shaka-packager/packager/media/formats/mp2t/es_parser_h264.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_h264.h"
#include <stdint.h>
#include "packager/base/logging.h"
#include "packager/base/numerics/safe_conversions.h"
#include "packager/media/base/media_sample.h"
#include "packager/media/base/offset_byte_queue.h"
#include "packager/media/base/timestamp.h"
#include "packager/media/base/video_stream_info.h"
#include "packager/media/filters/avc_decoder_configuration.h"
#include "packager/media/filters/h264_byte_to_unit_stream_converter.h"
#include "packager/media/filters/h264_parser.h"
#include "packager/media/formats/mp2t/mp2t_common.h"
namespace edash_packager {
namespace media {
namespace mp2t {
namespace {
// An AUD NALU is at least 4 bytes:
// 3 bytes for the start code + 1 byte for the NALU type.
const int kMinAUDSize = 4;
} // anonymous namespace
EsParserH264::EsParserH264(uint32_t pid,
const NewStreamInfoCB& new_stream_info_cb,
const EmitSampleCB& emit_sample_cb)
: EsParser(pid),
new_stream_info_cb_(new_stream_info_cb),
emit_sample_cb_(emit_sample_cb),
es_queue_(new media::OffsetByteQueue()),
h264_parser_(new H264Parser()),
current_access_unit_pos_(0),
next_access_unit_pos_(0),
stream_converter_(new H264ByteToUnitStreamConverter),
decoder_config_check_pending_(false),
pending_sample_duration_(0),
waiting_for_key_frame_(true) {
}
EsParserH264::~EsParserH264() {
}
bool EsParserH264::Parse(const uint8_t* buf,
int size,
int64_t pts,
int64_t dts) {
// Note: Parse is invoked each time a PES packet has been reassembled.
// Unfortunately, a PES packet does not necessarily map
// to an h264 access unit, although the HLS recommendation is to use one PES
// for each access unit (but this is just a recommendation and some streams
// do not comply with this recommendation).
// HLS recommendation: "In AVC video, you should have both a DTS and a
// PTS in each PES header".
// However, some streams do not comply with this recommendation.
DVLOG_IF(1, pts == kNoTimestamp) << "Each video PES should have a PTS";
if (pts != kNoTimestamp) {
TimingDesc timing_desc;
timing_desc.pts = pts;
timing_desc.dts = (dts != kNoTimestamp) ? dts : pts;
// Link the end of the byte queue with the incoming timing descriptor.
timing_desc_list_.push_back(
std::pair<int64_t, TimingDesc>(es_queue_->tail(), timing_desc));
}
// Add the incoming bytes to the ES queue.
es_queue_->Push(buf, size);
return ParseInternal();
}
void EsParserH264::Flush() {
DVLOG(1) << "EsParserH264::Flush";
if (FindAUD(&current_access_unit_pos_)) {
// Simulate an additional AUD to force emitting the last access unit
// which is assumed to be complete at this point.
uint8_t aud[] = {0x00, 0x00, 0x01, 0x09};
es_queue_->Push(aud, sizeof(aud));
ParseInternal();
}
if (pending_sample_) {
// Flush pending sample.
DCHECK(pending_sample_duration_);
pending_sample_->set_duration(pending_sample_duration_);
emit_sample_cb_.Run(pid(), pending_sample_);
pending_sample_ = scoped_refptr<MediaSample>();
}
}
void EsParserH264::Reset() {
DVLOG(1) << "EsParserH264::Reset";
es_queue_.reset(new media::OffsetByteQueue());
h264_parser_.reset(new H264Parser());
current_access_unit_pos_ = 0;
next_access_unit_pos_ = 0;
timing_desc_list_.clear();
last_video_decoder_config_ = scoped_refptr<StreamInfo>();
decoder_config_check_pending_ = false;
pending_sample_ = scoped_refptr<MediaSample>();
pending_sample_duration_ = 0;
waiting_for_key_frame_ = true;
}
bool EsParserH264::FindAUD(int64_t* stream_pos) {
while (true) {
const uint8_t* es;
int size;
es_queue_->PeekAt(*stream_pos, &es, &size);
// Find a start code and move the stream to the start code parser position.
uint64_t start_code_offset;
uint8_t start_code_size;
bool start_code_found = NaluReader::FindStartCode(
es, size, &start_code_offset, &start_code_size);
*stream_pos += start_code_offset;
// No H264 start code found or NALU type not available yet.
if (!start_code_found ||
start_code_offset + start_code_size >= static_cast<uint64_t>(size)) {
return false;
}
// Exit the parser loop when an AUD is found.
