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chromium / chromium / src / 250b8204cef19bf2bf6b61b6d9c82d03f20e9ceb / . / media / filters / chunk_demuxer.cc
blob: e931c3fd72c3eb2fafa672cd51883c7a4825af0b [file] [log] [blame]
// Copyright (c) 2012 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "media/filters/chunk_demuxer.h"
#include <algorithm>
#include <limits>
#include <list>
#include <utility>
#include "base/bind.h"
#include "base/callback_helpers.h"
#include "base/location.h"
#include "base/macros.h"
#include "base/stl_util.h"
#include "media/base/audio_decoder_config.h"
#include "media/base/bind_to_current_loop.h"
#include "media/base/stream_parser_buffer.h"
#include "media/base/timestamp_constants.h"
#include "media/base/video_decoder_config.h"
#include "media/filters/frame_processor.h"
#include "media/filters/stream_parser_factory.h"
using base::TimeDelta;
namespace media {
ChunkDemuxerStream::ChunkDemuxerStream(Type type,
bool splice_frames_enabled)
: type_(type),
liveness_(DemuxerStream::LIVENESS_UNKNOWN),
state_(UNINITIALIZED),
splice_frames_enabled_(splice_frames_enabled),
partial_append_window_trimming_enabled_(false) {
}
void ChunkDemuxerStream::StartReturningData() {
DVLOG(1) << "ChunkDemuxerStream::StartReturningData()";
base::AutoLock auto_lock(lock_);
DCHECK(read_cb_.is_null());
ChangeState_Locked(RETURNING_DATA_FOR_READS);
}
void ChunkDemuxerStream::AbortReads() {
DVLOG(1) << "ChunkDemuxerStream::AbortReads()";
base::AutoLock auto_lock(lock_);
ChangeState_Locked(RETURNING_ABORT_FOR_READS);
if (!read_cb_.is_null())
base::ResetAndReturn(&read_cb_).Run(kAborted, NULL);
}
void ChunkDemuxerStream::CompletePendingReadIfPossible() {
base::AutoLock auto_lock(lock_);
if (read_cb_.is_null())
return;
CompletePendingReadIfPossible_Locked();
}
void ChunkDemuxerStream::Shutdown() {
DVLOG(1) << "ChunkDemuxerStream::Shutdown()";
base::AutoLock auto_lock(lock_);
ChangeState_Locked(SHUTDOWN);
// Pass an end of stream buffer to the pending callback to signal that no more
// data will be sent.
if (!read_cb_.is_null()) {
base::ResetAndReturn(&read_cb_).Run(DemuxerStream::kOk,
StreamParserBuffer::CreateEOSBuffer());
}
}
bool ChunkDemuxerStream::IsSeekWaitingForData() const {
base::AutoLock auto_lock(lock_);
// This method should not be called for text tracks. See the note in
// MediaSourceState::IsSeekWaitingForData().
DCHECK_NE(type_, DemuxerStream::TEXT);
return stream_->IsSeekPending();
}
void ChunkDemuxerStream::Seek(TimeDelta time) {
DVLOG(1) << "ChunkDemuxerStream::Seek(" << time.InSecondsF() << ")";
base::AutoLock auto_lock(lock_);
DCHECK(read_cb_.is_null());
DCHECK(state_ == UNINITIALIZED || state_ == RETURNING_ABORT_FOR_READS)
<< state_;
stream_->Seek(time);
}
bool ChunkDemuxerStream::Append(const StreamParser::BufferQueue& buffers) {
if (buffers.empty())
return false;
base::AutoLock auto_lock(lock_);
DCHECK_NE(state_, SHUTDOWN);
if (!stream_->Append(buffers)) {
DVLOG(1) << "ChunkDemuxerStream::Append() : stream append failed";
return false;
}
if (!read_cb_.is_null())
CompletePendingReadIfPossible_Locked();
return true;
}
void ChunkDemuxerStream::Remove(TimeDelta start, TimeDelta end,
TimeDelta duration) {
base::AutoLock auto_lock(lock_);
stream_->Remove(start, end, duration);
}
bool ChunkDemuxerStream::EvictCodedFrames(DecodeTimestamp media_time,
size_t newDataSize) {
base::AutoLock auto_lock(lock_);
return stream_->GarbageCollectIfNeeded(media_time, newDataSize);
}
void ChunkDemuxerStream::OnSetDuration(TimeDelta duration) {
base::AutoLock auto_lock(lock_);
stream_->OnSetDuration(duration);
}
Ranges<TimeDelta> ChunkDemuxerStream::GetBufferedRanges(
TimeDelta duration) const {
base::AutoLock auto_lock(lock_);
if (type_ == TEXT) {
// Since text tracks are discontinuous and the lack of cues should not block
// playback, report the buffered range for text tracks as [0, |duration|) so
// that intesections with audio & video tracks are computed correctly when
// no cues are present.
