modules/audio_coding/codecs/cng/audio_encoder_cng_unittest.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 /*
  *  Copyright (c) 2014 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 <memory>
 #include <vector>

 #include "common_audio/vad/mock/mock_vad.h"
 #include "modules/audio_coding/codecs/cng/audio_encoder_cng.h"
 #include "rtc_base/constructormagic.h"
 #include "rtc_base/numerics/safe_conversions.h"
 #include "test/gtest.h"
 #include "test/mock_audio_encoder.h"

 using ::testing::Return;
 using ::testing::_;
 using ::testing::SetArgPointee;
 using ::testing::InSequence;
 using ::testing::Invoke;

 namespace webrtc {

 namespace {
 static const size_t kMaxNumSamples = 48 * 10 * 2;  // 10 ms @ 48 kHz stereo.
 static const size_t kMockReturnEncodedBytes = 17;
 static const int kCngPayloadType = 18;
 }  // namespace

 class AudioEncoderCngTest : public ::testing::Test {
  protected:
   AudioEncoderCngTest()
       : mock_encoder_owner_(new MockAudioEncoder),
         mock_encoder_(mock_encoder_owner_.get()),
         mock_vad_(new MockVad),
         timestamp_(4711),
         num_audio_samples_10ms_(0),
         sample_rate_hz_(8000) {
     memset(audio_, 0, kMaxNumSamples * 2);
     EXPECT_CALL(*mock_encoder_, NumChannels()).WillRepeatedly(Return(1));
   }

   void TearDown() override {
     EXPECT_CALL(*mock_vad_, Die()).Times(1);
     cng_.reset();
   }

   AudioEncoderCngConfig MakeCngConfig() {
     AudioEncoderCngConfig config;
     config.speech_encoder = std::move(mock_encoder_owner_);
     EXPECT_TRUE(config.speech_encoder);

     // Let the AudioEncoderCng object use a MockVad instead of its internally
     // created Vad object.
     config.vad = mock_vad_;
     config.payload_type = kCngPayloadType;

     return config;
   }

   void CreateCng(AudioEncoderCngConfig&& config) {
     num_audio_samples_10ms_ = static_cast<size_t>(10 * sample_rate_hz_ / 1000);
     ASSERT_LE(num_audio_samples_10ms_, kMaxNumSamples);
     if (config.speech_encoder) {
       EXPECT_CALL(*mock_encoder_, SampleRateHz())
           .WillRepeatedly(Return(sample_rate_hz_));
       // Max10MsFramesInAPacket() is just used to verify that the SID frame
       // period is not too small. The return value does not matter that much,
       // as long as it is smaller than 10.
       EXPECT_CALL(*mock_encoder_, Max10MsFramesInAPacket())
           .WillOnce(Return(1u));
     }
     cng_ = CreateComfortNoiseEncoder(std::move(config));
   }

   void Encode() {
     ASSERT_TRUE(cng_) << "Must call CreateCng() first.";
     encoded_info_ = cng_->Encode(
         timestamp_,
         rtc::ArrayView<const int16_t>(audio_, num_audio_samples_10ms_),
         &encoded_);
     timestamp_ += static_cast<uint32_t>(num_audio_samples_10ms_);
   }

   // Expect |num_calls| calls to the encoder, all successful. The last call
   // claims to have encoded |kMockReturnEncodedBytes| bytes, and all the
   // preceding ones 0 bytes.
   void ExpectEncodeCalls(size_t num_calls) {
     InSequence s;
     AudioEncoder::EncodedInfo info;
     for (size_t j = 0; j < num_calls - 1; ++j) {
       EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).WillOnce(Return(info));
     }
     info.encoded_bytes = kMockReturnEncodedBytes;
     EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _))
         .WillOnce(
             Invoke(MockAudioEncoder::FakeEncoding(kMockReturnEncodedBytes)));
   }

   // Verifies that the cng_ object waits until it has collected
   // |blocks_per_frame| blocks of audio, and then dispatches all of them to
   // the underlying codec (speech or cng).
   void CheckBlockGrouping(size_t blocks_per_frame, bool active_speech) {
     EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
         .WillRepeatedly(Return(blocks_per_frame));
     auto config = MakeCngConfig();
     const int num_cng_coefficients = config.num_cng_coefficients;
     CreateCng(std::move(config));
     EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
         .WillRepeatedly(Return(active_speech ? Vad::kActive : Vad::kPassive));

     // Don't expect any calls to the encoder yet.
     EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).Times(0);
     for (size_t i = 0; i < blocks_per_frame - 1; ++i) {
       Encode();
       EXPECT_EQ(0u, encoded_info_.encoded_bytes);
     }
     if (active_speech)
       ExpectEncodeCalls(blocks_per_frame);
     Encode();
     if (active_speech) {
       EXPECT_EQ(kMockReturnEncodedBytes, encoded_info_.encoded_bytes);
     } else {
       EXPECT_EQ(static_cast<size_t>(num_cng_coefficients + 1),
                 encoded_info_.encoded_bytes);
     }
   }

