/* Various utility functions.
- Copyright (C) 2003 Free Software Foundation, Inc.
+ Copyright (C) 2005 Free Software Foundation, Inc.
This file is part of GNU Wget.
return copy;
}
-/* Return a count of how many times CHR occurs in STRING. */
-
-int
-count_char (const char *string, char chr)
-{
- const char *p;
- int count = 0;
- for (p = string; *p; p++)
- if (*p == chr)
- ++count;
- return count;
-}
-
/* 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 NULL; /* unreached */
}
+
+/* Concatenate the NULL-terminated list of string arguments into
+ freshly allocated space. */
+
+char *
+concat_strings (const char *str0, ...)
+{
+ 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 *))
+ {
+ 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
/* Return pointer to a static char[] buffer in which zero-terminated
string-representation of TM (in form hh:mm:ss) is printed.
{
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, 0);
- 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)
{
/* parent, no error */
printf (_("Continuing in background, pid %d.\n"), (int)pid);
- if (changedp)
+ if (logfile_changed)
printf (_("Output will be written to `%s'.\n"), opt.lfilename);
exit (0); /* #### should we use _exit()? */
}
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 the size of file named by FILENAME, or -1 if it cannot be
opened or seeked into. */
-long
+wgint
file_size (const char *filename)
{
- long size;
+#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 whether the file is readable.
- Inspired by the POST patch by Arnaud Wylie. */
+ 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;
- fseek (fp, 0, SEEK_END);
- size = ftell (fp);
+ 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
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
- something.
+ 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 return it. */
return unique_name_1 (file);
}
+
+/* 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)
+ {
+ xfree (uname);
+ uname = unique_name (name, 0);
+ }
+ if (opened_name && fp != NULL)
+ {
+ if (fp)
+ *opened_name = uname;
+ else
+ {
+ *opened_name = NULL;
+ xfree (uname);
+ }
+ }
+ else
+ xfree (uname);
+ return fp;
+}
+
+/* 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)
+{
+ 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
are missing, create them first. In case any mkdir() call fails,
int
make_directory (const char *directory)
{
- int quit = 0;
- int i;
- int ret = 0;
+ int i, ret, quit = 0;
char *dir;
/* Make a copy of dir, to be able to write to it. Otherwise, the
#ifdef HAVE_MMAP
{
- struct stat buf;
+ struct_stat buf;
if (fstat (fd, &buf) < 0)
goto mmap_lose;
fm->length = buf.st_size;
fm->content = xmalloc (size);
while (1)
{
- long nread;
+ wgint nread;
if (fm->length > size / 2)
{
/* #### I'm not sure whether the whole exponential-growth
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. */
-
-/* It's a shame that these simple things like linked lists and hash
- tables (see hash.c) need to be implemented over and over again. It
- would be nice to be able to use the routines from glib -- see
- www.gtk.org for details. However, that would make Wget depend on
- glib, and I want to avoid dependencies to external libraries for
- reasons of convenience and portability (I suspect Wget is more
- portable than anything ever written for Gnome). */
-
-/* Append an element to the list. If the list has a huge number of
- elements, this can get slow because it has to find the list's
- ending. If you think you have to call slist_append in a loop,
- think about calling slist_prepend() followed by slist_nreverse(). */
-
-slist *
-slist_append (slist *l, const char *s)
-{
- slist *newel = xnew (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;
-}
-
-/* Prepend S to the list. Unlike slist_append(), this is O(1). */
-
-slist *
-slist_prepend (slist *l, const char *s)
-{
- slist *newel = xnew (slist);
- newel->string = xstrdup (s);
- newel->next = l;
- return newel;
-}
-
-/* Destructively reverse L. */
-
-slist *
-slist_nreverse (slist *l)
-{
- slist *prev = NULL;
- while (l)
- {
- slist *next = l->next;
- l->next = prev;
- prev = l;
- l = next;
- }
- return prev;
-}
-
-/* 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)
-{
- while (l)
- {
- slist *n = l->next;
- xfree (l->string);
- xfree (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
return hash_table_contains (ht, s);
}
+static int
+string_set_to_array_mapper (void *key, void *value_ignored, void *arg)
+{
+ 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)
{
}
\f
-/* Engine for legible and legible_large_int; add thousand separators
- to numbers printed in 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[48];
int i, i1, mod;
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. */
number_to_string (inbuf, l);
- return legible_1 (inbuf);
+ return add_thousand_seps (inbuf);
}
/* Write a string representation of LARGE_INT NUMBER into the provided
- buffer. The buffer should be able to accept 24 characters,
- including the terminating zero.
