mpv/demux/demux.c

2115 lines
70 KiB
C

/*
* This file is part of mpv.
*
* mpv is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* mpv 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 Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with mpv. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <unistd.h>
#include <limits.h>
#include <pthread.h>
#include <math.h>
#include <sys/types.h>
#include <sys/stat.h>
#include "config.h"
#include "options/m_config.h"
#include "options/m_option.h"
#include "mpv_talloc.h"
#include "common/msg.h"
#include "common/global.h"
#include "osdep/threads.h"
#include "stream/stream.h"
#include "demux.h"
#include "timeline.h"
#include "stheader.h"
#include "cue.h"
// Demuxer list
extern const struct demuxer_desc demuxer_desc_edl;
extern const struct demuxer_desc demuxer_desc_cue;
extern const demuxer_desc_t demuxer_desc_rawaudio;
extern const demuxer_desc_t demuxer_desc_rawvideo;
extern const demuxer_desc_t demuxer_desc_tv;
extern const demuxer_desc_t demuxer_desc_mf;
extern const demuxer_desc_t demuxer_desc_matroska;
extern const demuxer_desc_t demuxer_desc_lavf;
extern const demuxer_desc_t demuxer_desc_playlist;
extern const demuxer_desc_t demuxer_desc_disc;
extern const demuxer_desc_t demuxer_desc_rar;
extern const demuxer_desc_t demuxer_desc_libarchive;
extern const demuxer_desc_t demuxer_desc_null;
extern const demuxer_desc_t demuxer_desc_timeline;
/* Please do not add any new demuxers here. If you want to implement a new
* demuxer, add it to libavformat, except for wrappers around external
* libraries and demuxers requiring binary support. */
const demuxer_desc_t *const demuxer_list[] = {
&demuxer_desc_disc,
&demuxer_desc_edl,
&demuxer_desc_cue,
&demuxer_desc_rawaudio,
&demuxer_desc_rawvideo,
#if HAVE_TV
&demuxer_desc_tv,
#endif
&demuxer_desc_matroska,
#if HAVE_LIBARCHIVE
&demuxer_desc_libarchive,
#endif
&demuxer_desc_rar,
&demuxer_desc_lavf,
&demuxer_desc_mf,
&demuxer_desc_playlist,
&demuxer_desc_null,
NULL
};
struct demux_opts {
int max_bytes;
int max_bytes_bw;
double min_secs;
int force_seekable;
double min_secs_cache;
int access_references;
int seekable_cache;
};
#define OPT_BASE_STRUCT struct demux_opts
const struct m_sub_options demux_conf = {
.opts = (const struct m_option[]){
OPT_DOUBLE("demuxer-readahead-secs", min_secs, M_OPT_MIN, .min = 0),
OPT_INTRANGE("demuxer-max-bytes", max_bytes, 0, 0, INT_MAX),
OPT_INTRANGE("demuxer-max-back-bytes", max_bytes_bw, 0, 0, INT_MAX),
OPT_FLAG("force-seekable", force_seekable, 0),
OPT_DOUBLE("cache-secs", min_secs_cache, M_OPT_MIN, .min = 0),
OPT_FLAG("access-references", access_references, 0),
OPT_FLAG("demuxer-seekable-cache", seekable_cache, 0),
{0}
},
.size = sizeof(struct demux_opts),
.defaults = &(const struct demux_opts){
.max_bytes = 400 * 1024 * 1024,
.max_bytes_bw = 0,
.min_secs = 1.0,
.min_secs_cache = 10.0,
.access_references = 1,
},
};
struct demux_internal {
struct mp_log *log;
// The demuxer runs potentially in another thread, so we keep two demuxer
// structs; the real demuxer can access the shadow struct only.
// Since demuxer and user threads both don't use locks, a third demuxer
// struct d_buffer is used to copy data between them in a synchronized way.
struct demuxer *d_thread; // accessed by demuxer impl. (producer)
struct demuxer *d_user; // accessed by player (consumer)
struct demuxer *d_buffer; // protected by lock; used to sync d_user/thread
// The lock protects the packet queues (struct demux_stream), d_buffer,
// and the fields below.
pthread_mutex_t lock;
pthread_cond_t wakeup;
pthread_t thread;
// -- All the following fields are protected by lock.
bool thread_terminate;
bool threading;
void (*wakeup_cb)(void *ctx);
void *wakeup_cb_ctx;
struct sh_stream **streams;
int num_streams;
int events;
bool warned_queue_overflow;
bool last_eof; // last actual global EOF status
bool eof; // whether we're in EOF state (reset for retry)
bool idle;
bool autoselect;
double min_secs;
int max_bytes;
int max_bytes_bw;
int seekable_cache;
// Set if we know that we are at the start of the file. This is used to
// avoid a redundant initial seek after enabling streams. We could just
// allow it, but to avoid buggy seeking affecting normal playback, we don't.
bool initial_state;
bool tracks_switched; // thread needs to inform demuxer of this
bool seeking; // there's a seek queued
int seek_flags; // flags for next seek (if seeking==true)
double seek_pts;
double ref_pts; // assumed player position (only for track switches)
double ts_offset; // timestamp offset to apply to everything
void (*run_fn)(void *); // if non-NULL, function queued to be run on
void *run_fn_arg; // the thread as run_fn(run_fn_arg)
// Cached state.
bool force_cache_update;
struct mp_tags *stream_metadata;
struct stream_cache_info stream_cache_info;
int64_t stream_size;
// Updated during init only.
char *stream_base_filename;
};
struct demux_stream {
struct demux_internal *in;
struct sh_stream *sh;
enum stream_type type;
// --- all fields are protected by in->lock
// demuxer state
bool selected; // user wants packets from this stream
bool active; // try to keep at least 1 packet queued
// if false, this stream is disabled, or passively
// read (like subtitles)
bool eof; // end of demuxed stream? (true if all buffer empty)
bool need_refresh; // enabled mid-stream
bool refreshing;
bool correct_dts; // packet DTS is strictly monotonically increasing
bool correct_pos; // packet pos is strictly monotonically increasing
size_t fw_packs; // number of packets in buffer (forward)
size_t fw_bytes; // total bytes of packets in buffer (forward)
size_t bw_bytes; // same as fw_bytes, but for back buffer
int64_t last_pos;
double last_dts;
double last_ts; // timestamp of the last packet added to queue
double back_pts; // smallest timestamp on the start of the back buffer
struct demux_packet *queue_head; // start of the full queue
struct demux_packet *queue_tail; // end of the full queue
// reader (decoder) state (bitrate calculations are part of it because we
// want to return the bitrate closest to the "current position")
double base_ts; // timestamp of the last packet returned to decoder
double last_br_ts; // timestamp of last packet bitrate was calculated
size_t last_br_bytes; // summed packet sizes since last bitrate calculation
double bitrate;
struct demux_packet *reader_head; // points at current decoder position
bool skip_to_keyframe;
bool attached_picture_added;
// for closed captions (demuxer_feed_caption)
struct sh_stream *cc;
bool ignore_eof; // ignore stream in underrun detection
};
// Return "a", or if that is NOPTS, return "def".
#define PTS_OR_DEF(a, def) ((a) == MP_NOPTS_VALUE ? (def) : (a))
// If one of the values is NOPTS, always pick the other one.
#define MP_PTS_MIN(a, b) MPMIN(PTS_OR_DEF(a, b), PTS_OR_DEF(b, a))
#define MP_PTS_MAX(a, b) MPMAX(PTS_OR_DEF(a, b), PTS_OR_DEF(b, a))
#define MP_ADD_PTS(a, b) ((a) == MP_NOPTS_VALUE ? (a) : ((a) + (b)))
static void demuxer_sort_chapters(demuxer_t *demuxer);
static void *demux_thread(void *pctx);
static void update_cache(struct demux_internal *in);
static int cached_demux_control(struct demux_internal *in, int cmd, void *arg);
static void clear_demux_state(struct demux_internal *in);
static void ds_clear_reader_state(struct demux_stream *ds)
{
ds->reader_head = NULL;
ds->base_ts = ds->last_br_ts = MP_NOPTS_VALUE;
ds->last_br_bytes = 0;
ds->bitrate = -1;
ds->skip_to_keyframe = false;
ds->attached_picture_added = false;
}
static void ds_clear_demux_state(struct demux_stream *ds)
{
ds_clear_reader_state(ds);
demux_packet_t *dp = ds->queue_head;
while (dp) {
demux_packet_t *dn = dp->next;
free_demux_packet(dp);
dp = dn;
}
ds->queue_head = ds->queue_tail = NULL;
ds->fw_packs = 0;
ds->fw_bytes = 0;
ds->bw_bytes = 0;
ds->eof = false;
ds->active = false;
ds->refreshing = false;
ds->need_refresh = false;
ds->correct_dts = ds->correct_pos = true;
ds->last_pos = -1;
ds->last_ts = ds->last_dts = MP_NOPTS_VALUE;
ds->back_pts = MP_NOPTS_VALUE;
}
void demux_set_ts_offset(struct demuxer *demuxer, double offset)
{
struct demux_internal *in = demuxer->in;
pthread_mutex_lock(&in->lock);
in->ts_offset = offset;
pthread_mutex_unlock(&in->lock);
}
// Allocate a new sh_stream of the given type. It either has to be released
// with talloc_free(), or added to a demuxer with demux_add_sh_stream(). You
// cannot add or read packets from the stream before it has been added.