   // Verifies that the audio is partitioned into larger blocks before calling
   // the VAD.
   void CheckVadInputSize(int input_frame_size_ms,
                          int expected_first_block_size_ms,
                          int expected_second_block_size_ms) {
     const size_t blocks_per_frame =
         static_cast<size_t>(input_frame_size_ms / 10);

     EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
         .WillRepeatedly(Return(blocks_per_frame));

     // Expect nothing to happen before the last block is sent to cng_.
     EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _)).Times(0);
     for (size_t i = 0; i < blocks_per_frame - 1; ++i) {
       Encode();
     }

     // Let the VAD decision be passive, since an active decision may lead to
     // early termination of the decision loop.
     InSequence s;
     EXPECT_CALL(
         *mock_vad_,
         VoiceActivity(_, expected_first_block_size_ms * sample_rate_hz_ / 1000,
                       sample_rate_hz_))
         .WillOnce(Return(Vad::kPassive));
     if (expected_second_block_size_ms > 0) {
       EXPECT_CALL(*mock_vad_,
                   VoiceActivity(
                       _, expected_second_block_size_ms * sample_rate_hz_ / 1000,
                       sample_rate_hz_))
           .WillOnce(Return(Vad::kPassive));
     }

     // With this call to Encode(), |mock_vad_| should be called according to the
     // above expectations.
     Encode();
   }

   // Tests a frame with both active and passive speech. Returns true if the
   // decision was active speech, false if it was passive.
   bool CheckMixedActivePassive(Vad::Activity first_type,
                                Vad::Activity second_type) {
     // Set the speech encoder frame size to 60 ms, to ensure that the VAD will
     // be called twice.
     const size_t blocks_per_frame = 6;
     EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
         .WillRepeatedly(Return(blocks_per_frame));
     InSequence s;
     EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
         .WillOnce(Return(first_type));
     if (first_type == Vad::kPassive) {
       // Expect a second call to the VAD only if the first frame was passive.
       EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
           .WillOnce(Return(second_type));
     }
     encoded_info_.payload_type = 0;
     for (size_t i = 0; i < blocks_per_frame; ++i) {
       Encode();
     }
     return encoded_info_.payload_type != kCngPayloadType;
   }

   std::unique_ptr<AudioEncoder> cng_;
   std::unique_ptr<MockAudioEncoder> mock_encoder_owner_;
   MockAudioEncoder* mock_encoder_;
   MockVad* mock_vad_;  // Ownership is transferred to |cng_|.
   uint32_t timestamp_;
   int16_t audio_[kMaxNumSamples];
   size_t num_audio_samples_10ms_;
   rtc::Buffer encoded_;
   AudioEncoder::EncodedInfo encoded_info_;
   int sample_rate_hz_;

   RTC_DISALLOW_COPY_AND_ASSIGN(AudioEncoderCngTest);
 };

 TEST_F(AudioEncoderCngTest, CreateAndDestroy) {
   CreateCng(MakeCngConfig());
 }

 TEST_F(AudioEncoderCngTest, CheckFrameSizePropagation) {
   CreateCng(MakeCngConfig());
   EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
       .WillOnce(Return(17U));
   EXPECT_EQ(17U, cng_->Num10MsFramesInNextPacket());
 }

 TEST_F(AudioEncoderCngTest, CheckTargetAudioBitratePropagation) {
   CreateCng(MakeCngConfig());
   EXPECT_CALL(*mock_encoder_,
               OnReceivedUplinkBandwidth(4711, absl::optional<int64_t>()));
   cng_->OnReceivedUplinkBandwidth(4711, absl::nullopt);
 }

 TEST_F(AudioEncoderCngTest, CheckPacketLossFractionPropagation) {
   CreateCng(MakeCngConfig());
   EXPECT_CALL(*mock_encoder_, OnReceivedUplinkPacketLossFraction(0.5));
   cng_->OnReceivedUplinkPacketLossFraction(0.5);
 }

 TEST_F(AudioEncoderCngTest, EncodeCallsVad) {
   EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
       .WillRepeatedly(Return(1U));
   CreateCng(MakeCngConfig());
   EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
       .WillOnce(Return(Vad::kPassive));
   Encode();
 }

 TEST_F(AudioEncoderCngTest, EncodeCollects1BlockPassiveSpeech) {
   CheckBlockGrouping(1, false);
 }

 TEST_F(AudioEncoderCngTest, EncodeCollects2BlocksPassiveSpeech) {
   CheckBlockGrouping(2, false);
 }

 TEST_F(AudioEncoderCngTest, EncodeCollects3BlocksPassiveSpeech) {
   CheckBlockGrouping(3, false);
 }

 TEST_F(AudioEncoderCngTest, EncodeCollects1BlockActiveSpeech) {
   CheckBlockGrouping(1, true);
 }

 TEST_F(AudioEncoderCngTest, EncodeCollects2BlocksActiveSpeech) {
   CheckBlockGrouping(2, true);
 }