Ranges<TimeDelta> text_range;
text_range.Add(TimeDelta(), duration);
return text_range;
}
Ranges<TimeDelta> range = stream_->GetBufferedTime();
if (range.size() == 0u)
return range;
// Clamp the end of the stream's buffered ranges to fit within the duration.
// This can be done by intersecting the stream's range with the valid time
// range.
Ranges<TimeDelta> valid_time_range;
valid_time_range.Add(range.start(0), duration);
return range.IntersectionWith(valid_time_range);
}
TimeDelta ChunkDemuxerStream::GetBufferedDuration() const {
return stream_->GetBufferedDuration();
}
size_t ChunkDemuxerStream::GetBufferedSize() const {
return stream_->GetBufferedSize();
}
void ChunkDemuxerStream::OnStartOfCodedFrameGroup(
DecodeTimestamp start_timestamp) {
DVLOG(2) << "ChunkDemuxerStream::OnStartOfCodedFrameGroup("
<< start_timestamp.InSecondsF() << ")";
base::AutoLock auto_lock(lock_);
stream_->OnStartOfCodedFrameGroup(start_timestamp);
}
bool ChunkDemuxerStream::UpdateAudioConfig(
const AudioDecoderConfig& config,
const scoped_refptr<MediaLog>& media_log) {
DCHECK(config.IsValidConfig());
DCHECK_EQ(type_, AUDIO);
base::AutoLock auto_lock(lock_);
if (!stream_) {
DCHECK_EQ(state_, UNINITIALIZED);
// On platforms which support splice frames, enable splice frames and
// partial append window support for most codecs (notably: not opus).
const bool codec_supported = config.codec() == kCodecMP3 ||
config.codec() == kCodecAAC ||
config.codec() == kCodecVorbis;
splice_frames_enabled_ = splice_frames_enabled_ && codec_supported;
partial_append_window_trimming_enabled_ =
splice_frames_enabled_ && codec_supported;
stream_.reset(
new SourceBufferStream(config, media_log, splice_frames_enabled_));
return true;
}
return stream_->UpdateAudioConfig(config);
}
bool ChunkDemuxerStream::UpdateVideoConfig(
const VideoDecoderConfig& config,
const scoped_refptr<MediaLog>& media_log) {
DCHECK(config.IsValidConfig());
DCHECK_EQ(type_, VIDEO);
base::AutoLock auto_lock(lock_);
if (!stream_) {
DCHECK_EQ(state_, UNINITIALIZED);
stream_.reset(
new SourceBufferStream(config, media_log, splice_frames_enabled_));
return true;
}
return stream_->UpdateVideoConfig(config);
}
void ChunkDemuxerStream::UpdateTextConfig(
const TextTrackConfig& config,
const scoped_refptr<MediaLog>& media_log) {
DCHECK_EQ(type_, TEXT);
base::AutoLock auto_lock(lock_);
DCHECK(!stream_);
DCHECK_EQ(state_, UNINITIALIZED);
stream_.reset(
new SourceBufferStream(config, media_log, splice_frames_enabled_));
}
void ChunkDemuxerStream::MarkEndOfStream() {
base::AutoLock auto_lock(lock_);
stream_->MarkEndOfStream();
}
void ChunkDemuxerStream::UnmarkEndOfStream() {
base::AutoLock auto_lock(lock_);
stream_->UnmarkEndOfStream();
}
// DemuxerStream methods.
