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// Copyright 2014 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/decoder_stream_traits.h"
#include <limits>
#include "base/logging.h"
#include "base/metrics/histogram_macros.h"
#include "media/base/audio_buffer.h"
#include "media/base/audio_decoder.h"
#include "media/base/audio_decoder_config.h"
#include "media/base/video_decoder.h"
#include "media/base/video_frame.h"
namespace media {
// Audio decoder stream traits implementation.
// static
std::string DecoderStreamTraits<DemuxerStream::AUDIO>::ToString() {
return "audio";
}
// static
bool DecoderStreamTraits<DemuxerStream::AUDIO>::NeedsBitstreamConversion(
DecoderType* decoder) {
return decoder->NeedsBitstreamConversion();
}
// static
scoped_refptr<DecoderStreamTraits<DemuxerStream::AUDIO>::OutputType>
DecoderStreamTraits<DemuxerStream::AUDIO>::CreateEOSOutput() {
return OutputType::CreateEOSBuffer();
}
DecoderStreamTraits<DemuxerStream::AUDIO>::DecoderStreamTraits(
MediaLog* media_log,
ChannelLayout initial_hw_layout)
: media_log_(media_log), initial_hw_layout_(initial_hw_layout) {}
DecoderStreamTraits<DemuxerStream::AUDIO>::DecoderConfigType
DecoderStreamTraits<DemuxerStream::AUDIO>::GetDecoderConfig(
DemuxerStream* stream) {
auto config = stream->audio_decoder_config();
// Demuxer is not aware of hw layout, so we set it here.
config.set_target_output_channel_layout(initial_hw_layout_);
return config;
}
void DecoderStreamTraits<DemuxerStream::AUDIO>::ReportStatistics(
const StatisticsCB& statistics_cb,
int bytes_decoded) {
stats_.audio_bytes_decoded = bytes_decoded;
statistics_cb.Run(stats_);
}
void DecoderStreamTraits<DemuxerStream::AUDIO>::InitializeDecoder(
DecoderType* decoder,
const DecoderConfigType& config,
bool /* low_delay */,
CdmContext* cdm_context,
InitCB init_cb,
const OutputCB& output_cb,
const WaitingCB& waiting_cb) {
DCHECK(config.IsValidConfig());
if (config_.IsValidConfig() && !config_.Matches(config))
OnConfigChanged(config);
config_ = config;
stats_.audio_decoder_name = decoder->GetDisplayName();
decoder->Initialize(config, cdm_context, std::move(init_cb), output_cb,
waiting_cb);
}
void DecoderStreamTraits<DemuxerStream::AUDIO>::OnStreamReset(
DemuxerStream* stream) {
DCHECK(stream);
// Stream is likely being seeked to a new timestamp, so make new validator to
// build new timestamp expectations.
audio_ts_validator_.reset(
new AudioTimestampValidator(stream->audio_decoder_config(), media_log_));
}
void DecoderStreamTraits<DemuxerStream::AUDIO>::OnDecode(
const DecoderBuffer& buffer) {
audio_ts_validator_->CheckForTimestampGap(buffer);
}
PostDecodeAction DecoderStreamTraits<DemuxerStream::AUDIO>::OnDecodeDone(
OutputType* buffer) {
audio_ts_validator_->RecordOutputDuration(*buffer);
return PostDecodeAction::DELIVER;
}
void DecoderStreamTraits<DemuxerStream::AUDIO>::OnConfigChanged(
const DecoderConfigType& config) {
// Reset validator with the latest config. Also ensures that we do not attempt
// to match timestamps across config boundaries.
audio_ts_validator_.reset(new AudioTimestampValidator(config, media_log_));
}
// Video decoder stream traits implementation.
// static
std::string DecoderStreamTraits<DemuxerStream::VIDEO>::ToString() {
return "video";
}
// static
bool DecoderStreamTraits<DemuxerStream::VIDEO>::NeedsBitstreamConversion(
DecoderType* decoder) {
return decoder->NeedsBitstreamConversion();
}
// static
scoped_refptr<DecoderStreamTraits<DemuxerStream::VIDEO>::OutputType>
DecoderStreamTraits<DemuxerStream::VIDEO>::CreateEOSOutput() {
return OutputType::CreateEOSFrame();
}
DecoderStreamTraits<DemuxerStream::VIDEO>::DecoderStreamTraits(
MediaLog* media_log)
// Randomly selected number of samples to keep.