 TEST_F(AudioEncoderCngTest, EncodeCollects3BlocksActiveSpeech) {
   CheckBlockGrouping(3, true);
 }

 TEST_F(AudioEncoderCngTest, EncodePassive) {
   const size_t kBlocksPerFrame = 3;
   EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
       .WillRepeatedly(Return(kBlocksPerFrame));
   auto config = MakeCngConfig();
   const auto sid_frame_interval_ms = config.sid_frame_interval_ms;
   const auto num_cng_coefficients = config.num_cng_coefficients;
   CreateCng(std::move(config));
   EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
       .WillRepeatedly(Return(Vad::kPassive));
   // Expect no calls at all to the speech encoder mock.
   EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).Times(0);
   uint32_t expected_timestamp = timestamp_;
   for (size_t i = 0; i < 100; ++i) {
     Encode();
     // Check if it was time to call the cng encoder. This is done once every
     // |kBlocksPerFrame| calls.
     if ((i + 1) % kBlocksPerFrame == 0) {
       // Now check if a SID interval has elapsed.
       if ((i % (sid_frame_interval_ms / 10)) < kBlocksPerFrame) {
         // If so, verify that we got a CNG encoding.
         EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
         EXPECT_FALSE(encoded_info_.speech);
         EXPECT_EQ(static_cast<size_t>(num_cng_coefficients) + 1,
                   encoded_info_.encoded_bytes);
         EXPECT_EQ(expected_timestamp, encoded_info_.encoded_timestamp);
       }
       expected_timestamp += rtc::checked_cast<uint32_t>(
           kBlocksPerFrame * num_audio_samples_10ms_);
     } else {
       // Otherwise, expect no output.
       EXPECT_EQ(0u, encoded_info_.encoded_bytes);
     }
   }
 }

 // Verifies that the correct action is taken for frames with both active and
 // passive speech.
 TEST_F(AudioEncoderCngTest, MixedActivePassive) {
   CreateCng(MakeCngConfig());

   // All of the frame is active speech.
   ExpectEncodeCalls(6);
   EXPECT_TRUE(CheckMixedActivePassive(Vad::kActive, Vad::kActive));
   EXPECT_TRUE(encoded_info_.speech);

   // First half of the frame is active speech.
   ExpectEncodeCalls(6);
   EXPECT_TRUE(CheckMixedActivePassive(Vad::kActive, Vad::kPassive));
   EXPECT_TRUE(encoded_info_.speech);

   // Second half of the frame is active speech.
   ExpectEncodeCalls(6);
   EXPECT_TRUE(CheckMixedActivePassive(Vad::kPassive, Vad::kActive));
   EXPECT_TRUE(encoded_info_.speech);

   // All of the frame is passive speech. Expect no calls to |mock_encoder_|.
   EXPECT_FALSE(CheckMixedActivePassive(Vad::kPassive, Vad::kPassive));
   EXPECT_FALSE(encoded_info_.speech);
 }

 // These tests verify that the audio is partitioned into larger blocks before
 // calling the VAD.
 // The parameters for CheckVadInputSize are:
 // CheckVadInputSize(frame_size, expected_first_block_size,
 //                   expected_second_block_size);
 TEST_F(AudioEncoderCngTest, VadInputSize10Ms) {
   CreateCng(MakeCngConfig());
   CheckVadInputSize(10, 10, 0);
 }
 TEST_F(AudioEncoderCngTest, VadInputSize20Ms) {
   CreateCng(MakeCngConfig());
   CheckVadInputSize(20, 20, 0);
 }
 TEST_F(AudioEncoderCngTest, VadInputSize30Ms) {
   CreateCng(MakeCngConfig());
   CheckVadInputSize(30, 30, 0);
 }
 TEST_F(AudioEncoderCngTest, VadInputSize40Ms) {
   CreateCng(MakeCngConfig());
   CheckVadInputSize(40, 20, 20);
 }
 TEST_F(AudioEncoderCngTest, VadInputSize50Ms) {
   CreateCng(MakeCngConfig());
   CheckVadInputSize(50, 30, 20);
 }
 TEST_F(AudioEncoderCngTest, VadInputSize60Ms) {
   CreateCng(MakeCngConfig());
   CheckVadInputSize(60, 30, 30);
 }

 // Verifies that the correct payload type is set when CNG is encoded.
 TEST_F(AudioEncoderCngTest, VerifyCngPayloadType) {
   CreateCng(MakeCngConfig());
   EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).Times(0);
   EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket()).WillOnce(Return(1U));
   EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
       .WillOnce(Return(Vad::kPassive));
   encoded_info_.payload_type = 0;
   Encode();
   EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
 }