void ChunkDemuxerStream::Read(const ReadCB& read_cb) {
base::AutoLock auto_lock(lock_);
DCHECK_NE(state_, UNINITIALIZED);
DCHECK(read_cb_.is_null());
read_cb_ = BindToCurrentLoop(read_cb);
CompletePendingReadIfPossible_Locked();
}
DemuxerStream::Type ChunkDemuxerStream::type() const { return type_; }
DemuxerStream::Liveness ChunkDemuxerStream::liveness() const {
base::AutoLock auto_lock(lock_);
return liveness_;
}
AudioDecoderConfig ChunkDemuxerStream::audio_decoder_config() {
CHECK_EQ(type_, AUDIO);
base::AutoLock auto_lock(lock_);
return stream_->GetCurrentAudioDecoderConfig();
}
VideoDecoderConfig ChunkDemuxerStream::video_decoder_config() {
CHECK_EQ(type_, VIDEO);
base::AutoLock auto_lock(lock_);
return stream_->GetCurrentVideoDecoderConfig();
}
bool ChunkDemuxerStream::SupportsConfigChanges() { return true; }
VideoRotation ChunkDemuxerStream::video_rotation() {
return VIDEO_ROTATION_0;
}
TextTrackConfig ChunkDemuxerStream::text_track_config() {
CHECK_EQ(type_, TEXT);
base::AutoLock auto_lock(lock_);
return stream_->GetCurrentTextTrackConfig();
}
void ChunkDemuxerStream::SetStreamMemoryLimit(size_t memory_limit) {
stream_->set_memory_limit(memory_limit);
}
void ChunkDemuxerStream::SetLiveness(Liveness liveness) {
base::AutoLock auto_lock(lock_);
liveness_ = liveness;
}
void ChunkDemuxerStream::ChangeState_Locked(State state) {
lock_.AssertAcquired();
DVLOG(1) << "ChunkDemuxerStream::ChangeState_Locked() : "
<< "type " << type_
<< " - " << state_ << " -> " << state;
state_ = state;
}
ChunkDemuxerStream::~ChunkDemuxerStream() {}
void ChunkDemuxerStream::CompletePendingReadIfPossible_Locked() {
lock_.AssertAcquired();
DCHECK(!read_cb_.is_null());
DemuxerStream::Status status = DemuxerStream::kAborted;
scoped_refptr<StreamParserBuffer> buffer;
switch (state_) {
case UNINITIALIZED:
NOTREACHED();
return;
case RETURNING_DATA_FOR_READS:
switch (stream_->GetNextBuffer(&buffer)) {
case SourceBufferStream::kSuccess:
status = DemuxerStream::kOk;
DVLOG(2) << __FUNCTION__ << ": returning kOk, type " << type_
<< ", dts " << buffer->GetDecodeTimestamp().InSecondsF()
<< ", pts " << buffer->timestamp().InSecondsF()
<< ", dur " << buffer->duration().InSecondsF()
<< ", key " << buffer->is_key_frame();
break;
case SourceBufferStream::kNeedBuffer:
// Return early without calling |read_cb_| since we don't have
// any data to return yet.
DVLOG(2) << __FUNCTION__ << ": returning kNeedBuffer, type "
<< type_;
return;
case SourceBufferStream::kEndOfStream:
status = DemuxerStream::kOk;
buffer = StreamParserBuffer::CreateEOSBuffer();
DVLOG(2) << __FUNCTION__ << ": returning kOk with EOS buffer, type "
<< type_;
break;
case SourceBufferStream::kConfigChange:
status = kConfigChanged;
buffer = NULL;
DVLOG(2) << __FUNCTION__ << ": returning kConfigChange, type "
<< type_;
break;
}
break;
case RETURNING_ABORT_FOR_READS:
// Null buffers should be returned in this state since we are waiting
// for a seek. Any buffers in the SourceBuffer should NOT be returned
// because they are associated with the seek.
status = DemuxerStream::kAborted;
buffer = NULL;
DVLOG(2) << __FUNCTION__ << ": returning kAborted, type " << type_;
break;
case SHUTDOWN:
status = DemuxerStream::kOk;
buffer = StreamParserBuffer::CreateEOSBuffer();
DVLOG(2) << __FUNCTION__ << ": returning kOk with EOS buffer, type "
<< type_;
break;
}
base::ResetAndReturn(&read_cb_).Run(status, buffer);
}
ChunkDemuxer::ChunkDemuxer(
const base::Closure& open_cb,
const EncryptedMediaInitDataCB& encrypted_media_init_data_cb,
const scoped_refptr<MediaLog>& media_log,
bool splice_frames_enabled)
: state_(WAITING_FOR_INIT),
cancel_next_seek_(false),
host_(NULL),
open_cb_(open_cb),
encrypted_media_init_data_cb_(encrypted_media_init_data_cb),
enable_text_(false),
media_log_(media_log),
duration_(kNoTimestamp()),
user_specified_duration_(-1),
liveness_(DemuxerStream::LIVENESS_UNKNOWN),
splice_frames_enabled_(splice_frames_enabled) {
DCHECK(!open_cb_.is_null());
DCHECK(!encrypted_media_init_data_cb_.is_null());
}
std::string ChunkDemuxer::GetDisplayName() const {
return "ChunkDemuxer";
}
void ChunkDemuxer::Initialize(
DemuxerHost* host,
const PipelineStatusCB& cb,
bool enable_text_tracks) {
DVLOG(1) << "Init()";
base::AutoLock auto_lock(lock_);
// The |init_cb_| must only be run after this method returns, so always post.
