/* * Copyright (c) 2015 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "audio/audio_send_stream.h" #include #include #include #include #include #include "api/task_queue/default_task_queue_factory.h" #include "api/test/mock_frame_encryptor.h" #include "audio/audio_state.h" #include "audio/conversion.h" #include "audio/mock_voe_channel_proxy.h" #include "call/test/mock_rtp_transport_controller_send.h" #include "logging/rtc_event_log/mock/mock_rtc_event_log.h" #include "modules/audio_device/include/mock_audio_device.h" #include "modules/audio_mixer/audio_mixer_impl.h" #include "modules/audio_mixer/sine_wave_generator.h" #include "modules/audio_processing/include/audio_processing_statistics.h" #include "modules/audio_processing/include/mock_audio_processing.h" #include "modules/rtp_rtcp/mocks/mock_rtcp_bandwidth_observer.h" #include "modules/rtp_rtcp/mocks/mock_rtp_rtcp.h" #include "modules/utility/maybe_worker_thread.h" #include "system_wrappers/include/clock.h" #include "test/gtest.h" #include "test/mock_audio_encoder.h" #include "test/mock_audio_encoder_factory.h" #include "test/scoped_key_value_config.h" #include "test/time_controller/real_time_controller.h" namespace webrtc { namespace test { namespace { using ::testing::_; using ::testing::AnyNumber; using ::testing::Eq; using ::testing::Field; using ::testing::InSequence; using ::testing::Invoke; using ::testing::Ne; using ::testing::NiceMock; using ::testing::Return; using ::testing::StrEq; static const float kTolerance = 0.0001f; const uint32_t kSsrc = 1234; const char* kCName = "foo_name"; const int kAudioLevelId = 2; const int kTransportSequenceNumberId = 4; const int32_t kEchoDelayMedian = 254; const int32_t kEchoDelayStdDev = -3; const double kDivergentFilterFraction = 0.2f; const double kEchoReturnLoss = -65; const double kEchoReturnLossEnhancement = 101; const double kResidualEchoLikelihood = -1.0f; const double kResidualEchoLikelihoodMax = 23.0f; const CallSendStatistics kCallStats = {112, 12, 13456, 17890}; const ReportBlock kReportBlock = {456, 780, 123, 567, 890, 132, 143, 13354}; const int kTelephoneEventPayloadType = 123; const int kTelephoneEventPayloadFrequency = 65432; const int kTelephoneEventCode = 45; const int kTelephoneEventDuration = 6789; constexpr int kIsacPayloadType = 103; const SdpAudioFormat kIsacFormat = {"isac", 16000, 1}; const SdpAudioFormat kOpusFormat = {"opus", 48000, 2}; const SdpAudioFormat kG722Format = {"g722", 8000, 1}; const AudioCodecSpec kCodecSpecs[] = { {kIsacFormat, {16000, 1, 32000, 10000, 32000}}, {kOpusFormat, {48000, 1, 32000, 6000, 510000}}, {kG722Format, {16000, 1, 64000}}}; // TODO(dklee): This mirrors calculation in audio_send_stream.cc, which // should be made more precise in the future. This can be changed when that // logic is more accurate. const DataSize kOverheadPerPacket = DataSize::Bytes(20 + 8 + 10 + 12); const TimeDelta kMinFrameLength = TimeDelta::Millis(20); const TimeDelta kMaxFrameLength = TimeDelta::Millis(120); const DataRate kMinOverheadRate = kOverheadPerPacket / kMaxFrameLength; const DataRate kMaxOverheadRate = kOverheadPerPacket / kMinFrameLength; class MockLimitObserver : public BitrateAllocator::LimitObserver { public: MOCK_METHOD(void, OnAllocationLimitsChanged, (BitrateAllocationLimits), (override)); }; std::unique_ptr SetupAudioEncoderMock( int payload_type, const SdpAudioFormat& format) { for (const auto& spec : kCodecSpecs) { if (format == spec.format) { std::unique_ptr encoder( new ::testing::NiceMock()); ON_CALL(*encoder.get(), SampleRateHz()) .WillByDefault(Return(spec.info.sample_rate_hz)); ON_CALL(*encoder.get(), NumChannels()) .WillByDefault(Return(spec.info.num_channels)); ON_CALL(*encoder.get(), RtpTimestampRateHz()) .WillByDefault(Return(spec.format.clockrate_hz)); ON_CALL(*encoder.get(), GetFrameLengthRange()) .WillByDefault(Return(absl::optional>{ {TimeDelta::Millis(20), TimeDelta::Millis(120)}})); return encoder; } } return nullptr; } rtc::scoped_refptr