// 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 #include "packager/base/files/file_path.h" #include "packager/base/files/file_util.h" #include "packager/media/base/audio_stream_info.h" #include "packager/media/base/video_stream_info.h" #include "packager/media/formats/mp2t/pes_packet.h" #include "packager/media/formats/mp2t/ts_writer.h" namespace edash_packager { namespace media { namespace mp2t { namespace { const int kTsPacketSize = 188; // Only {Audio,Video}Codec matter for this test. Other values are bogus. const VideoCodec kH264VideoCodec = VideoCodec::kCodecH264; const AudioCodec kAacAudioCodec = AudioCodec::kCodecAAC; const int kTrackId = 0; const uint32_t kTimeScale = 90000; const uint64_t kDuration = 180000; const char kCodecString[] = "avc1"; const char kLanguage[] = "eng"; const uint32_t kWidth = 1280; const uint32_t kHeight = 720; const uint32_t kPixelWidth = 1; const uint32_t kPixelHeight = 1; const uint16_t kTrickPlayRate = 1; const uint8_t kNaluLengthSize = 1; const bool kIsEncrypted = false; const uint8_t kSampleBits = 16; const uint8_t kNumChannels = 2; const uint32_t kSamplingFrequency = 44100; const uint32_t kMaxBitrate = 320000; const uint32_t kAverageBitrate = 256000; const uint8_t kExtraData[] = { 0x01, 0x02, }; } // namespace class TsWriterTest : public ::testing::Test { protected: // Using different file names for each test so that the tests can be run in // parallel. void SetUp() override { base::CreateTemporaryFile(&test_file_path_); // TODO(rkuroiwa): Use memory file prefix once its exposed. test_file_name_ = kLocalFilePrefix + test_file_path_.value(); } void TearDown() override { const bool kRecursive = true; base::DeleteFile(test_file_path_, !kRecursive); } bool ReadFileToVector(const base::FilePath& path, std::vector* out) { std::string content; if (!base::ReadFileToString(path, &content)) return false; out->assign(content.begin(), content.end()); return true; } // Checks whether |actual|'s prefix matches with |prefix| and the suffix // matches with |suffix|. If there is padding, then padding_length specifies // how long the padding is between prefix and suffix. // |actual| must be at least 188 bytes long. void ExpectTsPacketEqual(const uint8_t* prefix, size_t prefix_size, int padding_length, const uint8_t* suffix, size_t suffix_size, const uint8_t* actual) { std::vector actual_prefix(actual, actual + prefix_size); EXPECT_EQ(std::vector(prefix, prefix + prefix_size), actual_prefix); // Padding until the payload. for (size_t i = prefix_size; i < kTsPacketSize - suffix_size; ++i) { EXPECT_EQ(0xFF, actual[i]) << "at index " << i; } std::vector actual_suffix(actual + prefix_size + padding_length, actual + kTsPacketSize); EXPECT_EQ(std::vector(suffix, suffix + suffix_size), actual_suffix); } std::string test_file_name_; TsWriter ts_writer_; base::FilePath test_file_path_; }; TEST_F(TsWriterTest, InitializeVideoH264) { scoped_refptr stream_info(new VideoStreamInfo( kTrackId, kTimeScale, kDuration, kH264VideoCodec, kCodecString, kLanguage, kWidth, kHeight, kPixelWidth, kPixelHeight, kTrickPlayRate, kNaluLengthSize, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_TRUE(ts_writer_.Initialize(*stream_info)); } TEST_F(TsWriterTest, InitializeVideoNonH264) { scoped_refptr stream_info(new