init_cb_ = BindToCurrentLoop(cb);
if (state_ == SHUTDOWN) {
base::ResetAndReturn(&init_cb_).Run(DEMUXER_ERROR_COULD_NOT_OPEN);
return;
}
DCHECK_EQ(state_, WAITING_FOR_INIT);
host_ = host;
enable_text_ = enable_text_tracks;
ChangeState_Locked(INITIALIZING);
base::ResetAndReturn(&open_cb_).Run();
}
void ChunkDemuxer::Stop() {
DVLOG(1) << "Stop()";
Shutdown();
}
void ChunkDemuxer::Seek(TimeDelta time, const PipelineStatusCB& cb) {
DVLOG(1) << "Seek(" << time.InSecondsF() << ")";
DCHECK(time >= TimeDelta());
base::AutoLock auto_lock(lock_);
DCHECK(seek_cb_.is_null());
seek_cb_ = BindToCurrentLoop(cb);
if (state_ != INITIALIZED && state_ != ENDED) {
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_ERROR_INVALID_STATE);
return;
}
if (cancel_next_seek_) {
cancel_next_seek_ = false;
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_OK);
return;
}
SeekAllSources(time);
StartReturningData();
if (IsSeekWaitingForData_Locked()) {
DVLOG(1) << "Seek() : waiting for more data to arrive.";
return;
}
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_OK);
}
// Demuxer implementation.
base::Time ChunkDemuxer::GetTimelineOffset() const {
return timeline_offset_;
}
DemuxerStream* ChunkDemuxer::GetStream(DemuxerStream::Type type) {
DCHECK_NE(type, DemuxerStream::TEXT);
base::AutoLock auto_lock(lock_);
if (type == DemuxerStream::VIDEO)
return video_.get();
if (type == DemuxerStream::AUDIO)
return audio_.get();
return NULL;
}
TimeDelta ChunkDemuxer::GetStartTime() const {
return TimeDelta();
}
int64_t ChunkDemuxer::GetMemoryUsage() const {
base::AutoLock auto_lock(lock_);
return (audio_ ? audio_->GetBufferedSize() : 0) +
(video_ ? video_->GetBufferedSize() : 0);
}
void ChunkDemuxer::StartWaitingForSeek(TimeDelta seek_time) {
DVLOG(1) << "StartWaitingForSeek()";
base::AutoLock auto_lock(lock_);
DCHECK(state_ == INITIALIZED || state_ == ENDED || state_ == SHUTDOWN ||
state_ == PARSE_ERROR) << state_;
DCHECK(seek_cb_.is_null());
if (state_ == SHUTDOWN || state_ == PARSE_ERROR)
return;
AbortPendingReads();
SeekAllSources(seek_time);
// Cancel state set in CancelPendingSeek() since we want to
// accept the next Seek().
cancel_next_seek_ = false;
}
void ChunkDemuxer::CancelPendingSeek(TimeDelta seek_time) {
base::AutoLock auto_lock(lock_);
DCHECK_NE(state_, INITIALIZING);
DCHECK(seek_cb_.is_null() || IsSeekWaitingForData_Locked());
if (cancel_next_seek_)
return;
AbortPendingReads();
SeekAllSources(seek_time);
if (seek_cb_.is_null()) {
cancel_next_seek_ = true;
return;
}
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_OK);
}
ChunkDemuxer::Status ChunkDemuxer::AddId(const std::string& id,
const std::string& type,
std::vector<std::string>& codecs) {
base::AutoLock auto_lock(lock_);
if ((state_ != WAITING_FOR_INIT && state_ != INITIALIZING) || IsValidId(id))
return kReachedIdLimit;
bool has_audio = false;
bool has_video = false;
scoped_ptr<media::StreamParser> stream_parser(StreamParserFactory::Create(
type, codecs, media_log_, &has_audio, &has_video));
if (!stream_parser)
return ChunkDemuxer::kNotSupported;
if ((has_audio && !source_id_audio_.empty()) ||
(has_video && !source_id_video_.empty()))
return kReachedIdLimit;
if (has_audio)
source_id_audio_ = id;
if (has_video)
source_id_video_ = id;
scoped_ptr<FrameProcessor> frame_processor(
new FrameProcessor(base::Bind(&ChunkDemuxer::IncreaseDurationIfNecessary,
base::Unretained(this)),
media_log_));
scoped_ptr<MediaSourceState> source_state(new MediaSourceState(
std::move(stream_parser), std::move(frame_processor),
base::Bind(&ChunkDemuxer::CreateDemuxerStream, base::Unretained(this)),
media_log_));
MediaSourceState::NewTextTrackCB new_text_track_cb;
if (enable_text_) {
new_text_track_cb = base::Bind(&ChunkDemuxer::OnNewTextTrack,
