l)
+with_thousand_seps (wgint l)
{
char inbuf[24];
/* Print the number into the buffer. */
- long_to_string (inbuf, l);
- return legible_1 (inbuf);
+ number_to_string (inbuf, l);
+ return add_thousand_seps (inbuf);
}
-/* The same as legible(), but works on VERY_LONG_TYPE. See sysdep.h. */
-char *
-legible_very_long (VERY_LONG_TYPE l)
+/* Write a string representation of LARGE_INT NUMBER into the provided
+ buffer.
+
+ It would be dangerous to use sprintf, because the code wouldn't
+ work on a machine with gcc-provided long long support, but without
+ libc support for "%lld". However, such old systems platforms
+ typically lack snprintf and will end up using our version, which
+ does support "%lld" whereever long longs are available. */
+
+static void
+large_int_to_string (char *buffer, int bufsize, LARGE_INT number)
{
- char inbuf[128];
- /* Print the number into the buffer. */
- sprintf (inbuf, VERY_LONG_FORMAT, l);
- return legible_1 (inbuf);
+ snprintf (buffer, bufsize, LARGE_INT_FMT, number);
}
-/* Count the digits in a (long) integer. */
-int
-numdigit (long a)
+/* The same as with_thousand_seps, but works on LARGE_INT. */
+
+char *
+with_thousand_seps_large (LARGE_INT l)
{
- int res = 1;
- while ((a /= 10) != 0)
- ++res;
- return res;
+ char inbuf[48];
+ large_int_to_string (inbuf, sizeof (inbuf), l);
+ return add_thousand_seps (inbuf);
}
-/* Print NUMBER to BUFFER. This is equivalent to sprintf(buffer,
- "%ld", number), only much faster.
+/* N, a byte quantity, is converted to a human-readable abberviated
+ form a la sizes printed by `ls -lh'. The result is written to a
+ static buffer, a pointer to which is returned.
- BUFFER should accept 24 bytes. This should suffice for the longest
- numbers on 64-bit machines, including the `-' sign and the trailing
- \0. */
-void
-long_to_string (char *buffer, long number)
+ Unlike `with_thousand_seps', this approximates to the nearest unit.
+ Quoting GNU libit: "Most people visually process strings of 3-4
+ digits effectively, but longer strings of digits are more prone to
+ misinterpretation. Hence, converting to an abbreviated form
+ usually improves readability."
+
+ This intentionally uses kilobyte (KB), megabyte (MB), etc. in their
+ original computer science meaning of "multiples of 1024".
+ Multiples of 1000 would be useless since Wget already adds thousand
+ separators for legibility. We don't use the "*bibyte" names
+ invented in 1998, and seldom used in practice. Wikipedia's entry
+ on kilobyte discusses this in some detail. */
+
+char *
+human_readable (wgint n)
{
-#if (SIZEOF_LONG != 4) && (SIZEOF_LONG != 8)
- /* Huh? */
- sprintf (buffer, "%ld", number);
-#else /* (SIZEOF_LONG == 4) || (SIZEOF_LONG == 8) */
- char *p = buffer;
- int force = 0;
+ /* These suffixes are compatible with those of GNU `ls -lh'. */
+ static char powers[] =
+ {
+ 'K', /* kilobyte, 2^10 bytes */
+ 'M', /* megabyte, 2^20 bytes */
+ 'G', /* gigabyte, 2^30 bytes */
+ 'T', /* terabyte, 2^40 bytes */
+ 'P', /* petabyte, 2^50 bytes */
+ 'E', /* exabyte, 2^60 bytes */
+ };
+ static char buf[8];
+ int i;
+
+ /* If the quantity is smaller than 1K, just print it. */
+ if (n < 1024)
+ {
+ snprintf (buf, sizeof (buf), "%d", (int) n);
+ return buf;
+ }
+ /* Loop over powers, dividing N with 1024 in each iteration. This
+ works unchanged for all sizes of wgint, while still avoiding
+ non-portable `long double' arithmetic. */
+ for (i = 0; i < countof (powers); i++)
+ {
+ /* At each iteration N is greater than the *subsequent* power.
+ That way N/1024.0 produces a decimal number in the units of
+ *this* power. */
+ if ((n >> 10) < 1024 || i == countof (powers) - 1)
+ {
+ /* Must cast to long first because MS VC can't directly cast
+ __int64 to double. (This is safe because N is known to
+ be <2**20.) */
+ double val = (double) (long) n / 1024.0;
+ /* Print values smaller than 10 with one decimal digits, and
+ others without any decimals. */
+ snprintf (buf, sizeof (buf), "%.*f%c",
+ val < 10 ? 1 : 0, val, powers[i]);
+ return buf;
+ }
+ n >>= 10;
+ }
+ return NULL; /* unreached */
+}
+
+/* Count the digits in the provided number. Used to allocate space
+ when printing numbers. */
+
+int
+numdigit (wgint number)
+{
+ int cnt = 1;
if (number < 0)
+ ++cnt; /* accomodate '-' */
+ while ((number /= 10) != 0)
+ ++cnt;
+ return cnt;
+}
+
+#define PR(mask) *p++ = n / (mask) + '0'
+
+/* DIGITS_<D> is used to print a D-digit number and should be called
+ with mask==10^(D-1). It prints n/mask (the first digit), reducing
+ n to n%mask (the remaining digits), and calling DIGITS_<D-1>.
