#include "connect.h"
#include "hash.h"
#include "convert.h"
+#include "ptimer.h"
#ifdef HAVE_SSL
# include "gen_sslfunc.h" /* for ssl_iread */
extern int errno;
#endif
-/* See the comment in gethttp() why this is needed. */
-int global_download_count;
-
/* Total size of downloaded files. Used to enforce quota. */
LARGE_INT total_downloaded_bytes;
+/* If non-NULL, the stream to which output should be written. This
+ stream is initialized when `-O' is used. */
+FILE *output_stream;
+
+/* Whether output_document is a regular file we can manipulate,
+ i.e. not `-' or a device file. */
+int output_stream_regular;
\f
static struct {
- long chunk_bytes;
+ wgint chunk_bytes;
double chunk_start;
double sleep_adjust;
} limit_data;
is the timer that started at the beginning of download. */
static void
-limit_bandwidth (long bytes, struct wget_timer *timer)
+limit_bandwidth (wgint bytes, struct ptimer *timer)
{
- double delta_t = wtimer_read (timer) - limit_data.chunk_start;
+ double delta_t = ptimer_read (timer) - limit_data.chunk_start;
double expected;
limit_data.chunk_bytes += bytes;
double t0, t1;
if (slp < 200)
{
- DEBUGP (("deferring a %.2f ms sleep (%ld/%.2f).\n",
- slp, limit_data.chunk_bytes, delta_t));
+ DEBUGP (("deferring a %.2f ms sleep (%s/%.2f).\n",
+ slp, number_to_static_string (limit_data.chunk_bytes),
+ delta_t));
return;
}
- DEBUGP (("\nsleeping %.2f ms for %ld bytes, adjust %.2f ms\n",
- slp, limit_data.chunk_bytes, limit_data.sleep_adjust));
+ DEBUGP (("\nsleeping %.2f ms for %s bytes, adjust %.2f ms\n",
+ slp, number_to_static_string (limit_data.chunk_bytes),
+ limit_data.sleep_adjust));
- t0 = wtimer_read (timer);
+ t0 = ptimer_read (timer);
xsleep (slp / 1000);
- wtimer_update (timer);
- t1 = wtimer_read (timer);
+ t1 = ptimer_measure (timer);
/* Due to scheduling, we probably slept slightly longer (or
shorter) than desired. Calculate the difference between the
}
limit_data.chunk_bytes = 0;
- limit_data.chunk_start = wtimer_read (timer);
+ limit_data.chunk_start = ptimer_read (timer);
}
#ifndef MIN
# define MIN(i, j) ((i) <= (j) ? (i) : (j))
#endif
-/* Reads the contents of file descriptor FD, until it is closed, or a
- read error occurs. The data is read in 8K chunks, and stored to
- stream fp, which should have been open for writing.
+/* Write data in BUF to OUT. However, if *SKIP is non-zero, skip that
+ amount of data and decrease SKIP. Increment *TOTAL by the amount
+ of data written. */
+
+static int
+write_data (FILE *out, const char *buf, int bufsize, wgint *skip,
+ wgint *written)
+{
+ if (!out)
+ return 1;
+ if (*skip > bufsize)
+ {
+ *skip -= bufsize;
+ return 1;
+ }
+ if (*skip)
+ {
+ buf += *skip;
+ bufsize -= *skip;
+ *skip = 0;
+ if (bufsize == 0)
+ return 1;
+ }
+
+ fwrite (buf, 1, bufsize, out);
+ *written += bufsize;
+
+ /* Immediately flush the downloaded data. This should not hinder
+ performance: fast downloads will arrive in large 16K chunks
+ (which stdio would write out immediately anyway), and slow
+ downloads wouldn't be limited by disk speed. */
+ fflush (out);
+ return !ferror (out);
+}
+
+/* Read the contents of file descriptor FD until it the connection
+ terminates or a read error occurs. The data is read in portions of
+ up to 16K and written to OUT as it arrives. If opt.verbose is set,
+ the progress is shown.