 // Verifies that a SID frame is encoded immediately as the signal changes from
 // active speech to passive.
 TEST_F(AudioEncoderCngTest, VerifySidFrameAfterSpeech) {
   auto config = MakeCngConfig();
   const auto num_cng_coefficients = config.num_cng_coefficients;
   CreateCng(std::move(config));
   EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
       .WillRepeatedly(Return(1U));
   // Start with encoding noise.
   EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
       .Times(2)
       .WillRepeatedly(Return(Vad::kPassive));
   Encode();
   EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
   EXPECT_EQ(static_cast<size_t>(num_cng_coefficients) + 1,
             encoded_info_.encoded_bytes);
   // Encode again, and make sure we got no frame at all (since the SID frame
   // period is 100 ms by default).
   Encode();
   EXPECT_EQ(0u, encoded_info_.encoded_bytes);

   // Now encode active speech.
   encoded_info_.payload_type = 0;
   EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
       .WillOnce(Return(Vad::kActive));
   EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _))
       .WillOnce(
           Invoke(MockAudioEncoder::FakeEncoding(kMockReturnEncodedBytes)));
   Encode();
   EXPECT_EQ(kMockReturnEncodedBytes, encoded_info_.encoded_bytes);

   // Go back to noise again, and verify that a SID frame is emitted.
   EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
       .WillOnce(Return(Vad::kPassive));
   Encode();
   EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
   EXPECT_EQ(static_cast<size_t>(num_cng_coefficients) + 1,
             encoded_info_.encoded_bytes);
 }

 // Resetting the CNG should reset both the VAD and the encoder.
 TEST_F(AudioEncoderCngTest, Reset) {
   CreateCng(MakeCngConfig());
   EXPECT_CALL(*mock_encoder_, Reset()).Times(1);
   EXPECT_CALL(*mock_vad_, Reset()).Times(1);
   cng_->Reset();
 }

 #if GTEST_HAS_DEATH_TEST && !defined(WEBRTC_ANDROID)

 // This test fixture tests various error conditions that makes the
 // AudioEncoderCng die via CHECKs.
 class AudioEncoderCngDeathTest : public AudioEncoderCngTest {
  protected:
   AudioEncoderCngDeathTest() : AudioEncoderCngTest() {
     EXPECT_CALL(*mock_vad_, Die()).Times(1);
     delete mock_vad_;
     mock_vad_ = nullptr;
   }

   // Override AudioEncoderCngTest::TearDown, since that one expects a call to
   // the destructor of |mock_vad_|. In this case, that object is already
   // deleted.
   void TearDown() override { cng_.reset(); }

   AudioEncoderCngConfig MakeCngConfig() {
     // Don't provide a Vad mock object, since it would leak when the test dies.
     auto config = AudioEncoderCngTest::MakeCngConfig();
     config.vad = nullptr;
     return config;
   }

   void TryWrongNumCoefficients(int num) {
     EXPECT_DEATH(
         [&] {
           auto config = MakeCngConfig();
           config.num_cng_coefficients = num;
           CreateCng(std::move(config));
         }(),
         "Invalid configuration");
   }
 };

 TEST_F(AudioEncoderCngDeathTest, WrongFrameSize) {
   CreateCng(MakeCngConfig());
   num_audio_samples_10ms_ *= 2;  // 20 ms frame.
   EXPECT_DEATH(Encode(), "");
   num_audio_samples_10ms_ = 0;  // Zero samples.
   EXPECT_DEATH(Encode(), "");
 }

 TEST_F(AudioEncoderCngDeathTest, WrongNumCoefficientsA) {
   TryWrongNumCoefficients(-1);
 }

 TEST_F(AudioEncoderCngDeathTest, WrongNumCoefficientsB) {
   TryWrongNumCoefficients(0);
 }

 TEST_F(AudioEncoderCngDeathTest, WrongNumCoefficientsC) {
   TryWrongNumCoefficients(13);
 }

 TEST_F(AudioEncoderCngDeathTest, NullSpeechEncoder) {
   auto config = MakeCngConfig();
   config.speech_encoder = nullptr;
   EXPECT_DEATH(CreateCng(std::move(config)), "");
 }

 TEST_F(AudioEncoderCngDeathTest, StereoEncoder) {
   EXPECT_CALL(*mock_encoder_, NumChannels()).WillRepeatedly(Return(2));
   EXPECT_DEATH(CreateCng(MakeCngConfig()), "Invalid configuration");
 }

 TEST_F(AudioEncoderCngDeathTest, StereoConfig) {
   EXPECT_DEATH(
       [&] {
         auto config = MakeCngConfig();
         config.num_channels = 2;
         CreateCng(std::move(config));
       }(),
       "Invalid configuration");
 }

 TEST_F(AudioEncoderCngDeathTest, EncoderFrameSizeTooLarge) {
   CreateCng(MakeCngConfig());
   EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
       .WillRepeatedly(Return(7U));
   for (int i = 0; i < 6; ++i)
     Encode();
   EXPECT_DEATH(Encode(),
                "Frame size cannot be larger than 60 ms when using VAD/CNG.");
 }