+ 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 platforms will typically
- not have snprintf and will use our version, which does support
- "%lld" where long longs are available. */
+ 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, LARGE_INT number)
+large_int_to_string (char *buffer, int bufsize, LARGE_INT number)
{
- snprintf (buffer, 24, LARGE_INT_FMT, number);
+ snprintf (buffer, bufsize, LARGE_INT_FMT, number);
}
-/* The same as legible(), but works on LARGE_INT. */
+/* The same as with_thousand_seps, but works on LARGE_INT. */
char *
-legible_large_int (LARGE_INT l)
+with_thousand_seps_large (LARGE_INT l)
{
char inbuf[48];
- large_int_to_string (inbuf, l);
- return legible_1 (inbuf);
+ large_int_to_string (inbuf, sizeof (inbuf), l);
+ return add_thousand_seps (inbuf);
+}
+
+/* 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.
+
+ 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)
+{
+ /* 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 a (long) integer. */
+/* Count the digits in the provided number. Used to allocate space
+ when printing numbers. */
+
int
-numdigit (long number)
+numdigit (wgint number)
{
int cnt = 1;
if (number < 0)
- {
- number = -number;
- ++cnt;
- }
- while ((number /= 10) > 0)
+ ++cnt; /* accomodate '-' */
+ while ((number /= 10) != 0)
++cnt;
return cnt;
}
-/* Attempt to calculate INT_MAX on machines that don't bother to
- define it. */
-#ifndef INT_MAX
-# ifndef CHAR_BIT
-# define CHAR_BIT 8
-# endif
-# define INT_MAX ((int) ~((unsigned)1 << CHAR_BIT * sizeof (int) - 1))
-#endif
-
#define ONE_DIGIT(figure) *p++ = n / (figure) + '0'
#define ONE_DIGIT_ADVANCE(figure) (ONE_DIGIT (figure), n %= (figure))
#define DIGITS_9(figure) ONE_DIGIT_ADVANCE (figure); DIGITS_8 ((figure) / 10)
#define DIGITS_10(figure) ONE_DIGIT_ADVANCE (figure); DIGITS_9 ((figure) / 10)
-/* DIGITS_<11-20> are only used on machines with 64-bit longs. */
+/* DIGITS_<11-20> are only used on machines with 64-bit numbers. */
#define DIGITS_11(figure) ONE_DIGIT_ADVANCE (figure); DIGITS_10 ((figure) / 10)
#define DIGITS_12(figure) ONE_DIGIT_ADVANCE (figure); DIGITS_11 ((figure) / 10)
#define DIGITS_18(figure) ONE_DIGIT_ADVANCE (figure); DIGITS_17 ((figure) / 10)
#define DIGITS_19(figure) ONE_DIGIT_ADVANCE (figure); DIGITS_18 ((figure) / 10)
-/* Print NUMBER to BUFFER in base 10. This should be completely
- equivalent to `sprintf(buffer, "%ld", number)', only much faster.
+/* It is annoying that we have three different syntaxes for 64-bit constants:
+ - nnnL for 64-bit systems, where they are of type long;
+ - nnnLL for 32-bit systems that support long long;
+ - nnnI64 for MS compiler on Windows, which doesn't support long long. */
+
+#if SIZEOF_LONG > 4
+/* If long is large enough, use long constants. */
+# define C10000000000 10000000000L
+# define C100000000000 100000000000L
+# define C1000000000000 1000000000000L
+# define C10000000000000 10000000000000L
+# define C100000000000000 100000000000000L
+# define C1000000000000000 1000000000000000L
+# define C10000000000000000 10000000000000000L
+# define C100000000000000000 100000000000000000L
+# define C1000000000000000000 1000000000000000000L
+#else
+# if SIZEOF_LONG_LONG != 0
+/* Otherwise, if long long is available, use long long constants. */
+# define C10000000000 10000000000LL
+# define C100000000000 100000000000LL
+# define C1000000000000 1000000000000LL
+# define C10000000000000 10000000000000LL
+# define C100000000000000 100000000000000LL
+# define C1000000000000000 1000000000000000LL
+# define C10000000000000000 10000000000000000LL
+# define C100000000000000000 100000000000000000LL
+# define C1000000000000000000 1000000000000000000LL
+# else
+# if defined(WINDOWS)
+/* Use __int64 constants under Windows. */
+# define C10000000000 10000000000I64
+# define C100000000000 100000000000I64
+# define C1000000000000 1000000000000I64
+# define C10000000000000 10000000000000I64
+# define C100000000000000 100000000000000I64
+# define C1000000000000000 1000000000000000I64
+# define C10000000000000000 10000000000000000I64
+# define C100000000000000000 100000000000000000I64
+# define C1000000000000000000 1000000000000000000I64
+# endif
+# endif
+#endif
+
+/* SPRINTF_WGINT is used by number_to_string to handle pathological
+ cases and to portably support strange sizes of wgint. */
+#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))
+# endif
+# endif
+#endif
+
+/* 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 compared to this function.