// Note: NALU header for an AUD:
// - ref_idc must be 0
// - type must be Nalu::H264_AUD
if (es[start_code_offset + start_code_size] == Nalu::H264_AUD)
break;
// The current NALU is not an AUD, skip the start code
// and continue parsing the stream.
*stream_pos += start_code_size;
}
return true;
}
bool EsParserH264::ParseInternal() {
DCHECK_LE(es_queue_->head(), current_access_unit_pos_);
DCHECK_LE(current_access_unit_pos_, next_access_unit_pos_);
DCHECK_LE(next_access_unit_pos_, es_queue_->tail());
// Find the next AUD located at or after |current_access_unit_pos_|. This is
// needed since initially |current_access_unit_pos_| might not point to
// an AUD.
// Discard all the data before the updated |current_access_unit_pos_|
// since it won't be used again.
bool aud_found = FindAUD(&current_access_unit_pos_);
es_queue_->Trim(current_access_unit_pos_);
if (next_access_unit_pos_ < current_access_unit_pos_)
next_access_unit_pos_ = current_access_unit_pos_;
// Resume parsing later if no AUD was found.
if (!aud_found)
return true;
// Find the next AUD to make sure we have a complete access unit.
if (next_access_unit_pos_ < current_access_unit_pos_ + kMinAUDSize) {
next_access_unit_pos_ = current_access_unit_pos_ + kMinAUDSize;
DCHECK_LE(next_access_unit_pos_, es_queue_->tail());
}
if (!FindAUD(&next_access_unit_pos_))
return true;
// At this point, we know we have a full access unit.
bool is_key_frame = false;
int pps_id_for_access_unit = -1;
const uint8_t* es;
int size;
es_queue_->PeekAt(current_access_unit_pos_, &es, &size);
int access_unit_size = base::checked_cast<int, int64_t>(
next_access_unit_pos_ - current_access_unit_pos_);
DCHECK_LE(access_unit_size, size);
NaluReader reader(NaluReader::kH264, kIsAnnexbByteStream, es,
access_unit_size);
while (true) {
Nalu nalu;
bool is_eos = false;
switch (reader.Advance(&nalu)) {
case NaluReader::kOk:
break;
case NaluReader::kEOStream:
is_eos = true;
break;
default:
return false;
}
if (is_eos)
break;
switch (nalu.type()) {
case Nalu::H264_AUD: {
DVLOG(LOG_LEVEL_ES) << "Nalu: AUD";
break;
}
case Nalu::H264_SPS: {
DVLOG(LOG_LEVEL_ES) << "Nalu: SPS";
int sps_id;
if (h264_parser_->ParseSps(nalu, &sps_id) != H264Parser::kOk)
return false;
decoder_config_check_pending_ = true;
break;
}
case Nalu::H264_PPS: {
DVLOG(LOG_LEVEL_ES) << "Nalu: PPS";
int pps_id;
if (h264_parser_->ParsePps(nalu, &pps_id) != H264Parser::kOk) {
// Allow PPS parsing to fail if waiting for SPS.
if (last_video_decoder_config_)
return false;
} else {
decoder_config_check_pending_ = true;
}
break;
}
case Nalu::H264_IDRSlice:
case Nalu::H264_NonIDRSlice: {
is_key_frame = (nalu.type() == Nalu::H264_IDRSlice);
DVLOG(LOG_LEVEL_ES) << "Nalu: slice IDR=" << is_key_frame;
H264SliceHeader shdr;
if (h264_parser_->ParseSliceHeader(nalu, &shdr) != H264Parser::kOk) {
// Only accept an invalid SPS/PPS at the beginning when the stream
// does not necessarily start with an SPS/PPS/IDR.
if (last_video_decoder_config_)
return false;
} else {
pps_id_for_access_unit = shdr.pic_parameter_set_id;
}
break;
}
default: {
DVLOG(LOG_LEVEL_ES) << "Nalu: " << nalu.type();
}
}
}
if (waiting_for_key_frame_) {
waiting_for_key_frame_ = !is_key_frame;
}
if (!waiting_for_key_frame_) {
// Emit a frame and move the stream to the next AUD position.
RCHECK(EmitFrame(current_access_unit_pos_, access_unit_size,
is_key_frame, pps_id_for_access_unit));
}
current_access_unit_pos_ = next_access_unit_pos_;
es_queue_->Trim(current_access_unit_pos_);
return true;
}
bool EsParserH264::EmitFrame(int64_t access_unit_pos,
int access_unit_size,
bool is_key_frame,
int pps_id) {
// Get the access unit timing info.