SetupEncoderFactoryMock() { rtc::scoped_refptr factory = rtc::make_ref_counted(); ON_CALL(*factory.get(), GetSupportedEncoders()) .WillByDefault(Return(std::vector( std::begin(kCodecSpecs), std::end(kCodecSpecs)))); ON_CALL(*factory.get(), QueryAudioEncoder(_)) .WillByDefault(Invoke( [](const SdpAudioFormat& format) -> absl::optional { for (const auto& spec : kCodecSpecs) { if (format == spec.format) { return spec.info; } } return absl::nullopt; })); ON_CALL(*factory.get(), MakeAudioEncoderMock(_, _, _, _)) .WillByDefault(Invoke([](int payload_type, const SdpAudioFormat& format, absl::optional codec_pair_id, std::unique_ptr* return_value) { *return_value = SetupAudioEncoderMock(payload_type, format); })); return factory; } struct ConfigHelper { ConfigHelper(bool audio_bwe_enabled, bool expect_set_encoder_call, bool use_null_audio_processing) : stream_config_(/*send_transport=*/nullptr), audio_processing_( use_null_audio_processing ? nullptr : rtc::make_ref_counted>()), bitrate_allocator_(&limit_observer_), worker_queue_(field_trials, "ConfigHelper_worker_queue", time_controller_.GetTaskQueueFactory()), audio_encoder_(nullptr) { using ::testing::Invoke; AudioState::Config config; config.audio_mixer = AudioMixerImpl::Create(); config.audio_processing = audio_processing_; config.audio_device_module = rtc::make_ref_counted(); audio_state_ = AudioState::Create(config); SetupDefaultChannelSend(audio_bwe_enabled); SetupMockForSetupSendCodec(expect_set_encoder_call); SetupMockForCallEncoder(); // Use ISAC as default codec so as to prevent unnecessary `channel_proxy_` // calls from the default ctor behavior. stream_config_.send_codec_spec = AudioSendStream::Config::SendCodecSpec(kIsacPayloadType, kIsacFormat); stream_config_.rtp.ssrc = kSsrc; stream_config_.rtp.c_name = kCName; stream_config_.rtp.extensions.push_back( RtpExtension(RtpExtension::kAudioLevelUri, kAudioLevelId)); if (audio_bwe_enabled) { AddBweToConfig(&stream_config_); } stream_config_.encoder_factory = SetupEncoderFactoryMock(); stream_config_.min_bitrate_bps = 10000; stream_config_.max_bitrate_bps = 65000; } std::unique_ptr CreateAudioSendStream() { EXPECT_CALL(rtp_transport_, GetWorkerQueue()) .WillRepeatedly(Return(&worker_queue_)); return std::unique_ptr( new internal::AudioSendStream( time_controller_.GetClock(), stream_config_, audio_state_, time_controller_.GetTaskQueueFactory(), &rtp_transport_, &bitrate_allocator_, &event_log_, absl::nullopt, std::unique_ptr(channel_send_), field_trials)); } AudioSendStream::Config& config() { return stream_config_; } MockAudioEncoderFactory& mock_encoder_factory() { return *static_cast( stream_config_.encoder_factory.get()); } MockRtpRtcpInterface* rtp_rtcp() { return &rtp_rtcp_; } MockChannelSend* channel_send() { return channel_send_; } RtpTransportControllerSendInterface* transport() { return &rtp_transport_; } static void AddBweToConfig(AudioSendStream::Config* config) { config->rtp.extensions.push_back(RtpExtension( RtpExtension::kTransportSequenceNumberUri, kTransportSequenceNumberId)); config->send_codec_spec->transport_cc_enabled = true; } void SetupDefaultChannelSend(bool audio_bwe_enabled) { EXPECT_TRUE(channel_send_ == nullptr); channel_send_ = new ::testing::StrictMock(); EXPECT_CALL(*channel_send_, GetRtpRtcp()).WillRepeatedly(Invoke([this]() { return &this->rtp_rtcp_; })); EXPECT_CALL(rtp_rtcp_, SSRC).WillRepeatedly(Return(kSsrc)); EXPECT_CALL(*channel_send_, SetRTCP_CNAME(StrEq(kCName))).Times(1); EXPECT_CALL(*channel_send_, SetFrameEncryptor(_)).Times(1); EXPECT_CALL(*channel_send_, SetEncoderToPacketizerFrameTransformer(_)) .Times(1); EXPECT_CALL(rtp_rtcp_, SetExtmapAllowMixed(false)).Times(1); EXPECT_CALL(*channel_send_, SetSendAudioLevelIndicationStatus(true, kAudioLevelId)) .Times(1); EXPECT_CALL(rtp_transport_, GetBandwidthObserver()) .WillRepeatedly(Return(&bandwidth_observer_)); if (audio_bwe_enabled) { EXPECT_CALL(rtp_rtcp_, RegisterRtpHeaderExtension(TransportSequenceNumber::Uri(), kTransportSequenceNumberId)) .Times(1); EXPECT_CALL(*channel_send_, RegisterSenderCongestionControlObjects( &rtp_transport_, Eq(&bandwidth_observer_))) .Times(1); } else { EXPECT_CALL(*channel_send_, RegisterSenderCongestionControlObjects( &rtp_transport_, Eq(nullptr))) .Times(1); } EXPECT_CALL(*channel_send_, ResetSenderCongestionControlObjects()).Times(1); } void SetupMockForSetupSendCodec(bool expect_set_encoder_call) { if (expect_set_encoder_call) { EXPECT_CALL(*channel_send_, SetEncoder) .WillOnce( [this](int payload_type, std::unique_ptr encoder) { this->audio_encoder_ = std::move(encoder); return true; }); } } void SetupMockForCallEncoder() { // Let ModifyEncoder to invoke mock audio encoder. EXPECT_CALL(*channel_send_, CallEncoder(_)) .WillRepeatedly( [this](rtc::FunctionView modifier) { if (this->audio_encoder_) modifier(this->audio_encoder_.get()); }); } void SetupMockForSendTelephoneEvent() { EXPECT_TRUE(channel_send_); EXPECT_CALL(*channel_send_, SetSendTelephoneEventPayloadType( kTelephoneEventPayloadType, kTelephoneEventPayloadFrequency)); EXPECT_CALL( *channel_send_, SendTelephoneEventOutband(kTelephoneEventCode, kTelephoneEventDuration)) .WillOnce(Return(true)); } void SetupMockForGetStats(bool use_null_audio_processing) { using ::testing::DoAll; using ::testing::SetArgPointee; using ::testing::SetArgReferee; std::vector report_blocks; webrtc::ReportBlock block = kReportBlock; report_blocks.push_back(block); // Has wrong SSRC. block.source_SSRC = kSsrc; report_blocks.push_back(block); // Correct block. block.fraction_lost = 0; report_blocks.push_back(block); // Duplicate SSRC, bad fraction_lost. EXPECT_TRUE(channel_send_); EXPECT_CALL(*channel_send_, GetRTCPStatistics()) .WillRepeatedly(Return(kCallStats)); EXPECT_CALL(*channel_send_, GetRemoteRTCPReportBlocks()) .WillRepeatedly(Return(report_blocks)); EXPECT_CALL(*channel_send_, GetANAStatistics()) .WillRepeatedly(Return(ANAStats())); EXPECT_CALL(*channel_send_, GetTargetBitrate()).WillRepeatedly(Return(0)); audio_processing_stats_.echo_return_loss = kEchoReturnLoss; audio_processing_stats_.echo_return_loss_enhancement = kEchoReturnLossEnhancement; audio_processing_stats_.delay_median_ms = kEchoDelayMedian; audio_processing_stats_.delay_standard_deviation_ms = kEchoDelayStdDev; audio_processing_stats_.divergent_filter_fraction = kDivergentFilterFraction; audio_processing_stats_.residual_echo_likelihood = kResidualEchoLikelihood; audio_processing_stats_.residual_echo_likelihood_recent_max = kResidualEchoLikelihoodMax; if (!use_null_audio_processing) { ASSERT_TRUE(audio_processing_); EXPECT_CALL(*audio_processing_, GetStatistics(true)) .WillRepeatedly(Return(audio_processing_stats_)); } } MaybeWorkerThread* worker() { return &worker_queue_; } test::ScopedKeyValueConfig field_trials; private: RealTimeController time_controller_; rtc::scoped_refptr audio_state_; AudioSendStream::Config stream_config_; ::testing::StrictMock* channel_send_ = nullptr; rtc::scoped_refptr audio_processing_; AudioProcessingStats audio_processing_stats_; ::testing::StrictMock bandwidth_observer_; ::testing::NiceMock event_log_; ::testing::NiceMock rtp_transport_; ::testing::NiceMock rtp_rtcp_; ::testing::NiceMock limit_observer_; BitrateAllocator bitrate_allocator_; // `worker_queue` is defined last to ensure all pending tasks are cancelled // and deleted before any other members. MaybeWorkerThread worker_queue_; std::unique_ptr audio_encoder_; }; // The audio level ranges linearly [0,32767]. std::unique_ptr CreateAudioFrame1kHzSineWave(int16_t audio_level, int duration_ms, int sample_rate_hz, size_t num_channels) { size_t samples_per_channel = sample_rate_hz / (1000 / duration_ms); std::vector audio_data(samples_per_channel * num_channels, 0); std::unique_ptr audio_frame = std::make_unique(); audio_frame->UpdateFrame(0 /* RTP timestamp */, &audio_data[0], samples_per_channel, sample_rate_hz, AudioFrame::SpeechType::kNormalSpeech, AudioFrame::VADActivity::kVadUnknown, num_channels); SineWaveGenerator