+ Recursively this continues until DIGITS_1 is invoked. */
+
+#define DIGITS_1(mask) PR (mask)
+#define DIGITS_2(mask) PR (mask), n %= (mask), DIGITS_1 ((mask) / 10)
+#define DIGITS_3(mask) PR (mask), n %= (mask), DIGITS_2 ((mask) / 10)
+#define DIGITS_4(mask) PR (mask), n %= (mask), DIGITS_3 ((mask) / 10)
+#define DIGITS_5(mask) PR (mask), n %= (mask), DIGITS_4 ((mask) / 10)
+#define DIGITS_6(mask) PR (mask), n %= (mask), DIGITS_5 ((mask) / 10)
+#define DIGITS_7(mask) PR (mask), n %= (mask), DIGITS_6 ((mask) / 10)
+#define DIGITS_8(mask) PR (mask), n %= (mask), DIGITS_7 ((mask) / 10)
+#define DIGITS_9(mask) PR (mask), n %= (mask), DIGITS_8 ((mask) / 10)
+#define DIGITS_10(mask) PR (mask), n %= (mask), DIGITS_9 ((mask) / 10)
+
+/* DIGITS_<11-20> are only used on machines with 64-bit wgints. */
+
+#define DIGITS_11(mask) PR (mask), n %= (mask), DIGITS_10 ((mask) / 10)
+#define DIGITS_12(mask) PR (mask), n %= (mask), DIGITS_11 ((mask) / 10)
+#define DIGITS_13(mask) PR (mask), n %= (mask), DIGITS_12 ((mask) / 10)
+#define DIGITS_14(mask) PR (mask), n %= (mask), DIGITS_13 ((mask) / 10)
+#define DIGITS_15(mask) PR (mask), n %= (mask), DIGITS_14 ((mask) / 10)
+#define DIGITS_16(mask) PR (mask), n %= (mask), DIGITS_15 ((mask) / 10)
+#define DIGITS_17(mask) PR (mask), n %= (mask), DIGITS_16 ((mask) / 10)
+#define DIGITS_18(mask) PR (mask), n %= (mask), DIGITS_17 ((mask) / 10)
+#define DIGITS_19(mask) PR (mask), n %= (mask), DIGITS_18 ((mask) / 10)
+
+/* SPRINTF_WGINT is used by number_to_string to handle pathological
+ cases and to portably support strange sizes of wgint. Ideally this
+ would just use "%j" and intmax_t, but many systems don't support
+ it, so it's used only if nothing else works. */
+#if SIZEOF_LONG >= SIZEOF_WGINT
+# define SPRINTF_WGINT(buf, n) sprintf (buf, "%ld", (long) (n))
+#else
+# if SIZEOF_LONG_LONG >= SIZEOF_WGINT
+# define SPRINTF_WGINT(buf, n) sprintf (buf, "%lld", (long long) (n))
+# else
+# ifdef WINDOWS
+# define SPRINTF_WGINT(buf, n) sprintf (buf, "%I64", (__int64) (n))
+# else
+# define SPRINTF_WGINT(buf, n) sprintf (buf, "%j", (intmax_t) (n))
+# endif
+# endif
+#endif
+
+/* Shorthand for casting to wgint. */
+#define W wgint
+
+/* Print NUMBER to BUFFER in base 10. This is equivalent to
+ `sprintf(buffer, "%lld", (long long) number)', only typically much
+ faster and portable to machines without long long.
+
+ The speedup may make a difference in programs that frequently
+ convert numbers to strings. Some implementations of sprintf,
+ particularly the one in GNU libc, have been known to be extremely
+ slow when converting integers to strings.
+
+ Return the pointer to the location where the terminating zero was
+ printed. (Equivalent to calling buffer+strlen(buffer) after the
+ function is done.)
+
+ BUFFER should be big enough to accept as many bytes as you expect
+ the number to take up. On machines with 64-bit longs the maximum
+ needed size is 24 bytes. That includes the digits needed for the
+ largest 64-bit number, the `-' sign in case it's negative, and the
+ terminating '\0'. */
+
+char *
+number_to_string (char *buffer, wgint number)
+{
+ char *p = buffer;
+ wgint n = number;
+
+#if (SIZEOF_WGINT != 4) && (SIZEOF_WGINT != 8)
+ /* We are running in a strange or misconfigured environment. Let
+ sprintf cope with it. */
+ SPRINTF_WGINT (buffer, n);
+ p += strlen (buffer);
+#else /* (SIZEOF_WGINT == 4) || (SIZEOF_WGINT == 8) */
+
+ if (n < 0)
{
+ if (n < -WGINT_MAX)
+ {
+ /* -n would overflow. Have sprintf deal with this. */
+ SPRINTF_WGINT (buffer, n);
+ p += strlen (buffer);
+ return p;
+ }
+
*p++ = '-';
- number = -number;
+ n = -n;
}
-#define FROB(figure) do { \
- if (force || number >= figure) \
- *p++ = number / figure + '0', number %= figure, force = 1; \
- } while (0)
-#if SIZEOF_LONG == 8
- FROB (1000000000000000000L);
- FROB (100000000000000000L);
- FROB (10000000000000000L);
- FROB (1000000000000000L);
- FROB (100000000000000L);
- FROB (10000000000000L);
- FROB (1000000000000L);
- FROB (100000000000L);
- FROB (10000000000L);
-#endif /* SIZEOF_LONG == 8 */
- FROB (1000000000);
- FROB (100000000);
- FROB (10000000);
- FROB (1000000);
- FROB (100000);
- FROB (10000);
- FROB (1000);
- FROB (100);
- FROB (10);
-#undef FROB
- *p++ = number + '0';
+ /* Use the DIGITS_ macro appropriate for N's number of digits. That
+ way printing any N is fully open-coded without a loop or jump.