VideoStreamInfo( kTrackId, kTimeScale, kDuration, VideoCodec::kCodecVP9, kCodecString, kLanguage, kWidth, kHeight, kPixelWidth, kPixelHeight, kTrickPlayRate, kNaluLengthSize, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_FALSE(ts_writer_.Initialize(*stream_info)); } TEST_F(TsWriterTest, InitializeAudioAac) { scoped_refptr stream_info(new AudioStreamInfo( kTrackId, kTimeScale, kDuration, kAacAudioCodec, kCodecString, kLanguage, kSampleBits, kNumChannels, kSamplingFrequency, kMaxBitrate, kAverageBitrate, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_TRUE(ts_writer_.Initialize(*stream_info)); } TEST_F(TsWriterTest, InitializeAudioNonAac) { scoped_refptr stream_info(new AudioStreamInfo( kTrackId, kTimeScale, kDuration, AudioCodec::kCodecOpus, kCodecString, kLanguage, kSampleBits, kNumChannels, kSamplingFrequency, kMaxBitrate, kAverageBitrate, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_FALSE(ts_writer_.Initialize(*stream_info)); } TEST_F(TsWriterTest, NewSegment) { scoped_refptr stream_info(new VideoStreamInfo( kTrackId, kTimeScale, kDuration, kH264VideoCodec, kCodecString, kLanguage, kWidth, kHeight, kPixelWidth, kPixelHeight, kTrickPlayRate, kNaluLengthSize, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_TRUE(ts_writer_.Initialize(*stream_info)); EXPECT_TRUE(ts_writer_.NewSegment(test_file_name_)); ASSERT_TRUE(ts_writer_.FinalizeSegment()); std::vector content; ASSERT_TRUE(ReadFileToVector(test_file_path_, &content)); // 2 TS Packets. PAT, PMT. ASSERT_EQ(376u, content.size()); const uint8_t kExpectedPatPrefix[] = { 0x47, // Sync byte. 0x40, // payload_unit_start_indicator set. 0x00, // pid. 0x30, // Adaptation field and payload are both present. counter = 0. 0xA6, // Adaptation Field length. 0x00, // All adaptation field flags 0. }; const int kExpectedPatPrefixSize = arraysize(kExpectedPatPrefix); const uint8_t kExpectedPatPayload[] = { 0x00, // pointer field 0x00, 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. 0x20, // PMT PID. // CRC32. 0xAB, 0xB9, 0x9E, 0x9D, }; EXPECT_NO_FATAL_FAILURE(ExpectTsPacketEqual( kExpectedPatPrefix, kExpectedPatPrefixSize, 165, kExpectedPatPayload, arraysize(kExpectedPatPayload), content.data())); const uint8_t kExpectedPmtPrefix[] = { 0x47, // Sync byte. 0x40, // payload_unit_start_indicator set. 0x20, // pid. 0x30, // Adaptation field and payload are both present. counter = 0. 0xA1, // Adaptation Field length. 0x00, // All adaptation field flags 0. }; const int kExpectedPmtPrefixSize = arraysize(kExpectedPmtPrefix); const uint8_t kPmtH264[] = { 0x00, // pointer field 0x02, 0xB0, // assumes length is <= 256 bytes. 0x12, // length of the rest of this array. 0x00, 0x01, 0xC1, // version 0, current next indicator 1. 0x00, // section number 0x00, // last section number. 0xE0, // first 3 bits reserved. 0x50, // PCR PID is the elementary streams PID. 0xF0, // first 4 bits reserved. 0x00, // No descriptor at this level. 0x1B, 0xE0, 0x50, // stream_type -> PID. 0xF0, 0x00, // Es_info_length is 0. // CRC32. 0x56, 0x90, 0xF4, 0xEB, }; EXPECT_NO_FATAL_FAILURE(ExpectTsPacketEqual( kExpectedPmtPrefix, kExpectedPmtPrefixSize, 160, kPmtH264, arraysize(kPmtH264), content.data() + kTsPacketSize)); } TEST_F(TsWriterTest, AddPesPacket) { scoped_refptr stream_info(new VideoStreamInfo( kTrackId, kTimeScale, kDuration, kH264VideoCodec, kCodecString, kLanguage, kWidth, kHeight, kPixelWidth, kPixelHeight, kTrickPlayRate, kNaluLengthSize, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_TRUE(ts_writer_.Initialize(*stream_info)); EXPECT_TRUE(ts_writer_.NewSegment(test_file_name_)); scoped_ptr