 #endif  // GTEST_HAS_DEATH_TEST

 }  // namespace webrtc
	/*
	* Copyright (c) 2014 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 <memory>
	#include <vector>

	#include "common_audio/vad/mock/mock_vad.h"
	#include "modules/audio_coding/codecs/cng/audio_encoder_cng.h"
	#include "rtc_base/constructormagic.h"
	#include "rtc_base/numerics/safe_conversions.h"
	#include "test/gtest.h"
	#include "test/mock_audio_encoder.h"

	using ::testing::Return;
	using ::testing::_;
	using ::testing::SetArgPointee;
	using ::testing::InSequence;
	using ::testing::Invoke;

	namespace webrtc {

	namespace {
	static const size_t kMaxNumSamples = 48 * 10 * 2; // 10 ms @ 48 kHz stereo.
	static const size_t kMockReturnEncodedBytes = 17;
	static const int kCngPayloadType = 18;
	} // namespace

	class AudioEncoderCngTest : public ::testing::Test {
	protected:
	AudioEncoderCngTest()
	: mock_encoder_owner_(new MockAudioEncoder),
	mock_encoder_(mock_encoder_owner_.get()),
	mock_vad_(new MockVad),
	timestamp_(4711),
	num_audio_samples_10ms_(0),
	sample_rate_hz_(8000) {
	memset(audio_, 0, kMaxNumSamples * 2);
	EXPECT_CALL(*mock_encoder_, NumChannels()).WillRepeatedly(Return(1));
	}

	void TearDown() override {
	EXPECT_CALL(*mock_vad_, Die()).Times(1);
	cng_.reset();
	}

	AudioEncoderCngConfig MakeCngConfig() {
	AudioEncoderCngConfig config;
	config.speech_encoder = std::move(mock_encoder_owner_);
	EXPECT_TRUE(config.speech_encoder);

	// Let the AudioEncoderCng object use a MockVad instead of its internally
	// created Vad object.
	config.vad = mock_vad_;
	config.payload_type = kCngPayloadType;

	return config;
	}

	void CreateCng(AudioEncoderCngConfig&& config) {
	num_audio_samples_10ms_ = static_cast<size_t>(10 * sample_rate_hz_ / 1000);
	ASSERT_LE(num_audio_samples_10ms_, kMaxNumSamples);
	if (config.speech_encoder) {
	EXPECT_CALL(*mock_encoder_, SampleRateHz())
	.WillRepeatedly(Return(sample_rate_hz_));
	// Max10MsFramesInAPacket() is just used to verify that the SID frame
	// period is not too small. The return value does not matter that much,
	// as long as it is smaller than 10.
	EXPECT_CALL(*mock_encoder_, Max10MsFramesInAPacket())
	.WillOnce(Return(1u));
	}
	cng_ = CreateComfortNoiseEncoder(std::move(config));
	}

	void Encode() {
	ASSERT_TRUE(cng_) << "Must call CreateCng() first.";
	encoded_info_ = cng_->Encode(
	timestamp_,
	rtc::ArrayView<const int16_t>(audio_, num_audio_samples_10ms_),
	&encoded_);
	timestamp_ += static_cast<uint32_t>(num_audio_samples_10ms_);
	}

	// Expect \|num_calls\| calls to the encoder, all successful. The last call
	// claims to have encoded \|kMockReturnEncodedBytes\| bytes, and all the
	// preceding ones 0 bytes.
	void ExpectEncodeCalls(size_t num_calls) {
	InSequence s;
	AudioEncoder::EncodedInfo info;
	for (size_t j = 0; j < num_calls - 1; ++j) {
	EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).WillOnce(Return(info));
	}
	info.encoded_bytes = kMockReturnEncodedBytes;
	EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _))
	.WillOnce(
	Invoke(MockAudioEncoder::FakeEncoding(kMockReturnEncodedBytes)));
	}

	// Verifies that the cng_ object waits until it has collected
	// \|blocks_per_frame\| blocks of audio, and then dispatches all of them to
	// the underlying codec (speech or cng).
	void CheckBlockGrouping(size_t blocks_per_frame, bool active_speech) {
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillRepeatedly(Return(blocks_per_frame));
	auto config = MakeCngConfig();
	const int num_cng_coefficients = config.num_cng_coefficients;
	CreateCng(std::move(config));
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillRepeatedly(Return(active_speech ? Vad::kActive : Vad::kPassive));

	// Don't expect any calls to the encoder yet.
	EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).Times(0);
	for (size_t i = 0; i < blocks_per_frame - 1; ++i) {
	Encode();
	EXPECT_EQ(0u, encoded_info_.encoded_bytes);
	}
	if (active_speech)
	ExpectEncodeCalls(blocks_per_frame);
	Encode();
	if (active_speech) {
	EXPECT_EQ(kMockReturnEncodedBytes, encoded_info_.encoded_bytes);
	} else {
	EXPECT_EQ(static_cast<size_t>(num_cng_coefficients + 1),
	encoded_info_.encoded_bytes);
	}
	}