: keyframe_distance_average_(16) {}
DecoderStreamTraits<DemuxerStream::VIDEO>::DecoderConfigType
DecoderStreamTraits<DemuxerStream::VIDEO>::GetDecoderConfig(
DemuxerStream* stream) {
return stream->video_decoder_config();
}
void DecoderStreamTraits<DemuxerStream::VIDEO>::ReportStatistics(
const StatisticsCB& statistics_cb,
int bytes_decoded) {
stats_.video_bytes_decoded = bytes_decoded;
if (keyframe_distance_average_.count()) {
stats_.video_keyframe_distance_average =
keyframe_distance_average_.Average();
} else {
// Before we have enough keyframes to calculate the average distance, we
// will assume the average keyframe distance is infinitely large.
stats_.video_keyframe_distance_average = base::TimeDelta::Max();
}
statistics_cb.Run(stats_);
}
void DecoderStreamTraits<DemuxerStream::VIDEO>::InitializeDecoder(
DecoderType* decoder,
const DecoderConfigType& config,
bool low_delay,
CdmContext* cdm_context,
InitCB init_cb,
const OutputCB& output_cb,
const WaitingCB& waiting_cb) {
DCHECK(config.IsValidConfig());
stats_.video_decoder_name = decoder->GetDisplayName();
DVLOG(2) << stats_.video_decoder_name;
decoder->Initialize(config, low_delay, cdm_context, std::move(init_cb),
output_cb, waiting_cb);
}
void DecoderStreamTraits<DemuxerStream::VIDEO>::OnStreamReset(
DemuxerStream* stream) {
DCHECK(stream);
last_keyframe_timestamp_ = base::TimeDelta();
frame_metadata_.clear();
}
void DecoderStreamTraits<DemuxerStream::VIDEO>::OnDecode(
const DecoderBuffer& buffer) {
if (buffer.end_of_stream()) {
last_keyframe_timestamp_ = base::TimeDelta();
return;
}
frame_metadata_[buffer.timestamp()] = {
buffer.discard_padding().first == kInfiniteDuration, // should_drop
buffer.duration(), // duration
};
if (!buffer.is_key_frame())
return;
base::TimeDelta current_frame_timestamp = buffer.timestamp();
if (last_keyframe_timestamp_.is_zero()) {
last_keyframe_timestamp_ = current_frame_timestamp;
return;
}
const base::TimeDelta frame_distance =
current_frame_timestamp - last_keyframe_timestamp_;
last_keyframe_timestamp_ = current_frame_timestamp;
keyframe_distance_average_.AddSample(frame_distance);
}
PostDecodeAction DecoderStreamTraits<DemuxerStream::VIDEO>::OnDecodeDone(
OutputType* buffer) {
// Add a timestamp here (after decoding completed) to enable buffering delay
// measurements down the line.
buffer->metadata()->SetTimeTicks(media::VideoFrameMetadata::DECODE_TIME,
base::TimeTicks::Now());
auto it = frame_metadata_.find(buffer->timestamp());
// If the frame isn't in |frame_metadata_| it probably was erased below on a
// previous cycle. We could drop these, but today our video algorithm will put
// them back into sorted order or drop the frame if a later frame has already
// been rendered.
if (it == frame_metadata_.end())
return PostDecodeAction::DELIVER;
auto action = it->second.should_drop ? PostDecodeAction::DROP
: PostDecodeAction::DELIVER;
// Provide duration information to help the rendering algorithm on the very
// first and very last frames.
if (it->second.duration != kNoTimestamp) {
buffer->metadata()->SetTimeDelta(VideoFrameMetadata::FRAME_DURATION,
it->second.duration);
}
// We erase from the beginning onward to our target frame since frames should
// be returned in presentation order. It's possible to accumulate entries in
// this queue if playback begins at a non-keyframe; those frames may never be
// returned from the decoder.
frame_metadata_.erase(frame_metadata_.begin(), it + 1);
return action;
}
} // namespace media
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