base::Unretained(this));
}
source_state->Init(
base::Bind(&ChunkDemuxer::OnSourceInitDone, base::Unretained(this)),
has_audio, has_video, encrypted_media_init_data_cb_, new_text_track_cb);
source_state_map_[id] = source_state.release();
return kOk;
}
void ChunkDemuxer::RemoveId(const std::string& id) {
base::AutoLock auto_lock(lock_);
CHECK(IsValidId(id));
delete source_state_map_[id];
source_state_map_.erase(id);
if (source_id_audio_ == id)
source_id_audio_.clear();
if (source_id_video_ == id)
source_id_video_.clear();
}
Ranges<TimeDelta> ChunkDemuxer::GetBufferedRanges(const std::string& id) const {
base::AutoLock auto_lock(lock_);
DCHECK(!id.empty());
MediaSourceStateMap::const_iterator itr = source_state_map_.find(id);
DCHECK(itr != source_state_map_.end());
return itr->second->GetBufferedRanges(duration_, state_ == ENDED);
}
bool ChunkDemuxer::EvictCodedFrames(const std::string& id,
base::TimeDelta currentMediaTime,
size_t newDataSize) {
DVLOG(1) << __FUNCTION__ << "(" << id << ")"
<< " media_time=" << currentMediaTime.InSecondsF()
<< " newDataSize=" << newDataSize;
base::AutoLock auto_lock(lock_);
// Note: The direct conversion from PTS to DTS is safe here, since we don't
// need to know currentTime precisely for GC. GC only needs to know which GOP
// currentTime points to.
DecodeTimestamp media_time_dts =
DecodeTimestamp::FromPresentationTime(currentMediaTime);
DCHECK(!id.empty());
MediaSourceStateMap::const_iterator itr = source_state_map_.find(id);
if (itr == source_state_map_.end()) {
LOG(WARNING) << __FUNCTION__ << " stream " << id << " not found";
return false;
}
return itr->second->EvictCodedFrames(media_time_dts, newDataSize);
}
void ChunkDemuxer::AppendData(
const std::string& id,
const uint8_t* data,
size_t length,
TimeDelta append_window_start,
TimeDelta append_window_end,
TimeDelta* timestamp_offset,
const MediaSourceState::InitSegmentReceivedCB& init_segment_received_cb) {
DVLOG(1) << "AppendData(" << id << ", " << length << ")";
DCHECK(!id.empty());
DCHECK(timestamp_offset);
DCHECK(!init_segment_received_cb.is_null());
Ranges<TimeDelta> ranges;
{
base::AutoLock auto_lock(lock_);
DCHECK_NE(state_, ENDED);
// Capture if any of the SourceBuffers are waiting for data before we start
// parsing.
bool old_waiting_for_data = IsSeekWaitingForData_Locked();
if (length == 0u)
return;
DCHECK(data);
switch (state_) {
case INITIALIZING:
case INITIALIZED:
DCHECK(IsValidId(id));
if (!source_state_map_[id]->Append(data, length,
append_window_start,
append_window_end,
timestamp_offset,
init_segment_received_cb)) {
ReportError_Locked(PIPELINE_ERROR_DECODE);
return;
}
break;
case PARSE_ERROR:
DVLOG(1) << "AppendData(): Ignoring data after a parse error.";
return;
case WAITING_FOR_INIT:
case ENDED:
case SHUTDOWN:
DVLOG(1) << "AppendData(): called in unexpected state " << state_;
return;
}
// Check to see if data was appended at the pending seek point. This
// indicates we have parsed enough data to complete the seek.
if (old_waiting_for_data && !IsSeekWaitingForData_Locked() &&
!seek_cb_.is_null()) {
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_OK);
}
ranges = GetBufferedRanges_Locked();
}
host_->OnBufferedTimeRangesChanged(ranges);
}
void ChunkDemuxer::ResetParserState(const std::string& id,
TimeDelta append_window_start,
TimeDelta append_window_end,
TimeDelta* timestamp_offset) {
DVLOG(1) << "ResetParserState(" << id << ")";
base::AutoLock auto_lock(lock_);
DCHECK(!id.empty());
CHECK(IsValidId(id));
bool old_waiting_for_data = IsSeekWaitingForData_Locked();
source_state_map_[id]->ResetParserState(append_window_start,
append_window_end,
timestamp_offset);
// ResetParserState can possibly emit some buffers.
