// 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/formats/mp2t/ts_section_pes.h" #include "base/logging.h" #include "base/strings/string_number_conversions.h" #include "media/base/bit_reader.h" #include "media/base/buffers.h" #include "media/formats/mp2t/es_parser.h" #include "media/formats/mp2t/mp2t_common.h" #include "media/formats/mp2t/timestamp_unroller.h" static const int kPesStartCode = 0x000001; static bool IsTimestampSectionValid(int64 timestamp_section) { // |pts_section| has 40 bits: // - starting with either '0010' or '0011' or '0001' // - and ending with a marker bit. // See ITU H.222 standard - PES section. // Verify that all the marker bits are set to one. return ((timestamp_section & 0x1) != 0) && ((timestamp_section & 0x10000) != 0) && ((timestamp_section & 0x100000000) != 0); } static int64 ConvertTimestampSectionToTimestamp(int64 timestamp_section) { return (((timestamp_section >> 33) & 0x7) << 30) | (((timestamp_section >> 17) & 0x7fff) << 15) | (((timestamp_section >> 1) & 0x7fff) << 0); } namespace media { namespace mp2t { TsSectionPes::TsSectionPes(scoped_ptr es_parser, TimestampUnroller* timestamp_unroller) : es_parser_(es_parser.release()), wait_for_pusi_(true), timestamp_unroller_(timestamp_unroller) { DCHECK(es_parser_); DCHECK(timestamp_unroller_); } TsSectionPes::~TsSectionPes() { } bool TsSectionPes::Parse(bool payload_unit_start_indicator, const uint8* buf, int size) { // Ignore partial PES. if (wait_for_pusi_ && !payload_unit_start_indicator) return true; bool parse_result = true; if (payload_unit_start_indicator) { // Try emitting a packet since we might have a pending PES packet // with an undefined size. // In this case, a unit is emitted when the next unit is coming. int raw_pes_size; const uint8* raw_pes; pes_byte_queue_.Peek(&raw_pes, &raw_pes_size); if (raw_pes_size > 0) parse_result = Emit(true); // Reset the state. ResetPesState(); // Update the state. wait_for_pusi_ = false; } // Add the data to the parser state. if (size > 0) pes_byte_queue_.Push(buf, size); // Try emitting the current PES packet. return (parse_result && Emit(false)); } void TsSectionPes::Flush() { // Try emitting a packet since we might have a pending PES packet // with an undefined size. Emit(true); // Flush the underlying ES parser. es_parser_->Flush(); } void TsSectionPes::Reset() { ResetPesState(); es_parser_->Reset(); } bool TsSectionPes::Emit(bool emit_for_unknown_size) { int raw_pes_size; const uint8* raw_pes; pes_byte_queue_.Peek(&raw_pes, &raw_pes_size); // A PES should be at least 6 bytes. // Wait for more data to come if not enough bytes. if (raw_pes_size < 6) return true; // Check whether we have enough data to start parsing. int pes_packet_length = (static_cast(raw_pes[4]) << 8) | (static_cast(raw_pes[5])); if ((pes_packet_length == 0 && !emit_for_unknown_size) || (pes_packet_length != 0 && raw_pes_size < pes_packet_length + 6)) { // Wait for more data to come either because: // - there are not enough bytes, // - or the PES size is unknown and the "force emit" flag is not set. // (PES size might be unknown for video PES packet). return true; } DVLOG(LOG_LEVEL_PES) << "pes_packet_length=" << pes_packet_length; // Parse the packet. bool parse_result = ParseInternal(raw_pes, raw_pes_size); // Reset the state. ResetPesState(); return parse_result; } bool TsSectionPes::ParseInternal(const uint8* raw_pes, int raw_pes_size) { BitReader bit_reader(raw_pes, raw_pes_size); // Read up to the pes_packet_length (6 bytes). int packet_start_code_prefix; int stream_id; int pes_packet_length; RCHECK(bit_reader.ReadBits(24, &packet_start_code_prefix)); RCHECK(bit_reader.ReadBits(8, &stream_id)); RCHECK(bit_reader.ReadBits(16, &pes_packet_length)); RCHECK(packet_start_code_prefix == kPesStartCode); DVLOG(LOG_LEVEL_PES) << "stream_id=" << std::hex << stream_id << std::dec; if (pes_packet_length == 0) pes_packet_length = bit_reader.bits_available() / 8; // Ignore the PES for unknown stream IDs. // See ITU H.222 Table 2-22 "Stream_id