audio/voip/test/audio_channel_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2020 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/voip/audio_channel.h"
 #include "api/audio_codecs/builtin_audio_decoder_factory.h"
 #include "api/audio_codecs/builtin_audio_encoder_factory.h"
 #include "api/call/transport.h"
 #include "api/task_queue/task_queue_factory.h"
 #include "audio/voip/test/mock_task_queue.h"
 #include "modules/audio_mixer/audio_mixer_impl.h"
 #include "modules/audio_mixer/sine_wave_generator.h"
 #include "modules/rtp_rtcp/source/rtp_packet_received.h"
 #include "rtc_base/logging.h"
 #include "test/gmock.h"
 #include "test/gtest.h"
 #include "test/mock_transport.h"

 namespace webrtc {
 namespace {

 using ::testing::Invoke;
 using ::testing::NiceMock;
 using ::testing::Return;
 using ::testing::Unused;

 constexpr uint64_t kStartTime = 123456789;
 constexpr uint32_t kLocalSsrc = 0xdeadc0de;
 constexpr int16_t kAudioLevel = 3004;  // used for sine wave level
 constexpr int kPcmuPayload = 0;

 class AudioChannelTest : public ::testing::Test {
  public:
   const SdpAudioFormat kPcmuFormat = {"pcmu", 8000, 1};

   AudioChannelTest()
       : fake_clock_(kStartTime), wave_generator_(1000.0, kAudioLevel) {
     task_queue_factory_ = std::make_unique<MockTaskQueueFactory>(&task_queue_);
     audio_mixer_ = AudioMixerImpl::Create();
     encoder_factory_ = CreateBuiltinAudioEncoderFactory();
     decoder_factory_ = CreateBuiltinAudioDecoderFactory();

     // By default, run the queued task immediately.
     ON_CALL(task_queue_, PostTask)
         .WillByDefault(
             Invoke([&](std::unique_ptr<QueuedTask> task) { task->Run(); }));
   }

   void SetUp() override { audio_channel_ = CreateAudioChannel(kLocalSsrc); }

   void TearDown() override { audio_channel_ = nullptr; }

   rtc::scoped_refptr<AudioChannel> CreateAudioChannel(uint32_t ssrc) {
     // Use same audio mixer here for simplicity sake as we are not checking
     // audio activity of RTP in our testcases. If we need to do test on audio
     // signal activity then we need to assign audio mixer for each channel.
     // Also this uses the same transport object for different audio channel to
     // simplify network routing logic.
     rtc::scoped_refptr<AudioChannel> audio_channel =
         rtc::make_ref_counted<AudioChannel>(
             &transport_, ssrc, task_queue_factory_.get(), audio_mixer_.get(),
             decoder_factory_);
     audio_channel->SetEncoder(kPcmuPayload, kPcmuFormat,
                               encoder_factory_->MakeAudioEncoder(
                                   kPcmuPayload, kPcmuFormat, absl::nullopt));
     audio_channel->SetReceiveCodecs({{kPcmuPayload, kPcmuFormat}});
     audio_channel->StartSend();
     audio_channel->StartPlay();
     return audio_channel;
   }

   std::unique_ptr<AudioFrame> GetAudioFrame(int order) {
     auto frame = std::make_unique<AudioFrame>();
     frame->sample_rate_hz_ = kPcmuFormat.clockrate_hz;
     frame->samples_per_channel_ = kPcmuFormat.clockrate_hz / 100;  // 10 ms.
     frame->num_channels_ = kPcmuFormat.num_channels;
     frame->timestamp_ = frame->samples_per_channel_ * order;
     wave_generator_.GenerateNextFrame(frame.get());
     return frame;
   }

   SimulatedClock fake_clock_;
   SineWaveGenerator wave_generator_;
   NiceMock<MockTransport> transport_;
   NiceMock<MockTaskQueue> task_queue_;
   std::unique_ptr<TaskQueueFactory> task_queue_factory_;
   rtc::scoped_refptr<AudioMixer> audio_mixer_;
   rtc::scoped_refptr<AudioDecoderFactory> decoder_factory_;
   rtc::scoped_refptr<AudioEncoderFactory> encoder_factory_;
   rtc::scoped_refptr<AudioChannel> audio_channel_;
 };

