modules/audio_coding/neteq/neteq_stereo_unittest.cc - src - Git at Google

 /*
  *  Copyright (c) 2013 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.
  */

 // Test to verify correct stereo and multi-channel operation.

 #include <algorithm>
 #include <list>
 #include <memory>
 #include <string>

 #include "api/audio/audio_frame.h"
 #include "api/audio_codecs/builtin_audio_decoder_factory.h"
 #include "api/neteq/neteq.h"
 #include "modules/audio_coding/codecs/pcm16b/pcm16b.h"
 #include "modules/audio_coding/neteq/default_neteq_factory.h"
 #include "modules/audio_coding/neteq/tools/input_audio_file.h"
 #include "modules/audio_coding/neteq/tools/rtp_generator.h"
 #include "rtc_base/strings/string_builder.h"
 #include "system_wrappers/include/clock.h"
 #include "test/gtest.h"
 #include "test/testsupport/file_utils.h"

 namespace webrtc {

 struct TestParameters {
   int frame_size;
   int sample_rate;
   size_t num_channels;
 };

 // This is a parameterized test. The test parameters are supplied through a
 // TestParameters struct, which is obtained through the GetParam() method.
 //
 // The objective of the test is to create a mono input signal and a
 // multi-channel input signal, where each channel is identical to the mono
 // input channel. The two input signals are processed through their respective
 // NetEq instances. After that, the output signals are compared. The expected
 // result is that each channel in the multi-channel output is identical to the
 // mono output.
 class NetEqStereoTest : public ::testing::TestWithParam<TestParameters> {
  protected:
   static const int kTimeStepMs = 10;
   static const size_t kMaxBlockSize = 480;  // 10 ms @ 48 kHz.
   static const uint8_t kPayloadTypeMono = 95;
   static const uint8_t kPayloadTypeMulti = 96;

   NetEqStereoTest()
       : num_channels_(GetParam().num_channels),
         sample_rate_hz_(GetParam().sample_rate),
         samples_per_ms_(sample_rate_hz_ / 1000),
         frame_size_ms_(GetParam().frame_size),
         frame_size_samples_(
             static_cast<size_t>(frame_size_ms_ * samples_per_ms_)),
         output_size_samples_(10 * samples_per_ms_),
         clock_(0),
         rtp_generator_mono_(samples_per_ms_),
         rtp_generator_(samples_per_ms_),
         payload_size_bytes_(0),
         multi_payload_size_bytes_(0),
         last_send_time_(0),
         last_arrival_time_(0) {
     NetEq::Config config;
     config.sample_rate_hz = sample_rate_hz_;
     DefaultNetEqFactory neteq_factory;
     auto decoder_factory = CreateBuiltinAudioDecoderFactory();
     neteq_mono_ = neteq_factory.CreateNetEq(config, decoder_factory, &clock_);
     neteq_ = neteq_factory.CreateNetEq(config, decoder_factory, &clock_);
     input_ = new int16_t[frame_size_samples_];
     encoded_ = new uint8_t[2 * frame_size_samples_];
     input_multi_channel_ = new int16_t[frame_size_samples_ * num_channels_];
     encoded_multi_channel_ =
         new uint8_t[frame_size_samples_ * 2 * num_channels_];
   }

   ~NetEqStereoTest() {
     delete[] input_;
     delete[] encoded_;
     delete[] input_multi_channel_;
     delete[] encoded_multi_channel_;
   }

   virtual void SetUp() {
     const std::string file_name =
         webrtc::test::ResourcePath("audio_coding/testfile32kHz", "pcm");
     input_file_.reset(new test::InputAudioFile(file_name));
     RTC_CHECK_GE(num_channels_, 2);
     ASSERT_TRUE(neteq_mono_->RegisterPayloadType(
         kPayloadTypeMono, SdpAudioFormat("l16", sample_rate_hz_, 1)));
     ASSERT_TRUE(neteq_->RegisterPayloadType(
         kPayloadTypeMulti,
         SdpAudioFormat("l16", sample_rate_hz_, num_channels_)));
   }