struct sh_stream *demux_alloc_sh_stream(enum stream_type type)
{
struct sh_stream *sh = talloc_ptrtype(NULL, sh);
*sh = (struct sh_stream) {
.type = type,
.index = -1,
.ff_index = -1, // may be overwritten by demuxer
.demuxer_id = -1, // ... same
.codec = talloc_zero(sh, struct mp_codec_params),
.tags = talloc_zero(sh, struct mp_tags),
};
sh->codec->type = type;
return sh;
}
// Add a new sh_stream to the demuxer. Note that as soon as the stream has been
// added, it must be immutable, and must not be released (this will happen when
// the demuxer is destroyed).
void demux_add_sh_stream(struct demuxer *demuxer, struct sh_stream *sh)
{
struct demux_internal *in = demuxer->in;
pthread_mutex_lock(&in->lock);
assert(!sh->ds); // must not be added yet
sh->ds = talloc(sh, struct demux_stream);
*sh->ds = (struct demux_stream) {
.in = in,
.sh = sh,
.type = sh->type,
.selected = in->autoselect,
};
if (!sh->codec->codec)
sh->codec->codec = "";
sh->index = in->num_streams;
if (sh->ff_index < 0)
sh->ff_index = sh->index;
if (sh->demuxer_id < 0) {
sh->demuxer_id = 0;
for (int n = 0; n < in->num_streams; n++) {
if (in->streams[n]->type == sh->type)
sh->demuxer_id += 1;
}
}
MP_TARRAY_APPEND(in, in->streams, in->num_streams, sh);
in->events |= DEMUX_EVENT_STREAMS;
if (in->wakeup_cb)
in->wakeup_cb(in->wakeup_cb_ctx);
pthread_mutex_unlock(&in->lock);
}
// Update sh->tags (lazily). This must be called by demuxers which update
// stream tags after init. (sh->tags can be accessed by the playback thread,
// which means the demuxer thread cannot write or read it directly.)
// Before init is finished, sh->tags can still be accessed freely.
// Ownership of tags goes to the function.
void demux_set_stream_tags(struct demuxer *demuxer, struct sh_stream *sh,
struct mp_tags *tags)
{
struct demux_internal *in = demuxer->in;
assert(demuxer == in->d_thread);
if (sh->ds) {
while (demuxer->num_update_stream_tags <= sh->index) {
MP_TARRAY_APPEND(demuxer, demuxer->update_stream_tags,
demuxer->num_update_stream_tags, NULL);
}
talloc_free(demuxer->update_stream_tags[sh->index]);
demuxer->update_stream_tags[sh->index] = talloc_steal(demuxer, tags);
demux_changed(demuxer, DEMUX_EVENT_METADATA);
} else {
// not added yet
talloc_free(sh->tags);
sh->tags = talloc_steal(sh, tags);
}
}
// Return a stream with the given index. Since streams can only be added during
// the lifetime of the demuxer, it is guaranteed that an index within the valid
// range [0, demux_get_num_stream()) always returns a valid sh_stream pointer,
// which will be valid until the demuxer is destroyed.
struct sh_stream *demux_get_stream(struct demuxer *demuxer, int index)
{
struct demux_internal *in = demuxer->in;
pthread_mutex_lock(&in->lock);
assert(index >= 0 && index < in->num_streams);
struct sh_stream *r = in->streams[index];
pthread_mutex_unlock(&in->lock);
return r;
}
// See demux_get_stream().
int demux_get_num_stream(struct demuxer *demuxer)
{
struct demux_internal *in = demuxer->in;
pthread_mutex_lock(&in->lock);
int r = in->num_streams;
pthread_mutex_unlock(&in->lock);
return r;
}
void free_demuxer(demuxer_t *demuxer)
{
if (!demuxer)
return;
struct demux_internal *in = demuxer->in;
assert(demuxer == in->d_user);
demux_stop_thread(demuxer);
if (demuxer->desc->close)
demuxer->desc->close(in->d_thread);
clear_demux_state(in);
for (int n = in->num_streams - 1; n >= 0; n--)
talloc_free(in->streams[n]);
pthread_mutex_destroy(&in->lock);
pthread_cond_destroy(&in->wakeup);
talloc_free(demuxer);
}
void free_demuxer_and_stream(struct demuxer *demuxer)
{
if (!demuxer)
return;
struct stream *s = demuxer->stream;
free_demuxer(demuxer);
free_stream(s);
}
// Start the demuxer thread, which reads ahead packets on its own.
void demux_start_thread(struct demuxer *demuxer)
{
struct demux_internal *in = demuxer->in;
assert(demuxer == in->d_user);
if (!in->threading) {
in->threading = true;
if (pthread_create(&in->thread, NULL, demux_thread, in))
in->threading = false;
}
}
void demux_stop_thread(struct demuxer *demuxer)
{
struct demux_internal *in = demuxer->in;
assert(demuxer == in->d_user);
if (in->threading) {
pthread_mutex_lock(&in->lock);
in->thread_terminate = true;
pthread_cond_signal(&in->wakeup);
pthread_mutex_unlock(&in->lock);
pthread_join(in->thread, NULL);
in->threading = false;
in->thread_terminate = false;
}
}
// The demuxer thread will call cb(ctx) if there's a new packet, or EOF is reached.
void demux_set_wakeup_cb(struct demuxer *demuxer, void (*cb)(void *ctx), void *ctx)
{
struct demux_internal *in = demuxer->in;
pthread_mutex_lock(&in->lock);
in->wakeup_cb = cb;
in->wakeup_cb_ctx = ctx;
pthread_mutex_unlock(&in->lock);
}
const char *stream_type_name(enum stream_type type)
{
switch (type) {
case STREAM_VIDEO: return "video";
case STREAM_AUDIO: return "audio";
case STREAM_SUB: return "sub";
default: return "unknown";
}
}
void demuxer_feed_caption(struct sh_stream *stream, demux_packet_t *dp)
{
struct demuxer *demuxer = stream->ds->in->d_thread;
struct demux_internal *in = demuxer->in;
struct sh_stream *sh = stream->ds->cc;
if (!sh) {
sh = demux_alloc_sh_stream(STREAM_SUB);
if (!sh) {
talloc_free(dp);
return;
}
sh->codec->codec = "eia_608";
stream->ds->cc = sh;
demux_add_sh_stream(demuxer, sh);
}
pthread_mutex_lock(&in->lock);
sh->ds->ignore_eof = true;
dp->pts = MP_ADD_PTS(dp->pts, -in->ts_offset);
dp->dts = MP_ADD_PTS(dp->dts, -in->ts_offset);
pthread_mutex_unlock(&in->lock);
demux_add_packet(sh, dp);
}
// An obscure mechanism to get stream switching to be executed faster.
// On a switch, it seeks back, and then grabs all packets that were
// "missing" from the packet queue of the newly selected stream.
// Returns MP_NOPTS_VALUE if no seek should happen.
static double get_refresh_seek_pts(struct demux_internal *in)
{
struct demuxer *demux = in->d_thread;
double start_ts = in->ref_pts;
bool needed = false;
bool normal_seek = true;
bool refresh_possible = true;
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
if (!ds->selected)
continue;
if (ds->type == STREAM_VIDEO || ds->type == STREAM_AUDIO)
start_ts = MP_PTS_MIN(start_ts, ds->base_ts);
needed |= ds->need_refresh;
// If there were no other streams selected, we can use a normal seek.
normal_seek &= ds->need_refresh;
ds->need_refresh = false;
refresh_possible &= ds->correct_dts || ds->correct_pos;
}
if (!needed || start_ts == MP_NOPTS_VALUE || !demux->desc->seek ||
!demux->seekable || demux->partially_seekable)
return MP_NOPTS_VALUE;
if (normal_seek)
return start_ts;
if (!refresh_possible) {
MP_VERBOSE(in, "can't issue refresh seek\n");
return MP_NOPTS_VALUE;
}
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
// Streams which didn't have any packets yet will return all packets,
// other streams return packets only starting from the last position.
if (ds->last_pos != -1 || ds->last_dts != MP_NOPTS_VALUE)
ds->refreshing |= ds->selected;
}
// Seek back to player's current position, with a small offset added.
return start_ts - 1.0;
}
// Get the PTS in the keyframe range starting at or following dp. We assume
// that the minimum PTS values within a keyframe range are strictly monotonic
// increasing relative to the range after it. Since we don't assume that the
// first packet has the minimum PTS, a search within the keyframe range is done.