+ 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
terminating '\0'. */
char *
-number_to_string (char *buffer, long number)
+number_to_string (char *buffer, wgint number)
{
char *p = buffer;
- long n = number;
+ wgint n = number;
-#if (SIZEOF_LONG != 4) && (SIZEOF_LONG != 8)
+#if (SIZEOF_WGINT != 4) && (SIZEOF_WGINT != 8)
/* We are running in a strange or misconfigured environment. Let
sprintf cope with it. */
- sprintf (buffer, "%ld", n);
+ SPRINTF_WGINT (buffer, n);
p += strlen (buffer);
-#else /* (SIZEOF_LONG == 4) || (SIZEOF_LONG == 8) */
+#else /* (SIZEOF_WGINT == 4) || (SIZEOF_WGINT == 8) */
if (n < 0)
{
- if (n < -INT_MAX)
+ if (n < -WGINT_MAX)
{
/* We cannot print a '-' and assign -n to n because -n would
overflow. Let sprintf deal with this border case. */
- sprintf (buffer, "%ld", n);
+ SPRINTF_WGINT (buffer, n);
p += strlen (buffer);
return p;
}
else if (n < 10000000) { DIGITS_7 (1000000); }
else if (n < 100000000) { DIGITS_8 (10000000); }
else if (n < 1000000000) { DIGITS_9 (100000000); }
-#if SIZEOF_LONG == 4
+#if SIZEOF_WGINT == 4
+ /* wgint is four bytes long: we're done. */
/* ``if (1)'' serves only to preserve editor indentation. */
else if (1) { DIGITS_10 (1000000000); }
-#else /* SIZEOF_LONG != 4 */
- else if (n < 10000000000L) { DIGITS_10 (1000000000L); }
- else if (n < 100000000000L) { DIGITS_11 (10000000000L); }
- else if (n < 1000000000000L) { DIGITS_12 (100000000000L); }
- else if (n < 10000000000000L) { DIGITS_13 (1000000000000L); }
- else if (n < 100000000000000L) { DIGITS_14 (10000000000000L); }
- else if (n < 1000000000000000L) { DIGITS_15 (100000000000000L); }
- else if (n < 10000000000000000L) { DIGITS_16 (1000000000000000L); }
- else if (n < 100000000000000000L) { DIGITS_17 (10000000000000000L); }
- else if (n < 1000000000000000000L) { DIGITS_18 (100000000000000000L); }
- else { DIGITS_19 (1000000000000000000L); }
-#endif /* SIZEOF_LONG != 4 */
+#else
+ /* wgint is 64 bits long -- make sure to process all the digits. */
+ else if (n < C10000000000) { DIGITS_10 (1000000000); }
+ else if (n < C100000000000) { DIGITS_11 (C10000000000); }
+ else if (n < C1000000000000) { DIGITS_12 (C100000000000); }
+ else if (n < C10000000000000) { DIGITS_13 (C1000000000000); }
+ else if (n < C100000000000000) { DIGITS_14 (C10000000000000); }
+ else if (n < C1000000000000000) { DIGITS_15 (C100000000000000); }
+ else if (n < C10000000000000000) { DIGITS_16 (C1000000000000000); }
+ else if (n < C100000000000000000) { DIGITS_17 (C10000000000000000); }
+ else if (n < C1000000000000000000) { DIGITS_18 (C100000000000000000); }
+ else { DIGITS_19 (C1000000000000000000); }
+#endif
*p = '\0';
-#endif /* (SIZEOF_LONG == 4) || (SIZEOF_LONG == 8) */
+#endif /* (SIZEOF_WGINT == 4) || (SIZEOF_WGINT == 8) */
return p;
}
#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. */
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.