+ (Also see description of DIGITS_*.) */
+
+ if (n < 10) DIGITS_1 (1);
+ else if (n < 100) DIGITS_2 (10);
+ else if (n < 1000) DIGITS_3 (100);
+ else if (n < 10000) DIGITS_4 (1000);
+ else if (n < 100000) DIGITS_5 (10000);
+ else if (n < 1000000) DIGITS_6 (100000);
+ else if (n < 10000000) DIGITS_7 (1000000);
+ else if (n < 100000000) DIGITS_8 (10000000);
+ else if (n < 1000000000) DIGITS_9 (100000000);
+#if SIZEOF_WGINT == 4
+ /* wgint is 32 bits wide: no number has more than 10 digits. */
+ else DIGITS_10 (1000000000);
+#else
+ /* wgint is 64 bits wide: handle numbers with more than 9 decimal
+ digits. Constants are constructed by compile-time multiplication
+ to avoid dealing with different notations for 64-bit constants
+ (nnnL, nnnLL, and nnnI64, depending on the compiler). */
+ else if (n < 10*(W)1000000000) DIGITS_10 (1000000000);
+ else if (n < 100*(W)1000000000) DIGITS_11 (10*(W)1000000000);
+ else if (n < 1000*(W)1000000000) DIGITS_12 (100*(W)1000000000);
+ else if (n < 10000*(W)1000000000) DIGITS_13 (1000*(W)1000000000);
+ else if (n < 100000*(W)1000000000) DIGITS_14 (10000*(W)1000000000);
+ else if (n < 1000000*(W)1000000000) DIGITS_15 (100000*(W)1000000000);
+ else if (n < 10000000*(W)1000000000) DIGITS_16 (1000000*(W)1000000000);
+ else if (n < 100000000*(W)1000000000) DIGITS_17 (10000000*(W)1000000000);
+ else if (n < 1000000000*(W)1000000000) DIGITS_18 (100000000*(W)1000000000);
+ else DIGITS_19 (1000000000*(W)1000000000);
+#endif
+
*p = '\0';
-#endif /* (SIZEOF_LONG == 4) || (SIZEOF_LONG == 8) */
+#endif /* (SIZEOF_WGINT == 4) || (SIZEOF_WGINT == 8) */
+
+ return p;
+}
+
+#undef PR
+#undef W
+#undef DIGITS_1
+#undef DIGITS_2
+#undef DIGITS_3
+#undef DIGITS_4
+#undef DIGITS_5
+#undef DIGITS_6
+#undef DIGITS_7
+#undef DIGITS_8
+#undef DIGITS_9
+#undef DIGITS_10
+#undef DIGITS_11
+#undef DIGITS_12
+#undef DIGITS_13
+#undef DIGITS_14
+#undef DIGITS_15
+#undef DIGITS_16
+#undef DIGITS_17
+#undef DIGITS_18
+#undef DIGITS_19
+
+#define RING_SIZE 3
+
+/* Print NUMBER to a statically allocated string and return a pointer
+ to the printed representation.
+
+ This function is intended to be used in conjunction with printf.
+ It is hard to portably print wgint values:
+ a) you cannot use printf("%ld", number) because wgint can be long
+ long on 32-bit machines with LFS.
+ b) you cannot use printf("%lld", number) because NUMBER could be
+ long on 32-bit machines without LFS, or on 64-bit machines,
+ which do not require LFS. Also, Windows doesn't support %lld.
+ c) you cannot use printf("%j", (int_max_t) number) because not all
+ versions of printf support "%j", the most notable being the one
+ on Windows.
+ d) you cannot #define WGINT_FMT to the appropriate format and use
+ printf(WGINT_FMT, number) because that would break translations
+ for user-visible messages, such as printf("Downloaded: %d
+ bytes\n", number).
+
+ What you should use instead is printf("%s", number_to_static_string
+ (number)).
+
+ CAVEAT: since the function returns pointers to static data, you
+ must be careful to copy its result before calling it again.