	// Verifies that the audio is partitioned into larger blocks before calling
	// the VAD.
	void CheckVadInputSize(int input_frame_size_ms,
	int expected_first_block_size_ms,
	int expected_second_block_size_ms) {
	const size_t blocks_per_frame =
	static_cast<size_t>(input_frame_size_ms / 10);

	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillRepeatedly(Return(blocks_per_frame));

	// Expect nothing to happen before the last block is sent to cng_.
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _)).Times(0);
	for (size_t i = 0; i < blocks_per_frame - 1; ++i) {
	Encode();
	}

	// Let the VAD decision be passive, since an active decision may lead to
	// early termination of the decision loop.
	InSequence s;
	EXPECT_CALL(
	*mock_vad_,
	VoiceActivity(_, expected_first_block_size_ms * sample_rate_hz_ / 1000,
	sample_rate_hz_))
	.WillOnce(Return(Vad::kPassive));
	if (expected_second_block_size_ms > 0) {
	EXPECT_CALL(*mock_vad_,
	VoiceActivity(
	_, expected_second_block_size_ms * sample_rate_hz_ / 1000,
	sample_rate_hz_))
	.WillOnce(Return(Vad::kPassive));
	}

	// With this call to Encode(), \|mock_vad_\| should be called according to the
	// above expectations.
	Encode();
	}

	// Tests a frame with both active and passive speech. Returns true if the
	// decision was active speech, false if it was passive.
	bool CheckMixedActivePassive(Vad::Activity first_type,
	Vad::Activity second_type) {
	// Set the speech encoder frame size to 60 ms, to ensure that the VAD will
	// be called twice.
	const size_t blocks_per_frame = 6;
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillRepeatedly(Return(blocks_per_frame));
	InSequence s;
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillOnce(Return(first_type));
	if (first_type == Vad::kPassive) {
	// Expect a second call to the VAD only if the first frame was passive.
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillOnce(Return(second_type));
	}
	encoded_info_.payload_type = 0;
	for (size_t i = 0; i < blocks_per_frame; ++i) {
	Encode();
	}
	return encoded_info_.payload_type != kCngPayloadType;
	}

	std::unique_ptr<AudioEncoder> cng_;
	std::unique_ptr<MockAudioEncoder> mock_encoder_owner_;
	MockAudioEncoder* mock_encoder_;
	MockVad* mock_vad_; // Ownership is transferred to \|cng_\|.
	uint32_t timestamp_;
	int16_t audio_[kMaxNumSamples];
	size_t num_audio_samples_10ms_;
	rtc::Buffer encoded_;
	AudioEncoder::EncodedInfo encoded_info_;
	int sample_rate_hz_;

	RTC_DISALLOW_COPY_AND_ASSIGN(AudioEncoderCngTest);
	};

	TEST_F(AudioEncoderCngTest, CreateAndDestroy) {
	CreateCng(MakeCngConfig());
	}

	TEST_F(AudioEncoderCngTest, CheckFrameSizePropagation) {
	CreateCng(MakeCngConfig());
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillOnce(Return(17U));
	EXPECT_EQ(17U, cng_->Num10MsFramesInNextPacket());
	}

	TEST_F(AudioEncoderCngTest, CheckTargetAudioBitratePropagation) {
	CreateCng(MakeCngConfig());
	EXPECT_CALL(*mock_encoder_,
	OnReceivedUplinkBandwidth(4711, absl::optional<int64_t>()));
	cng_->OnReceivedUplinkBandwidth(4711, absl::nullopt);
	}

	TEST_F(AudioEncoderCngTest, CheckPacketLossFractionPropagation) {
	CreateCng(MakeCngConfig());
	EXPECT_CALL(*mock_encoder_, OnReceivedUplinkPacketLossFraction(0.5));
	cng_->OnReceivedUplinkPacketLossFraction(0.5);
	}

	TEST_F(AudioEncoderCngTest, EncodeCallsVad) {
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillRepeatedly(Return(1U));
	CreateCng(MakeCngConfig());
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillOnce(Return(Vad::kPassive));
	Encode();
	}

	TEST_F(AudioEncoderCngTest, EncodeCollects1BlockPassiveSpeech) {
	CheckBlockGrouping(1, false);
	}

	TEST_F(AudioEncoderCngTest, EncodeCollects2BlocksPassiveSpeech) {
	CheckBlockGrouping(2, false);
	}

	TEST_F(AudioEncoderCngTest, EncodeCollects3BlocksPassiveSpeech) {
	CheckBlockGrouping(3, false);
	}

	TEST_F(AudioEncoderCngTest, EncodeCollects1BlockActiveSpeech) {
	CheckBlockGrouping(1, true);
	}

	TEST_F(AudioEncoderCngTest, EncodeCollects2BlocksActiveSpeech) {
	CheckBlockGrouping(2, true);
	}

	TEST_F(AudioEncoderCngTest, EncodeCollects3BlocksActiveSpeech) {
	CheckBlockGrouping(3, true);
	}

