// Copyright 2016 Google Inc. All rights reserved. // // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file or at // https://developers.google.com/open-source/licenses/bsd #include "packager/media/formats/mp2t/ts_writer.h" #include #include "packager/base/logging.h" #include "packager/media/base/audio_stream_info.h" #include "packager/media/base/buffer_writer.h" #include "packager/media/base/stream_info.h" #include "packager/media/base/video_stream_info.h" #include "packager/media/formats/mp2t/ts_packet_writer_util.h" namespace shaka { namespace media { namespace mp2t { namespace { // For all the pointer fields in the following PAT and PMTs, they are not really // part of PAT or PMT but it's there so that TsPacket can point to a memory // location that starts from pointer field. const uint8_t kProgramAssociationTableId = 0x00; // This PAT can be used for both encrypted and clear. const uint8_t kPat[] = { 0x00, // pointer field kProgramAssociationTableId, 0xB0, // The last 2 '00' assumes that this PAT is not very long. 0x0D, // Length of the rest of this array. 0x00, 0x00, // Transport stream ID is 0. 0xC1, // version number 0, current next indicator 1. 0x00, // section number 0x00, // last section number // program number -> PMT PID mapping. 0x00, 0x01, // program number is 1. 0xE0, // first 3 bits is reserved. ProgramMapTableWriter::kPmtPid, // CRC32. 0xF9, 0x62, 0xF5, 0x8B, }; const bool kHasPcr = true; const bool kPayloadUnitStartIndicator = true; // This is the size of the first few fields in a TS packet, i.e. TS packet size // without adaptation field or the payload. const int kTsPacketHeaderSize = 4; const int kTsPacketSize = 188; const int kTsPacketMaximumPayloadSize = kTsPacketSize - kTsPacketHeaderSize; const size_t kMaxPesPacketLengthValue = 0xFFFF; void WritePatToBuffer(const uint8_t* pat, int pat_size, ContinuityCounter* continuity_counter, BufferWriter* writer) { const int kPatPid = 0; WritePayloadToBufferWriter(pat, pat_size, kPayloadUnitStartIndicator, kPatPid, !kHasPcr, 0, continuity_counter, writer); } // The only difference between writing PTS or DTS is the leading bits. void WritePtsOrDts(uint8_t leading_bits, uint64_t pts_or_dts, BufferWriter* writer) { // First byte has 3 MSB of PTS. uint8_t first_byte = leading_bits << 4 | (((pts_or_dts >> 30) & 0x07) << 1) | 1; // Second byte has the next 8 bits of pts. uint8_t second_byte = (pts_or_dts >> 22) & 0xFF; // Third byte has the next 7 bits of pts followed by a marker bit. uint8_t third_byte = (((pts_or_dts >> 15) & 0x7F) << 1) | 1; // Fourth byte has the next 8 bits of pts. uint8_t fourth_byte = ((pts_or_dts >> 7) & 0xFF); // Fifth byte has the last 7 bits of pts followed by a marker bit. uint8_t fifth_byte = ((pts_or_dts & 0x7F) << 1) | 1; writer->AppendInt(first_byte); writer->AppendInt(second_byte); writer->AppendInt(third_byte); writer->AppendInt(fourth_byte); writer->AppendInt(fifth_byte); } bool WritePesToFile(const PesPacket& pes, ContinuityCounter* continuity_counter, File* file) { // The size of the length field. const int kAdaptationFieldLengthSize = 1; // The size of the flags field. const int kAdaptationFieldHeaderSize = 1; const int kPcrFieldSize = 6; const int kTsPacketMaxPayloadWithPcr = kTsPacketMaximumPayloadSize - kAdaptationFieldLengthSize - kAdaptationFieldHeaderSize - kPcrFieldSize; const uint64_t pcr_base = pes.has_dts() ? pes.dts() : pes.pts(); const int pid = ProgramMapTableWriter::kElementaryPid; // This writer will hold part of PES packet after PES_packet_length field. BufferWriter pes_header_writer; // The first bit must be '10' for PES with video or audio stream id. The other // flags (bits) don't matter so they are 0. pes_header_writer.AppendInt(static_cast(0x80)); pes_header_writer.AppendInt( static_cast(static_cast(pes.has_pts()) << 7 | static_cast(pes.has_dts()) << 6 // Other fields are all 0. )); uint8_t pes_header_data_length = 0; if (pes.has_pts()) pes_header_data_length += 5; if (pes.has_dts()) pes_header_data_length += 