+ However, to make it more useful with printf, the function maintains
+ an internal ring of static buffers to return. That way things like
+ printf("%s %s", number_to_static_string (num1),
+ number_to_static_string (num2)) work as expected. Three buffers
+ are currently used, which means that "%s %s %s" will work, but "%s
+ %s %s %s" won't. If you need to print more than three wgints,
+ bump the RING_SIZE (or rethink your message.) */
+
+char *
+number_to_static_string (wgint number)
+{
+ static char ring[RING_SIZE][24];
+ static int ringpos;
+ char *buf = ring[ringpos];
+ number_to_string (buf, number);
+ ringpos = (ringpos + 1) % RING_SIZE;
+ return buf;
+}
+\f
+/* Support for timers. */
+
+#undef TIMER_WINDOWS
+#undef TIMER_GETTIMEOFDAY
+#undef TIMER_TIME
+
+/* Depending on the OS and availability of gettimeofday(), one and
+ only one of the above constants will be defined. Virtually all
+ modern Unix systems will define TIMER_GETTIMEOFDAY; Windows will
+ use TIMER_WINDOWS. TIMER_TIME is a catch-all method for
+ non-Windows systems without gettimeofday. */
+
+#ifdef WINDOWS
+# define TIMER_WINDOWS
+#else /* not WINDOWS */
+# ifdef HAVE_GETTIMEOFDAY
+# define TIMER_GETTIMEOFDAY
+# else
+# define TIMER_TIME
+# endif
+#endif /* not WINDOWS */
+
+#ifdef TIMER_GETTIMEOFDAY
+typedef struct timeval wget_sys_time;
+#endif
+
+#ifdef TIMER_TIME
+typedef time_t wget_sys_time;
+#endif
+
+#ifdef TIMER_WINDOWS
+typedef union {
+ DWORD lores; /* In case GetTickCount is used */
+ LARGE_INTEGER hires; /* In case high-resolution timer is used */
+} wget_sys_time;
+#endif
+
+struct wget_timer {
+ /* Whether the start time has been initialized. */
+ int initialized;
+
+ /* The starting point in time which, subtracted from the current
+ time, yields elapsed time. */
+ wget_sys_time start;
+
+ /* The most recent elapsed time, calculated by wtimer_update().
+ Measured in milliseconds. */
+ double elapsed_last;
+
+ /* Approximately, the time elapsed between the true start of the
+ measurement and the time represented by START. */
+ double elapsed_pre_start;
+};
+
+#ifdef TIMER_WINDOWS
+
+/* Whether high-resolution timers are used. Set by wtimer_initialize_once
+ the first time wtimer_allocate is called. */
+static int using_hires_timers;
+
+/* Frequency of high-resolution timers -- number of updates per
+ millisecond. Calculated the first time wtimer_allocate is called
+ provided that high-resolution timers are available. */
+static double hires_millisec_freq;
+
+/* The first time a timer is created, determine whether to use
+ high-resolution timers. */
+
+static void
+wtimer_initialize_once (void)
+{
+ static int init_done;
+ if (!init_done)
+ {
+ LARGE_INTEGER freq;
+ init_done = 1;
+ freq.QuadPart = 0;
+ QueryPerformanceFrequency (&freq);
+ if (freq.QuadPart != 0)
+ {
+ using_hires_timers = 1;
+ hires_millisec_freq = (double) freq.QuadPart / 1000.0;
+ }
+ }
}
+#endif /* TIMER_WINDOWS */
+
+/* Allocate a timer. Calling wtimer_read on the timer will return
+ zero. It is not legal to call wtimer_update with a freshly
+ allocated timer -- use wtimer_reset first. */
+
+struct wget_timer *
+wtimer_allocate (void)
+{
+ struct wget_timer *wt = xnew (struct wget_timer);
+ xzero (*wt);
+
+#ifdef TIMER_WINDOWS
+ wtimer_initialize_once ();
+#endif
+
+ return wt;
+}
+
+/* Allocate a new timer and reset it. Return the new timer. */
+
+struct wget_timer *
+wtimer_new (void)
+{
+ struct wget_timer *wt = wtimer_allocate ();
+ wtimer_reset (wt);
+ return wt;
+}
+
+/* Free the resources associated with the timer. Its further use is
+ prohibited. */
+
+void
+wtimer_delete (struct wget_timer *wt)
+{
+ xfree (wt);
+}
+
+/* Store system time to WST. */
+
+static void
+wtimer_sys_set (wget_sys_time *wst)
+{
+#ifdef TIMER_GETTIMEOFDAY
+ gettimeofday (wst, NULL);
+#endif
+
+#ifdef TIMER_TIME
+ time (wst);
+#endif
+
+#ifdef TIMER_WINDOWS
+ if (using_hires_timers)
+ {
+ QueryPerformanceCounter (&wst->hires);
+ }
+ else
+ {
+ /* Where hires counters are not available, use GetTickCount rather
+ GetSystemTime, because it is unaffected by clock skew and simpler
+ to use. Note that overflows don't affect us because we never use
+ absolute values of the ticker, only the differences. */
+ wst->lores = GetTickCount ();
+ }
+#endif
+}
+
+/* Reset timer WT. This establishes the starting point from which
+ wtimer_read() will return the number of elapsed milliseconds.
+ It is allowed to reset a previously used timer. */
+
+void
+wtimer_reset (struct wget_timer *wt)
+{
+ /* Set the start time to the current time. */
+ wtimer_sys_set (&wt->start);
+ wt->elapsed_last = 0;
+ wt->elapsed_pre_start = 0;
+ wt->initialized = 1;
+}
+
+static double
+wtimer_sys_diff (wget_sys_time *wst1, wget_sys_time *wst2)
+{
+#ifdef TIMER_GETTIMEOFDAY
+ return ((double)(wst1->tv_sec - wst2->tv_sec) * 1000
+ + (double)(wst1->tv_usec - wst2->tv_usec) / 1000);
+#endif
+
+#ifdef TIMER_TIME
+ return 1000 * (*wst1 - *wst2);
+#endif
+
+#ifdef WINDOWS
+ if (using_hires_timers)
+ return (wst1->hires.QuadPart - wst2->hires.QuadPart) / hires_millisec_freq;
+ else
+ return wst1->lores - wst2->lores;
+#endif
+}
+
+/* Update the timer's elapsed interval. This function causes the
+ timer to call gettimeofday (or time(), etc.) to update its idea of
+ current time. To get the elapsed interval in milliseconds, use
+ wtimer_read.