assignments" bool is_audio_stream_id = ((stream_id & 0xe0) == 0xc0); bool is_video_stream_id = ((stream_id & 0xf0) == 0xe0); // According to ETSI DVB standard (ETSI TS 101 154) section 4.1.6.1 // AC-3 and DTS audio streams may have stream_id 0xbd. These streams // have the same syntax as regular audio streams. bool is_private_stream_1 = (stream_id == 0xbd); if (!is_audio_stream_id && !is_video_stream_id && !is_private_stream_1) { DVLOG(LOG_LEVEL_PES) << "Dropped TsPacket for stream_id=0x" << std::hex << stream_id << std::dec; return true; } // Read up to "pes_header_data_length". int dummy_2; int PES_scrambling_control; int PES_priority; int data_alignment_indicator; int copyright; int original_or_copy; int pts_dts_flags; int escr_flag; int es_rate_flag; int dsm_trick_mode_flag; int additional_copy_info_flag; int pes_crc_flag; int pes_extension_flag; int pes_header_data_length; RCHECK(bit_reader.ReadBits(2, &dummy_2)); RCHECK(dummy_2 == 0x2); RCHECK(bit_reader.ReadBits(2, &PES_scrambling_control)); RCHECK(bit_reader.ReadBits(1, &PES_priority)); RCHECK(bit_reader.ReadBits(1, &data_alignment_indicator)); RCHECK(bit_reader.ReadBits(1, ©right)); RCHECK(bit_reader.ReadBits(1, &original_or_copy)); RCHECK(bit_reader.ReadBits(2, &pts_dts_flags)); RCHECK(bit_reader.ReadBits(1, &escr_flag)); RCHECK(bit_reader.ReadBits(1, &es_rate_flag)); RCHECK(bit_reader.ReadBits(1, &dsm_trick_mode_flag)); RCHECK(bit_reader.ReadBits(1, &additional_copy_info_flag)); RCHECK(bit_reader.ReadBits(1, &pes_crc_flag)); RCHECK(bit_reader.ReadBits(1, &pes_extension_flag)); RCHECK(bit_reader.ReadBits(8, &pes_header_data_length)); int pes_header_start_size = bit_reader.bits_available() / 8; // Compute the size and the offset of the ES payload. // "6" for the 6 bytes read before and including |pes_packet_length|. // "3" for the 3 bytes read before and including |pes_header_data_length|. int es_size = pes_packet_length - 3 - pes_header_data_length; int es_offset = 6 + 3 + pes_header_data_length; RCHECK(es_size >= 0); RCHECK(es_offset + es_size <= raw_pes_size); // Read the timing information section. bool is_pts_valid = false; bool is_dts_valid = false; int64 pts_section = 0; int64 dts_section = 0; if (pts_dts_flags == 0x2) { RCHECK(bit_reader.ReadBits(40, &pts_section)); RCHECK((((pts_section >> 36) & 0xf) == 0x2) && IsTimestampSectionValid(pts_section)); is_pts_valid = true; } if (pts_dts_flags == 0x3) { RCHECK(bit_reader.ReadBits(40, &pts_section)); RCHECK(bit_reader.ReadBits(40, &dts_section)); RCHECK((((pts_section >> 36) & 0xf) == 0x3) && IsTimestampSectionValid(pts_section)); RCHECK((((dts_section >> 36) & 0xf) == 0x1) && IsTimestampSectionValid(dts_section)); is_pts_valid = true; is_dts_valid = true; } // Convert and unroll the timestamps. base::TimeDelta media_pts(kNoTimestamp()); DecodeTimestamp media_dts(kNoDecodeTimestamp()); if (is_pts_valid) { int64 pts = timestamp_unroller_->GetUnrolledTimestamp( ConvertTimestampSectionToTimestamp(pts_section)); media_pts = base::TimeDelta::FromMicroseconds((1000 * pts) / 90); } if (is_dts_valid) { int64 dts = timestamp_unroller_->GetUnrolledTimestamp( ConvertTimestampSectionToTimestamp(dts_section)); media_dts = DecodeTimestamp::FromMicroseconds((1000 * dts) / 90); } // Discard the rest of the PES packet header. // TODO(damienv): check if some info of the PES packet header are useful. DCHECK_EQ(bit_reader.bits_available() % 8, 0); int pes_header_remaining_size = pes_header_data_length - (pes_header_start_size - bit_reader.bits_available() / 8); RCHECK(pes_header_remaining_size >= 0); // Read the PES packet. DVLOG(LOG_LEVEL_PES) << "Emit a reassembled PES:" << " size=" << es_size << " pts=" << media_pts.InMilliseconds() << " dts=" << media_dts.InMilliseconds() << " data_alignment_indicator=" << data_alignment_indicator; return es_parser_->Parse(&raw_pes[es_offset], es_size, media_pts, media_dts); } void TsSectionPes::ResetPesState() { pes_byte_queue_.Reset(); wait_for_pusi_ = true; } } // namespace mp2t } // namespace media