   virtual void TearDown() {}

   int GetNewPackets() {
     if (!input_file_->Read(frame_size_samples_, input_)) {
       return -1;
     }
     payload_size_bytes_ =
         WebRtcPcm16b_Encode(input_, frame_size_samples_, encoded_);
     if (frame_size_samples_ * 2 != payload_size_bytes_) {
       return -1;
     }
     int next_send_time = rtp_generator_mono_.GetRtpHeader(
         kPayloadTypeMono, frame_size_samples_, &rtp_header_mono_);
     MakeMultiChannelInput();
     multi_payload_size_bytes_ = WebRtcPcm16b_Encode(
         input_multi_channel_, frame_size_samples_ * num_channels_,
         encoded_multi_channel_);
     if (frame_size_samples_ * 2 * num_channels_ != multi_payload_size_bytes_) {
       return -1;
     }
     rtp_generator_.GetRtpHeader(kPayloadTypeMulti, frame_size_samples_,
                                 &rtp_header_);
     return next_send_time;
   }

   virtual void MakeMultiChannelInput() {
     test::InputAudioFile::DuplicateInterleaved(
         input_, frame_size_samples_, num_channels_, input_multi_channel_);
   }

   virtual void VerifyOutput(size_t num_samples) {
     const int16_t* output_data = output_.data();
     const int16_t* output_multi_channel_data = output_multi_channel_.data();
     for (size_t i = 0; i < num_samples; ++i) {
       for (size_t j = 0; j < num_channels_; ++j) {
         ASSERT_EQ(output_data[i],
                   output_multi_channel_data[i * num_channels_ + j])
             << "Diff in sample " << i << ", channel " << j << ".";
       }
     }
   }

   virtual int GetArrivalTime(int send_time) {
     int arrival_time = last_arrival_time_ + (send_time - last_send_time_);
     last_send_time_ = send_time;
     last_arrival_time_ = arrival_time;
     return arrival_time;
   }

   virtual bool Lost() { return false; }

   void RunTest(int num_loops) {
     // Get next input packets (mono and multi-channel).
     int next_send_time;
     int next_arrival_time;
     do {
       next_send_time = GetNewPackets();
       ASSERT_NE(-1, next_send_time);
       next_arrival_time = GetArrivalTime(next_send_time);
     } while (Lost());  // If lost, immediately read the next packet.

     int time_now = 0;
     for (int k = 0; k < num_loops; ++k) {
       while (time_now >= next_arrival_time) {
         // Insert packet in mono instance.
         ASSERT_EQ(NetEq::kOK,
                   neteq_mono_->InsertPacket(
                       rtp_header_mono_, rtc::ArrayView<const uint8_t>(
                                             encoded_, payload_size_bytes_)));
         // Insert packet in multi-channel instance.
         ASSERT_EQ(NetEq::kOK, neteq_->InsertPacket(
                                   rtp_header_, rtc::ArrayView<const uint8_t>(
                                                    encoded_multi_channel_,
                                                    multi_payload_size_bytes_)));
         // Get next input packets (mono and multi-channel).
         do {
           next_send_time = GetNewPackets();
           ASSERT_NE(-1, next_send_time);
           next_arrival_time = GetArrivalTime(next_send_time);
         } while (Lost());  // If lost, immediately read the next packet.
       }
       // Get audio from mono instance.
       bool muted;
       EXPECT_EQ(NetEq::kOK, neteq_mono_->GetAudio(&output_, &muted));
       ASSERT_FALSE(muted);
       EXPECT_EQ(1u, output_.num_channels_);
       EXPECT_EQ(output_size_samples_, output_.samples_per_channel_);
       // Get audio from multi-channel instance.
       ASSERT_EQ(NetEq::kOK, neteq_->GetAudio(&output_multi_channel_, &muted));
       ASSERT_FALSE(muted);
       EXPECT_EQ(num_channels_, output_multi_channel_.num_channels_);
       EXPECT_EQ(output_size_samples_,
                 output_multi_channel_.samples_per_channel_);
       rtc::StringBuilder ss;
       ss << "Lap number " << k << ".";
       SCOPED_TRACE(ss.str());  // Print out the parameter values on failure.
       // Compare mono and multi-channel.
       ASSERT_NO_FATAL_FAILURE(VerifyOutput(output_size_samples_));