wave_generator(1000.0, audio_level); wave_generator.GenerateNextFrame(audio_frame.get()); return audio_frame; } } // namespace TEST(AudioSendStreamTest, ConfigToString) { AudioSendStream::Config config(/*send_transport=*/nullptr); config.rtp.ssrc = kSsrc; config.rtp.c_name = kCName; config.min_bitrate_bps = 12000; config.max_bitrate_bps = 34000; config.has_dscp = true; config.send_codec_spec = AudioSendStream::Config::SendCodecSpec(kIsacPayloadType, kIsacFormat); config.send_codec_spec->nack_enabled = true; config.send_codec_spec->transport_cc_enabled = false; config.send_codec_spec->cng_payload_type = 42; config.send_codec_spec->red_payload_type = 43; config.encoder_factory = MockAudioEncoderFactory::CreateUnusedFactory(); config.rtp.extmap_allow_mixed = true; config.rtp.extensions.push_back( RtpExtension(RtpExtension::kAudioLevelUri, kAudioLevelId)); config.rtcp_report_interval_ms = 2500; EXPECT_EQ( "{rtp: {ssrc: 1234, extmap-allow-mixed: true, extensions: [{uri: " "urn:ietf:params:rtp-hdrext:ssrc-audio-level, id: 2}], " "c_name: foo_name}, rtcp_report_interval_ms: 2500, " "send_transport: null, " "min_bitrate_bps: 12000, max_bitrate_bps: 34000, has " "audio_network_adaptor_config: false, has_dscp: true, " "send_codec_spec: {nack_enabled: true, transport_cc_enabled: false, " "enable_non_sender_rtt: false, cng_payload_type: 42, " "red_payload_type: 43, payload_type: 103, " "format: {name: isac, clockrate_hz: 16000, num_channels: 1, " "parameters: {}}}}", config.ToString()); } TEST(AudioSendStreamTest, ConstructDestruct) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); } } TEST(AudioSendStreamTest, SendTelephoneEvent) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); helper.SetupMockForSendTelephoneEvent(); EXPECT_TRUE(send_stream->SendTelephoneEvent( kTelephoneEventPayloadType, kTelephoneEventPayloadFrequency, kTelephoneEventCode, kTelephoneEventDuration)); } } TEST(AudioSendStreamTest, SetMuted) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); EXPECT_CALL(*helper.channel_send(), SetInputMute(true)); send_stream->SetMuted(true); } } TEST(AudioSendStreamTest, AudioBweCorrectObjectsOnChannelProxy) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); } } TEST(AudioSendStreamTest, NoAudioBweCorrectObjectsOnChannelProxy) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); } } TEST(AudioSendStreamTest, GetStats) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); helper.SetupMockForGetStats(use_null_audio_processing); AudioSendStream::Stats stats = send_stream->GetStats(true); EXPECT_EQ(kSsrc, stats.local_ssrc); EXPECT_EQ(kCallStats.payload_bytes_sent, stats.payload_bytes_sent); EXPECT_EQ(kCallStats.header_and_padding_bytes_sent, stats.header_and_padding_bytes_sent); EXPECT_EQ(kCallStats.packetsSent, stats.packets_sent); EXPECT_EQ(kReportBlock.cumulative_num_packets_lost, stats.packets_lost); EXPECT_EQ(Q8ToFloat(kReportBlock.fraction_lost), stats.fraction_lost); EXPECT_EQ(kIsacFormat.name, stats.codec_name); EXPECT_EQ(static_cast(kReportBlock.interarrival_jitter / (kIsacFormat.clockrate_hz / 1000)), stats.jitter_ms); EXPECT_EQ(kCallStats.rttMs, stats.rtt_ms); EXPECT_EQ(0, stats.audio_level); EXPECT_EQ(0, stats.total_input_energy); EXPECT_EQ(0, stats.total_input_duration); if (!use_null_audio_processing) { EXPECT_EQ(kEchoDelayMedian, stats.apm_statistics.delay_median_ms); EXPECT_EQ(kEchoDelayStdDev, stats.apm_statistics.delay_standard_deviation_ms); EXPECT_EQ(kEchoReturnLoss, stats.apm_statistics.echo_return_loss); EXPECT_EQ(kEchoReturnLossEnhancement, stats.apm_statistics.echo_return_loss_enhancement); EXPECT_EQ(kDivergentFilterFraction, stats.apm_statistics.divergent_filter_fraction); EXPECT_EQ(kResidualEchoLikelihood, stats.apm_statistics.residual_echo_likelihood); EXPECT_EQ(kResidualEchoLikelihoodMax, stats.apm_statistics.residual_echo_likelihood_recent_max); } } } TEST(AudioSendStreamTest, GetStatsAudioLevel) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); helper.SetupMockForGetStats(use_null_audio_processing); EXPECT_CALL(*helper.channel_send(), ProcessAndEncodeAudio) .Times(AnyNumber()); constexpr