	TEST_F(AudioEncoderCngTest, EncodePassive) {
	const size_t kBlocksPerFrame = 3;
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillRepeatedly(Return(kBlocksPerFrame));
	auto config = MakeCngConfig();
	const auto sid_frame_interval_ms = config.sid_frame_interval_ms;
	const auto num_cng_coefficients = config.num_cng_coefficients;
	CreateCng(std::move(config));
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillRepeatedly(Return(Vad::kPassive));
	// Expect no calls at all to the speech encoder mock.
	EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).Times(0);
	uint32_t expected_timestamp = timestamp_;
	for (size_t i = 0; i < 100; ++i) {
	Encode();
	// Check if it was time to call the cng encoder. This is done once every
	// \|kBlocksPerFrame\| calls.
	if ((i + 1) % kBlocksPerFrame == 0) {
	// Now check if a SID interval has elapsed.
	if ((i % (sid_frame_interval_ms / 10)) < kBlocksPerFrame) {
	// If so, verify that we got a CNG encoding.
	EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
	EXPECT_FALSE(encoded_info_.speech);
	EXPECT_EQ(static_cast<size_t>(num_cng_coefficients) + 1,
	encoded_info_.encoded_bytes);
	EXPECT_EQ(expected_timestamp, encoded_info_.encoded_timestamp);
	}
	expected_timestamp += rtc::checked_cast<uint32_t>(
	kBlocksPerFrame * num_audio_samples_10ms_);
	} else {
	// Otherwise, expect no output.
	EXPECT_EQ(0u, encoded_info_.encoded_bytes);
	}
	}
	}

	// Verifies that the correct action is taken for frames with both active and
	// passive speech.
	TEST_F(AudioEncoderCngTest, MixedActivePassive) {
	CreateCng(MakeCngConfig());

	// All of the frame is active speech.
	ExpectEncodeCalls(6);
	EXPECT_TRUE(CheckMixedActivePassive(Vad::kActive, Vad::kActive));
	EXPECT_TRUE(encoded_info_.speech);

	// First half of the frame is active speech.
	ExpectEncodeCalls(6);
	EXPECT_TRUE(CheckMixedActivePassive(Vad::kActive, Vad::kPassive));
	EXPECT_TRUE(encoded_info_.speech);

	// Second half of the frame is active speech.
	ExpectEncodeCalls(6);
	EXPECT_TRUE(CheckMixedActivePassive(Vad::kPassive, Vad::kActive));
	EXPECT_TRUE(encoded_info_.speech);

	// All of the frame is passive speech. Expect no calls to \|mock_encoder_\|.
	EXPECT_FALSE(CheckMixedActivePassive(Vad::kPassive, Vad::kPassive));
	EXPECT_FALSE(encoded_info_.speech);
	}

	// These tests verify that the audio is partitioned into larger blocks before
	// calling the VAD.
	// The parameters for CheckVadInputSize are:
	// CheckVadInputSize(frame_size, expected_first_block_size,
	// expected_second_block_size);
	TEST_F(AudioEncoderCngTest, VadInputSize10Ms) {
	CreateCng(MakeCngConfig());
	CheckVadInputSize(10, 10, 0);
	}
	TEST_F(AudioEncoderCngTest, VadInputSize20Ms) {
	CreateCng(MakeCngConfig());
	CheckVadInputSize(20, 20, 0);
	}
	TEST_F(AudioEncoderCngTest, VadInputSize30Ms) {
	CreateCng(MakeCngConfig());
	CheckVadInputSize(30, 30, 0);
	}
	TEST_F(AudioEncoderCngTest, VadInputSize40Ms) {
	CreateCng(MakeCngConfig());
	CheckVadInputSize(40, 20, 20);
	}
	TEST_F(AudioEncoderCngTest, VadInputSize50Ms) {
	CreateCng(MakeCngConfig());
	CheckVadInputSize(50, 30, 20);
	}
	TEST_F(AudioEncoderCngTest, VadInputSize60Ms) {
	CreateCng(MakeCngConfig());
	CheckVadInputSize(60, 30, 30);
	}

	// Verifies that the correct payload type is set when CNG is encoded.
	TEST_F(AudioEncoderCngTest, VerifyCngPayloadType) {
	CreateCng(MakeCngConfig());
	EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _)).Times(0);
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket()).WillOnce(Return(1U));
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillOnce(Return(Vad::kPassive));
	encoded_info_.payload_type = 0;
	Encode();
	EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
	}

	// Verifies that a SID frame is encoded immediately as the signal changes from
	// active speech to passive.
	TEST_F(AudioEncoderCngTest, VerifySidFrameAfterSpeech) {
	auto config = MakeCngConfig();
	const auto num_cng_coefficients = config.num_cng_coefficients;
	CreateCng(std::move(config));
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillRepeatedly(Return(1U));
	// Start with encoding noise.
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.Times(2)
	.WillRepeatedly(Return(Vad::kPassive));
	Encode();
	EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
	EXPECT_EQ(static_cast<size_t>(num_cng_coefficients) + 1,
	encoded_info_.encoded_bytes);
	// Encode again, and make sure we got no frame at all (since the SID frame
	// period is 100 ms by default).
	Encode();
	EXPECT_EQ(0u, encoded_info_.encoded_bytes);