TimingDesc current_timing_desc = {kNoTimestamp, kNoTimestamp};
while (!timing_desc_list_.empty() &&
timing_desc_list_.front().first <= access_unit_pos) {
current_timing_desc = timing_desc_list_.front().second;
timing_desc_list_.pop_front();
}
if (current_timing_desc.pts == kNoTimestamp)
return false;
// Emit a frame.
DVLOG(LOG_LEVEL_ES) << "Emit frame: stream_pos=" << current_access_unit_pos_
<< " size=" << access_unit_size;
int es_size;
const uint8_t* es;
es_queue_->PeekAt(current_access_unit_pos_, &es, &es_size);
CHECK_GE(es_size, access_unit_size);
// Convert frame to unit stream format.
std::vector<uint8_t> converted_frame;
if (!stream_converter_->ConvertByteStreamToNalUnitStream(
es, access_unit_size, &converted_frame)) {
DLOG(ERROR) << "Failure to convert video frame to unit stream format.";
return false;
}
if (decoder_config_check_pending_) {
// Update the video decoder configuration if needed.
const H264Pps* pps = h264_parser_->GetPps(pps_id);
if (!pps) {
// Only accept an invalid PPS at the beginning when the stream
// does not necessarily start with an SPS/PPS/IDR.
// In this case, the initial frames are conveyed to the upper layer with
// an invalid VideoDecoderConfig and it's up to the upper layer
// to process this kind of frame accordingly.
if (last_video_decoder_config_)
return false;
} else {
const H264Sps* sps = h264_parser_->GetSps(pps->seq_parameter_set_id);
if (!sps)
return false;
RCHECK(UpdateVideoDecoderConfig(sps));
decoder_config_check_pending_ = false;
}
}
// Create the media sample, emitting always the previous sample after
// calculating its duration.
scoped_refptr<MediaSample> media_sample = MediaSample::CopyFrom(
converted_frame.data(), converted_frame.size(), is_key_frame);
media_sample->set_dts(current_timing_desc.dts);
media_sample->set_pts(current_timing_desc.pts);
if (pending_sample_) {
DCHECK_GT(media_sample->dts(), pending_sample_->dts());
pending_sample_duration_ = media_sample->dts() - pending_sample_->dts();
pending_sample_->set_duration(pending_sample_duration_);
emit_sample_cb_.Run(pid(), pending_sample_);
}
pending_sample_ = media_sample;
return true;
}
bool EsParserH264::UpdateVideoDecoderConfig(const H264Sps* sps) {
std::vector<uint8_t> decoder_config_record;
if (!stream_converter_->GetAVCDecoderConfigurationRecord(
&decoder_config_record)) {
DLOG(ERROR) << "Failure to construct an AVCDecoderConfigurationRecord";
return false;
}
if (last_video_decoder_config_) {
if (last_video_decoder_config_->extra_data() != decoder_config_record) {
// Video configuration has changed. Issue warning.
// TODO(tinskip): Check the nature of the configuration change. Only
// minor configuration changes (such as frame ordering) can be handled
// gracefully by decoders without notification. Major changes (such as
// video resolution changes) should be treated as errors.
LOG(WARNING) << "H.264 decoder configuration has changed.";
last_video_decoder_config_->set_extra_data(decoder_config_record);
}
return true;
}
uint32_t coded_width = 0;
uint32_t coded_height = 0;
uint32_t pixel_width = 0;
uint32_t pixel_height = 0;
if (!ExtractResolutionFromSps(*sps, &coded_width, &coded_height, &pixel_width,
&pixel_height)) {
LOG(ERROR) << "Failed to parse SPS.";
return false;
}
last_video_decoder_config_ = scoped_refptr<StreamInfo>(
new VideoStreamInfo(
pid(),
kMpeg2Timescale,
kInfiniteDuration,
kCodecH264,
AVCDecoderConfiguration::GetCodecString(decoder_config_record[1],
decoder_config_record[2],
decoder_config_record[3]),
std::string(),
coded_width,
coded_height,
pixel_width,
pixel_height,
0,
H264ByteToUnitStreamConverter::kUnitStreamNaluLengthSize,
decoder_config_record.data(),
decoder_config_record.size(),
false));
DVLOG(1) << "Profile IDC: " << sps->profile_idc;
DVLOG(1) << "Level IDC: " << sps->level_idc;
DVLOG(1) << "log2_max_frame_num_minus4: " << sps->log2_max_frame_num_minus4;
// Video config notification.
new_stream_info_cb_.Run(last_video_decoder_config_);
return true;
}
} // namespace mp2t
} // namespace media
} // namespace edash_packager