shaka-packager/packager/media/formats/mp2t/es_parser_adts.cc

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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 "packager/media/formats/mp2t/es_parser_adts.h"
#include <stdint.h>
#include <algorithm>
#include <list>
#include "packager/base/logging.h"
#include "packager/base/strings/string_number_conversions.h"
#include "packager/media/base/audio_timestamp_helper.h"
#include "packager/media/base/bit_reader.h"
#include "packager/media/base/media_sample.h"
#include "packager/media/base/timestamp.h"
#include "packager/media/formats/mp2t/adts_header.h"
#include "packager/media/formats/mp2t/mp2t_common.h"
#include "packager/media/formats/mpeg/adts_constants.h"
namespace shaka {
namespace media {
namespace mp2t {
// Look for a syncword.
// |new_pos| returns
// - either the byte position of the frame (if found)
// - or the byte position of 1st byte that was not processed (if not found).
// In every case, the returned value in |new_pos| is such that new_pos >= pos
// |audio_header| is updated with the new audio frame info if a syncword is
// found.
// Return whether a syncword was found.
static bool LookForSyncWord(const uint8_t* raw_es,
int raw_es_size,
int pos,
int* new_pos,
AudioHeader* audio_header) {
DCHECK_GE(pos, 0);
DCHECK_LE(pos, raw_es_size);
const int max_offset =
raw_es_size - static_cast<int>(audio_header->GetMinFrameSize());
if (pos >= max_offset) {
// Do not change the position if:
// - max_offset < 0: not enough bytes to get a full header
// Since pos >= 0, this is a subcase of the next condition.
// - pos >= max_offset: might be the case after reading one full frame,
// |pos| is then incremented by the frame size and might then point
// to the end of the buffer.
*new_pos = pos;
return false;
}
for (int offset = pos; offset < max_offset; offset++) {
const uint8_t* cur_buf = &raw_es[offset];
if (!audio_header->IsSyncWord(cur_buf))
continue;
if (!audio_header->Parse(cur_buf, raw_es_size - offset))
continue;
// Check whether there is another frame |size| apart from the current one.
const size_t remaining_size = static_cast<size_t>(raw_es_size - offset);
const int kSyncWordSize = 2;
if (remaining_size >= audio_header->GetFrameSize() + kSyncWordSize &&
!audio_header->IsSyncWord(&cur_buf[audio_header->GetFrameSize()])) {
continue;
}
*new_pos = offset;
return true;
}
*new_pos = max_offset;
return false;
}
EsParserAdts::EsParserAdts(uint32_t pid,
const NewStreamInfoCB& new_stream_info_cb,
const EmitSampleCB& emit_sample_cb,
bool sbr_in_mimetype)
: EsParser(pid),
audio_header_(new AdtsHeader),
new_stream_info_cb_(new_stream_info_cb),
emit_sample_cb_(emit_sample_cb),
sbr_in_mimetype_(sbr_in_mimetype) {}
EsParserAdts::~EsParserAdts() {
}
bool EsParserAdts::Parse(const uint8_t* buf,
int size,
int64_t pts,
int64_t dts) {
int raw_es_size;
const uint8_t* raw_es;
// The incoming PTS applies to the access unit that comes just after
// the beginning of |buf|.
if (pts != kNoTimestamp) {
es_byte_queue_.Peek(&raw_es, &raw_es_size);
pts_list_.push_back(EsPts(raw_es_size, pts));
}
// Copy the input data to the ES buffer.
es_byte_queue_.Push(buf, static_cast<int>(size));
es_byte_queue_.Peek(&raw_es, &raw_es_size);
// Look for every frame in the ES buffer starting at offset = 0
int es_position = 0;
while (LookForSyncWord(raw_es, raw_es_size, es_position, &es_position,
audio_header_.get())) {
const uint8_t* frame_ptr = raw_es + es_position;
DVLOG(LOG_LEVEL_ES) << "syncword @ pos=" << es_position
<< " frame_size=" << audio_header_->GetFrameSize();
DVLOG(LOG_LEVEL_ES) << "header: "
<< base::HexEncode(frame_ptr,
audio_header_->GetHeaderSize());
// Do not process the frame if this one is a partial frame.
int remaining_size = raw_es_size - es_position;
if (static_cast<int>(audio_header_->GetFrameSize()) > remaining_size)
break;
// Update the audio configuration if needed.
if (!UpdateAudioConfiguration(*audio_header_))
return false;
// Get the PTS & the duration of this access unit.