 // Validate RTP packet generation by feeding audio frames with sine wave.
 // Resulted RTP packet is looped back into AudioChannel and gets decoded into
 // audio frame to see if it has some signal to indicate its validity.
 TEST_F(AudioChannelTest, PlayRtpByLocalLoop) {
   auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
     audio_channel_->ReceivedRTPPacket(
         rtc::ArrayView<const uint8_t>(packet, length));
     return true;
   };
   EXPECT_CALL(transport_, SendRtp).WillOnce(Invoke(loop_rtp));

   auto audio_sender = audio_channel_->GetAudioSender();
   audio_sender->SendAudioData(GetAudioFrame(0));
   audio_sender->SendAudioData(GetAudioFrame(1));

   AudioFrame empty_frame, audio_frame;
   empty_frame.Mute();
   empty_frame.mutable_data();  // This will zero out the data.
   audio_frame.CopyFrom(empty_frame);
   audio_mixer_->Mix(/*number_of_channels*/ 1, &audio_frame);

   // We expect now audio frame to pick up something.
   EXPECT_NE(memcmp(empty_frame.data(), audio_frame.data(),
                    AudioFrame::kMaxDataSizeBytes),
             0);
 }

 // Validate assigned local SSRC is resulted in RTP packet.
 TEST_F(AudioChannelTest, VerifyLocalSsrcAsAssigned) {
   RtpPacketReceived rtp;
   auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
     rtp.Parse(packet, length);
     return true;
   };
   EXPECT_CALL(transport_, SendRtp).WillOnce(Invoke(loop_rtp));

   auto audio_sender = audio_channel_->GetAudioSender();
   audio_sender->SendAudioData(GetAudioFrame(0));
   audio_sender->SendAudioData(GetAudioFrame(1));

   EXPECT_EQ(rtp.Ssrc(), kLocalSsrc);
 }

 // Check metrics after processing an RTP packet.
 TEST_F(AudioChannelTest, TestIngressStatistics) {
   auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
     audio_channel_->ReceivedRTPPacket(
         rtc::ArrayView<const uint8_t>(packet, length));
     return true;
   };
   EXPECT_CALL(transport_, SendRtp).WillRepeatedly(Invoke(loop_rtp));

   auto audio_sender = audio_channel_->GetAudioSender();
   audio_sender->SendAudioData(GetAudioFrame(0));
   audio_sender->SendAudioData(GetAudioFrame(1));

   AudioFrame audio_frame;
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);

   absl::optional<IngressStatistics> ingress_stats =
       audio_channel_->GetIngressStatistics();
   EXPECT_TRUE(ingress_stats);
   EXPECT_EQ(ingress_stats->neteq_stats.total_samples_received, 160ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.concealed_samples, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.concealment_events, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.inserted_samples_for_deceleration, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.removed_samples_for_acceleration, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.silent_concealed_samples, 0ULL);
   // To extract the jitter buffer length in millisecond, jitter_buffer_delay_ms
   // needs to be divided by jitter_buffer_emitted_count (number of samples).
   EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_delay_ms, 1600ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_emitted_count, 160ULL);
   EXPECT_GT(ingress_stats->neteq_stats.jitter_buffer_target_delay_ms, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.interruption_count, 0);
   EXPECT_EQ(ingress_stats->neteq_stats.total_interruption_duration_ms, 0);
   EXPECT_DOUBLE_EQ(ingress_stats->total_duration, 0.02);

   // Now without any RTP pending in jitter buffer pull more.
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);

   // Send another RTP packet to intentionally break PLC.
   audio_sender->SendAudioData(GetAudioFrame(2));
   audio_sender->SendAudioData(GetAudioFrame(3));

   ingress_stats = audio_channel_->GetIngressStatistics();
   EXPECT_TRUE(ingress_stats);
   EXPECT_EQ(ingress_stats->neteq_stats.total_samples_received, 320ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.concealed_samples, 168ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.concealment_events, 1ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.inserted_samples_for_deceleration, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.removed_samples_for_acceleration, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.silent_concealed_samples, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_delay_ms, 1600ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_emitted_count, 160ULL);
   EXPECT_GT(ingress_stats->neteq_stats.jitter_buffer_target_delay_ms, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.interruption_count, 0);
   EXPECT_EQ(ingress_stats->neteq_stats.total_interruption_duration_ms, 0);
   EXPECT_DOUBLE_EQ(ingress_stats->total_duration, 0.04);