// Need to check whether seeking can be completed.
if (old_waiting_for_data && !IsSeekWaitingForData_Locked() &&
!seek_cb_.is_null()) {
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_OK);
}
}
void ChunkDemuxer::Remove(const std::string& id, TimeDelta start,
TimeDelta end) {
DVLOG(1) << "Remove(" << id << ", " << start.InSecondsF()
<< ", " << end.InSecondsF() << ")";
base::AutoLock auto_lock(lock_);
DCHECK(!id.empty());
CHECK(IsValidId(id));
DCHECK(start >= base::TimeDelta()) << start.InSecondsF();
DCHECK(start < end) << "start " << start.InSecondsF()
<< " end " << end.InSecondsF();
DCHECK(duration_ != kNoTimestamp());
DCHECK(start <= duration_) << "start " << start.InSecondsF()
<< " duration " << duration_.InSecondsF();
if (start == duration_)
return;
source_state_map_[id]->Remove(start, end, duration_);
host_->OnBufferedTimeRangesChanged(GetBufferedRanges_Locked());
}
double ChunkDemuxer::GetDuration() {
base::AutoLock auto_lock(lock_);
return GetDuration_Locked();
}
double ChunkDemuxer::GetDuration_Locked() {
lock_.AssertAcquired();
if (duration_ == kNoTimestamp())
return std::numeric_limits<double>::quiet_NaN();
// Return positive infinity if the resource is unbounded.
// http://www.whatwg.org/specs/web-apps/current-work/multipage/video.html#dom-media-duration
if (duration_ == kInfiniteDuration())
return std::numeric_limits<double>::infinity();
if (user_specified_duration_ >= 0)
return user_specified_duration_;
return duration_.InSecondsF();
}
void ChunkDemuxer::SetDuration(double duration) {
base::AutoLock auto_lock(lock_);
DVLOG(1) << "SetDuration(" << duration << ")";
DCHECK_GE(duration, 0);
if (duration == GetDuration_Locked())
return;
// Compute & bounds check the TimeDelta representation of duration.
// This can be different if the value of |duration| doesn't fit the range or
// precision of TimeDelta.
TimeDelta min_duration = TimeDelta::FromInternalValue(1);
// Don't use TimeDelta::Max() here, as we want the largest finite time delta.
TimeDelta max_duration =
TimeDelta::FromInternalValue(std::numeric_limits<int64_t>::max() - 1);
double min_duration_in_seconds = min_duration.InSecondsF();
double max_duration_in_seconds = max_duration.InSecondsF();
TimeDelta duration_td;
if (duration == std::numeric_limits<double>::infinity()) {
duration_td = media::kInfiniteDuration();
} else if (duration < min_duration_in_seconds) {
duration_td = min_duration;
} else if (duration > max_duration_in_seconds) {
duration_td = max_duration;
} else {
duration_td = TimeDelta::FromMicroseconds(
duration * base::Time::kMicrosecondsPerSecond);
}
DCHECK(duration_td > TimeDelta());
user_specified_duration_ = duration;
duration_ = duration_td;
host_->SetDuration(duration_);
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->OnSetDuration(duration_);
}
}
bool ChunkDemuxer::IsParsingMediaSegment(const std::string& id) {
base::AutoLock auto_lock(lock_);
DVLOG(1) << "IsParsingMediaSegment(" << id << ")";
CHECK(IsValidId(id));
return source_state_map_[id]->parsing_media_segment();
}
void ChunkDemuxer::SetSequenceMode(const std::string& id,
bool sequence_mode) {
base::AutoLock auto_lock(lock_);
DVLOG(1) << "SetSequenceMode(" << id << ", " << sequence_mode << ")";
CHECK(IsValidId(id));
DCHECK_NE(state_, ENDED);
source_state_map_[id]->SetSequenceMode(sequence_mode);
}
void ChunkDemuxer::SetGroupStartTimestampIfInSequenceMode(
const std::string& id,
base::TimeDelta timestamp_offset) {
base::AutoLock auto_lock(lock_);
DVLOG(1) << "SetGroupStartTimestampIfInSequenceMode(" << id << ", "
<< timestamp_offset.InSecondsF() << ")";
CHECK(IsValidId(id));
DCHECK_NE(state_, ENDED);
source_state_map_[id]->SetGroupStartTimestampIfInSequenceMode(
timestamp_offset);
}
void ChunkDemuxer::MarkEndOfStream(PipelineStatus status) {
DVLOG(1) << "MarkEndOfStream(" << status << ")";
base::AutoLock auto_lock(lock_);
DCHECK_NE(state_, WAITING_FOR_INIT);
DCHECK_NE(state_, ENDED);
if (state_ == SHUTDOWN || state_ == PARSE_ERROR)
return;
if (state_ == INITIALIZING) {
ReportError_Locked(DEMUXER_ERROR_COULD_NOT_OPEN);
return;
}
bool old_waiting_for_data = IsSeekWaitingForData_Locked();
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->MarkEndOfStream();
}
CompletePendingReadsIfPossible();
// Give a chance to resume the pending seek process.