// This function does not assume dp->keyframe==true, because it deals with weird
// cases like apparently seeking to non-keyframes, or pruning the complete
// backbuffer, which might end up with non-keyframes even at queue start.
// The caller assumption is that the first frame decoded from this packet
// position will result in a frame with the PTS returned from this function.
// (For corner cases with non-key frames, assuming those packets are skipped.)
static double recompute_keyframe_target_pts(struct demux_packet *dp)
{
bool in_keyframe_range = false;
double res = MP_NOPTS_VALUE;
while (dp) {
if (dp->keyframe) {
if (in_keyframe_range)
break;
in_keyframe_range = true;
}
if (in_keyframe_range) {
double ts = PTS_OR_DEF(dp->pts, dp->dts);
if (dp->segmented && (ts < dp->start || ts > dp->end))
ts = MP_NOPTS_VALUE;
res = MP_PTS_MIN(res, ts);
}
dp = dp->next;
}
return res;
}
void demux_add_packet(struct sh_stream *stream, demux_packet_t *dp)
{
struct demux_stream *ds = stream ? stream->ds : NULL;
if (!dp || !ds) {
talloc_free(dp);
return;
}
struct demux_internal *in = ds->in;
pthread_mutex_lock(&in->lock);
bool drop = ds->refreshing;
if (ds->refreshing) {
// Resume reading once the old position was reached (i.e. we start
// returning packets where we left off before the refresh).
// If it's the same position, drop, but continue normally next time.
if (ds->correct_dts) {
ds->refreshing = dp->dts < ds->last_dts;
} else if (ds->correct_pos) {
ds->refreshing = dp->pos < ds->last_pos;
} else {
ds->refreshing = false; // should not happen
}
}
if (!ds->selected || ds->need_refresh || in->seeking || drop) {
pthread_mutex_unlock(&in->lock);
talloc_free(dp);
return;
}
ds->correct_pos &= dp->pos >= 0 && dp->pos > ds->last_pos;
ds->correct_dts &= dp->dts != MP_NOPTS_VALUE && dp->dts > ds->last_dts;
ds->last_pos = dp->pos;
ds->last_dts = dp->dts;
dp->stream = stream->index;
dp->next = NULL;
// (keep in mind that even if the reader went out of data, the queue is not
// necessarily empty due to the backbuffer)
if (!ds->reader_head && (!ds->skip_to_keyframe || dp->keyframe)) {
ds->reader_head = dp;
ds->skip_to_keyframe = false;
}
size_t bytes = demux_packet_estimate_total_size(dp);
if (ds->reader_head) {
ds->fw_packs++;
ds->fw_bytes += bytes;
} else {
ds->bw_bytes += bytes;
}
if (ds->queue_tail) {
// next packet in stream
ds->queue_tail->next = dp;
ds->queue_tail = dp;
} else {
// first packet in stream
ds->queue_head = ds->queue_tail = dp;
}
// (In theory it'd be more efficient to make this incremental.)
if (ds->back_pts == MP_NOPTS_VALUE && dp->keyframe)
ds->back_pts = recompute_keyframe_target_pts(ds->queue_head);
if (!ds->ignore_eof) {
// obviously not true anymore
ds->eof = false;
in->last_eof = in->eof = false;
}
// For video, PTS determination is not trivial, but for other media types
// distinguishing PTS and DTS is not useful.
if (stream->type != STREAM_VIDEO && dp->pts == MP_NOPTS_VALUE)
dp->pts = dp->dts;
double ts = dp->dts == MP_NOPTS_VALUE ? dp->pts : dp->dts;
if (ts != MP_NOPTS_VALUE && (ts > ds->last_ts || ts + 10 < ds->last_ts))
ds->last_ts = ts;
if (ds->base_ts == MP_NOPTS_VALUE)
ds->base_ts = ds->last_ts;
MP_DBG(in, "append packet to %s: size=%d pts=%f dts=%f pos=%"PRIi64" "
"[num=%zd size=%zd]\n", stream_type_name(stream->type),
dp->len, dp->pts, dp->dts, dp->pos, ds->fw_packs, ds->fw_bytes);
// Wake up if this was the first packet after start/possible underrun.
if (ds->in->wakeup_cb && ds->reader_head && !ds->reader_head->next)
ds->in->wakeup_cb(ds->in->wakeup_cb_ctx);
pthread_cond_signal(&in->wakeup);
pthread_mutex_unlock(&in->lock);
}
// Returns true if there was "progress" (lock was released temporarily).
static bool read_packet(struct demux_internal *in)
{
in->eof = false;
in->idle = true;
// Check if we need to read a new packet. We do this if all queues are below
// the minimum, or if a stream explicitly needs new packets. Also includes
// safe-guards against packet queue overflow.
bool active = false, read_more = false;
size_t bytes = 0;
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
active |= ds->active;
read_more |= (ds->active && !ds->reader_head) || ds->refreshing;
bytes += ds->fw_bytes;
if (ds->active && ds->last_ts != MP_NOPTS_VALUE && in->min_secs > 0 &&
ds->last_ts >= ds->base_ts)
read_more |= ds->last_ts - ds->base_ts < in->min_secs;
}
MP_DBG(in, "bytes=%zd, active=%d, more=%d\n",
bytes, active, read_more);
if (bytes >= in->max_bytes) {
if (!in->warned_queue_overflow) {
in->warned_queue_overflow = true;
MP_WARN(in, "Too many packets in the demuxer packet queues:\n");
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
if (ds->selected) {
MP_WARN(in, " %s/%d: %zd packets, %zd bytes\n",
stream_type_name(ds->type), n,
ds->fw_packs, ds->fw_bytes);
}
}
}
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
bool eof = !ds->reader_head;
if (eof && !ds->eof) {
if (in->wakeup_cb)
in->wakeup_cb(in->wakeup_cb_ctx);
}
ds->eof |= eof;
}
pthread_cond_signal(&in->wakeup);
return false;
}
double seek_pts = get_refresh_seek_pts(in);
bool refresh_seek = seek_pts != MP_NOPTS_VALUE;
read_more |= refresh_seek;
if (!read_more)
return false;
// Actually read a packet. Drop the lock while doing so, because waiting
// for disk or network I/O can take time.
in->idle = false;
in->initial_state = false;
pthread_mutex_unlock(&in->lock);
struct demuxer *demux = in->d_thread;
if (refresh_seek) {
MP_VERBOSE(in, "refresh seek to %f\n", seek_pts);
demux->desc->seek(demux, seek_pts, SEEK_HR);
}
bool eof = true;
if (demux->desc->fill_buffer && !demux_cancel_test(demux))
eof = demux->desc->fill_buffer(demux) <= 0;
update_cache(in);
pthread_mutex_lock(&in->lock);
if (!in->seeking) {
if (eof) {
for (int n = 0; n < in->num_streams; n++)
in->streams[n]->ds->eof = true;
// If we had EOF previously, then don't wakeup (avoids wakeup loop)
if (!in->last_eof) {
if (in->wakeup_cb)
in->wakeup_cb(in->wakeup_cb_ctx);
pthread_cond_signal(&in->wakeup);
MP_VERBOSE(in, "EOF reached.\n");
}
}
in->eof = in->last_eof = eof;
}
return true;
}
static void prune_old_packets(struct demux_internal *in)
{
size_t buffered = 0;
for (int n = 0; n < in->num_streams; n++)
buffered += in->streams[n]->ds->bw_bytes;
MP_TRACE(in, "total backbuffer = %zd\n", buffered);
// It's not clear what the ideal way to prune old packets is. For now, we
// prune the oldest packet runs, as long as the total cache amount is too
// big.
while (buffered > in->max_bytes_bw) {
double earliest_ts = MP_NOPTS_VALUE;
int earliest_stream = -1;
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
if (ds->queue_head && ds->queue_head != ds->reader_head) {
struct demux_packet *dp = ds->queue_head;
double ts = PTS_OR_DEF(dp->dts, dp->pts);
// Note: in obscure cases, packets might have no timestamps set,
// in which case we still need to prune _something_.
if (earliest_ts == MP_NOPTS_VALUE ||
(ts != MP_NOPTS_VALUE && ts < earliest_ts))
{
earliest_ts = ts;
earliest_stream = n;
}
}
}
assert(earliest_stream >= 0); // incorrect accounting of "buffered"?
struct demux_stream *ds = in->streams[earliest_stream]->ds;
ds->back_pts = MP_NOPTS_VALUE;
// Prune all packets until the next keyframe or reader_head. Keeping
// those packets would not help with seeking at all, so we strictly
// drop them.