while (!pts_list_.empty() &&
pts_list_.front().first <= es_position) {
audio_timestamp_helper_->SetBaseTimestamp(pts_list_.front().second);
pts_list_.pop_front();
}
int64_t current_pts = audio_timestamp_helper_->GetTimestamp();
int64_t frame_duration =
audio_timestamp_helper_->GetFrameDuration(kSamplesPerAACFrame);
// Emit an audio frame.
bool is_key_frame = true;
std::shared_ptr<MediaSample> sample = MediaSample::CopyFrom(
frame_ptr + audio_header_->GetHeaderSize(),
audio_header_->GetFrameSize() - audio_header_->GetHeaderSize(),
is_key_frame);
sample->set_pts(current_pts);
sample->set_dts(current_pts);
sample->set_duration(frame_duration);
emit_sample_cb_.Run(pid(), sample);
// Update the PTS of the next frame.
audio_timestamp_helper_->AddFrames(kSamplesPerAACFrame);
// Skip the current frame.
es_position += static_cast<int>(audio_header_->GetFrameSize());
}
// Discard all the bytes that have been processed.
DiscardEs(es_position);
return true;
}
void EsParserAdts::Flush() {
}
void EsParserAdts::Reset() {
es_byte_queue_.Reset();
pts_list_.clear();
last_audio_decoder_config_ = std::shared_ptr<AudioStreamInfo>();
}
bool EsParserAdts::UpdateAudioConfiguration(const AudioHeader& audio_header) {
const uint8_t kAacSampleSizeBits(16);
std::vector<uint8_t> audio_specific_config;
audio_header.GetAudioSpecificConfig(&audio_specific_config);
if (last_audio_decoder_config_) {
// Verify that the audio decoder config has not changed.
if (last_audio_decoder_config_->codec_config() == audio_specific_config) {
// Audio configuration has not changed.
return true;
}
NOTIMPLEMENTED() << "Varying audio configurations are not supported.";
return false;
}
// The following code is written according to ISO 14496 Part 3 Table 1.11 and
// Table 1.22. (Table 1.11 refers to the capping to 48000, Table 1.22 refers
// to SBR doubling the AAC sample rate.)
int samples_per_second = audio_header.GetSamplingFrequency();
// TODO(kqyang): Review if it makes sense to have |sbr_in_mimetype_| in
// es_parser.
int extended_samples_per_second = sbr_in_mimetype_
? std::min(2 * samples_per_second, 48000)
: samples_per_second;
const Codec codec = kCodecAAC;
last_audio_decoder_config_ = std::make_shared<AudioStreamInfo>(
pid(), kMpeg2Timescale, kInfiniteDuration, codec,
AudioStreamInfo::GetCodecString(codec, audio_header.GetObjectType()),
audio_specific_config.data(), audio_specific_config.size(),
kAacSampleSizeBits, audio_header.GetNumChannels(),
extended_samples_per_second, 0 /* seek preroll */, 0 /* codec delay */,
0 /* max bitrate */, 0 /* avg bitrate */, std::string(), false);
DVLOG(1) << "Sampling frequency: " << samples_per_second;
DVLOG(1) << "Extended sampling frequency: " << extended_samples_per_second;
DVLOG(1) << "Channel config: "
<< static_cast<int>(audio_header.GetNumChannels());
DVLOG(1) << "Object type: " << static_cast<int>(audio_header.GetObjectType());
// Reset the timestamp helper to use a new sampling frequency.
if (audio_timestamp_helper_) {
int64_t base_timestamp = audio_timestamp_helper_->GetTimestamp();
audio_timestamp_helper_.reset(
new AudioTimestampHelper(kMpeg2Timescale, samples_per_second));
audio_timestamp_helper_->SetBaseTimestamp(base_timestamp);
} else {
audio_timestamp_helper_.reset(
new AudioTimestampHelper(kMpeg2Timescale, extended_samples_per_second));
}
// Audio config notification.
new_stream_info_cb_.Run(last_audio_decoder_config_);
return true;
}
void EsParserAdts::DiscardEs(int nbytes) {
DCHECK_GE(nbytes, 0);
if (nbytes <= 0)
return;
// Adjust the ES position of each PTS.
for (EsPtsList::iterator it = pts_list_.begin(); it != pts_list_.end(); ++it)
it->first -= nbytes;
// Discard |nbytes| of ES.
es_byte_queue_.Pop(nbytes);
}
} // namespace mp2t
} // namespace media
} // namespace shaka