   // Pull the last RTP packet.
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);

   ingress_stats = audio_channel_->GetIngressStatistics();
   EXPECT_TRUE(ingress_stats);
   EXPECT_EQ(ingress_stats->neteq_stats.total_samples_received, 480ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.concealed_samples, 168ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.concealment_events, 1ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.inserted_samples_for_deceleration, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.removed_samples_for_acceleration, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.silent_concealed_samples, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_delay_ms, 3200ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_emitted_count, 320ULL);
   EXPECT_GT(ingress_stats->neteq_stats.jitter_buffer_target_delay_ms, 0ULL);
   EXPECT_EQ(ingress_stats->neteq_stats.interruption_count, 0);
   EXPECT_EQ(ingress_stats->neteq_stats.total_interruption_duration_ms, 0);
   EXPECT_DOUBLE_EQ(ingress_stats->total_duration, 0.06);
 }

 // Check ChannelStatistics metric after processing RTP and RTCP packets.
 TEST_F(AudioChannelTest, TestChannelStatistics) {
   auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
     audio_channel_->ReceivedRTPPacket(
         rtc::ArrayView<const uint8_t>(packet, length));
     return true;
   };
   auto loop_rtcp = [&](const uint8_t* packet, size_t length) {
     audio_channel_->ReceivedRTCPPacket(
         rtc::ArrayView<const uint8_t>(packet, length));
     return true;
   };
   EXPECT_CALL(transport_, SendRtp).WillRepeatedly(Invoke(loop_rtp));
   EXPECT_CALL(transport_, SendRtcp).WillRepeatedly(Invoke(loop_rtcp));

   // Simulate microphone giving audio frame (10 ms). This will trigger tranport
   // to send RTP as handled in loop_rtp above.
   auto audio_sender = audio_channel_->GetAudioSender();
   audio_sender->SendAudioData(GetAudioFrame(0));
   audio_sender->SendAudioData(GetAudioFrame(1));

   // Simulate speaker requesting audio frame (10 ms). This will trigger VoIP
   // engine to fetch audio samples from RTP packets stored in jitter buffer.
   AudioFrame audio_frame;
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);
   audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);

   // Force sending RTCP SR report in order to have remote_rtcp field available
   // in channel statistics. This will trigger tranport to send RTCP as handled
   // in loop_rtcp above.
   audio_channel_->SendRTCPReportForTesting(kRtcpSr);

   absl::optional<ChannelStatistics> channel_stats =
       audio_channel_->GetChannelStatistics();
   EXPECT_TRUE(channel_stats);

   EXPECT_EQ(channel_stats->packets_sent, 1ULL);
   EXPECT_EQ(channel_stats->bytes_sent, 160ULL);

   EXPECT_EQ(channel_stats->packets_received, 1ULL);
   EXPECT_EQ(channel_stats->bytes_received, 160ULL);
   EXPECT_EQ(channel_stats->jitter, 0);
   EXPECT_EQ(channel_stats->packets_lost, 0);
   EXPECT_EQ(channel_stats->remote_ssrc.value(), kLocalSsrc);

   EXPECT_TRUE(channel_stats->remote_rtcp.has_value());

   EXPECT_EQ(channel_stats->remote_rtcp->jitter, 0);
   EXPECT_EQ(channel_stats->remote_rtcp->packets_lost, 0);
   EXPECT_EQ(channel_stats->remote_rtcp->fraction_lost, 0);
   EXPECT_GT(channel_stats->remote_rtcp->last_report_received_timestamp_ms, 0);
   EXPECT_FALSE(channel_stats->remote_rtcp->round_trip_time.has_value());
 }