       time_now += kTimeStepMs;
       clock_.AdvanceTimeMilliseconds(kTimeStepMs);
     }
   }

   const size_t num_channels_;
   const int sample_rate_hz_;
   const int samples_per_ms_;
   const int frame_size_ms_;
   const size_t frame_size_samples_;
   const size_t output_size_samples_;
   SimulatedClock clock_;
   std::unique_ptr<NetEq> neteq_mono_;
   std::unique_ptr<NetEq> neteq_;
   test::RtpGenerator rtp_generator_mono_;
   test::RtpGenerator rtp_generator_;
   int16_t* input_;
   int16_t* input_multi_channel_;
   uint8_t* encoded_;
   uint8_t* encoded_multi_channel_;
   AudioFrame output_;
   AudioFrame output_multi_channel_;
   RTPHeader rtp_header_mono_;
   RTPHeader rtp_header_;
   size_t payload_size_bytes_;
   size_t multi_payload_size_bytes_;
   int last_send_time_;
   int last_arrival_time_;
   std::unique_ptr<test::InputAudioFile> input_file_;
 };

 class NetEqStereoTestNoJitter : public NetEqStereoTest {
  protected:
   NetEqStereoTestNoJitter() : NetEqStereoTest() {
     // Start the sender 100 ms before the receiver to pre-fill the buffer.
     // This is to avoid doing preemptive expand early in the test.
     // TODO(hlundin): Mock the decision making instead to control the modes.
     last_arrival_time_ = -100;
   }
 };

 TEST_P(NetEqStereoTestNoJitter, RunTest) {
   RunTest(8);
 }

 class NetEqStereoTestPositiveDrift : public NetEqStereoTest {
  protected:
   NetEqStereoTestPositiveDrift() : NetEqStereoTest(), drift_factor(0.9) {
     // Start the sender 100 ms before the receiver to pre-fill the buffer.
     // This is to avoid doing preemptive expand early in the test.
     // TODO(hlundin): Mock the decision making instead to control the modes.
     last_arrival_time_ = -100;
   }
   virtual int GetArrivalTime(int send_time) {
     int arrival_time =
         last_arrival_time_ + drift_factor * (send_time - last_send_time_);
     last_send_time_ = send_time;
     last_arrival_time_ = arrival_time;
     return arrival_time;
   }

   double drift_factor;
 };

 TEST_P(NetEqStereoTestPositiveDrift, RunTest) {
   RunTest(100);
 }

 class NetEqStereoTestNegativeDrift : public NetEqStereoTestPositiveDrift {
  protected:
   NetEqStereoTestNegativeDrift() : NetEqStereoTestPositiveDrift() {
     drift_factor = 1.1;
     last_arrival_time_ = 0;
   }
 };

 TEST_P(NetEqStereoTestNegativeDrift, RunTest) {
   RunTest(100);
 }

 class NetEqStereoTestDelays : public NetEqStereoTest {
  protected:
   static const int kDelayInterval = 10;
   static const int kDelay = 1000;
   NetEqStereoTestDelays() : NetEqStereoTest(), frame_index_(0) {}

   virtual int GetArrivalTime(int send_time) {
     // Deliver immediately, unless we have a back-log.
     int arrival_time = std::min(last_arrival_time_, send_time);
     if (++frame_index_ % kDelayInterval == 0) {
       // Delay this packet.
       arrival_time += kDelay;
     }
     last_send_time_ = send_time;
     last_arrival_time_ = arrival_time;
     return arrival_time;
   }

   int frame_index_;
 };

 TEST_P(NetEqStereoTestDelays, RunTest) {
   RunTest(1000);
 }

 class NetEqStereoTestLosses : public NetEqStereoTest {
  protected:
   static const int kLossInterval = 10;
   NetEqStereoTestLosses() : NetEqStereoTest(), frame_index_(0) {}

   virtual bool Lost() { return (++frame_index_) % kLossInterval == 0; }

   // TODO(hlundin): NetEq is not giving bitexact results for these cases.
   virtual void VerifyOutput(size_t num_samples) {
     for (size_t i = 0; i < num_samples; ++i) {
       const int16_t* output_data = output_.data();
       const int16_t* output_multi_channel_data = output_multi_channel_.data();
       auto first_channel_sample = output_multi_channel_data[i * num_channels_];
       for (size_t j = 0; j < num_channels_; ++j) {
         const int kErrorMargin = 200;
         EXPECT_NEAR(output_data[i],
                     output_multi_channel_data[i * num_channels_ + j],
                     kErrorMargin)
             << "Diff in sample " << i << ", channel " << j << ".";
         EXPECT_EQ(first_channel_sample,
                   output_multi_channel_data[i * num_channels_ + j]);
       }
     }
   }

   int frame_index_;
 };