if (status != PIPELINE_OK) {
ReportError_Locked(status);
return;
}
ChangeState_Locked(ENDED);
DecreaseDurationIfNecessary();
if (old_waiting_for_data && !IsSeekWaitingForData_Locked() &&
!seek_cb_.is_null()) {
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_OK);
}
}
void ChunkDemuxer::UnmarkEndOfStream() {
DVLOG(1) << "UnmarkEndOfStream()";
base::AutoLock auto_lock(lock_);
DCHECK_EQ(state_, ENDED);
ChangeState_Locked(INITIALIZED);
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->UnmarkEndOfStream();
}
}
void ChunkDemuxer::Shutdown() {
DVLOG(1) << "Shutdown()";
base::AutoLock auto_lock(lock_);
if (state_ == SHUTDOWN)
return;
ShutdownAllStreams();
ChangeState_Locked(SHUTDOWN);
if(!seek_cb_.is_null())
base::ResetAndReturn(&seek_cb_).Run(PIPELINE_ERROR_ABORT);
}
void ChunkDemuxer::SetMemoryLimits(DemuxerStream::Type type,
size_t memory_limit) {
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->SetMemoryLimits(type, memory_limit);
}
}
void ChunkDemuxer::ChangeState_Locked(State new_state) {
lock_.AssertAcquired();
DVLOG(1) << "ChunkDemuxer::ChangeState_Locked() : "
<< state_ << " -> " << new_state;
state_ = new_state;
}
ChunkDemuxer::~ChunkDemuxer() {
DCHECK_NE(state_, INITIALIZED);
STLDeleteValues(&source_state_map_);
}
void ChunkDemuxer::ReportError_Locked(PipelineStatus error) {
DVLOG(1) << "ReportError_Locked(" << error << ")";
lock_.AssertAcquired();
DCHECK_NE(error, PIPELINE_OK);
ChangeState_Locked(PARSE_ERROR);
PipelineStatusCB cb;
if (!init_cb_.is_null()) {
std::swap(cb, init_cb_);
} else {
if (!seek_cb_.is_null())
std::swap(cb, seek_cb_);
ShutdownAllStreams();
}
if (!cb.is_null()) {
cb.Run(error);
return;
}
base::AutoUnlock auto_unlock(lock_);
host_->OnDemuxerError(error);
}
bool ChunkDemuxer::IsSeekWaitingForData_Locked() const {
lock_.AssertAcquired();
for (MediaSourceStateMap::const_iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
if (itr->second->IsSeekWaitingForData())
return true;
}
return false;
}
void ChunkDemuxer::OnSourceInitDone(
const StreamParser::InitParameters& params) {
DVLOG(1) << "OnSourceInitDone(" << params.duration.InSecondsF() << ")";
lock_.AssertAcquired();
DCHECK_EQ(state_, INITIALIZING);
if (!audio_ && !video_) {
ReportError_Locked(DEMUXER_ERROR_COULD_NOT_OPEN);
return;
}
if (params.duration != TimeDelta() && duration_ == kNoTimestamp())
UpdateDuration(params.duration);
if (!params.timeline_offset.is_null()) {
if (!timeline_offset_.is_null() &&
params.timeline_offset != timeline_offset_) {
MEDIA_LOG(ERROR, media_log_)
<< "Timeline offset is not the same across all SourceBuffers.";
ReportError_Locked(DEMUXER_ERROR_COULD_NOT_OPEN);
return;
}
timeline_offset_ = params.timeline_offset;
}
if (params.liveness != DemuxerStream::LIVENESS_UNKNOWN) {
if (audio_)
audio_->SetLiveness(params.liveness);
if (video_)
video_->SetLiveness(params.liveness);
}
// Wait until all streams have initialized.
if ((!source_id_audio_.empty() && !audio_) ||
(!source_id_video_.empty() && !video_)) {
return;
}
SeekAllSources(GetStartTime());
StartReturningData();
if (duration_ == kNoTimestamp())
duration_ = kInfiniteDuration();
// The demuxer is now initialized after the |start_timestamp_| was set.