 // Check ChannelStatistics RTT metric after processing RTP and RTCP packets
 // using three audio channels where each represents media endpoint.
 //
 //  1) AC1 <- RTP/RTCP -> AC2
 //  2) AC1 <- RTP/RTCP -> AC3
 //
 // During step 1), AC1 should be able to check RTT from AC2's SSRC.
 // During step 2), AC1 should be able to check RTT from AC3's SSRC.
 TEST_F(AudioChannelTest, RttIsAvailableAfterChangeOfRemoteSsrc) {
   // Create AC2 and AC3.
   constexpr uint32_t kAc2Ssrc = 0xdeadbeef;
   constexpr uint32_t kAc3Ssrc = 0xdeafbeef;

   auto ac_2 = CreateAudioChannel(kAc2Ssrc);
   auto ac_3 = CreateAudioChannel(kAc3Ssrc);

   auto send_recv_rtp = [&](rtc::scoped_refptr<AudioChannel> rtp_sender,
                            rtc::scoped_refptr<AudioChannel> rtp_receiver) {
     // Setup routing logic via transport_.
     auto route_rtp = [&](const uint8_t* packet, size_t length, Unused) {
       rtp_receiver->ReceivedRTPPacket(rtc::MakeArrayView(packet, length));
       return true;
     };
     ON_CALL(transport_, SendRtp).WillByDefault(route_rtp);

     // This will trigger route_rtp callback via transport_.
     rtp_sender->GetAudioSender()->SendAudioData(GetAudioFrame(0));
     rtp_sender->GetAudioSender()->SendAudioData(GetAudioFrame(1));

     // Process received RTP in receiver.
     AudioFrame audio_frame;
     audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);
     audio_mixer_->Mix(/*number_of_channels=*/1, &audio_frame);

     // Revert to default to avoid using reference in route_rtp lambda.
     ON_CALL(transport_, SendRtp).WillByDefault(Return(true));
   };

   auto send_recv_rtcp = [&](rtc::scoped_refptr<AudioChannel> rtcp_sender,
                             rtc::scoped_refptr<AudioChannel> rtcp_receiver) {
     // Setup routing logic via transport_.
     auto route_rtcp = [&](const uint8_t* packet, size_t length) {
       rtcp_receiver->ReceivedRTCPPacket(rtc::MakeArrayView(packet, length));
       return true;
     };
     ON_CALL(transport_, SendRtcp).WillByDefault(route_rtcp);

     // This will trigger route_rtcp callback via transport_.
     rtcp_sender->SendRTCPReportForTesting(kRtcpSr);

     // Revert to default to avoid using reference in route_rtcp lambda.
     ON_CALL(transport_, SendRtcp).WillByDefault(Return(true));
   };

   // AC1 <-- RTP/RTCP --> AC2
   send_recv_rtp(audio_channel_, ac_2);
   send_recv_rtp(ac_2, audio_channel_);
   send_recv_rtcp(audio_channel_, ac_2);
   send_recv_rtcp(ac_2, audio_channel_);

   absl::optional<ChannelStatistics> channel_stats =
       audio_channel_->GetChannelStatistics();
   ASSERT_TRUE(channel_stats);
   EXPECT_EQ(channel_stats->remote_ssrc, kAc2Ssrc);
   ASSERT_TRUE(channel_stats->remote_rtcp);
   EXPECT_GT(channel_stats->remote_rtcp->round_trip_time, 0.0);

   // AC1 <-- RTP/RTCP --> AC3
   send_recv_rtp(audio_channel_, ac_3);
   send_recv_rtp(ac_3, audio_channel_);
   send_recv_rtcp(audio_channel_, ac_3);
   send_recv_rtcp(ac_3, audio_channel_);

   channel_stats = audio_channel_->GetChannelStatistics();
   ASSERT_TRUE(channel_stats);
   EXPECT_EQ(channel_stats->remote_ssrc, kAc3Ssrc);
   ASSERT_TRUE(channel_stats->remote_rtcp);
   EXPECT_GT(channel_stats->remote_rtcp->round_trip_time, 0.0);
 }