 TEST_P(NetEqStereoTestLosses, RunTest) {
   RunTest(100);
 }

 class NetEqStereoTestSingleActiveChannelPlc : public NetEqStereoTestLosses {
  protected:
   NetEqStereoTestSingleActiveChannelPlc() : NetEqStereoTestLosses() {}

   virtual void MakeMultiChannelInput() override {
     // Create a multi-channel input by copying the mono channel from file to the
     // first channel, and setting the others to zero.
     memset(input_multi_channel_, 0,
            frame_size_samples_ * num_channels_ * sizeof(int16_t));
     for (size_t i = 0; i < frame_size_samples_; ++i) {
       input_multi_channel_[i * num_channels_] = input_[i];
     }
   }

   virtual void VerifyOutput(size_t num_samples) override {
     // Simply verify that all samples in channels other than the first are zero.
     const int16_t* output_multi_channel_data = output_multi_channel_.data();
     for (size_t i = 0; i < num_samples; ++i) {
       for (size_t j = 1; j < num_channels_; ++j) {
         EXPECT_EQ(0, output_multi_channel_data[i * num_channels_ + j])
             << "Sample " << i << ", channel " << j << " is non-zero.";
       }
     }
   }
 };

 TEST_P(NetEqStereoTestSingleActiveChannelPlc, RunTest) {
   RunTest(100);
 }

 // Creates a list of parameter sets.
 std::list<TestParameters> GetTestParameters() {
   std::list<TestParameters> l;
   const int sample_rates[] = {8000, 16000, 32000};
   const int num_rates = sizeof(sample_rates) / sizeof(sample_rates[0]);
   // Loop through sample rates.
   for (int rate_index = 0; rate_index < num_rates; ++rate_index) {
     int sample_rate = sample_rates[rate_index];
     // Loop through all frame sizes between 10 and 60 ms.
     for (int frame_size = 10; frame_size <= 60; frame_size += 10) {
       TestParameters p;
       p.frame_size = frame_size;
       p.sample_rate = sample_rate;
       p.num_channels = 2;
       l.push_back(p);
       if (sample_rate == 8000) {
         // Add a five-channel test for 8000 Hz.
         p.num_channels = 5;
         l.push_back(p);
       }
     }
   }
   return l;
 }

 // Pretty-printing the test parameters in case of an error.
 void PrintTo(const TestParameters& p, ::std::ostream* os) {
   *os << "{frame_size = " << p.frame_size
       << ", num_channels = " << p.num_channels
       << ", sample_rate = " << p.sample_rate << "}";
 }

 // Instantiate the tests. Each test is instantiated using the function above,
 // so that all different parameter combinations are tested.
 INSTANTIATE_TEST_SUITE_P(MultiChannel,
                          NetEqStereoTestNoJitter,
                          ::testing::ValuesIn(GetTestParameters()));

 INSTANTIATE_TEST_SUITE_P(MultiChannel,
                          NetEqStereoTestPositiveDrift,
                          ::testing::ValuesIn(GetTestParameters()));

 INSTANTIATE_TEST_SUITE_P(MultiChannel,
                          NetEqStereoTestNegativeDrift,
                          ::testing::ValuesIn(GetTestParameters()));

 INSTANTIATE_TEST_SUITE_P(MultiChannel,
                          NetEqStereoTestDelays,
                          ::testing::ValuesIn(GetTestParameters()));

 INSTANTIATE_TEST_SUITE_P(MultiChannel,
                          NetEqStereoTestLosses,
                          ::testing::ValuesIn(GetTestParameters()));

 INSTANTIATE_TEST_SUITE_P(MultiChannel,
                          NetEqStereoTestSingleActiveChannelPlc,
                          ::testing::ValuesIn(GetTestParameters()));
 }  // namespace webrtc
	/*
	* Copyright (c) 2013 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.
	*/

	// Test to verify correct stereo and multi-channel operation.