// In addition, we need to find the new possibly min. seek target,
// which in the worst case could be inside the forward buffer. The fact
// that many keyframe ranges without keyframes exist (audio packets)
// makes this much harder.
// Note: might be pretty inefficient for streams with many small audio
// or subtitle packets. (All are keyframes, and selection logic runs for
// every packet.)
struct demux_packet *next_seek_target = NULL;
for (struct demux_packet *dp = ds->queue_head; dp; dp = dp->next) {
// (Has to be _after_ queue_head to drop at least 1 packet.)
if (dp->keyframe && dp != ds->queue_head) {
next_seek_target = dp;
// Note that we set back_pts to this even if we leave some
// packets before it - it will still be only viable seek target.
ds->back_pts = recompute_keyframe_target_pts(dp);
if (ds->back_pts != MP_NOPTS_VALUE)
break;
}
}
while (ds->queue_head && (ds->queue_head != ds->reader_head &&
ds->queue_head != next_seek_target))
{
struct demux_packet *dp = ds->queue_head;
size_t bytes = demux_packet_estimate_total_size(dp);
buffered -= bytes;
MP_TRACE(in, "dropping backbuffer packet size %zd from stream %d\n",
bytes, earliest_stream);
ds->queue_head = dp->next;
if (!ds->queue_head)
ds->queue_tail = NULL;
talloc_free(dp);
ds->bw_bytes -= bytes;
}
}
}
static void execute_trackswitch(struct demux_internal *in)
{
in->tracks_switched = false;
bool any_selected = false;
for (int n = 0; n < in->num_streams; n++)
any_selected |= in->streams[n]->ds->selected;
pthread_mutex_unlock(&in->lock);
if (in->d_thread->desc->control)
in->d_thread->desc->control(in->d_thread, DEMUXER_CTRL_SWITCHED_TRACKS, 0);
stream_control(in->d_thread->stream, STREAM_CTRL_SET_READAHEAD,
&(int){any_selected});
pthread_mutex_lock(&in->lock);
}
static void execute_seek(struct demux_internal *in)
{
int flags = in->seek_flags;
double pts = in->seek_pts;
in->seeking = false;
in->initial_state = false;
pthread_mutex_unlock(&in->lock);
MP_VERBOSE(in, "execute seek (to %f flags %d)\n", pts, flags);
if (in->d_thread->desc->seek)
in->d_thread->desc->seek(in->d_thread, pts, flags);
MP_VERBOSE(in, "seek done\n");
pthread_mutex_lock(&in->lock);
}
static void *demux_thread(void *pctx)
{
struct demux_internal *in = pctx;
mpthread_set_name("demux");
pthread_mutex_lock(&in->lock);
while (!in->thread_terminate) {
if (in->run_fn) {
in->run_fn(in->run_fn_arg);
in->run_fn = NULL;
pthread_cond_signal(&in->wakeup);
continue;
}
if (in->tracks_switched) {
execute_trackswitch(in);
continue;
}
if (in->seeking) {
execute_seek(in);
continue;
}
if (!in->eof) {
if (read_packet(in))
continue; // read_packet unlocked, so recheck conditions
}
if (in->force_cache_update) {
pthread_mutex_unlock(&in->lock);
update_cache(in);
pthread_mutex_lock(&in->lock);
in->force_cache_update = false;
continue;
}
pthread_cond_signal(&in->wakeup);
pthread_cond_wait(&in->wakeup, &in->lock);
}
pthread_mutex_unlock(&in->lock);
return NULL;
}
static struct demux_packet *dequeue_packet(struct demux_stream *ds)
{
if (ds->sh->attached_picture) {
ds->eof = true;
if (ds->attached_picture_added)
return NULL;
ds->attached_picture_added = true;
struct demux_packet *pkt = demux_copy_packet(ds->sh->attached_picture);
if (!pkt)
abort();
pkt->stream = ds->sh->index;
return pkt;
}
if (!ds->reader_head)
return NULL;
struct demux_packet *pkt = ds->reader_head;
ds->reader_head = pkt->next;
// Update cached packet queue state.
ds->fw_packs--;
size_t bytes = demux_packet_estimate_total_size(pkt);
ds->fw_bytes -= bytes;
ds->bw_bytes += bytes;
// The returned packet is mutated etc. and will be owned by the user.
pkt = demux_copy_packet(pkt);
if (!pkt)
abort();
pkt->next = NULL;
double ts = PTS_OR_DEF(pkt->dts, pkt->pts);
if (ts != MP_NOPTS_VALUE)
ds->base_ts = ts;
if (pkt->keyframe && ts != MP_NOPTS_VALUE) {
// Update bitrate - only at keyframe points, because we use the
// (possibly) reordered packet timestamps instead of realtime.
double d = ts - ds->last_br_ts;
if (ds->last_br_ts == MP_NOPTS_VALUE || d < 0) {
ds->bitrate = -1;
ds->last_br_ts = ts;
ds->last_br_bytes = 0;
} else if (d >= 0.5) { // a window of least 500ms for UI purposes
ds->bitrate = ds->last_br_bytes / d;
ds->last_br_ts = ts;
ds->last_br_bytes = 0;
}
}
ds->last_br_bytes += pkt->len;
// This implies this function is actually called from "the" user thread.
if (pkt->pos >= ds->in->d_user->filepos)
ds->in->d_user->filepos = pkt->pos;
pkt->pts = MP_ADD_PTS(pkt->pts, ds->in->ts_offset);
pkt->dts = MP_ADD_PTS(pkt->dts, ds->in->ts_offset);
pkt->start = MP_ADD_PTS(pkt->start, ds->in->ts_offset);
pkt->end = MP_ADD_PTS(pkt->end, ds->in->ts_offset);
prune_old_packets(ds->in);
return pkt;
}
// Whether to avoid actively demuxing new packets to find a new packet on the
// given stream.
// Attached pictures (cover art) should never actively read.
// Sparse packets (Subtitles) interleaved with other non-sparse packets (video,
// audio) should never be read actively, meaning the demuxer thread does not
// try to exceed default readahead in order to find a new packet.
static bool use_lazy_packet_reading(struct demux_stream *ds)
{
if (ds->sh->attached_picture)
return true;
if (ds->type != STREAM_SUB)
return false;
// Subtitles are only lazily read if there's at least 1 other actively read
// stream.
for (int n = 0; n < ds->in->num_streams; n++) {
struct demux_stream *s = ds->in->streams[n]->ds;
if (s->type != STREAM_SUB && s->selected && !s->eof && !
s->sh->attached_picture)
return true;
}
return false;
}
// Read a packet from the given stream. The returned packet belongs to the
// caller, who has to free it with talloc_free(). Might block. Returns NULL
// on EOF.
struct demux_packet *demux_read_packet(struct sh_stream *sh)
{
struct demux_stream *ds = sh ? sh->ds : NULL;
struct demux_packet *pkt = NULL;
if (ds) {
struct demux_internal *in = ds->in;
pthread_mutex_lock(&in->lock);
if (!use_lazy_packet_reading(ds)) {
const char *t = stream_type_name(ds->type);
MP_DBG(in, "reading packet for %s\n", t);
in->eof = false; // force retry
while (ds->selected && !ds->reader_head) {
ds->active = true;
// Note: the following code marks EOF if it can't continue
if (in->threading) {
MP_VERBOSE(in, "waiting for demux thread (%s)\n", t);
pthread_cond_signal(&in->wakeup);
pthread_cond_wait(&in->wakeup, &in->lock);
} else {
read_packet(in);
}
if (ds->eof)
break;
}
}
pkt = dequeue_packet(ds);
pthread_cond_signal(&in->wakeup); // possibly read more
pthread_mutex_unlock(&in->lock);
}
return pkt;
}
// Poll the demuxer queue, and if there's a packet, return it. Otherwise, just
// make the demuxer thread read packets for this stream, and if there's at
// least one packet, call the wakeup callback.
// Unlike demux_read_packet(), this always enables readahead (except for
// interleaved subtitles).