-
- #### Perhaps we should also support ftime(), which exists on old
- BSD 4.2-influenced systems? (It also existed under MS DOS Borland
- C, if memory serves me.) */
+ non-Windows systems without gettimeofday. */
#ifdef WINDOWS
# define TIMER_WINDOWS
#endif
#ifdef TIMER_WINDOWS
-typedef ULARGE_INTEGER wget_sys_time;
+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 {
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 *wt = xnew (struct wget_timer);
xzero (*wt);
+
+#ifdef TIMER_WINDOWS
+ wtimer_initialize_once ();
+#endif
+
return wt;
}
#endif
#ifdef TIMER_WINDOWS
- /* We use GetSystemTime to get the elapsed time. MSDN warns that
- system clock adjustments can skew the output of GetSystemTime
- when used as a timer and gives preference to GetTickCount and
- high-resolution timers. But GetTickCount can overflow, and hires
- timers are typically used for profiling, not for regular time
- measurement. Since we handle clock skew anyway, we just use
- GetSystemTime. */
- FILETIME ft;
- SYSTEMTIME st;
- GetSystemTime (&st);
-
- /* As recommended by MSDN, we convert SYSTEMTIME to FILETIME, copy
- FILETIME to ULARGE_INTEGER, and use regular 64-bit integer
- arithmetic on that. */
- SystemTimeToFileTime (&st, &ft);
- wst->HighPart = ft.dwHighDateTime;
- wst->LowPart = ft.dwLowDateTime;
+ 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_elapsed() will return the number of elapsed milliseconds.
- It is allowed to reset a previously used timer.
-
- If a non-zero value is used as START, the timer's values will be
- offset by START. */
+ It is allowed to reset a previously used timer. */
void
wtimer_reset (struct wget_timer *wt)
#endif
#ifdef WINDOWS
- /* VC++ 6 doesn't support direct cast of uint64 to double. To work
- around this, we subtract, then convert to signed, then finally to
- double. */
- return (double)(signed __int64)(wst1->QuadPart - wst2->QuadPart) / 10000;
+ if (using_hires_timers)
+ return (wst1->hires.QuadPart - wst2->hires.QuadPart) / hires_millisec_freq;
+ else
+ return wst1->lores - wst2->lores;
#endif
}
#endif
#ifdef TIMER_WINDOWS
- /* According to MSDN, GetSystemTime returns a broken-down time
- structure the smallest member of which are milliseconds. */
- return 1;
+ if (using_hires_timers)
+ return 1.0 / hires_millisec_freq;
+ else
+ return 10; /* according to MSDN */
#endif
}
\f
int rnd3 = random_number (1000);
return rnd1 / 1000.0 + rnd2 / 1000000.0 + rnd3 / 1000000000.0;
}
-
-#if 0
-/* A debugging function for checking whether an MD5 library works. */
-
-#include "gen-md5.h"
-
-char *
-debug_test_md5 (char *buf)
-{
- unsigned char raw[16];
- static char res[33];
- unsigned char *p1;
- char *p2;
- int cnt;
- ALLOCA_MD5_CONTEXT (ctx);
-
- gen_md5_init (ctx);
- gen_md5_update ((unsigned char *)buf, strlen (buf), ctx);
- gen_md5_finish (ctx, raw);
-
- p1 = raw;
- p2 = res;
- cnt = 16;
- while (cnt--)
- {
- *p2++ = XNUM_TO_digit (*p1 >> 4);
- *p2++ = XNUM_TO_digit (*p1 & 0xf);
- ++p1;
- }
- *p2 = '\0';
-
- return res;
-}
-#endif
\f
/* Implementation of run_with_timeout, a generic timeout-forcing
routine for systems with Unix-like signal handling. */
#ifdef HAVE_NANOSLEEP
/* nanosleep is the preferred interface because it offers high
accuracy and, more importantly, because it allows us to reliably
- restart after having been interrupted by a signal such as
- SIGWINCH. */
+ 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 = 1000000000L * (seconds - (long) seconds);