	#include <algorithm>
	#include <list>
	#include <memory>
	#include <string>

	#include "api/audio/audio_frame.h"
	#include "api/audio_codecs/builtin_audio_decoder_factory.h"
	#include "api/neteq/neteq.h"
	#include "modules/audio_coding/codecs/pcm16b/pcm16b.h"
	#include "modules/audio_coding/neteq/default_neteq_factory.h"
	#include "modules/audio_coding/neteq/tools/input_audio_file.h"
	#include "modules/audio_coding/neteq/tools/rtp_generator.h"
	#include "rtc_base/strings/string_builder.h"
	#include "system_wrappers/include/clock.h"
	#include "test/gtest.h"
	#include "test/testsupport/file_utils.h"

	namespace webrtc {

	struct TestParameters {
	int frame_size;
	int sample_rate;
	size_t num_channels;
	};

	// This is a parameterized test. The test parameters are supplied through a
	// TestParameters struct, which is obtained through the GetParam() method.
	//
	// The objective of the test is to create a mono input signal and a
	// multi-channel input signal, where each channel is identical to the mono
	// input channel. The two input signals are processed through their respective
	// NetEq instances. After that, the output signals are compared. The expected
	// result is that each channel in the multi-channel output is identical to the
	// mono output.
	class NetEqStereoTest : public ::testing::TestWithParam<TestParameters> {
	protected:
	static const int kTimeStepMs = 10;
	static const size_t kMaxBlockSize = 480; // 10 ms @ 48 kHz.
	static const uint8_t kPayloadTypeMono = 95;
	static const uint8_t kPayloadTypeMulti = 96;

	NetEqStereoTest()
	: num_channels_(GetParam().num_channels),
	sample_rate_hz_(GetParam().sample_rate),
	samples_per_ms_(sample_rate_hz_ / 1000),
	frame_size_ms_(GetParam().frame_size),
	frame_size_samples_(
	static_cast<size_t>(frame_size_ms_ * samples_per_ms_)),
	output_size_samples_(10 * samples_per_ms_),
	clock_(0),
	rtp_generator_mono_(samples_per_ms_),
	rtp_generator_(samples_per_ms_),
	payload_size_bytes_(0),
	multi_payload_size_bytes_(0),
	last_send_time_(0),
	last_arrival_time_(0) {
	NetEq::Config config;
	config.sample_rate_hz = sample_rate_hz_;
	DefaultNetEqFactory neteq_factory;
	auto decoder_factory = CreateBuiltinAudioDecoderFactory();
	neteq_mono_ = neteq_factory.CreateNetEq(config, decoder_factory, &clock_);
	neteq_ = neteq_factory.CreateNetEq(config, decoder_factory, &clock_);
	input_ = new int16_t[frame_size_samples_];
	encoded_ = new uint8_t[2 * frame_size_samples_];
	input_multi_channel_ = new int16_t[frame_size_samples_ * num_channels_];
	encoded_multi_channel_ =
	new uint8_t[frame_size_samples_ * 2 * num_channels_];
	}

	~NetEqStereoTest() {
	delete[] input_;
	delete[] encoded_;
	delete[] input_multi_channel_;
	delete[] encoded_multi_channel_;
	}

	virtual void SetUp() {
	const std::string file_name =
	webrtc::test::ResourcePath("audio_coding/testfile32kHz", "pcm");
	input_file_.reset(new test::InputAudioFile(file_name));
	RTC_CHECK_GE(num_channels_, 2);
	ASSERT_TRUE(neteq_mono_->RegisterPayloadType(
	kPayloadTypeMono, SdpAudioFormat("l16", sample_rate_hz_, 1)));
	ASSERT_TRUE(neteq_->RegisterPayloadType(
	kPayloadTypeMulti,
	SdpAudioFormat("l16", sample_rate_hz_, num_channels_)));
	}