+
+ This function handles clock skew, i.e. time that moves backwards is
+ ignored. */
+
+void
+wtimer_update (struct wget_timer *wt)
+{
+ wget_sys_time now;
+ double elapsed;
+
+ assert (wt->initialized != 0);
+
+ wtimer_sys_set (&now);
+ elapsed = wt->elapsed_pre_start + wtimer_sys_diff (&now, &wt->start);
+
+ /* Ideally we'd just return the difference between NOW and
+ wt->start. However, the system timer can be set back, and we
+ could return a value smaller than when we were last called, even
+ a negative value. Both of these would confuse the callers, which
+ expect us to return monotonically nondecreasing values.
+
+ Therefore: if ELAPSED is smaller than its previous known value,
+ we reset wt->start to the current time and effectively start
+ measuring from this point. But since we don't want the elapsed
+ value to start from zero, we set elapsed_pre_start to the last
+ elapsed time and increment all future calculations by that
+ amount. */
+
+ if (elapsed < wt->elapsed_last)
+ {
+ wt->start = now;
+ wt->elapsed_pre_start = wt->elapsed_last;
+ elapsed = wt->elapsed_last;
+ }
+
+ wt->elapsed_last = elapsed;
+}
+
+/* Return the elapsed time in milliseconds between the last call to
+ wtimer_reset and the last call to wtimer_update.
+
+ A typical use of the timer interface would be:
+
+ struct wtimer *timer = wtimer_new ();
+ ... do something that takes a while ...
+ wtimer_update ();
+ double msecs = wtimer_read (); */
+
+double
+wtimer_read (const struct wget_timer *wt)
+{
+ return wt->elapsed_last;
+}
+
+/* Return the assessed granularity of the timer implementation, in
+ milliseconds. This is used by code that tries to substitute a
+ better value for timers that have returned zero. */
+
+double
+wtimer_granularity (void)
+{
+#ifdef TIMER_GETTIMEOFDAY
+ /* Granularity of gettimeofday varies wildly between architectures.
+ However, it appears that on modern machines it tends to be better
+ than 1ms. Assume 100 usecs. (Perhaps the configure process
+ could actually measure this?) */
+ return 0.1;
+#endif
+
+#ifdef TIMER_TIME
+ return 1000;
+#endif
+
+#ifdef TIMER_WINDOWS
+ if (using_hires_timers)
+ return 1.0 / hires_millisec_freq;
+ else
+ return 10; /* according to MSDN */
+#endif
+}
+\f
+/* This should probably be at a better place, but it doesn't really
+ fit into html-parse.c. */
+
+/* The function returns the pointer to the malloc-ed quoted version of
+ string s. It will recognize and quote numeric and special graphic
+ entities, as per RFC1866:
+
+ `&' -> `&'
+ `<' -> `<'
+ `>' -> `>'
+ `"' -> `"'
+ SP -> ` '
+
+ No other entities are recognized or replaced. */
+char *
+html_quote_string (const char *s)
+{
+ const char *b = s;
+ char *p, *res;
+ int i;
+
+ /* Pass through the string, and count the new size. */
+ for (i = 0; *s; s++, i++)
+ {
+ if (*s == '&')
+ i += 4; /* `amp;' */
+ else if (*s == '<' || *s == '>')
+ i += 3; /* `lt;' and `gt;' */
+ else if (*s == '\"')
+ i += 5; /* `quot;' */
+ else if (*s == ' ')
+ i += 4; /* #32; */
+ }
+ res = (char *)xmalloc (i + 1);
+ s = b;
+ for (p = res; *s; s++)
+ {
+ switch (*s)
+ {
+ case '&':
+ *p++ = '&';
+ *p++ = 'a';
+ *p++ = 'm';
+ *p++ = 'p';
+ *p++ = ';';
+ break;
+ case '<': case '>':
+ *p++ = '&';
+ *p++ = (*s == '<' ? 'l' : 'g');
+ *p++ = 't';
+ *p++ = ';';
+ break;
+ case '\"':
+ *p++ = '&';
+ *p++ = 'q';
+ *p++ = 'u';
+ *p++ = 'o';
+ *p++ = 't';
+ *p++ = ';';
+ break;
+ case ' ':
+ *p++ = '&';
+ *p++ = '#';
+ *p++ = '3';
+ *p++ = '2';
+ *p++ = ';';
+ break;
+ default:
+ *p++ = *s;
+ }
+ }
+ *p = '\0';
+ return res;
+}
+
+/* Determine the width of the terminal we're running on. If that's
+ not possible, return 0. */
+
+int
+determine_screen_width (void)
+{
+ /* If there's a way to get the terminal size using POSIX
+ tcgetattr(), somebody please tell me. */
+#ifdef TIOCGWINSZ
+ int fd;
+ struct winsize wsz;
+
+ if (opt.lfilename != NULL)
+ return 0;
+
+ fd = fileno (stderr);
+ if (ioctl (fd, TIOCGWINSZ, &wsz) < 0)
+ return 0; /* most likely ENOTTY */
+
+ return wsz.ws_col;
+#else /* not TIOCGWINSZ */
+# ifdef WINDOWS
+ CONSOLE_SCREEN_BUFFER_INFO csbi;
+ if (!GetConsoleScreenBufferInfo (GetStdHandle (STD_ERROR_HANDLE), &csbi))
+ return 0;
+ return csbi.dwSize.X;
+# else /* neither WINDOWS nor TIOCGWINSZ */
+ return 0;
+#endif /* neither WINDOWS nor TIOCGWINSZ */
+#endif /* not TIOCGWINSZ */
+}
+
+/* Return a random number between 0 and MAX-1, inclusive.