ChangeState_Locked(INITIALIZED);
base::ResetAndReturn(&init_cb_).Run(PIPELINE_OK);
}
ChunkDemuxerStream*
ChunkDemuxer::CreateDemuxerStream(DemuxerStream::Type type) {
switch (type) {
case DemuxerStream::AUDIO:
if (audio_)
return NULL;
audio_.reset(
new ChunkDemuxerStream(DemuxerStream::AUDIO, splice_frames_enabled_));
return audio_.get();
break;
case DemuxerStream::VIDEO:
if (video_)
return NULL;
video_.reset(
new ChunkDemuxerStream(DemuxerStream::VIDEO, splice_frames_enabled_));
return video_.get();
break;
case DemuxerStream::TEXT: {
return new ChunkDemuxerStream(DemuxerStream::TEXT,
splice_frames_enabled_);
break;
}
case DemuxerStream::UNKNOWN:
case DemuxerStream::NUM_TYPES:
NOTREACHED();
return NULL;
}
NOTREACHED();
return NULL;
}
void ChunkDemuxer::OnNewTextTrack(ChunkDemuxerStream* text_stream,
const TextTrackConfig& config) {
lock_.AssertAcquired();
DCHECK_NE(state_, SHUTDOWN);
host_->AddTextStream(text_stream, config);
}
bool ChunkDemuxer::IsValidId(const std::string& source_id) const {
lock_.AssertAcquired();
return source_state_map_.count(source_id) > 0u;
}
void ChunkDemuxer::UpdateDuration(TimeDelta new_duration) {
DCHECK(duration_ != new_duration);
user_specified_duration_ = -1;
duration_ = new_duration;
host_->SetDuration(new_duration);
}
void ChunkDemuxer::IncreaseDurationIfNecessary(TimeDelta new_duration) {
DCHECK(new_duration != kNoTimestamp());
DCHECK(new_duration != kInfiniteDuration());
// Per April 1, 2014 MSE spec editor's draft:
// https://dvcs.w3.org/hg/html-media/raw-file/d471a4412040/media-source/
// media-source.html#sourcebuffer-coded-frame-processing
// 5. If the media segment contains data beyond the current duration, then run
// the duration change algorithm with new duration set to the maximum of
// the current duration and the group end timestamp.
if (new_duration <= duration_)
return;
DVLOG(2) << __FUNCTION__ << ": Increasing duration: "
<< duration_.InSecondsF() << " -> " << new_duration.InSecondsF();
UpdateDuration(new_duration);
}
void ChunkDemuxer::DecreaseDurationIfNecessary() {
lock_.AssertAcquired();
TimeDelta max_duration;
for (MediaSourceStateMap::const_iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
max_duration = std::max(max_duration,
itr->second->GetMaxBufferedDuration());
}
if (max_duration == TimeDelta())
return;
if (max_duration < duration_)
UpdateDuration(max_duration);
}
Ranges<TimeDelta> ChunkDemuxer::GetBufferedRanges() const {
base::AutoLock auto_lock(lock_);
return GetBufferedRanges_Locked();
}
Ranges<TimeDelta> ChunkDemuxer::GetBufferedRanges_Locked() const {
lock_.AssertAcquired();
bool ended = state_ == ENDED;
// TODO(acolwell): When we start allowing SourceBuffers that are not active,
// we'll need to update this loop to only add ranges from active sources.
MediaSourceState::RangesList ranges_list;
for (MediaSourceStateMap::const_iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
ranges_list.push_back(itr->second->GetBufferedRanges(duration_, ended));
}
return MediaSourceState::ComputeRangesIntersection(ranges_list, ended);
}
void ChunkDemuxer::StartReturningData() {
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->StartReturningData();
}
}
void ChunkDemuxer::AbortPendingReads() {
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->AbortReads();
}
}
void ChunkDemuxer::SeekAllSources(TimeDelta seek_time) {
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->Seek(seek_time);
}
}
void ChunkDemuxer::CompletePendingReadsIfPossible() {
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->CompletePendingReadIfPossible();
}
}
void ChunkDemuxer::ShutdownAllStreams() {
for (MediaSourceStateMap::iterator itr = source_state_map_.begin();
itr != source_state_map_.end(); ++itr) {
itr->second->Shutdown();
}
}
} // namespace media