	virtual void TearDown() {}

	int GetNewPackets() {
	if (!input_file_->Read(frame_size_samples_, input_)) {
	return -1;
	}
	payload_size_bytes_ =
	WebRtcPcm16b_Encode(input_, frame_size_samples_, encoded_);
	if (frame_size_samples_ * 2 != payload_size_bytes_) {
	return -1;
	}
	int next_send_time = rtp_generator_mono_.GetRtpHeader(
	kPayloadTypeMono, frame_size_samples_, &rtp_header_mono_);
	MakeMultiChannelInput();
	multi_payload_size_bytes_ = WebRtcPcm16b_Encode(
	input_multi_channel_, frame_size_samples_ * num_channels_,
	encoded_multi_channel_);
	if (frame_size_samples_ * 2 * num_channels_ != multi_payload_size_bytes_) {
	return -1;
	}
	rtp_generator_.GetRtpHeader(kPayloadTypeMulti, frame_size_samples_,
	&rtp_header_);
	return next_send_time;
	}

	virtual void MakeMultiChannelInput() {
	test::InputAudioFile::DuplicateInterleaved(
	input_, frame_size_samples_, num_channels_, input_multi_channel_);
	}

	virtual void VerifyOutput(size_t num_samples) {
	const int16_t* output_data = output_.data();
	const int16_t* output_multi_channel_data = output_multi_channel_.data();
	for (size_t i = 0; i < num_samples; ++i) {
	for (size_t j = 0; j < num_channels_; ++j) {
	ASSERT_EQ(output_data[i],
	output_multi_channel_data[i * num_channels_ + j])
	<< "Diff in sample " << i << ", channel " << j << ".";
	}
	}
	}

	virtual int GetArrivalTime(int send_time) {
	int arrival_time = last_arrival_time_ + (send_time - last_send_time_);
	last_send_time_ = send_time;
	last_arrival_time_ = arrival_time;
	return arrival_time;
	}

	virtual bool Lost() { return false; }

	void RunTest(int num_loops) {
	// Get next input packets (mono and multi-channel).
	int next_send_time;
	int next_arrival_time;
	do {
	next_send_time = GetNewPackets();
	ASSERT_NE(-1, next_send_time);
	next_arrival_time = GetArrivalTime(next_send_time);
	} while (Lost()); // If lost, immediately read the next packet.

	int time_now = 0;
	for (int k = 0; k < num_loops; ++k) {
	while (time_now >= next_arrival_time) {
	// Insert packet in mono instance.
	ASSERT_EQ(NetEq::kOK,
	neteq_mono_->InsertPacket(
	rtp_header_mono_, rtc::ArrayView<const uint8_t>(
	encoded_, payload_size_bytes_)));
	// Insert packet in multi-channel instance.
	ASSERT_EQ(NetEq::kOK, neteq_->InsertPacket(
	rtp_header_, rtc::ArrayView<const uint8_t>(
	encoded_multi_channel_,
	multi_payload_size_bytes_)));
	// Get next input packets (mono and multi-channel).
	do {
	next_send_time = GetNewPackets();
	ASSERT_NE(-1, next_send_time);
	next_arrival_time = GetArrivalTime(next_send_time);
	} while (Lost()); // If lost, immediately read the next packet.
	}
	// Get audio from mono instance.
	bool muted;
	EXPECT_EQ(NetEq::kOK, neteq_mono_->GetAudio(&output_, &muted));
	ASSERT_FALSE(muted);
	EXPECT_EQ(1u, output_.num_channels_);
	EXPECT_EQ(output_size_samples_, output_.samples_per_channel_);
	// Get audio from multi-channel instance.
	ASSERT_EQ(NetEq::kOK, neteq_->GetAudio(&output_multi_channel_, &muted));
	ASSERT_FALSE(muted);
	EXPECT_EQ(num_channels_, output_multi_channel_.num_channels_);
	EXPECT_EQ(output_size_samples_,
	output_multi_channel_.samples_per_channel_);
	rtc::StringBuilder ss;
	ss << "Lap number " << k << ".";
	SCOPED_TRACE(ss.str()); // Print out the parameter values on failure.
	// Compare mono and multi-channel.
	ASSERT_NO_FATAL_FAILURE(VerifyOutput(output_size_samples_));