+
+ If MAX is greater than the value of RAND_MAX+1 on the system, the
+ returned value will be in the range [0, RAND_MAX]. This may be
+ fixed in a future release.
+
+ The random number generator is seeded automatically the first time
+ it is called.
+
+ This uses rand() for portability. It has been suggested that
+ random() offers better randomness, but this is not required for
+ Wget, so I chose to go for simplicity and use rand
+ unconditionally.
+
+ DO NOT use this for cryptographic purposes. It is only meant to be
+ used in situations where quality of the random numbers returned
+ doesn't really matter. */
+
+int
+random_number (int max)
+{
+ static int seeded;
+ double bounded;
+ int rnd;
+
+ if (!seeded)
+ {
+ srand (time (NULL));
+ seeded = 1;
+ }
+ rnd = rand ();
+
+ /* On systems that don't define RAND_MAX, assume it to be 2**15 - 1,
+ and enforce that assumption by masking other bits. */
+#ifndef RAND_MAX
+# define RAND_MAX 32767
+ rnd &= RAND_MAX;
+#endif
+
+ /* This is equivalent to rand() % max, but uses the high-order bits
+ for better randomness on architecture where rand() is implemented
+ using a simple congruential generator. */
+
+ bounded = (double)max * rnd / (RAND_MAX + 1.0);
+ return (int)bounded;
+}
+
+/* Return a random uniformly distributed floating point number in the
+ [0, 1) range. The precision of returned numbers is 9 digits.
+
+ Modify this to use erand48() where available! */
+
+double
+random_float (void)
+{
+ /* We can't rely on any specific value of RAND_MAX, but I'm pretty
+ sure it's greater than 1000. */
+ int rnd1 = random_number (1000);
+ int rnd2 = random_number (1000);
+ int rnd3 = random_number (1000);
+ return rnd1 / 1000.0 + rnd2 / 1000000.0 + rnd3 / 1000000000.0;
+}
+\f
+/* Implementation of run_with_timeout, a generic timeout-forcing
+ routine for systems with Unix-like signal handling. */
+
+#ifdef USE_SIGNAL_TIMEOUT
+# ifdef HAVE_SIGSETJMP
+# define SETJMP(env) sigsetjmp (env, 1)
+
+static sigjmp_buf run_with_timeout_env;
+
+static RETSIGTYPE
+abort_run_with_timeout (int sig)
+{
+ assert (sig == SIGALRM);
+ siglongjmp (run_with_timeout_env, -1);
+}
+# else /* not HAVE_SIGSETJMP */
+# define SETJMP(env) setjmp (env)
+
+static jmp_buf run_with_timeout_env;
+
+static RETSIGTYPE
+abort_run_with_timeout (int sig)
+{
+ assert (sig == SIGALRM);
+ /* We don't have siglongjmp to preserve the set of blocked signals;
+ if we longjumped out of the handler at this point, SIGALRM would
+ remain blocked. We must unblock it manually. */
+ int mask = siggetmask ();
+ mask &= ~sigmask (SIGALRM);
+ sigsetmask (mask);
+
+ /* Now it's safe to longjump. */
+ longjmp (run_with_timeout_env, -1);
+}
+# endif /* not HAVE_SIGSETJMP */
+
+/* Arrange for SIGALRM to be delivered in TIMEOUT seconds. This uses
+ setitimer where available, alarm otherwise.
+
+ TIMEOUT should be non-zero. If the timeout value is so small that
+ it would be rounded to zero, it is rounded to the least legal value
+ instead (1us for setitimer, 1s for alarm). That ensures that
+ SIGALRM will be delivered in all cases. */
+
+static void
+alarm_set (double timeout)
+{
+#ifdef ITIMER_REAL
+ /* Use the modern itimer interface. */
+ struct itimerval itv;
+ xzero (itv);
+ itv.it_value.tv_sec = (long) timeout;
+ itv.it_value.tv_usec = 1000000 * (timeout - (long)timeout);
+ if (itv.it_value.tv_sec == 0 && itv.it_value.tv_usec == 0)
+ /* Ensure that we wait for at least the minimum interval.