// Returns:
// < 0: EOF was reached, *out_pkt=NULL
// == 0: no new packet yet, but maybe later, *out_pkt=NULL
// > 0: new packet read, *out_pkt is set
// Note: when reading interleaved subtitles, the demuxer won't try to forcibly
// read ahead to get the next subtitle packet (as the next packet could be
// minutes away). In this situation, this function will just return -1.
int demux_read_packet_async(struct sh_stream *sh, struct demux_packet **out_pkt)
{
struct demux_stream *ds = sh ? sh->ds : NULL;
int r = -1;
*out_pkt = NULL;
if (ds) {
if (ds->in->threading) {
pthread_mutex_lock(&ds->in->lock);
*out_pkt = dequeue_packet(ds);
if (use_lazy_packet_reading(ds)) {
r = *out_pkt ? 1 : -1;
} else {
r = *out_pkt ? 1 : ((ds->eof || !ds->selected) ? -1 : 0);
ds->active = ds->selected; // enable readahead
ds->in->eof = false; // force retry
pthread_cond_signal(&ds->in->wakeup); // possibly read more
}
pthread_mutex_unlock(&ds->in->lock);
} else {
*out_pkt = demux_read_packet(sh);
r = *out_pkt ? 1 : -1;
}
}
return r;
}
// Return whether a packet is queued. Never blocks, never forces any reads.
bool demux_has_packet(struct sh_stream *sh)
{
bool has_packet = false;
if (sh) {
pthread_mutex_lock(&sh->ds->in->lock);
has_packet = sh->ds->reader_head;
pthread_mutex_unlock(&sh->ds->in->lock);
}
return has_packet;
}
// Read and return any packet we find. NULL means EOF.
struct demux_packet *demux_read_any_packet(struct demuxer *demuxer)
{
struct demux_internal *in = demuxer->in;
assert(!in->threading); // doesn't work with threading
bool read_more = true;
while (read_more) {
for (int n = 0; n < in->num_streams; n++) {
struct sh_stream *sh = in->streams[n];
sh->ds->active = sh->ds->selected; // force read_packet() to read
struct demux_packet *pkt = dequeue_packet(sh->ds);
if (pkt)
return pkt;
}
// retry after calling this
pthread_mutex_lock(&in->lock); // lock only because read_packet unlocks
read_more = read_packet(in);
read_more &= !in->eof;
pthread_mutex_unlock(&in->lock);
}
return NULL;
}
void demuxer_help(struct mp_log *log)
{
int i;
mp_info(log, "Available demuxers:\n");
mp_info(log, " demuxer: info:\n");
for (i = 0; demuxer_list[i]; i++) {
mp_info(log, "%10s %s\n",
demuxer_list[i]->name, demuxer_list[i]->desc);
}
}
static const char *d_level(enum demux_check level)
{
switch (level) {
case DEMUX_CHECK_FORCE: return "force";
case DEMUX_CHECK_UNSAFE: return "unsafe";
case DEMUX_CHECK_REQUEST:return "request";
case DEMUX_CHECK_NORMAL: return "normal";
}
abort();
}
static int decode_float(char *str, float *out)
{
char *rest;
float dec_val;
dec_val = strtod(str, &rest);
if (!rest || (rest == str) || !isfinite(dec_val))
return -1;
*out = dec_val;
return 0;
}
static int decode_gain(struct mp_log *log, struct mp_tags *tags,
const char *tag, float *out)
{
char *tag_val = NULL;
float dec_val;
tag_val = mp_tags_get_str(tags, tag);
if (!tag_val)
return -1;
if (decode_float(tag_val, &dec_val) < 0) {
mp_msg(log, MSGL_ERR, "Invalid replaygain value\n");
return -1;
}
*out = dec_val;
return 0;
}
static int decode_peak(struct mp_log *log, struct mp_tags *tags,
const char *tag, float *out)
{
char *tag_val = NULL;
float dec_val;
*out = 1.0;
tag_val = mp_tags_get_str(tags, tag);
if (!tag_val)
return 0;
if (decode_float(tag_val, &dec_val) < 0 || dec_val <= 0.0)
return -1;
*out = dec_val;
return 0;
}
static struct replaygain_data *decode_rgain(struct mp_log *log,
struct mp_tags *tags)
{
struct replaygain_data rg = {0};
if (decode_gain(log, tags, "REPLAYGAIN_TRACK_GAIN", &rg.track_gain) >= 0 &&
decode_peak(log, tags, "REPLAYGAIN_TRACK_PEAK", &rg.track_peak) >= 0)
{
if (decode_gain(log, tags, "REPLAYGAIN_ALBUM_GAIN", &rg.album_gain) < 0 ||
decode_peak(log, tags, "REPLAYGAIN_ALBUM_PEAK", &rg.album_peak) < 0)
{
rg.album_gain = rg.track_gain;
rg.album_peak = rg.track_peak;
}
return talloc_memdup(NULL, &rg, sizeof(rg));
}
if (decode_gain(log, tags, "REPLAYGAIN_GAIN", &rg.track_gain) >= 0 &&
decode_peak(log, tags, "REPLAYGAIN_PEAK", &rg.track_peak) >= 0)
{
rg.album_gain = rg.track_gain;
rg.album_peak = rg.track_peak;
return talloc_memdup(NULL, &rg, sizeof(rg));
}
return NULL;
}
static void demux_update_replaygain(demuxer_t *demuxer)
{
struct demux_internal *in = demuxer->in;
for (int n = 0; n < in->num_streams; n++) {
struct sh_stream *sh = in->streams[n];
if (sh->type == STREAM_AUDIO && !sh->codec->replaygain_data) {
struct replaygain_data *rg = decode_rgain(demuxer->log, sh->tags);
if (!rg)
rg = decode_rgain(demuxer->log, demuxer->metadata);
if (rg)
sh->codec->replaygain_data = talloc_steal(in, rg);
}
}
}
// Copy all fields from src to dst, depending on event flags.
static void demux_copy(struct demuxer *dst, struct demuxer *src)
{
if (src->events & DEMUX_EVENT_INIT) {
// Note that we do as shallow copies as possible. We expect the data
// that is not-copied (only referenced) to be immutable.
// This implies e.g. that no chapters are added after initialization.
dst->chapters = src->chapters;
dst->num_chapters = src->num_chapters;
dst->editions = src->editions;
dst->num_editions = src->num_editions;
dst->edition = src->edition;
dst->attachments = src->attachments;
dst->num_attachments = src->num_attachments;
dst->matroska_data = src->matroska_data;
dst->playlist = src->playlist;
dst->seekable = src->seekable;
dst->partially_seekable = src->partially_seekable;
dst->filetype = src->filetype;
dst->ts_resets_possible = src->ts_resets_possible;
dst->fully_read = src->fully_read;
dst->start_time = src->start_time;
dst->duration = src->duration;
dst->is_network = src->is_network;
dst->priv = src->priv;
}
if (src->events & DEMUX_EVENT_METADATA) {
talloc_free(dst->metadata);
dst->metadata = mp_tags_dup(dst, src->metadata);
if (dst->num_update_stream_tags != src->num_update_stream_tags) {
dst->num_update_stream_tags = src->num_update_stream_tags;
talloc_free(dst->update_stream_tags);
dst->update_stream_tags =
talloc_zero_array(dst, struct mp_tags *, dst->num_update_stream_tags);
}
for (int n = 0; n < dst->num_update_stream_tags; n++) {
talloc_free(dst->update_stream_tags[n]);
dst->update_stream_tags[n] =
talloc_steal(dst->update_stream_tags, src->update_stream_tags[n]);
src->update_stream_tags[n] = NULL;
}
}
dst->events |= src->events;
src->events = 0;
}
// This is called by demuxer implementations if certain parameters change
// at runtime.
// events is one of DEMUX_EVENT_*
// The code will copy the fields references by the events to the user-thread.
void demux_changed(demuxer_t *demuxer, int events)
{
assert(demuxer == demuxer->in->d_thread); // call from demuxer impl. only
struct demux_internal *in = demuxer->in;
demuxer->events |= events;
update_cache(in);
pthread_mutex_lock(&in->lock);
if (demuxer->events & DEMUX_EVENT_INIT)
demuxer_sort_chapters(demuxer);
demux_copy(in->d_buffer, demuxer);
if (in->wakeup_cb)
in->wakeup_cb(in->wakeup_cb_ctx);
pthread_mutex_unlock(&in->lock);
}
// Called by the user thread (i.e. player) to update metadata and other things
// from the demuxer thread.
void demux_update(demuxer_t *demuxer)
{
assert(demuxer == demuxer->in->d_user);
struct demux_internal *in = demuxer->in;
if (!in->threading)
update_cache(in);
pthread_mutex_lock(&in->lock);
demux_copy(demuxer, in->d_buffer);
demuxer->events |= in->events;
in->events = 0;
if (demuxer->events & DEMUX_EVENT_METADATA) {
int num_streams = MPMIN(in->num_streams, demuxer->num_update_stream_tags);
for (int n = 0; n < num_streams; n++) {
struct mp_tags *tags = demuxer->update_stream_tags[n];
demuxer->update_stream_tags[n] = NULL;
if (tags) {
struct sh_stream *sh = in->streams[n];
talloc_free(sh->tags);
sh->tags = talloc_steal(sh, tags);
}
}
// Often useful audio-only files, which have metadata in the audio track
// metadata instead of the main metadata (especially OGG).