pes(new PesPacket()); pes->set_stream_id(0xE0); pes->set_duration(99000); pes->set_pts(0x900); pes->set_dts(0x900); const uint8_t kAnyData[] = { 0x12, 0x88, 0x4f, 0x4a, }; pes->mutable_data()->assign(kAnyData, kAnyData + arraysize(kAnyData)); EXPECT_TRUE(ts_writer_.AddPesPacket(pes.Pass())); ASSERT_TRUE(ts_writer_.FinalizeSegment()); std::vector content; ASSERT_TRUE(ReadFileToVector(test_file_path_, &content)); // 3 TS Packets. PAT, PMT, and PES. ASSERT_EQ(564u, content.size()); const int kPesStartPosition = 376; // Prefix of the expected output. Rest of the packet should be filled with // padding. const uint8_t kExpectedOutputPrefix[] = { 0x47, // Sync byte. 0x40, // payload_unit_start_indicator set. 0x50, // pid. 0x30, // Adaptation field and payload are both present. counter = 0. 0xA0, // Adaptation Field length. 0x10, // pcr flag. 0x00, 0x00, 0x04, 0x80, 0x00, 0x00, // PCR. }; const uint8_t kExpectedPayload[] = { 0x00, 0x00, 0x01, // Start code. 0xE0, // stream id. 0x00, 0x11, // PES_packet_length. 0x80, // Flags. 0xC0, // PTS and DTS both present. 0x0A, // PES_header_data_length. 0x31, // Since PTS is 0 this is '0011' (fixed) and marker bit at LSB. 0x00, // PTS leading bits 0. 0x01, // PTS 0 followed by marker bit. 0x12, // PTS 0x900 shifted. 0x01, // PTS 0 followed by marker bit. 0x11, // Fixed '0001' followed by marker bit at LSB. 0x00, // DTS leading bits 0. 0x01, // DTS 0 followed by marker bit. 0x12, // DTS 0x900 shifted. 0x01, // DTS 0 followed by marker bit. 0x12, 0x88, 0x4f, 0x4a, // Payload. }; EXPECT_NO_FATAL_FAILURE(ExpectTsPacketEqual( kExpectedOutputPrefix, arraysize(kExpectedOutputPrefix), 153, kExpectedPayload, arraysize(kExpectedPayload), content.data() + kPesStartPosition)); } // Verify that PES packet > 64KiB can be handled. TEST_F(TsWriterTest, BigPesPacket) { scoped_refptr stream_info(new VideoStreamInfo( kTrackId, kTimeScale, kDuration, kH264VideoCodec, kCodecString, kLanguage, kWidth, kHeight, kPixelWidth, kPixelHeight, kTrickPlayRate, kNaluLengthSize, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_TRUE(ts_writer_.Initialize(*stream_info)); EXPECT_TRUE(ts_writer_.NewSegment(test_file_name_)); scoped_ptr pes(new PesPacket()); pes->set_duration(99000); pes->set_pts(0); pes->set_dts(0); // A little over 2 TS Packets (3 TS Packets). const std::vector big_data(400, 0x23); *pes->mutable_data() = big_data; EXPECT_TRUE(ts_writer_.AddPesPacket(pes.Pass())); ASSERT_TRUE(ts_writer_.FinalizeSegment()); std::vector content; ASSERT_TRUE(ReadFileToVector(test_file_path_, &content)); // The first TsPacket can only carry // 177 (TS packet size - header - adaptation_field) - 19 (PES header data) = // 158 bytes of the PES packet payload. // So this should create // 2 + 1 + ceil((400 - 158) / 184) = 5 TsPackets. // Where 184 is the maxium payload of a TS packet. EXPECT_EQ(5u * 188, content.size()); // Check continuity counter. EXPECT_EQ(0, (content[2 * 188 + 3] & 0xF)); EXPECT_EQ(1, (content[3 * 188 + 3] & 0xF)); EXPECT_EQ(2, (content[4 * 188 + 3] & 0xF)); } // Bug found in code review. It should check whether PTS is present not whether // PTS (implicilty) cast to bool is true. TEST_F(TsWriterTest, PesPtsZeroNoDts) { scoped_refptr stream_info(new VideoStreamInfo( kTrackId, kTimeScale, kDuration, kH264VideoCodec, kCodecString, kLanguage, kWidth, kHeight, kPixelWidth, kPixelHeight, kTrickPlayRate, kNaluLengthSize, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_TRUE(ts_writer_.Initialize(*stream_info)); EXPECT_TRUE(ts_writer_.NewSegment(test_file_name_)); scoped_ptr