	time_now += kTimeStepMs;
	clock_.AdvanceTimeMilliseconds(kTimeStepMs);
	}
	}

	const size_t num_channels_;
	const int sample_rate_hz_;
	const int samples_per_ms_;
	const int frame_size_ms_;
	const size_t frame_size_samples_;
	const size_t output_size_samples_;
	SimulatedClock clock_;
	std::unique_ptr<NetEq> neteq_mono_;
	std::unique_ptr<NetEq> neteq_;
	test::RtpGenerator rtp_generator_mono_;
	test::RtpGenerator rtp_generator_;
	int16_t* input_;
	int16_t* input_multi_channel_;
	uint8_t* encoded_;
	uint8_t* encoded_multi_channel_;
	AudioFrame output_;
	AudioFrame output_multi_channel_;
	RTPHeader rtp_header_mono_;
	RTPHeader rtp_header_;
	size_t payload_size_bytes_;
	size_t multi_payload_size_bytes_;
	int last_send_time_;
	int last_arrival_time_;
	std::unique_ptr<test::InputAudioFile> input_file_;
	};

	class NetEqStereoTestNoJitter : public NetEqStereoTest {
	protected:
	NetEqStereoTestNoJitter() : NetEqStereoTest() {
	// Start the sender 100 ms before the receiver to pre-fill the buffer.
	// This is to avoid doing preemptive expand early in the test.
	// TODO(hlundin): Mock the decision making instead to control the modes.
	last_arrival_time_ = -100;
	}
	};

	TEST_P(NetEqStereoTestNoJitter, RunTest) {
	RunTest(8);
	}

	class NetEqStereoTestPositiveDrift : public NetEqStereoTest {
	protected:
	NetEqStereoTestPositiveDrift() : NetEqStereoTest(), drift_factor(0.9) {
	// Start the sender 100 ms before the receiver to pre-fill the buffer.
	// This is to avoid doing preemptive expand early in the test.
	// TODO(hlundin): Mock the decision making instead to control the modes.
	last_arrival_time_ = -100;
	}
	virtual int GetArrivalTime(int send_time) {
	int arrival_time =
	last_arrival_time_ + drift_factor * (send_time - last_send_time_);
	last_send_time_ = send_time;
	last_arrival_time_ = arrival_time;
	return arrival_time;
	}

	double drift_factor;
	};

	TEST_P(NetEqStereoTestPositiveDrift, RunTest) {
	RunTest(100);
	}

	class NetEqStereoTestNegativeDrift : public NetEqStereoTestPositiveDrift {
	protected:
	NetEqStereoTestNegativeDrift() : NetEqStereoTestPositiveDrift() {
	drift_factor = 1.1;
	last_arrival_time_ = 0;
	}
	};

	TEST_P(NetEqStereoTestNegativeDrift, RunTest) {
	RunTest(100);
	}

	class NetEqStereoTestDelays : public NetEqStereoTest {
	protected:
	static const int kDelayInterval = 10;
	static const int kDelay = 1000;
	NetEqStereoTestDelays() : NetEqStereoTest(), frame_index_(0) {}

	virtual int GetArrivalTime(int send_time) {
	// Deliver immediately, unless we have a back-log.
	int arrival_time = std::min(last_arrival_time_, send_time);
	if (++frame_index_ % kDelayInterval == 0) {
	// Delay this packet.
	arrival_time += kDelay;
	}
	last_send_time_ = send_time;
	last_arrival_time_ = arrival_time;
	return arrival_time;
	}

	int frame_index_;
	};

	TEST_P(NetEqStereoTestDelays, RunTest) {
	RunTest(1000);
	}

	class NetEqStereoTestLosses : public NetEqStereoTest {
	protected:
	static const int kLossInterval = 10;
	NetEqStereoTestLosses() : NetEqStereoTest(), frame_index_(0) {}

	virtual bool Lost() { return (++frame_index_) % kLossInterval == 0; }

	// TODO(hlundin): NetEq is not giving bitexact results for these cases.
	virtual void VerifyOutput(size_t num_samples) {
	for (size_t i = 0; i < num_samples; ++i) {
	const int16_t* output_data = output_.data();
	const int16_t* output_multi_channel_data = output_multi_channel_.data();
	auto first_channel_sample = output_multi_channel_data[i * num_channels_];
	for (size_t j = 0; j < num_channels_; ++j) {
	const int kErrorMargin = 200;
	EXPECT_NEAR(output_data[i],
	output_multi_channel_data[i * num_channels_ + j],
	kErrorMargin)
	<< "Diff in sample " << i << ", channel " << j << ".";
	EXPECT_EQ(first_channel_sample,
	output_multi_channel_data[i * num_channels_ + j]);
	}
	}
	}

	int frame_index_;
	};