if (in->num_streams == 1)
mp_tags_merge(demuxer->metadata, in->streams[0]->tags);
if (in->stream_metadata)
mp_tags_merge(demuxer->metadata, in->stream_metadata);
}
if (demuxer->events & (DEMUX_EVENT_METADATA | DEMUX_EVENT_STREAMS))
demux_update_replaygain(demuxer);
pthread_mutex_unlock(&in->lock);
}
static void demux_init_cache(struct demuxer *demuxer)
{
struct demux_internal *in = demuxer->in;
struct stream *stream = demuxer->stream;
char *base = NULL;
stream_control(stream, STREAM_CTRL_GET_BASE_FILENAME, &base);
in->stream_base_filename = talloc_steal(demuxer, base);
}
static void demux_init_cuesheet(struct demuxer *demuxer)
{
char *cue = mp_tags_get_str(demuxer->metadata, "cuesheet");
if (cue && !demuxer->num_chapters) {
struct cue_file *f = mp_parse_cue(bstr0(cue));
if (f) {
if (mp_check_embedded_cue(f) < 0) {
MP_WARN(demuxer, "Embedded cue sheet references more than one file. "
"Ignoring it.\n");
} else {
for (int n = 0; n < f->num_tracks; n++) {
struct cue_track *t = &f->tracks[n];
int idx = demuxer_add_chapter(demuxer, "", t->start, -1);
mp_tags_merge(demuxer->chapters[idx].metadata, t->tags);
}
}
}
talloc_free(f);
}
}
static void demux_maybe_replace_stream(struct demuxer *demuxer)
{
struct demux_internal *in = demuxer->in;
assert(!in->threading && demuxer == in->d_user);
if (demuxer->fully_read) {
MP_VERBOSE(demuxer, "assuming demuxer read all data; closing stream\n");
free_stream(demuxer->stream);
demuxer->stream = open_memory_stream(NULL, 0); // dummy
in->d_thread->stream = demuxer->stream;
in->d_buffer->stream = demuxer->stream;
if (demuxer->desc->control)
demuxer->desc->control(in->d_thread, DEMUXER_CTRL_REPLACE_STREAM, NULL);
}
}
static struct demuxer *open_given_type(struct mpv_global *global,
struct mp_log *log,
const struct demuxer_desc *desc,
struct stream *stream,
struct demuxer_params *params,
enum demux_check check)
{
if (mp_cancel_test(stream->cancel))
return NULL;
struct demuxer *demuxer = talloc_ptrtype(NULL, demuxer);
struct demux_opts *opts = mp_get_config_group(demuxer, global, &demux_conf);
*demuxer = (struct demuxer) {
.desc = desc,
.stream = stream,
.seekable = stream->seekable,
.filepos = -1,
.global = global,
.log = mp_log_new(demuxer, log, desc->name),
.glog = log,
.filename = talloc_strdup(demuxer, stream->url),
.is_network = stream->is_network,
.access_references = opts->access_references,
.events = DEMUX_EVENT_ALL,
};
demuxer->seekable = stream->seekable;
if (demuxer->stream->underlying && !demuxer->stream->underlying->seekable)
demuxer->seekable = false;
struct demux_internal *in = demuxer->in = talloc_ptrtype(demuxer, in);
*in = (struct demux_internal){
.log = demuxer->log,
.d_thread = talloc(demuxer, struct demuxer),
.d_buffer = talloc(demuxer, struct demuxer),
.d_user = demuxer,
.min_secs = opts->min_secs,
.max_bytes = opts->max_bytes,
.max_bytes_bw = opts->max_bytes_bw,
.seekable_cache = opts->seekable_cache,
.initial_state = true,
};
pthread_mutex_init(&in->lock, NULL);
pthread_cond_init(&in->wakeup, NULL);
*in->d_thread = *demuxer;
*in->d_buffer = *demuxer;
in->d_thread->metadata = talloc_zero(in->d_thread, struct mp_tags);
in->d_user->metadata = talloc_zero(in->d_user, struct mp_tags);
in->d_buffer->metadata = talloc_zero(in->d_buffer, struct mp_tags);
mp_dbg(log, "Trying demuxer: %s (force-level: %s)\n",
desc->name, d_level(check));
// not for DVD/BD/DVB in particular
if (stream->seekable && (!params || !params->timeline))
stream_seek(stream, 0);
// Peek this much data to avoid that stream_read() run by some demuxers
// will flush previous peeked data.
stream_peek(stream, STREAM_BUFFER_SIZE);
in->d_thread->params = params; // temporary during open()
int ret = demuxer->desc->open(in->d_thread, check);
if (ret >= 0) {
in->d_thread->params = NULL;
if (in->d_thread->filetype)
mp_verbose(log, "Detected file format: %s (%s)\n",
in->d_thread->filetype, desc->desc);
else
mp_verbose(log, "Detected file format: %s\n", desc->desc);
if (!in->d_thread->seekable)
mp_verbose(log, "Stream is not seekable.\n");
if (!in->d_thread->seekable && opts->force_seekable) {
mp_warn(log, "Not seekable, but enabling seeking on user request.\n");
in->d_thread->seekable = true;
in->d_thread->partially_seekable = true;
}
demux_init_cuesheet(in->d_thread);
demux_init_cache(demuxer);
demux_changed(in->d_thread, DEMUX_EVENT_ALL);
demux_update(demuxer);
stream_control(demuxer->stream, STREAM_CTRL_SET_READAHEAD,
&(int){params ? params->initial_readahead : false});
if (!(params && params->disable_timeline)) {
struct timeline *tl = timeline_load(global, log, demuxer);
if (tl) {
struct demuxer_params params2 = {0};
params2.timeline = tl;
struct demuxer *sub =
open_given_type(global, log, &demuxer_desc_timeline, stream,
&params2, DEMUX_CHECK_FORCE);
if (sub) {
demuxer = sub;
} else {
timeline_destroy(tl);
}
}
}
if (demuxer->is_network || stream->caching)
in->min_secs = MPMAX(in->min_secs, opts->min_secs_cache);
return demuxer;
}
free_demuxer(demuxer);
return NULL;
}
static const int d_normal[] = {DEMUX_CHECK_NORMAL, DEMUX_CHECK_UNSAFE, -1};
static const int d_request[] = {DEMUX_CHECK_REQUEST, -1};
static const int d_force[] = {DEMUX_CHECK_FORCE, -1};
// params can be NULL
struct demuxer *demux_open(struct stream *stream, struct demuxer_params *params,
struct mpv_global *global)
{
const int *check_levels = d_normal;
const struct demuxer_desc *check_desc = NULL;
struct mp_log *log = mp_log_new(NULL, global->log, "!demux");
struct demuxer *demuxer = NULL;
char *force_format = params ? params->force_format : NULL;
if (!force_format)
force_format = stream->demuxer;
if (force_format && force_format[0]) {
check_levels = d_request;
if (force_format[0] == '+') {
force_format += 1;
check_levels = d_force;
}
for (int n = 0; demuxer_list[n]; n++) {
if (strcmp(demuxer_list[n]->name, force_format) == 0)
check_desc = demuxer_list[n];
}
if (!check_desc) {
mp_err(log, "Demuxer %s does not exist.\n", force_format);
goto done;
}
}
// Test demuxers from first to last, one pass for each check_levels[] entry
for (int pass = 0; check_levels[pass] != -1; pass++) {
enum demux_check level = check_levels[pass];
mp_verbose(log, "Trying demuxers for level=%s.\n", d_level(level));
for (int n = 0; demuxer_list[n]; n++) {
const struct demuxer_desc *desc = demuxer_list[n];
if (!check_desc || desc == check_desc) {
demuxer = open_given_type(global, log, desc, stream, params, level);
if (demuxer) {
talloc_steal(demuxer, log);
log = NULL;
goto done;
}
}
}
}
done:
talloc_free(log);
return demuxer;
}
// Convenience function: open the stream, enable the cache (according to params
// and global opts.), open the demuxer.