+ Specifying zero would mean "wait forever". */
+ itv.it_value.tv_usec = 1;
+ setitimer (ITIMER_REAL, &itv, NULL);
+#else /* not ITIMER_REAL */
+ /* Use the old alarm() interface. */
+ int secs = (int) timeout;
+ if (secs == 0)
+ /* Round TIMEOUTs smaller than 1 to 1, not to zero. This is
+ because alarm(0) means "never deliver the alarm", i.e. "wait
+ forever", which is not what someone who specifies a 0.5s
+ timeout would expect. */
+ secs = 1;
+ alarm (secs);
+#endif /* not ITIMER_REAL */
+}
+
+/* Cancel the alarm set with alarm_set. */
+
+static void
+alarm_cancel (void)
+{
+#ifdef ITIMER_REAL
+ struct itimerval disable;
+ xzero (disable);
+ setitimer (ITIMER_REAL, &disable, NULL);
+#else /* not ITIMER_REAL */
+ alarm (0);
+#endif /* not ITIMER_REAL */
+}
+
+/* Call FUN(ARG), but don't allow it to run for more than TIMEOUT
+ seconds. Returns non-zero if the function was interrupted with a
+ timeout, zero otherwise.
+
+ This works by setting up SIGALRM to be delivered in TIMEOUT seconds
+ using setitimer() or alarm(). The timeout is enforced by
+ longjumping out of the SIGALRM handler. This has several
+ advantages compared to the traditional approach of relying on
+ signals causing system calls to exit with EINTR:
+
+ * The callback function is *forcibly* interrupted after the
+ timeout expires, (almost) regardless of what it was doing and
+ whether it was in a syscall. For example, a calculation that
+ takes a long time is interrupted as reliably as an IO
+ operation.
+
+ * It works with both SYSV and BSD signals because it doesn't
+ depend on the default setting of SA_RESTART.
+
+ * It doesn't require special handler setup beyond a simple call
+ to signal(). (It does use sigsetjmp/siglongjmp, but they're
+ optional.)
+
+ The only downside is that, if FUN allocates internal resources that
+ are normally freed prior to exit from the functions, they will be
+ lost in case of timeout. */
+
+int
+run_with_timeout (double timeout, void (*fun) (void *), void *arg)
+{
+ int saved_errno;
+
+ if (timeout == 0)
+ {
+ fun (arg);
+ return 0;
+ }
+
+ signal (SIGALRM, abort_run_with_timeout);
+ if (SETJMP (run_with_timeout_env) != 0)
+ {
+ /* Longjumped out of FUN with a timeout. */
+ signal (SIGALRM, SIG_DFL);
+ return 1;
+ }
+ alarm_set (timeout);
+ fun (arg);
+
+ /* Preserve errno in case alarm() or signal() modifies it. */
+ saved_errno = errno;
+ alarm_cancel ();
+ signal (SIGALRM, SIG_DFL);
+ errno = saved_errno;
+
+ return 0;
+}
+
+#else /* not USE_SIGNAL_TIMEOUT */
+
+#ifndef WINDOWS
+/* A stub version of run_with_timeout that just calls FUN(ARG). Don't
+ define it under Windows, because Windows has its own version of
+ run_with_timeout that uses threads. */
+
+int
+run_with_timeout (double timeout, void (*fun) (void *), void *arg)
+{
+ fun (arg);
+ return 0;
+}
+#endif /* not WINDOWS */
+#endif /* not USE_SIGNAL_TIMEOUT */
+\f
+#ifndef WINDOWS
+
+/* Sleep the specified amount of seconds. On machines without
+ nanosleep(), this may sleep shorter if interrupted by signals. */
+
+void
+xsleep (double seconds)
+{
+#ifdef HAVE_NANOSLEEP
+ /* nanosleep is the preferred interface because it offers high
+ accuracy and, more importantly, because it allows us to reliably
+ restart receiving a signal such as SIGWINCH. (There was an
+ actual Debian bug report about --limit-rate malfunctioning while
+ the terminal was being resized.) */
+ struct timespec sleep, remaining;
+ sleep.tv_sec = (long) seconds;
+ sleep.tv_nsec = 1000000000 * (seconds - (long) seconds);
+ while (nanosleep (&sleep, &remaining) < 0 && errno == EINTR)
+ /* If nanosleep has been interrupted by a signal, adjust the
+ sleeping period and return to sleep. */
+ sleep = remaining;
+#else /* not HAVE_NANOSLEEP */
+#ifdef HAVE_USLEEP
+ /* If usleep is available, use it in preference to select. */
+ if (seconds >= 1)
+ {
+ /* On some systems, usleep cannot handle values larger than
+ 1,000,000. If the period is larger than that, use sleep
+ first, then add usleep for subsecond accuracy. */
+ sleep (seconds);
+ seconds -= (long) seconds;
+ }
+ usleep (seconds * 1000000);
+#else /* not HAVE_USLEEP */
+#ifdef HAVE_SELECT
+ /* Note that, although Windows supports select, this sleeping
+ strategy doesn't work there because Winsock's select doesn't
+ implement timeout when it is passed NULL pointers for all fd
+ sets. (But it does work under Cygwin, which implements its own
+ select.) */
+ struct timeval sleep;
+ sleep.tv_sec = (long) seconds;
+ sleep.tv_usec = 1000000 * (seconds - (long) seconds);
+ select (0, NULL, NULL, NULL, &sleep);