 }  // namespace
 }  // namespace webrtc
	/*
	* Copyright (c) 2020 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/voip/audio_channel.h"
	#include "api/audio_codecs/builtin_audio_decoder_factory.h"
	#include "api/audio_codecs/builtin_audio_encoder_factory.h"
	#include "api/call/transport.h"
	#include "api/task_queue/task_queue_factory.h"
	#include "audio/voip/test/mock_task_queue.h"
	#include "modules/audio_mixer/audio_mixer_impl.h"
	#include "modules/audio_mixer/sine_wave_generator.h"
	#include "modules/rtp_rtcp/source/rtp_packet_received.h"
	#include "rtc_base/logging.h"
	#include "test/gmock.h"
	#include "test/gtest.h"
	#include "test/mock_transport.h"

	namespace webrtc {
	namespace {

	using ::testing::Invoke;
	using ::testing::NiceMock;
	using ::testing::Return;
	using ::testing::Unused;

	constexpr uint64_t kStartTime = 123456789;
	constexpr uint32_t kLocalSsrc = 0xdeadc0de;
	constexpr int16_t kAudioLevel = 3004; // used for sine wave level
	constexpr int kPcmuPayload = 0;

	class AudioChannelTest : public ::testing::Test {
	public:
	const SdpAudioFormat kPcmuFormat = {"pcmu", 8000, 1};

	AudioChannelTest()
	: fake_clock_(kStartTime), wave_generator_(1000.0, kAudioLevel) {
	task_queue_factory_ = std::make_unique<MockTaskQueueFactory>(&task_queue_);
	audio_mixer_ = AudioMixerImpl::Create();
	encoder_factory_ = CreateBuiltinAudioEncoderFactory();
	decoder_factory_ = CreateBuiltinAudioDecoderFactory();

	// By default, run the queued task immediately.
	ON_CALL(task_queue_, PostTask)
	.WillByDefault(
	Invoke([&](std::unique_ptr<QueuedTask> task) { task->Run(); }));
	}

	void SetUp() override { audio_channel_ = CreateAudioChannel(kLocalSsrc); }

	void TearDown() override { audio_channel_ = nullptr; }

	rtc::scoped_refptr<AudioChannel> CreateAudioChannel(uint32_t ssrc) {
	// Use same audio mixer here for simplicity sake as we are not checking
	// audio activity of RTP in our testcases. If we need to do test on audio
	// signal activity then we need to assign audio mixer for each channel.
	// Also this uses the same transport object for different audio channel to
	// simplify network routing logic.
	rtc::scoped_refptr<AudioChannel> audio_channel =
	rtc::make_ref_counted<AudioChannel>(
	&transport_, ssrc, task_queue_factory_.get(), audio_mixer_.get(),
	decoder_factory_);
	audio_channel->SetEncoder(kPcmuPayload, kPcmuFormat,
	encoder_factory_->MakeAudioEncoder(
	kPcmuPayload, kPcmuFormat, absl::nullopt));
	audio_channel->SetReceiveCodecs({{kPcmuPayload, kPcmuFormat}});
	audio_channel->StartSend();
	audio_channel->StartPlay();
	return audio_channel;
	}

	std::unique_ptr<AudioFrame> GetAudioFrame(int order) {
	auto frame = std::make_unique<AudioFrame>();
	frame->sample_rate_hz_ = kPcmuFormat.clockrate_hz;
	frame->samples_per_channel_ = kPcmuFormat.clockrate_hz / 100; // 10 ms.
	frame->num_channels_ = kPcmuFormat.num_channels;
	frame->timestamp_ = frame->samples_per_channel_ * order;
	wave_generator_.GenerateNextFrame(frame.get());
	return frame;
	}

	SimulatedClock fake_clock_;
	SineWaveGenerator wave_generator_;
	NiceMock<MockTransport> transport_;
	NiceMock<MockTaskQueue> task_queue_;
	std::unique_ptr<TaskQueueFactory> task_queue_factory_;
	rtc::scoped_refptr<AudioMixer> audio_mixer_;
	rtc::scoped_refptr<AudioDecoderFactory> decoder_factory_;
	rtc::scoped_refptr<AudioEncoderFactory> encoder_factory_;
	rtc::scoped_refptr<AudioChannel> audio_channel_;
	};