int kSampleRateHz = 48000; constexpr size_t kNumChannels = 1; constexpr int16_t kSilentAudioLevel = 0; constexpr int16_t kMaxAudioLevel = 32767; // Audio level is [0,32767]. constexpr int kAudioFrameDurationMs = 10; // Process 10 audio frames (100 ms) of silence. After this, on the next // (11-th) frame, the audio level will be updated with the maximum audio // level of the first 11 frames. See AudioLevel. for (size_t i = 0; i < 10; ++i) { send_stream->SendAudioData( CreateAudioFrame1kHzSineWave(kSilentAudioLevel, kAudioFrameDurationMs, kSampleRateHz, kNumChannels)); } AudioSendStream::Stats stats = send_stream->GetStats(); EXPECT_EQ(kSilentAudioLevel, stats.audio_level); EXPECT_NEAR(0.0f, stats.total_input_energy, kTolerance); EXPECT_NEAR(0.1f, stats.total_input_duration, kTolerance); // 100 ms = 0.1 s // Process 10 audio frames (100 ms) of maximum audio level. // Note that AudioLevel updates the audio level every 11th frame, processing // 10 frames above was needed to see a non-zero audio level here. for (size_t i = 0; i < 10; ++i) { send_stream->SendAudioData(CreateAudioFrame1kHzSineWave( kMaxAudioLevel, kAudioFrameDurationMs, kSampleRateHz, kNumChannels)); } stats = send_stream->GetStats(); EXPECT_EQ(kMaxAudioLevel, stats.audio_level); // Energy increases by energy*duration, where energy is audio level in // [0,1]. EXPECT_NEAR(0.1f, stats.total_input_energy, kTolerance); // 0.1 s of max EXPECT_NEAR(0.2f, stats.total_input_duration, kTolerance); // 200 ms = 0.2 s } } TEST(AudioSendStreamTest, SendCodecAppliesAudioNetworkAdaptor) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); helper.config().send_codec_spec = AudioSendStream::Config::SendCodecSpec(0, kOpusFormat); const std::string kAnaConfigString = "abcde"; const std::string kAnaReconfigString = "12345"; helper.config().audio_network_adaptor_config = kAnaConfigString; EXPECT_CALL(helper.mock_encoder_factory(), MakeAudioEncoderMock(_, _, _, _)) .WillOnce(Invoke([&kAnaConfigString, &kAnaReconfigString]( int payload_type, const SdpAudioFormat& format, absl::optional codec_pair_id, std::unique_ptr* return_value) { auto mock_encoder = SetupAudioEncoderMock(payload_type, format); EXPECT_CALL(*mock_encoder, EnableAudioNetworkAdaptor(StrEq(kAnaConfigString), _)) .WillOnce(Return(true)); EXPECT_CALL(*mock_encoder, EnableAudioNetworkAdaptor(StrEq(kAnaReconfigString), _)) .WillOnce(Return(true)); *return_value = std::move(mock_encoder); })); auto send_stream = helper.CreateAudioSendStream(); auto stream_config = helper.config(); stream_config.audio_network_adaptor_config = kAnaReconfigString; send_stream->Reconfigure(stream_config, nullptr); } } TEST(AudioSendStreamTest, AudioNetworkAdaptorReceivesOverhead) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); helper.config().send_codec_spec = AudioSendStream::Config::SendCodecSpec(0, kOpusFormat); const std::string kAnaConfigString = "abcde"; EXPECT_CALL(helper.mock_encoder_factory(), MakeAudioEncoderMock(_, _, _, _)) .WillOnce(Invoke( [&kAnaConfigString](int payload_type, const SdpAudioFormat& format, absl::optional codec_pair_id, std::unique_ptr* return_value) { auto mock_encoder = SetupAudioEncoderMock(payload_type, format); InSequence s; EXPECT_CALL( *mock_encoder, OnReceivedOverhead(Eq(kOverheadPerPacket.bytes()))) .Times(2); EXPECT_CALL(*mock_encoder, EnableAudioNetworkAdaptor(StrEq(kAnaConfigString), _)) .WillOnce(Return(true)); // Note: Overhead is received AFTER ANA has been enabled. EXPECT_CALL( *mock_encoder, OnReceivedOverhead(Eq(kOverheadPerPacket.bytes()))) .WillOnce(Return()); *return_value = std::move(mock_encoder); })); EXPECT_CALL(*helper.rtp_rtcp(), ExpectedPerPacketOverhead) .WillRepeatedly(Return(kOverheadPerPacket.bytes())); auto send_stream = helper.CreateAudioSendStream(); auto stream_config = helper.config(); stream_config.audio_network_adaptor_config = kAnaConfigString; send_stream->Reconfigure(stream_config, nullptr); } } // VAD is applied when codec is mono and the CNG frequency matches the codec // clock rate. TEST(AudioSendStreamTest, SendCodecCanApplyVad) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, false, use_null_audio_processing); helper.config().send_codec_spec = AudioSendStream::Config::SendCodecSpec(9, kG722Format); helper.config().send_codec_spec->cng_payload_type = 105; std::unique_ptr stolen_encoder; EXPECT_CALL(*helper.channel_send(), SetEncoder) .WillOnce([&stolen_encoder](int payload_type, std::unique_ptr encoder) { stolen_encoder = std::move(encoder); return true; }); EXPECT_CALL(*helper.channel_send(), RegisterCngPayloadType(105, 8000)); auto send_stream = helper.CreateAudioSendStream(); // We cannot truly determine if the encoder created is an AudioEncoderCng. // It is the only reasonable implementation that will return something from // ReclaimContainedEncoders, though. ASSERT_TRUE(stolen_encoder); EXPECT_FALSE(stolen_encoder->ReclaimContainedEncoders().empty()); } } TEST(AudioSendStreamTest, DoesNotPassHigherBitrateThanMaxBitrate) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); EXPECT_CALL( *helper.channel_send(), OnBitrateAllocation( Field(&BitrateAllocationUpdate::target_bitrate, Eq(DataRate::BitsPerSec(helper.config().max_bitrate_bps))))); BitrateAllocationUpdate update; update.target_bitrate = DataRate::BitsPerSec(helper.config().max_bitrate_bps + 5000); update.packet_loss_ratio = 0; update.round_trip_time = TimeDelta::Millis(50); update.bwe_period = TimeDelta::Millis(6000); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } TEST(AudioSendStreamTest, SSBweTargetInRangeRespected) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); EXPECT_CALL( *helper.channel_send(), OnBitrateAllocation(Field( &BitrateAllocationUpdate::target_bitrate, Eq(DataRate::BitsPerSec(helper.config().max_bitrate_bps - 5000))))); BitrateAllocationUpdate update; update.target_bitrate = DataRate::BitsPerSec(helper.config().max_bitrate_bps - 5000); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } TEST(AudioSendStreamTest, SSBweFieldTrialMinRespected) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); ScopedKeyValueConfig field_trials( helper.field_trials, "WebRTC-Audio-Allocation/min:6kbps,max:64kbps/"); auto send_stream = helper.CreateAudioSendStream(); EXPECT_CALL( *helper.channel_send(), OnBitrateAllocation(Field(&BitrateAllocationUpdate::target_bitrate, Eq(DataRate::KilobitsPerSec(6))))); BitrateAllocationUpdate update; update.target_bitrate = DataRate::KilobitsPerSec(1); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } TEST(AudioSendStreamTest, SSBweFieldTrialMaxRespected) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); ScopedKeyValueConfig field_trials( helper.field_trials, "WebRTC-Audio-Allocation/min:6kbps,max:64kbps/"); auto send_stream = helper.CreateAudioSendStream(); EXPECT_CALL( *helper.channel_send(), OnBitrateAllocation(Field(&BitrateAllocationUpdate::target_bitrate, Eq(DataRate::KilobitsPerSec(64))))); BitrateAllocationUpdate update; update.target_bitrate = DataRate::KilobitsPerSec(128); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } TEST(AudioSendStreamTest, SSBweWithOverhead) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); ScopedKeyValueConfig field_trials(helper.field_trials, "WebRTC-Audio-LegacyOverhead/Disabled/"); EXPECT_CALL(*helper.rtp_rtcp(), ExpectedPerPacketOverhead) .WillRepeatedly(Return(kOverheadPerPacket.bytes())); auto send_stream = helper.CreateAudioSendStream(); const DataRate bitrate = DataRate::BitsPerSec(helper.config().max_bitrate_bps) + kMaxOverheadRate; EXPECT_CALL(*helper.channel_send(), OnBitrateAllocation(Field( &BitrateAllocationUpdate::target_bitrate, Eq(bitrate)))); BitrateAllocationUpdate update; update.target_bitrate = bitrate; helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } TEST(AudioSendStreamTest, SSBweWithOverheadMinRespected) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); ScopedKeyValueConfig