5; pes_header_writer.AppendInt(pes_header_data_length); if (pes.has_pts() && pes.has_dts()) { WritePtsOrDts(0x03, pes.pts(), &pes_header_writer); WritePtsOrDts(0x01, pes.dts(), &pes_header_writer); } else if (pes.has_pts()) { WritePtsOrDts(0x02, pes.pts(), &pes_header_writer); } // Put the first TS packet's payload into a buffer. This contains the PES // packet's header. BufferWriter first_ts_packet_buffer(kTsPacketSize); first_ts_packet_buffer.AppendNBytes(static_cast(0x000001), 3); first_ts_packet_buffer.AppendInt(pes.stream_id()); const size_t pes_packet_length = pes.data().size() + pes_header_writer.Size(); first_ts_packet_buffer.AppendInt(static_cast( pes_packet_length > kMaxPesPacketLengthValue ? 0 : pes_packet_length)); first_ts_packet_buffer.AppendBuffer(pes_header_writer); const int available_payload = kTsPacketMaxPayloadWithPcr - first_ts_packet_buffer.Size(); const int bytes_consumed = std::min(static_cast(pes.data().size()), available_payload); first_ts_packet_buffer.AppendArray(pes.data().data(), bytes_consumed); BufferWriter output_writer; WritePayloadToBufferWriter(first_ts_packet_buffer.Buffer(), first_ts_packet_buffer.Size(), kPayloadUnitStartIndicator, pid, kHasPcr, pcr_base, continuity_counter, &output_writer); const size_t remaining_pes_data_size = pes.data().size() - bytes_consumed; if (remaining_pes_data_size > 0) { WritePayloadToBufferWriter(pes.data().data() + bytes_consumed, remaining_pes_data_size, !kPayloadUnitStartIndicator, pid, !kHasPcr, 0, continuity_counter, &output_writer); } return output_writer.WriteToFile(file).ok(); } } // namespace TsWriter::TsWriter() {} TsWriter::~TsWriter() {} bool TsWriter::Initialize(const StreamInfo& stream_info) { const StreamType stream_type = stream_info.stream_type(); if (stream_type != StreamType::kStreamVideo && stream_type != StreamType::kStreamAudio) { LOG(ERROR) << "TsWriter cannot handle stream type " << stream_type << " yet."; return false; } if (stream_info.stream_type() == StreamType::kStreamVideo) { const VideoStreamInfo& video_stream_info = static_cast(stream_info); if (video_stream_info.codec() != VideoCodec::kCodecH264) { LOG(ERROR) << "TsWriter cannot handle video codec " << video_stream_info.codec() << " yet."; return false; } pmt_writer_.reset(new H264ProgramMapTableWriter(&pmt_continuity_counter_)); } else { DCHECK_EQ(stream_type, StreamType::kStreamAudio); const AudioStreamInfo& audio_stream_info = static_cast(stream_info); if (audio_stream_info.codec() != AudioCodec::kCodecAAC) { LOG(ERROR) << "TsWriter cannot handle audio codec " << audio_stream_info.codec() << " yet."; return false; } pmt_writer_.reset(new AacProgramMapTableWriter( audio_stream_info.codec_config(), &pmt_continuity_counter_)); } return true; } bool TsWriter::NewSegment(const std::string& file_name) { if (current_file_) { LOG(ERROR) << "File " << current_file_->file_name() << " still open."; return false; } current_file_.reset(File::Open(file_name.c_str(), "w")); if (!current_file_) { LOG(ERROR) << "Failed to open file " << file_name; return false; } BufferWriter psi; WritePatToBuffer(kPat, arraysize(kPat), &pat_continuity_counter_, &psi); if (encrypted_) { if (!pmt_writer_->EncryptedSegmentPmt(&psi)) { return false; } } else { if (!pmt_writer_->ClearSegmentPmt(&psi)) { return false; } } if (!psi.WriteToFile(current_file_.get()).ok()) { LOG(ERROR) << "Failed to write PSI to file."; return false; } return true; } void TsWriter::SignalEncypted() { encrypted_ = true; } bool TsWriter::FinalizeSegment() { return current_file_.release()->Close(); } bool TsWriter::AddPesPacket(scoped_ptr pes_packet) { DCHECK(current_file_); if (!WritePesToFile(*pes_packet, &elementary_stream_continuity_counter_, current_file_.get())) { LOG(ERROR) << "Failed to write pes to file."; return false; } // No need to keep pes_packet around so not passing it anywhere. return true; } void TsWriter::SetProgramMapTableWriterForTesting( scoped_ptr table_writer) { pmt_writer_ = table_writer.Pass(); } } // namespace mp2t } // namespace media } // namespace shaka