	// Validate RTP packet generation by feeding audio frames with sine wave.
	// Resulted RTP packet is looped back into AudioChannel and gets decoded into
	// audio frame to see if it has some signal to indicate its validity.
	TEST_F(AudioChannelTest, PlayRtpByLocalLoop) {
	auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
	audio_channel_->ReceivedRTPPacket(
	rtc::ArrayView<const uint8_t>(packet, length));
	return true;
	};
	EXPECT_CALL(transport_, SendRtp).WillOnce(Invoke(loop_rtp));

	auto audio_sender = audio_channel_->GetAudioSender();
	audio_sender->SendAudioData(GetAudioFrame(0));
	audio_sender->SendAudioData(GetAudioFrame(1));

	AudioFrame empty_frame, audio_frame;
	empty_frame.Mute();
	empty_frame.mutable_data(); // This will zero out the data.
	audio_frame.CopyFrom(empty_frame);
	audio_mixer_->Mix(/number_of_channels/ 1, &audio_frame);

	// We expect now audio frame to pick up something.
	EXPECT_NE(memcmp(empty_frame.data(), audio_frame.data(),
	AudioFrame::kMaxDataSizeBytes),
	0);
	}

	// Validate assigned local SSRC is resulted in RTP packet.
	TEST_F(AudioChannelTest, VerifyLocalSsrcAsAssigned) {
	RtpPacketReceived rtp;
	auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
	rtp.Parse(packet, length);
	return true;
	};
	EXPECT_CALL(transport_, SendRtp).WillOnce(Invoke(loop_rtp));

	auto audio_sender = audio_channel_->GetAudioSender();
	audio_sender->SendAudioData(GetAudioFrame(0));
	audio_sender->SendAudioData(GetAudioFrame(1));

	EXPECT_EQ(rtp.Ssrc(), kLocalSsrc);
	}

	// Check metrics after processing an RTP packet.
	TEST_F(AudioChannelTest, TestIngressStatistics) {
	auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
	audio_channel_->ReceivedRTPPacket(
	rtc::ArrayView<const uint8_t>(packet, length));
	return true;
	};
	EXPECT_CALL(transport_, SendRtp).WillRepeatedly(Invoke(loop_rtp));

	auto audio_sender = audio_channel_->GetAudioSender();
	audio_sender->SendAudioData(GetAudioFrame(0));
	audio_sender->SendAudioData(GetAudioFrame(1));

	AudioFrame audio_frame;
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);

	absl::optional<IngressStatistics> ingress_stats =
	audio_channel_->GetIngressStatistics();
	EXPECT_TRUE(ingress_stats);
	EXPECT_EQ(ingress_stats->neteq_stats.total_samples_received, 160ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.concealed_samples, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.concealment_events, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.inserted_samples_for_deceleration, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.removed_samples_for_acceleration, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.silent_concealed_samples, 0ULL);
	// To extract the jitter buffer length in millisecond, jitter_buffer_delay_ms
	// needs to be divided by jitter_buffer_emitted_count (number of samples).
	EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_delay_ms, 1600ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_emitted_count, 160ULL);
	EXPECT_GT(ingress_stats->neteq_stats.jitter_buffer_target_delay_ms, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.interruption_count, 0);
	EXPECT_EQ(ingress_stats->neteq_stats.total_interruption_duration_ms, 0);
	EXPECT_DOUBLE_EQ(ingress_stats->total_duration, 0.02);

	// Now without any RTP pending in jitter buffer pull more.
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);

	// Send another RTP packet to intentionally break PLC.
	audio_sender->SendAudioData(GetAudioFrame(2));
	audio_sender->SendAudioData(GetAudioFrame(3));

	ingress_stats = audio_channel_->GetIngressStatistics();
	EXPECT_TRUE(ingress_stats);
	EXPECT_EQ(ingress_stats->neteq_stats.total_samples_received, 320ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.concealed_samples, 168ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.concealment_events, 1ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.inserted_samples_for_deceleration, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.removed_samples_for_acceleration, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.silent_concealed_samples, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_delay_ms, 1600ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_emitted_count, 160ULL);
	EXPECT_GT(ingress_stats->neteq_stats.jitter_buffer_target_delay_ms, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.interruption_count, 0);
	EXPECT_EQ(ingress_stats->neteq_stats.total_interruption_duration_ms, 0);
	EXPECT_DOUBLE_EQ(ingress_stats->total_duration, 0.04);