field_trials( helper.field_trials, "WebRTC-Audio-LegacyOverhead/Disabled/" "WebRTC-Audio-Allocation/min:6kbps,max:64kbps/"); EXPECT_CALL(*helper.rtp_rtcp(), ExpectedPerPacketOverhead) .WillRepeatedly(Return(kOverheadPerPacket.bytes())); auto send_stream = helper.CreateAudioSendStream(); const DataRate bitrate = DataRate::KilobitsPerSec(6) + kMinOverheadRate; EXPECT_CALL(*helper.channel_send(), OnBitrateAllocation(Field( &BitrateAllocationUpdate::target_bitrate, Eq(bitrate)))); BitrateAllocationUpdate update; update.target_bitrate = DataRate::KilobitsPerSec(1); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } TEST(AudioSendStreamTest, SSBweWithOverheadMaxRespected) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(true, true, use_null_audio_processing); ScopedKeyValueConfig field_trials( helper.field_trials, "WebRTC-Audio-LegacyOverhead/Disabled/" "WebRTC-Audio-Allocation/min:6kbps,max:64kbps/"); EXPECT_CALL(*helper.rtp_rtcp(), ExpectedPerPacketOverhead) .WillRepeatedly(Return(kOverheadPerPacket.bytes())); auto send_stream = helper.CreateAudioSendStream(); const DataRate bitrate = DataRate::KilobitsPerSec(64) + kMaxOverheadRate; EXPECT_CALL(*helper.channel_send(), OnBitrateAllocation(Field( &BitrateAllocationUpdate::target_bitrate, Eq(bitrate)))); BitrateAllocationUpdate update; update.target_bitrate = DataRate::KilobitsPerSec(128); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } TEST(AudioSendStreamTest, ProbingIntervalOnBitrateUpdated) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); EXPECT_CALL(*helper.channel_send(), OnBitrateAllocation(Field(&BitrateAllocationUpdate::bwe_period, Eq(TimeDelta::Millis(5000))))); BitrateAllocationUpdate update; update.target_bitrate = DataRate::BitsPerSec(helper.config().max_bitrate_bps + 5000); update.packet_loss_ratio = 0; update.round_trip_time = TimeDelta::Millis(50); update.bwe_period = TimeDelta::Millis(5000); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); } } // Test that AudioSendStream doesn't recreate the encoder unnecessarily. TEST(AudioSendStreamTest, DontRecreateEncoder) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, false, use_null_audio_processing); // WillOnce is (currently) the default used by ConfigHelper if asked to set // an expectation for SetEncoder. Since this behavior is essential for this // test to be correct, it's instead set-up manually here. Otherwise a simple // change to ConfigHelper (say to WillRepeatedly) would silently make this // test useless. EXPECT_CALL(*helper.channel_send(), SetEncoder).WillOnce(Return()); EXPECT_CALL(*helper.channel_send(), RegisterCngPayloadType(105, 8000)); helper.config().send_codec_spec = AudioSendStream::Config::SendCodecSpec(9, kG722Format); helper.config().send_codec_spec->cng_payload_type = 105; auto send_stream = helper.CreateAudioSendStream(); send_stream->Reconfigure(helper.config(), nullptr); } } TEST(AudioSendStreamTest, ReconfigureTransportCcResetsFirst) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); auto new_config = helper.config(); ConfigHelper::AddBweToConfig(&new_config); EXPECT_CALL(*helper.rtp_rtcp(), RegisterRtpHeaderExtension(TransportSequenceNumber::Uri(), kTransportSequenceNumberId)) .Times(1); { ::testing::InSequence seq; EXPECT_CALL(*helper.channel_send(), ResetSenderCongestionControlObjects()) .Times(1); EXPECT_CALL(*helper.channel_send(), RegisterSenderCongestionControlObjects(helper.transport(), Ne(nullptr))) .Times(1); } send_stream->Reconfigure(new_config, nullptr); } } TEST(AudioSendStreamTest, OnTransportOverheadChanged) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); auto new_config = helper.config(); // CallEncoder will be called on overhead change. EXPECT_CALL(*helper.channel_send(), CallEncoder); const size_t transport_overhead_per_packet_bytes = 333; send_stream->SetTransportOverhead(transport_overhead_per_packet_bytes); EXPECT_EQ(transport_overhead_per_packet_bytes, send_stream->TestOnlyGetPerPacketOverheadBytes()); } } TEST(AudioSendStreamTest, DoesntCallEncoderWhenOverheadUnchanged) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); auto