// (use free_demuxer_and_stream() to free the underlying stream too)
// Also for some reason may close the opened stream if it's not needed.
struct demuxer *demux_open_url(const char *url,
struct demuxer_params *params,
struct mp_cancel *cancel,
struct mpv_global *global)
{
struct demuxer_params dummy = {0};
if (!params)
params = &dummy;
struct stream *s = stream_create(url, STREAM_READ | params->stream_flags,
cancel, global);
if (!s)
return NULL;
if (!params->disable_cache)
stream_enable_cache_defaults(&s);
struct demuxer *d = demux_open(s, params, global);
if (d) {
demux_maybe_replace_stream(d);
} else {
params->demuxer_failed = true;
free_stream(s);
}
return d;
}
// called locked, from user thread only
static void clear_reader_state(struct demux_internal *in)
{
for (int n = 0; n < in->num_streams; n++)
ds_clear_reader_state(in->streams[n]->ds);
in->warned_queue_overflow = false;
in->d_user->filepos = -1; // implicitly synchronized
}
static void clear_demux_state(struct demux_internal *in)
{
clear_reader_state(in);
for (int n = 0; n < in->num_streams; n++)
ds_clear_demux_state(in->streams[n]->ds);
in->eof = false;
in->last_eof = false;
in->idle = true;
}
// clear the packet queues
void demux_flush(demuxer_t *demuxer)
{
pthread_mutex_lock(&demuxer->in->lock);
clear_demux_state(demuxer->in);
pthread_mutex_unlock(&demuxer->in->lock);
}
static void recompute_buffers(struct demux_stream *ds)
{
ds->fw_packs = 0;
ds->fw_bytes = 0;
ds->bw_bytes = 0;
bool in_backbuffer = true;
for (struct demux_packet *dp = ds->queue_head; dp; dp = dp->next) {
if (dp == ds->reader_head)
in_backbuffer = false;
size_t bytes = demux_packet_estimate_total_size(dp);
if (in_backbuffer) {
ds->bw_bytes += bytes;
} else {
ds->fw_packs++;
ds->fw_bytes += bytes;
}
}
}
static struct demux_packet *find_seek_target(struct demux_stream *ds,
double pts, int flags)
{
struct demux_packet *target = NULL;
double target_diff = MP_NOPTS_VALUE;
for (struct demux_packet *dp = ds->queue_head; dp; dp = dp->next) {
if (!dp->keyframe)
continue;
double range_pts = recompute_keyframe_target_pts(dp);
if (range_pts == MP_NOPTS_VALUE)
continue;
double diff = range_pts - pts;
if (flags & SEEK_FORWARD) {
diff = -diff;
if (diff > 0)
continue;
}
if (target_diff != MP_NOPTS_VALUE) {
if (diff <= 0) {
if (target_diff <= 0 && diff <= target_diff)
continue;
} else if (diff >= target_diff)
continue;
}
target_diff = diff;
target = dp;
}
return target;
}
// must be called locked
static bool try_seek_cache(struct demux_internal *in, double pts, int flags)
{
if ((flags & SEEK_FACTOR) || !in->seekable_cache)
return false;
// no idea how this could interact
if (in->seeking)
return false;
struct demux_ctrl_reader_state rstate;
if (cached_demux_control(in, DEMUXER_CTRL_GET_READER_STATE, &rstate) < 0)
return false;
double start = MP_ADD_PTS(rstate.ts_min, -in->ts_offset);
double end = MP_ADD_PTS(rstate.ts_max, -in->ts_offset);
MP_VERBOSE(in, "in-cache seek range = %f <-> %f (%f)\n", start, end, pts);
if (start == MP_NOPTS_VALUE || end == MP_NOPTS_VALUE)
return false;
if (pts < start || pts > end)
return false;
clear_reader_state(in);
// Adjust the seek target to the found video key frames. Otherwise the
// video will undershoot the seek target, while audio will be closer to it.
// The player frontend will play the additional video without audio, so
// you get silent audio for the amount of "undershoot". Adjusting the seek
// target will make the audio seek to the video target or before.
// (If hr-seeks are used, it's better to skip this, as it would only mean
// that more audio data than necessary would have to be decoded.)
if (!(flags & SEEK_HR)) {
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
if (ds->selected && ds->type == STREAM_VIDEO) {
struct demux_packet *target = find_seek_target(ds, pts, flags);
if (target) {
double target_pts = recompute_keyframe_target_pts(target);
if (target_pts != MP_NOPTS_VALUE) {
MP_VERBOSE(in, "adjust seek target %f -> %f\n",
pts, target_pts);
// (We assume the find_seek_target() will return the
// same target for the video stream.)
pts = target_pts;
flags &= ~SEEK_FORWARD;
}
}
break;
}
}
}
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
struct demux_packet *target = find_seek_target(ds, pts, flags);
ds->reader_head = target;
ds->skip_to_keyframe = !target;
recompute_buffers(ds);
MP_VERBOSE(in, "seeking stream %d (%s) to ",
n, stream_type_name(ds->type));
if (target) {
MP_VERBOSE(in, "packet %f/%f\n", target->pts, target->dts);
} else {
MP_VERBOSE(in, "nothing\n");
}
}
return true;
}
int demux_seek(demuxer_t *demuxer, double seek_pts, int flags)
{
struct demux_internal *in = demuxer->in;
assert(demuxer == in->d_user);
if (!demuxer->seekable) {
MP_WARN(demuxer, "Cannot seek in this file.\n");
return 0;
}
if (seek_pts == MP_NOPTS_VALUE)
return 0;
pthread_mutex_lock(&in->lock);
MP_VERBOSE(in, "queuing seek to %f%s\n", seek_pts,
in->seeking ? " (cascade)" : "");
if (!(flags & SEEK_FACTOR))
seek_pts = MP_ADD_PTS(seek_pts, -in->ts_offset);
if (try_seek_cache(in, seek_pts, flags)) {
MP_VERBOSE(in, "in-cache seek worked!\n");
} else {
clear_demux_state(in);
in->seeking = true;
in->seek_flags = flags;
in->seek_pts = seek_pts;
if (!in->threading)
execute_seek(in);
}
pthread_cond_signal(&in->wakeup);
pthread_mutex_unlock(&in->lock);
return 1;
}
struct sh_stream *demuxer_stream_by_demuxer_id(struct demuxer *d,
enum stream_type t, int id)
{
int num = demux_get_num_stream(d);
for (int n = 0; n < num; n++) {
struct sh_stream *s = demux_get_stream(d, n);
if (s->type == t && s->demuxer_id == id)
return s;
}
return NULL;
}
// Set whether the given stream should return packets.
// ref_pts is used only if the stream is enabled. Then it serves as approximate
// start pts for this stream (in the worst case it is ignored).
void demuxer_select_track(struct demuxer *demuxer, struct sh_stream *stream,
double ref_pts, bool selected)
{
struct demux_internal *in = demuxer->in;
pthread_mutex_lock(&in->lock);
// don't flush buffers if stream is already selected / unselected
if (stream->ds->selected != selected) {
stream->ds->selected = selected;
ds_clear_demux_state(stream->ds);
in->tracks_switched = true;
stream->ds->need_refresh = selected && !in->initial_state;
if (stream->ds->need_refresh)
in->ref_pts = MP_ADD_PTS(ref_pts, -in->ts_offset);
if (in->threading) {
pthread_cond_signal(&in->wakeup);
} else {
execute_trackswitch(in);
}
}
pthread_mutex_unlock(&in->lock);
}
void demux_set_stream_autoselect(struct demuxer *demuxer, bool autoselect)
{
assert(!demuxer->in->threading); // laziness
demuxer->in->autoselect = autoselect;
}
// This is for demuxer implementations only. demuxer_select_track() sets the
// logical state, while this function returns the actual state (in case the
// demuxer attempts to cache even unselected packets for track switching - this
// will potentially be done in the future).
bool demux_stream_is_selected(struct sh_stream *stream)
{
if (!stream)
return false;
bool r = false;
pthread_mutex_lock(&stream->ds->in->lock);
r = stream->ds->selected;
pthread_mutex_unlock(&stream->ds->in->lock);
return r;
}
int demuxer_add_attachment(demuxer_t *demuxer, char *name, char *type,
void *data, size_t data_size)
{
if (!(demuxer->num_attachments % 32))
demuxer->attachments = talloc_realloc(demuxer, demuxer->attachments,
struct demux_attachment,
demuxer->num_attachments + 32);
struct demux_attachment *att = &demuxer->attachments[demuxer->num_attachments];
att->name = talloc_strdup(demuxer->attachments, name);
att->type = talloc_strdup(demuxer->attachments, type);
att->data = talloc_memdup(demuxer->attachments, data, data_size);
att->data_size = data_size;
return demuxer->num_attachments++;
}
static int chapter_compare(const void *p1, const void *p2)
{
struct demux_chapter *c1 = (void *)p1;
struct demux_chapter *c2 = (void *)p2;
if (c1->pts > c2->pts)
return 1;
else if (c1->pts < c2->pts)
return -1;
return c1->original_index > c2->original_index ? 1 :-1; // never equal
}
static void demuxer_sort_chapters(demuxer_t *demuxer)
{
qsort(demuxer->chapters, demuxer->num_chapters,
sizeof(struct demux_chapter), chapter_compare);
}
int demuxer_add_chapter(demuxer_t *demuxer, char *name,
double pts, uint64_t demuxer_id)
{
struct demux_chapter new = {
.original_index = demuxer->num_chapters,
.pts = pts,
.metadata = talloc_zero(demuxer, struct mp_tags),
.demuxer_id = demuxer_id,
};
mp_tags_set_str(new.metadata, "TITLE", name);
MP_TARRAY_APPEND(demuxer, demuxer->chapters, demuxer->num_chapters, new);
return demuxer->num_chapters - 1;
}
// must be called not locked
static void update_cache(struct demux_internal *in)
{
struct demuxer *demuxer = in->d_thread;
struct stream *stream = demuxer->stream;
// Don't lock while querying the stream.