	// Pull the last RTP packet.
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);

	ingress_stats = audio_channel_->GetIngressStatistics();
	EXPECT_TRUE(ingress_stats);
	EXPECT_EQ(ingress_stats->neteq_stats.total_samples_received, 480ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.concealed_samples, 168ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.concealment_events, 1ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.inserted_samples_for_deceleration, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.removed_samples_for_acceleration, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.silent_concealed_samples, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_delay_ms, 3200ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.jitter_buffer_emitted_count, 320ULL);
	EXPECT_GT(ingress_stats->neteq_stats.jitter_buffer_target_delay_ms, 0ULL);
	EXPECT_EQ(ingress_stats->neteq_stats.interruption_count, 0);
	EXPECT_EQ(ingress_stats->neteq_stats.total_interruption_duration_ms, 0);
	EXPECT_DOUBLE_EQ(ingress_stats->total_duration, 0.06);
	}

	// Check ChannelStatistics metric after processing RTP and RTCP packets.
	TEST_F(AudioChannelTest, TestChannelStatistics) {
	auto loop_rtp = [&](const uint8_t* packet, size_t length, Unused) {
	audio_channel_->ReceivedRTPPacket(
	rtc::ArrayView<const uint8_t>(packet, length));
	return true;
	};
	auto loop_rtcp = [&](const uint8_t* packet, size_t length) {
	audio_channel_->ReceivedRTCPPacket(
	rtc::ArrayView<const uint8_t>(packet, length));
	return true;
	};
	EXPECT_CALL(transport_, SendRtp).WillRepeatedly(Invoke(loop_rtp));
	EXPECT_CALL(transport_, SendRtcp).WillRepeatedly(Invoke(loop_rtcp));

	// Simulate microphone giving audio frame (10 ms). This will trigger tranport
	// to send RTP as handled in loop_rtp above.
	auto audio_sender = audio_channel_->GetAudioSender();
	audio_sender->SendAudioData(GetAudioFrame(0));
	audio_sender->SendAudioData(GetAudioFrame(1));

	// Simulate speaker requesting audio frame (10 ms). This will trigger VoIP
	// engine to fetch audio samples from RTP packets stored in jitter buffer.
	AudioFrame audio_frame;
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);

	// Force sending RTCP SR report in order to have remote_rtcp field available
	// in channel statistics. This will trigger tranport to send RTCP as handled
	// in loop_rtcp above.
	audio_channel_->SendRTCPReportForTesting(kRtcpSr);

	absl::optional<ChannelStatistics> channel_stats =
	audio_channel_->GetChannelStatistics();
	EXPECT_TRUE(channel_stats);

	EXPECT_EQ(channel_stats->packets_sent, 1ULL);
	EXPECT_EQ(channel_stats->bytes_sent, 160ULL);

	EXPECT_EQ(channel_stats->packets_received, 1ULL);
	EXPECT_EQ(channel_stats->bytes_received, 160ULL);
	EXPECT_EQ(channel_stats->jitter, 0);
	EXPECT_EQ(channel_stats->packets_lost, 0);
	EXPECT_EQ(channel_stats->remote_ssrc.value(), kLocalSsrc);

	EXPECT_TRUE(channel_stats->remote_rtcp.has_value());

	EXPECT_EQ(channel_stats->remote_rtcp->jitter, 0);
	EXPECT_EQ(channel_stats->remote_rtcp->packets_lost, 0);
	EXPECT_EQ(channel_stats->remote_rtcp->fraction_lost, 0);
	EXPECT_GT(channel_stats->remote_rtcp->last_report_received_timestamp_ms, 0);
	EXPECT_FALSE(channel_stats->remote_rtcp->round_trip_time.has_value());
	}