new_config = helper.config(); // CallEncoder will be called on overhead change. EXPECT_CALL(*helper.channel_send(), CallEncoder); const size_t transport_overhead_per_packet_bytes = 333; send_stream->SetTransportOverhead(transport_overhead_per_packet_bytes); // Set the same overhead again, CallEncoder should not be called again. EXPECT_CALL(*helper.channel_send(), CallEncoder).Times(0); send_stream->SetTransportOverhead(transport_overhead_per_packet_bytes); // New overhead, call CallEncoder again EXPECT_CALL(*helper.channel_send(), CallEncoder); send_stream->SetTransportOverhead(transport_overhead_per_packet_bytes + 1); } } TEST(AudioSendStreamTest, AudioOverheadChanged) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); const size_t audio_overhead_per_packet_bytes = 555; EXPECT_CALL(*helper.rtp_rtcp(), ExpectedPerPacketOverhead) .WillRepeatedly(Return(audio_overhead_per_packet_bytes)); auto send_stream = helper.CreateAudioSendStream(); auto new_config = helper.config(); BitrateAllocationUpdate update; update.target_bitrate = DataRate::BitsPerSec(helper.config().max_bitrate_bps) + kMaxOverheadRate; EXPECT_CALL(*helper.channel_send(), OnBitrateAllocation); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); EXPECT_EQ(audio_overhead_per_packet_bytes, send_stream->TestOnlyGetPerPacketOverheadBytes()); EXPECT_CALL(*helper.rtp_rtcp(), ExpectedPerPacketOverhead) .WillRepeatedly(Return(audio_overhead_per_packet_bytes + 20)); EXPECT_CALL(*helper.channel_send(), OnBitrateAllocation); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); EXPECT_EQ(audio_overhead_per_packet_bytes + 20, send_stream->TestOnlyGetPerPacketOverheadBytes()); } } TEST(AudioSendStreamTest, OnAudioAndTransportOverheadChanged) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); const size_t audio_overhead_per_packet_bytes = 555; EXPECT_CALL(*helper.rtp_rtcp(), ExpectedPerPacketOverhead) .WillRepeatedly(Return(audio_overhead_per_packet_bytes)); auto send_stream = helper.CreateAudioSendStream(); auto new_config = helper.config(); const size_t transport_overhead_per_packet_bytes = 333; send_stream->SetTransportOverhead(transport_overhead_per_packet_bytes); BitrateAllocationUpdate update; update.target_bitrate = DataRate::BitsPerSec(helper.config().max_bitrate_bps) + kMaxOverheadRate; EXPECT_CALL(*helper.channel_send(), OnBitrateAllocation); helper.worker()->RunSynchronous( [&] { send_stream->OnBitrateUpdated(update); }); EXPECT_EQ( transport_overhead_per_packet_bytes + audio_overhead_per_packet_bytes, send_stream->TestOnlyGetPerPacketOverheadBytes()); } } // Validates that reconfiguring the AudioSendStream with a Frame encryptor // correctly reconfigures on the object without crashing. TEST(AudioSendStreamTest, ReconfigureWithFrameEncryptor) { for (bool use_null_audio_processing : {false, true}) { ConfigHelper helper(false, true, use_null_audio_processing); auto send_stream = helper.CreateAudioSendStream(); auto new_config = helper.config(); rtc::scoped_refptr mock_frame_encryptor_0( rtc::make_ref_counted()); new_config.frame_encryptor = mock_frame_encryptor_0; EXPECT_CALL(*helper.channel_send(), SetFrameEncryptor(Ne(nullptr))) .Times(1); send_stream->Reconfigure(new_config, nullptr); // Not updating the frame encryptor shouldn't force it to reconfigure. EXPECT_CALL(*helper.channel_send(), SetFrameEncryptor(_)).Times(0); send_stream->Reconfigure(new_config, nullptr); // Updating frame encryptor to a new object should force a call to the // proxy. rtc::scoped_refptr mock_frame_encryptor_1( rtc::make_ref_counted()); new_config.frame_encryptor = mock_frame_encryptor_1; new_config.crypto_options.sframe.require_frame_encryption = true; EXPECT_CALL(*helper.channel_send(), SetFrameEncryptor(Ne(nullptr))) .Times(1); send_stream->Reconfigure(new_config, nullptr); } } } // namespace test } // namespace webrtc