struct mp_tags *stream_metadata = NULL;
struct stream_cache_info stream_cache_info = {.size = -1};
int64_t stream_size = stream_get_size(stream);
stream_control(stream, STREAM_CTRL_GET_METADATA, &stream_metadata);
stream_control(stream, STREAM_CTRL_GET_CACHE_INFO, &stream_cache_info);
pthread_mutex_lock(&in->lock);
in->stream_size = stream_size;
in->stream_cache_info = stream_cache_info;
if (stream_metadata) {
talloc_free(in->stream_metadata);
in->stream_metadata = talloc_steal(in, stream_metadata);
in->d_buffer->events |= DEMUX_EVENT_METADATA;
}
pthread_mutex_unlock(&in->lock);
}
// must be called locked
static int cached_stream_control(struct demux_internal *in, int cmd, void *arg)
{
// If the cache is active, wake up the thread to possibly update cache state.
if (in->stream_cache_info.size >= 0) {
in->force_cache_update = true;
pthread_cond_signal(&in->wakeup);
}
switch (cmd) {
case STREAM_CTRL_GET_CACHE_INFO:
if (in->stream_cache_info.size < 0)
return STREAM_UNSUPPORTED;
*(struct stream_cache_info *)arg = in->stream_cache_info;
return STREAM_OK;
case STREAM_CTRL_GET_SIZE:
if (in->stream_size < 0)
return STREAM_UNSUPPORTED;
*(int64_t *)arg = in->stream_size;
return STREAM_OK;
case STREAM_CTRL_GET_BASE_FILENAME:
if (!in->stream_base_filename)
return STREAM_UNSUPPORTED;
*(char **)arg = talloc_strdup(NULL, in->stream_base_filename);
return STREAM_OK;
}
return STREAM_ERROR;
}
// must be called locked
static int cached_demux_control(struct demux_internal *in, int cmd, void *arg)
{
switch (cmd) {
case DEMUXER_CTRL_STREAM_CTRL: {
struct demux_ctrl_stream_ctrl *c = arg;
int r = cached_stream_control(in, c->ctrl, c->arg);
if (r == STREAM_ERROR)
break;
c->res = r;
return CONTROL_OK;
}
case DEMUXER_CTRL_GET_BITRATE_STATS: {
double *rates = arg;
for (int n = 0; n < STREAM_TYPE_COUNT; n++)
rates[n] = -1;
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
if (ds->selected && ds->bitrate >= 0)
rates[ds->type] = MPMAX(0, rates[ds->type]) + ds->bitrate;
}
return CONTROL_OK;
}
case DEMUXER_CTRL_GET_READER_STATE: {
struct demux_ctrl_reader_state *r = arg;
*r = (struct demux_ctrl_reader_state){
.eof = in->last_eof,
.seekable = in->seekable_cache,
.ts_start = MP_NOPTS_VALUE,
.ts_min = MP_NOPTS_VALUE,
.ts_max = MP_NOPTS_VALUE,
.ts_reader = MP_NOPTS_VALUE,
.ts_duration = -1,
};
bool any_packets = false;
bool seek_ok = true;
for (int n = 0; n < in->num_streams; n++) {
struct demux_stream *ds = in->streams[n]->ds;
if (ds->active && !(!ds->queue_head && ds->eof) && !ds->ignore_eof)
{
r->underrun |= !ds->reader_head && !ds->eof;
r->ts_reader = MP_PTS_MAX(r->ts_reader, ds->base_ts);
// (yes, this is asymmetric, and uses MAX in both cases - it's ok
// if it's a bit off for ts_max, as the demuxer can just wait for
// new packets if we seek there and also last_ts is the hightest
// DTS or PTS, while ts_min should be as accurate as possible, as
// we would have to trigger a real seek if it's off and we seeked
// there)
r->ts_min = MP_PTS_MAX(r->ts_min, ds->back_pts);
r->ts_max = MP_PTS_MAX(r->ts_max, ds->last_ts);
if (ds->back_pts == MP_NOPTS_VALUE ||
ds->last_ts == MP_NOPTS_VALUE)
seek_ok = false;
if (ds->queue_head) {
any_packets = true;
double ts = PTS_OR_DEF(ds->queue_head->dts,
ds->queue_head->pts);
r->ts_start = MP_PTS_MIN(r->ts_start, ts);
if (ds->queue_tail->segmented)
r->ts_max = MP_PTS_MIN(r->ts_max, ds->queue_tail->end);
}
}
}
r->idle = (in->idle && !r->underrun) || r->eof;
r->underrun &= !r->idle;
r->ts_start = MP_ADD_PTS(r->ts_start, in->ts_offset);
r->ts_min = MP_ADD_PTS(r->ts_min, in->ts_offset);
r->ts_max = MP_ADD_PTS(r->ts_max, in->ts_offset);
if (r->ts_reader != MP_NOPTS_VALUE && r->ts_reader <= r->ts_max)
r->ts_duration = r->ts_max - r->ts_reader;
if (in->seeking || !any_packets)
r->ts_duration = 0;
if (in->seeking || !seek_ok)
r->ts_max = r->ts_min = MP_NOPTS_VALUE;
return CONTROL_OK;
}
}
return CONTROL_UNKNOWN;
}
struct demux_control_args {
struct demuxer *demuxer;
int cmd;
void *arg;
int *r;
};
static void thread_demux_control(void *p)
{
struct demux_control_args *args = p;
struct demuxer *demuxer = args->demuxer;
int cmd = args->cmd;
void *arg = args->arg;
struct demux_internal *in = demuxer->in;
int r = CONTROL_UNKNOWN;
if (cmd == DEMUXER_CTRL_STREAM_CTRL) {
struct demux_ctrl_stream_ctrl *c = arg;
if (in->threading)
MP_VERBOSE(demuxer, "blocking for STREAM_CTRL %d\n", c->ctrl);
c->res = stream_control(demuxer->stream, c->ctrl, c->arg);
if (c->res != STREAM_UNSUPPORTED)
r = CONTROL_OK;
}
if (r != CONTROL_OK) {
if (in->threading)
MP_VERBOSE(demuxer, "blocking for DEMUXER_CTRL %d\n", cmd);
if (demuxer->desc->control)
r = demuxer->desc->control(demuxer->in->d_thread, cmd, arg);
}
*args->r = r;
}
int demux_control(demuxer_t *demuxer, int cmd, void *arg)
{
struct demux_internal *in = demuxer->in;
assert(demuxer == in->d_user);
if (in->threading) {
pthread_mutex_lock(&in->lock);
int cr = cached_demux_control(in, cmd, arg);
pthread_mutex_unlock(&in->lock);
if (cr != CONTROL_UNKNOWN)
return cr;
}
int r = 0;
struct demux_control_args args = {demuxer, cmd, arg, &r};
if (in->threading) {
MP_VERBOSE(in, "blocking on demuxer thread\n");
pthread_mutex_lock(&in->lock);
while (in->run_fn)
pthread_cond_wait(&in->wakeup, &in->lock);
in->run_fn = thread_demux_control;
in->run_fn_arg = &args;
pthread_cond_signal(&in->wakeup);
while (in->run_fn)
pthread_cond_wait(&in->wakeup, &in->lock);
pthread_mutex_unlock(&in->lock);
} else {
thread_demux_control(&args);
}
return r;
}
int demux_stream_control(demuxer_t *demuxer, int ctrl, void *arg)
{
struct demux_ctrl_stream_ctrl c = {ctrl, arg, STREAM_UNSUPPORTED};
demux_control(demuxer, DEMUXER_CTRL_STREAM_CTRL, &c);
return c.res;
}
bool demux_cancel_test(struct demuxer *demuxer)
{
return mp_cancel_test(demuxer->stream->cancel);
}
struct demux_chapter *demux_copy_chapter_data(struct demux_chapter *c, int num)
{
struct demux_chapter *new = talloc_array(NULL, struct demux_chapter, num);
for (int n = 0; n < num; n++) {
new[n] = c[n];
new[n].metadata = mp_tags_dup(new, new[n].metadata);
}
return new;
}