- The EXPECTED argument is passed to show_progress() unchanged, but
- otherwise ignored.
+ TOREAD is the amount of data expected to arrive, normally only used
+ by the progress gauge.
- If opt.verbose is set, the progress is also shown. RESTVAL
- represents a value from which to start downloading (which will be
- shown accordingly). If RESTVAL is non-zero, the stream should have
- been open for appending.
+ STARTPOS is the position from which the download starts, used by
+ the progress gauge. If QTYREAD is non-NULL, the value it points to
+ is incremented by the amount of data read from the network. If
+ QTYWRITTEN is non-NULL, the value it points to is incremented by
+ the amount of data written to disk. The time it took to download
+ the data (in milliseconds) is stored to ELAPSED.
- The function exits and returns codes of 0, -1 and -2 if the
- connection was closed, there was a read error, or if it could not
- write to the output stream, respectively. */
+ The function exits and returns the amount of data read. In case of
+ error while reading data, -1 is returned. In case of error while
+ writing data, -2 is returned. */
int
-fd_read_body (int fd, FILE *out, long *len, long restval, long expected,
- int use_expected, double *elapsed)
+fd_read_body (int fd, FILE *out, wgint toread, wgint startpos,
+ wgint *qtyread, wgint *qtywritten, double *elapsed, int flags)
{
- int res = 0;
+ int ret = 0;
static char dlbuf[16384];
int dlbufsize = sizeof (dlbuf);
- struct wget_timer *timer = wtimer_allocate ();
- double last_successful_read_tm;
+ struct ptimer *timer = NULL;
+ double last_successful_read_tm = 0;
/* The progress gauge, set according to the user preferences. */
void *progress = NULL;
data arrives slowly. */
int progress_interactive = 0;
- *len = restval;
+ int exact = flags & rb_read_exactly;
+ wgint skip = 0;
+
+ /* How much data we've read/written. */
+ wgint sum_read = 0;
+ wgint sum_written = 0;
+
+ if (flags & rb_skip_startpos)
+ skip = startpos;
if (opt.verbose)
{
- progress = progress_create (restval, expected);
+ /* If we're skipping STARTPOS bytes, pass 0 as the INITIAL
+ argument to progress_create because the indicator doesn't
+ (yet) know about "skipping" data. */
+ progress = progress_create (skip ? 0 : startpos, startpos + toread);
progress_interactive = progress_interactive_p (progress);
}
if (opt.limit_rate)
limit_bandwidth_reset ();
- wtimer_reset (timer);
- last_successful_read_tm = 0;
+
+ /* A timer is needed for tracking progress, for throttling, and for
+ tracking elapsed time. If either of these are requested, start
+ the timer. */
+ if (progress || opt.limit_rate || elapsed)
+ {
+ timer = ptimer_new ();
+ last_successful_read_tm = 0;
+ }
/* Use a smaller buffer for low requested bandwidths. For example,
with --limit-rate=2k, it doesn't make sense to slurp in 16K of
if (opt.limit_rate && opt.limit_rate < dlbufsize)
dlbufsize = opt.limit_rate;
- /* Read from fd while there is available data.