+ /* If select returns -1 and errno is EINTR, it means we were
+ interrupted by a signal. But without knowing how long we've
+ actually slept, we can't return to sleep. Using gettimeofday to
+ track sleeps is slow and unreliable due to clock skew. */
+#else /* not HAVE_SELECT */
+ sleep (seconds);
+#endif /* not HAVE_SELECT */
+#endif /* not HAVE_USLEEP */
+#endif /* not HAVE_NANOSLEEP */
+}
+
+#endif /* not WINDOWS */
+
+/* Encode the string S of length LENGTH to base64 format and place it
+ to STORE. STORE will be 0-terminated, and must point to a writable
+ buffer of at least 1+BASE64_LENGTH(length) bytes. */
+
+void
+base64_encode (const char *s, char *store, int length)
+{
+ /* Conversion table. */
+ static char tbl[64] = {
+ 'A','B','C','D','E','F','G','H',
+ 'I','J','K','L','M','N','O','P',
+ 'Q','R','S','T','U','V','W','X',
+ 'Y','Z','a','b','c','d','e','f',
+ 'g','h','i','j','k','l','m','n',
+ 'o','p','q','r','s','t','u','v',
+ 'w','x','y','z','0','1','2','3',
+ '4','5','6','7','8','9','+','/'
+ };
+ int i;
+ unsigned char *p = (unsigned char *)store;
+
+ /* Transform the 3x8 bits to 4x6 bits, as required by base64. */
+ for (i = 0; i < length; i += 3)
+ {
+ *p++ = tbl[s[0] >> 2];
+ *p++ = tbl[((s[0] & 3) << 4) + (s[1] >> 4)];
+ *p++ = tbl[((s[1] & 0xf) << 2) + (s[2] >> 6)];
+ *p++ = tbl[s[2] & 0x3f];
+ s += 3;
+ }
+ /* Pad the result if necessary... */
+ if (i == length + 1)
+ *(p - 1) = '=';
+ else if (i == length + 2)
+ *(p - 1) = *(p - 2) = '=';
+ /* ...and zero-terminate it. */
+ *p = '\0';
+}
+
+#define IS_ASCII(c) (((c) & 0x80) == 0)
+#define IS_BASE64(c) ((IS_ASCII (c) && base64_char_to_value[c] >= 0) || c == '=')
+
+/* Get next character from the string, except that non-base64
+ characters are ignored, as mandated by rfc2045. */
+#define NEXT_BASE64_CHAR(c, p) do { \
+ c = *p++; \
+} while (c != '\0' && !IS_BASE64 (c))
+
+/* Decode data from BASE64 (assumed to be encoded as base64) into
+ memory pointed to by TO. TO should be large enough to accomodate
+ the decoded data, which is guaranteed to be less than
+ strlen(base64).
+
+ Since TO is assumed to contain binary data, it is not
+ NUL-terminated. The function returns the length of the data
+ written to TO. -1 is returned in case of error caused by malformed
+ base64 input. */
+
+int
+base64_decode (const char *base64, char *to)
+{
+ /* Table of base64 values for first 128 characters. */
+ static short base64_char_to_value[128] =
+ {
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, /* 0- 9 */
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, /* 10- 19 */
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, /* 20- 29 */
+ -1, -1, -1, -1, -1, -1, -1, -1, -1, -1, /* 30- 39 */
+ -1, -1, -1, 62, -1, -1, -1, 63, 52, 53, /* 40- 49 */
+ 54, 55, 56, 57, 58, 59, 60, 61, -1, -1, /* 50- 59 */
+ -1, -1, -1, -1, -1, 0, 1, 2, 3, 4, /* 60- 69 */
+ 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, /* 70- 79 */
+ 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, /* 80- 89 */
+ 25, -1, -1, -1, -1, -1, -1, 26, 27, 28, /* 90- 99 */
+ 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, /* 100-109 */
+ 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, /* 110-119 */
+ 49, 50, 51, -1, -1, -1, -1, -1 /* 120-127 */
+ };
+
+ const char *p = base64;
+ char *q = to;
+
+ while (1)
+ {
+ unsigned char c;
+ unsigned long value;
+
+ /* Process first byte of a quadruplet. */
+ NEXT_BASE64_CHAR (c, p);
+ if (!c)
+ break;
+ if (c == '=')
+ return -1; /* illegal '=' while decoding base64 */
+ value = base64_char_to_value[c] << 18;
+
+ /* Process scond byte of a quadruplet. */
+ NEXT_BASE64_CHAR (c, p);
+ if (!c)
+ return -1; /* premature EOF while decoding base64 */
+ if (c == '=')
+ return -1; /* illegal `=' while decoding base64 */
+ value |= base64_char_to_value[c] << 12;
+ *q++ = value >> 16;
+
+ /* Process third byte of a quadruplet. */
+ NEXT_BASE64_CHAR (c, p);
+ if (!c)
+ return -1; /* premature EOF while decoding base64 */
+
+ if (c == '=')
+ {
+ NEXT_BASE64_CHAR (c, p);
+ if (!c)
+ return -1; /* premature EOF while dcoding base64 */
+ if (c != '=')
+ return -1; /* padding `=' expected but not found */
+ continue;
+ }
+
+ value |= base64_char_to_value[c] << 6;
+ *q++ = 0xff & value >> 8;
+
+ /* Process fourth byte of a quadruplet. */
+ NEXT_BASE64_CHAR (c, p);
+ if (!c)
+ return -1; /* premature EOF while dcoding base64 */
+ if (c == '=')
+ continue;
+
+ value |= base64_char_to_value[c];
+ *q++ = 0xff & value;
+ }
+
+ return q - to;
+}
+
+#undef IS_ASCII
+#undef IS_BASE64
+#undef NEXT_BASE64_CHAR