pes(new PesPacket()); pes->set_stream_id(0xE0); pes->set_duration(99000); pes->set_pts(0x0); const uint8_t kAnyData[] = { 0x12, 0x88, 0x4F, 0x4A, }; pes->mutable_data()->assign(kAnyData, kAnyData + arraysize(kAnyData)); EXPECT_TRUE(ts_writer_.AddPesPacket(pes.Pass())); ASSERT_TRUE(ts_writer_.FinalizeSegment()); std::vector content; ASSERT_TRUE(ReadFileToVector(test_file_path_, &content)); // 3 TS Packets. PAT, PMT, and PES. ASSERT_EQ(564u, content.size()); const int kPesStartPosition = 376; // Prefix of the expected output. Rest of the packet should be filled with // padding. const uint8_t kExpectedOutputPrefix[] = { 0x47, // Sync byte. 0x40, // payload_unit_start_indicator set. 0x50, // pid. 0x30, // Adaptation field and payload are both present. counter = 0. 0xA5, // Adaptation Field length. 0x10, // pcr flag. 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, // PCR. }; const uint8_t kExpectedPayload[] = { 0x00, 0x00, 0x01, // Start code. 0xE0, // stream id. 0x00, 0x0C, // PES_packet_length. 0x80, // Flags. 0x80, // Only PTS present. 0x05, // PES_header_data_length. 0x21, // Since PTS is 0 this is '0010' (fixed) and marker bit at LSB. 0x00, // PTS 0. 0x01, // PTS 0 followed by marker bit. 0x00, // PTS 0. 0x01, // PTS 0 followed by marker bit. 0x12, 0x88, 0x4F, 0x4A, // Payload. }; EXPECT_NO_FATAL_FAILURE(ExpectTsPacketEqual( kExpectedOutputPrefix, arraysize(kExpectedOutputPrefix), 158, kExpectedPayload, arraysize(kExpectedPayload), content.data() + kPesStartPosition)); } // Verify that TS packet with payload 183 is handled correctly, e.g. // adaptation_field_length should be 0. TEST_F(TsWriterTest, TsPacketPayload183Bytes) { scoped_refptr stream_info(new VideoStreamInfo( kTrackId, kTimeScale, kDuration, kH264VideoCodec, kCodecString, kLanguage, kWidth, kHeight, kPixelWidth, kPixelHeight, kTrickPlayRate, kNaluLengthSize, kExtraData, arraysize(kExtraData), kIsEncrypted)); EXPECT_TRUE(ts_writer_.Initialize(*stream_info)); EXPECT_TRUE(ts_writer_.NewSegment(test_file_name_)); scoped_ptr pes(new PesPacket()); pes->set_stream_id(0xE0); pes->set_pts(0x00); pes->set_dts(0x00); // Note that first TS packet will have adaptation fields with PCR, so make // payload big enough so that second PES packet's payload is 183. // First TS packet can carry 157 bytes of PES payload. The next one should // carry 183 bytes. std::vector pes_payload(157 + 183, 0xAF); *pes->mutable_data() = pes_payload; EXPECT_TRUE(ts_writer_.AddPesPacket(pes.Pass())); ASSERT_TRUE(ts_writer_.FinalizeSegment()); const uint8_t kExpectedOutputPrefix[] = { 0x47, // Sync byte. 0x00, // payload_unit_start_indicator set. 0x50, // pid. 0x31, // Adaptation field and payload are both present. counter = 0. 0x00, // Adaptation Field length, 1 byte padding. }; std::vector content; ASSERT_TRUE(ReadFileToVector(test_file_path_, &content)); // 4 TsPackets. PAT, PMT, TsPacket with PES header, TsPacket rest of PES // payload. ASSERT_EQ(752u, content.size()); const int kPesStartPosition = 564; std::vector actual_prefix(content.data() + kPesStartPosition, content.data() + kPesStartPosition + 5); EXPECT_EQ( std::vector(kExpectedOutputPrefix, kExpectedOutputPrefix + 5), actual_prefix); } } // namespace mp2t } // namespace media } // namespace edash_packager