-
- Normally, if expected is 0, it means that it is not known how
- much data is expected. However, if use_expected is specified,
- then expected being zero means exactly that. */
- while (!use_expected || (*len < expected))
+ /* Read from FD while there is data to read. Normally toread==0
+ means that it is unknown how much data is to arrive. However, if
+ EXACT is set, then toread==0 means what it says: that no data
+ should be read. */
+ while (!exact || (sum_read < toread))
{
- int amount_to_read = (use_expected
- ? MIN (expected - *len, dlbufsize) : dlbufsize);
+ int rdsize = exact ? MIN (toread - sum_read, dlbufsize) : dlbufsize;
double tmout = opt.read_timeout;
if (progress_interactive)
{
- double waittm;
/* For interactive progress gauges, always specify a ~1s
timeout, so that the gauge can be updated regularly even
when the data arrives very slowly or stalls. */
tmout = 0.95;
- waittm = (wtimer_read (timer) - last_successful_read_tm) / 1000;
- if (waittm + tmout > opt.read_timeout)
+ if (opt.read_timeout)
{
- /* Don't allow waiting time to exceed read timeout. */
- tmout = opt.read_timeout - waittm;
- if (tmout < 0)
+ double waittm;
+ waittm = (ptimer_read (timer) - last_successful_read_tm) / 1000;
+ if (waittm + tmout > opt.read_timeout)
{
- /* We've already exceeded the timeout. */
- res = -1, errno = ETIMEDOUT;
- break;
+ /* Don't let total idle time exceed read timeout. */
+ tmout = opt.read_timeout - waittm;
+ if (tmout < 0)
+ {
+ /* We've already exceeded the timeout. */
+ ret = -1, errno = ETIMEDOUT;
+ break;
+ }
}
}
}
- res = fd_read (fd, dlbuf, amount_to_read, tmout);
+ ret = fd_read (fd, dlbuf, rdsize, tmout);
+
+ if (ret == 0 || (ret < 0 && errno != ETIMEDOUT))
+ break; /* read error */
+ else if (ret < 0)
+ ret = 0; /* read timeout */
- if (res == 0 || (res < 0 && errno != ETIMEDOUT))
- break;
- else if (res < 0)
- res = 0; /* timeout */
+ if (progress || opt.limit_rate)
+ {
+ ptimer_measure (timer);
+ if (ret > 0)
+ last_successful_read_tm = ptimer_read (timer);
+ }
- wtimer_update (timer);
- if (res > 0)
+ if (ret > 0)
{
- fwrite (dlbuf, 1, res, out);
- /* Always flush the contents of the network packet. This
- should not hinder performance: fast downloads will be
- received in 16K chunks (which stdio would write out
- anyway), and slow downloads won't be limited by disk
- performance. */
- fflush (out);
- if (ferror (out))
+ sum_read += ret;
+ if (!write_data (out, dlbuf, ret, &skip, &sum_written))
{
- res = -2;
+ ret = -2;
goto out;
}
- last_successful_read_tm = wtimer_read (timer);
}
if (opt.limit_rate)
- limit_bandwidth (res, timer);
+ limit_bandwidth (ret, timer);
- *len += res;
if (progress)
- progress_update (progress, res, wtimer_read (timer));
+ progress_update (progress, ret, ptimer_read (timer));
#ifdef WINDOWS
- if (use_expected && expected > 0)
- ws_percenttitle (100.0 * (double)(*len) / (double)expected);
+ if (toread > 0 && !opt.quiet)
+ ws_percenttitle (100.0 *
+ (startpos + sum_read) / (startpos + toread));
#endif
}
- if (res < -1)
- res = -1;
+ if (ret < -1)
+ ret = -1;
out:
if (progress)
- progress_finish (progress, wtimer_read (timer));
+ progress_finish (progress, ptimer_read (timer));
+
if (elapsed)
- *elapsed = wtimer_read (timer);
- wtimer_delete (timer);
+ *elapsed = ptimer_read (timer);
+ if (timer)
+ ptimer_destroy (timer);
- return res;
+ if (qtyread)
+ *qtyread += sum_read;
+ if (qtywritten)
+ *qtywritten += sum_written;
+
+ return ret;
}
\f
/* Read a hunk of data from FD, up until a terminator. The terminator
a read. If the read returns a different amount of data, the
process is retried until all data arrives safely.
- BUFSIZE is the size of the initial buffer expected to read all the
- data in the typical case.
+ SIZEHINT is the buffer size sufficient to hold all the data in the
+ typical case (it is used as the initial buffer size). MAXSIZE is
+ the maximum amount of memory this function is allowed to allocate,
+ or 0 if no upper limit is to be enforced.