	TEST_P(NetEqStereoTestLosses, RunTest) {
	RunTest(100);
	}

	class NetEqStereoTestSingleActiveChannelPlc : public NetEqStereoTestLosses {
	protected:
	NetEqStereoTestSingleActiveChannelPlc() : NetEqStereoTestLosses() {}

	virtual void MakeMultiChannelInput() override {
	// Create a multi-channel input by copying the mono channel from file to the
	// first channel, and setting the others to zero.
	memset(input_multi_channel_, 0,
	frame_size_samples_ * num_channels_ * sizeof(int16_t));
	for (size_t i = 0; i < frame_size_samples_; ++i) {
	input_multi_channel_[i * num_channels_] = input_[i];
	}
	}

	virtual void VerifyOutput(size_t num_samples) override {
	// Simply verify that all samples in channels other than the first are zero.
	const int16_t* output_multi_channel_data = output_multi_channel_.data();
	for (size_t i = 0; i < num_samples; ++i) {
	for (size_t j = 1; j < num_channels_; ++j) {
	EXPECT_EQ(0, output_multi_channel_data[i * num_channels_ + j])
	<< "Sample " << i << ", channel " << j << " is non-zero.";
	}
	}
	}
	};

	TEST_P(NetEqStereoTestSingleActiveChannelPlc, RunTest) {
	RunTest(100);
	}

	// Creates a list of parameter sets.
	std::list<TestParameters> GetTestParameters() {
	std::list<TestParameters> l;
	const int sample_rates[] = {8000, 16000, 32000};
	const int num_rates = sizeof(sample_rates) / sizeof(sample_rates[0]);
	// Loop through sample rates.
	for (int rate_index = 0; rate_index < num_rates; ++rate_index) {
	int sample_rate = sample_rates[rate_index];
	// Loop through all frame sizes between 10 and 60 ms.
	for (int frame_size = 10; frame_size <= 60; frame_size += 10) {
	TestParameters p;
	p.frame_size = frame_size;
	p.sample_rate = sample_rate;
	p.num_channels = 2;
	l.push_back(p);
	if (sample_rate == 8000) {
	// Add a five-channel test for 8000 Hz.
	p.num_channels = 5;
	l.push_back(p);
	}
	}
	}
	return l;
	}

	// Pretty-printing the test parameters in case of an error.
	void PrintTo(const TestParameters& p, ::std::ostream* os) {
	*os << "{frame_size = " << p.frame_size
	<< ", num_channels = " << p.num_channels
	<< ", sample_rate = " << p.sample_rate << "}";
	}

	// Instantiate the tests. Each test is instantiated using the function above,
	// so that all different parameter combinations are tested.
	INSTANTIATE_TEST_SUITE_P(MultiChannel,
	NetEqStereoTestNoJitter,
	::testing::ValuesIn(GetTestParameters()));

	INSTANTIATE_TEST_SUITE_P(MultiChannel,
	NetEqStereoTestPositiveDrift,
	::testing::ValuesIn(GetTestParameters()));

	INSTANTIATE_TEST_SUITE_P(MultiChannel,
	NetEqStereoTestNegativeDrift,
	::testing::ValuesIn(GetTestParameters()));

	INSTANTIATE_TEST_SUITE_P(MultiChannel,
	NetEqStereoTestDelays,
	::testing::ValuesIn(GetTestParameters()));

	INSTANTIATE_TEST_SUITE_P(MultiChannel,
	NetEqStereoTestLosses,
	::testing::ValuesIn(GetTestParameters()));

	INSTANTIATE_TEST_SUITE_P(MultiChannel,
	NetEqStereoTestSingleActiveChannelPlc,
	::testing::ValuesIn(GetTestParameters()));
	} // namespace webrtc