	// Now encode active speech.
	encoded_info_.payload_type = 0;
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillOnce(Return(Vad::kActive));
	EXPECT_CALL(*mock_encoder_, EncodeImpl(_, _, _))
	.WillOnce(
	Invoke(MockAudioEncoder::FakeEncoding(kMockReturnEncodedBytes)));
	Encode();
	EXPECT_EQ(kMockReturnEncodedBytes, encoded_info_.encoded_bytes);

	// Go back to noise again, and verify that a SID frame is emitted.
	EXPECT_CALL(*mock_vad_, VoiceActivity(_, _, _))
	.WillOnce(Return(Vad::kPassive));
	Encode();
	EXPECT_EQ(kCngPayloadType, encoded_info_.payload_type);
	EXPECT_EQ(static_cast<size_t>(num_cng_coefficients) + 1,
	encoded_info_.encoded_bytes);
	}

	// Resetting the CNG should reset both the VAD and the encoder.
	TEST_F(AudioEncoderCngTest, Reset) {
	CreateCng(MakeCngConfig());
	EXPECT_CALL(*mock_encoder_, Reset()).Times(1);
	EXPECT_CALL(*mock_vad_, Reset()).Times(1);
	cng_->Reset();
	}

	#if GTEST_HAS_DEATH_TEST && !defined(WEBRTC_ANDROID)

	// This test fixture tests various error conditions that makes the
	// AudioEncoderCng die via CHECKs.
	class AudioEncoderCngDeathTest : public AudioEncoderCngTest {
	protected:
	AudioEncoderCngDeathTest() : AudioEncoderCngTest() {
	EXPECT_CALL(*mock_vad_, Die()).Times(1);
	delete mock_vad_;
	mock_vad_ = nullptr;
	}

	// Override AudioEncoderCngTest::TearDown, since that one expects a call to
	// the destructor of \|mock_vad_\|. In this case, that object is already
	// deleted.
	void TearDown() override { cng_.reset(); }

	AudioEncoderCngConfig MakeCngConfig() {
	// Don't provide a Vad mock object, since it would leak when the test dies.
	auto config = AudioEncoderCngTest::MakeCngConfig();
	config.vad = nullptr;
	return config;
	}

	void TryWrongNumCoefficients(int num) {
	EXPECT_DEATH(
	[&] {
	auto config = MakeCngConfig();
	config.num_cng_coefficients = num;
	CreateCng(std::move(config));
	}(),
	"Invalid configuration");
	}
	};

	TEST_F(AudioEncoderCngDeathTest, WrongFrameSize) {
	CreateCng(MakeCngConfig());
	num_audio_samples_10ms_ *= 2; // 20 ms frame.
	EXPECT_DEATH(Encode(), "");
	num_audio_samples_10ms_ = 0; // Zero samples.
	EXPECT_DEATH(Encode(), "");
	}

	TEST_F(AudioEncoderCngDeathTest, WrongNumCoefficientsA) {
	TryWrongNumCoefficients(-1);
	}

	TEST_F(AudioEncoderCngDeathTest, WrongNumCoefficientsB) {
	TryWrongNumCoefficients(0);
	}

	TEST_F(AudioEncoderCngDeathTest, WrongNumCoefficientsC) {
	TryWrongNumCoefficients(13);
	}

	TEST_F(AudioEncoderCngDeathTest, NullSpeechEncoder) {
	auto config = MakeCngConfig();
	config.speech_encoder = nullptr;
	EXPECT_DEATH(CreateCng(std::move(config)), "");
	}

	TEST_F(AudioEncoderCngDeathTest, StereoEncoder) {
	EXPECT_CALL(*mock_encoder_, NumChannels()).WillRepeatedly(Return(2));
	EXPECT_DEATH(CreateCng(MakeCngConfig()), "Invalid configuration");
	}

	TEST_F(AudioEncoderCngDeathTest, StereoConfig) {
	EXPECT_DEATH(
	[&] {
	auto config = MakeCngConfig();
	config.num_channels = 2;
	CreateCng(std::move(config));
	}(),
	"Invalid configuration");
	}

	TEST_F(AudioEncoderCngDeathTest, EncoderFrameSizeTooLarge) {
	CreateCng(MakeCngConfig());
	EXPECT_CALL(*mock_encoder_, Num10MsFramesInNextPacket())
	.WillRepeatedly(Return(7U));
	for (int i = 0; i < 6; ++i)
	Encode();
	EXPECT_DEATH(Encode(),
	"Frame size cannot be larger than 60 ms when using VAD/CNG.");
	}

	#endif // GTEST_HAS_DEATH_TEST

	} // namespace webrtc