This function should be used as a building block for other
functions -- see fd_read_line as a simple example. */
char *
-fd_read_hunk (int fd, hunk_terminator_t hunk_terminator, int bufsize)
+fd_read_hunk (int fd, hunk_terminator_t terminator, long sizehint, long maxsize)
{
+ long bufsize = sizehint;
char *hunk = xmalloc (bufsize);
int tail = 0; /* tail position in HUNK */
+ assert (maxsize >= bufsize);
+
while (1)
{
const char *end;
xfree (hunk);
return NULL;
}
- end = hunk_terminator (hunk, tail, pklen);
+ end = terminator (hunk, tail, pklen);
if (end)
{
/* The data contains the terminator: we'll drain the data up
if (tail == bufsize - 1)
{
+ /* Double the buffer size, but refuse to allocate more than
+ MAXSIZE bytes. */
+ if (maxsize && bufsize >= maxsize)
+ {
+ xfree (hunk);
+ errno = ENOMEM;
+ return NULL;
+ }
bufsize <<= 1;
+ if (maxsize && bufsize > maxsize)
+ bufsize = maxsize;
hunk = xrealloc (hunk, bufsize);
}
}
return NULL;
}
+/* The maximum size of the single line we agree to accept. This is
+ not meant to impose an arbitrary limit, but to protect the user
+ from Wget slurping up available memory upon encountering malicious
+ or buggy server output. Define it to 0 to remove the limit. */
+#define FD_READ_LINE_MAX 4096
+
/* Read one line from FD and return it. The line is allocated using
- malloc.
+ malloc, but is never larger than FD_READ_LINE_MAX.
If an error occurs, or if no data can be read, NULL is returned.
In the former case errno indicates the error condition, and in the
char *
fd_read_line (int fd)
{
- return fd_read_hunk (fd, line_terminator, 128);
+ return fd_read_hunk (fd, line_terminator, 128, FD_READ_LINE_MAX);
}
\f
/* Return a printed representation of the download rate, as
appropriate for the speed. If PAD is non-zero, strings will be
padded to the width of 7 characters (xxxx.xx). */
char *
-retr_rate (long bytes, double msecs, int pad)
+retr_rate (wgint bytes, double msecs, int pad)
{
static char res[20];
- static char *rate_names[] = {"B/s", "KB/s", "MB/s", "GB/s" };
+ static const char *rate_names[] = {"B/s", "KB/s", "MB/s", "GB/s" };
int units = 0;
double dlrate = calc_rate (bytes, msecs, &units);
UNITS is zero for B/s, one for KB/s, two for MB/s, and three for
GB/s. */
double
-calc_rate (long bytes, double msecs, int *units)
+calc_rate (wgint bytes, double msecs, int *units)
{
double dlrate;
if (msecs == 0)
/* If elapsed time is exactly zero, it means we're under the
- granularity of the timer. This often happens on systems that
- use time() for the timer. */
- msecs = wtimer_granularity ();
+ resolution of the timer. This can easily happen on systems
+ that use time() for the timer. Since the interval lies between
+ 0 and the timer's resolution, assume half the resolution. */
+ msecs = ptimer_resolution () / 2.0;
- dlrate = (double)1000 * bytes / msecs;
+ dlrate = 1000.0 * bytes / msecs;
if (dlrate < 1024.0)
*units = 0;
else if (dlrate < 1024.0 * 1024.0)
newloc_parsed = url_parse (mynewloc, &up_error_code);
if (!newloc_parsed)
{
- logprintf (LOG_NOTQUIET, "%s: %s.\n", mynewloc,
+ logprintf (LOG_NOTQUIET, "%s: %s.\n", escnonprint_uri (mynewloc),
url_error (up_error_code));
url_free (u);
xfree (url);
xfree (url);
}
- ++global_download_count;
RESTORE_POST_DATA;
return result;
int maxlen = strlen (fname) + 1 + numdigit (opt.backups) + 1;
char *from = (char *)alloca (maxlen);
char *to = (char *)alloca (maxlen);
- struct stat sb;
+ struct_stat sb;
int i;
if (stat (fname, &sb) == 0)