	// Check ChannelStatistics RTT metric after processing RTP and RTCP packets
	// using three audio channels where each represents media endpoint.
	//
	// 1) AC1 <- RTP/RTCP -> AC2
	// 2) AC1 <- RTP/RTCP -> AC3
	//
	// During step 1), AC1 should be able to check RTT from AC2's SSRC.
	// During step 2), AC1 should be able to check RTT from AC3's SSRC.
	TEST_F(AudioChannelTest, RttIsAvailableAfterChangeOfRemoteSsrc) {
	// Create AC2 and AC3.
	constexpr uint32_t kAc2Ssrc = 0xdeadbeef;
	constexpr uint32_t kAc3Ssrc = 0xdeafbeef;

	auto ac_2 = CreateAudioChannel(kAc2Ssrc);
	auto ac_3 = CreateAudioChannel(kAc3Ssrc);

	auto send_recv_rtp = [&](rtc::scoped_refptr<AudioChannel> rtp_sender,
	rtc::scoped_refptr<AudioChannel> rtp_receiver) {
	// Setup routing logic via transport_.
	auto route_rtp = [&](const uint8_t* packet, size_t length, Unused) {
	rtp_receiver->ReceivedRTPPacket(rtc::MakeArrayView(packet, length));
	return true;
	};
	ON_CALL(transport_, SendRtp).WillByDefault(route_rtp);

	// This will trigger route_rtp callback via transport_.
	rtp_sender->GetAudioSender()->SendAudioData(GetAudioFrame(0));
	rtp_sender->GetAudioSender()->SendAudioData(GetAudioFrame(1));

	// Process received RTP in receiver.
	AudioFrame audio_frame;
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);
	audio_mixer_->Mix(/number_of_channels=/1, &audio_frame);

	// Revert to default to avoid using reference in route_rtp lambda.
	ON_CALL(transport_, SendRtp).WillByDefault(Return(true));
	};

	auto send_recv_rtcp = [&](rtc::scoped_refptr<AudioChannel> rtcp_sender,
	rtc::scoped_refptr<AudioChannel> rtcp_receiver) {
	// Setup routing logic via transport_.
	auto route_rtcp = [&](const uint8_t* packet, size_t length) {
	rtcp_receiver->ReceivedRTCPPacket(rtc::MakeArrayView(packet, length));
	return true;
	};
	ON_CALL(transport_, SendRtcp).WillByDefault(route_rtcp);

	// This will trigger route_rtcp callback via transport_.
	rtcp_sender->SendRTCPReportForTesting(kRtcpSr);

	// Revert to default to avoid using reference in route_rtcp lambda.
	ON_CALL(transport_, SendRtcp).WillByDefault(Return(true));
	};

	// AC1 <-- RTP/RTCP --> AC2
	send_recv_rtp(audio_channel_, ac_2);
	send_recv_rtp(ac_2, audio_channel_);
	send_recv_rtcp(audio_channel_, ac_2);
	send_recv_rtcp(ac_2, audio_channel_);

	absl::optional<ChannelStatistics> channel_stats =
	audio_channel_->GetChannelStatistics();
	ASSERT_TRUE(channel_stats);
	EXPECT_EQ(channel_stats->remote_ssrc, kAc2Ssrc);
	ASSERT_TRUE(channel_stats->remote_rtcp);
	EXPECT_GT(channel_stats->remote_rtcp->round_trip_time, 0.0);

	// AC1 <-- RTP/RTCP --> AC3
	send_recv_rtp(audio_channel_, ac_3);
	send_recv_rtp(ac_3, audio_channel_);
	send_recv_rtcp(audio_channel_, ac_3);
	send_recv_rtcp(ac_3, audio_channel_);

	channel_stats = audio_channel_->GetChannelStatistics();
	ASSERT_TRUE(channel_stats);
	EXPECT_EQ(channel_stats->remote_ssrc, kAc3Ssrc);
	ASSERT_TRUE(channel_stats->remote_rtcp);
	EXPECT_GT(channel_stats->remote_rtcp->round_trip_time, 0.0);
	}

	} // namespace
	} // namespace webrtc