modules/video_coding/video_sender_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.
  */

 #include <memory>
 #include <vector>

 #include "api/test/mock_video_encoder.h"
 #include "api/video/i420_buffer.h"
 #include "api/video_codecs/vp8_temporal_layers.h"
 #include "modules/video_coding/codecs/vp8/include/vp8.h"
 #include "modules/video_coding/include/mock/mock_vcm_callbacks.h"
 #include "modules/video_coding/include/video_coding.h"
 #include "modules/video_coding/utility/default_video_bitrate_allocator.h"
 #include "modules/video_coding/utility/simulcast_rate_allocator.h"
 #include "modules/video_coding/video_coding_impl.h"
 #include "system_wrappers/include/clock.h"
 #include "test/frame_generator.h"
 #include "test/gtest.h"
 #include "test/testsupport/fileutils.h"
 #include "test/video_codec_settings.h"

 using ::testing::_;
 using ::testing::AllOf;
 using ::testing::ElementsAre;
 using ::testing::ElementsAreArray;
 using ::testing::Field;
 using ::testing::NiceMock;
 using ::testing::Pointee;
 using ::testing::Return;
 using ::testing::FloatEq;
 using std::vector;
 using webrtc::test::FrameGenerator;

 namespace webrtc {
 namespace vcm {
 namespace {
 static const int kDefaultHeight = 720;
 static const int kDefaultWidth = 1280;
 static const int kMaxNumberOfTemporalLayers = 3;
 static const int kNumberOfLayers = 3;
 static const int kNumberOfStreams = 3;
 static const int kUnusedPayloadType = 10;

 struct Vp8StreamInfo {
   float framerate_fps[kMaxNumberOfTemporalLayers];
   int bitrate_kbps[kMaxNumberOfTemporalLayers];
 };

 MATCHER_P(MatchesVp8StreamInfo, expected, "") {
   bool res = true;
   for (int tl = 0; tl < kMaxNumberOfTemporalLayers; ++tl) {
     if (fabs(expected.framerate_fps[tl] - arg.framerate_fps[tl]) > 0.5) {
       *result_listener << " framerate_fps[" << tl
                        << "] = " << arg.framerate_fps[tl] << " (expected "
                        << expected.framerate_fps[tl] << ") ";
       res = false;
     }
     if (abs(expected.bitrate_kbps[tl] - arg.bitrate_kbps[tl]) > 10) {
       *result_listener << " bitrate_kbps[" << tl
                        << "] = " << arg.bitrate_kbps[tl] << " (expected "
                        << expected.bitrate_kbps[tl] << ") ";
       res = false;
     }
   }
   return res;
 }

 class EmptyFrameGenerator : public FrameGenerator {
  public:
   EmptyFrameGenerator(int width, int height) : width_(width), height_(height) {}
   VideoFrame* NextFrame() override {
     frame_.reset(new VideoFrame(I420Buffer::Create(width_, height_),
                                 webrtc::kVideoRotation_0, 0));
     return frame_.get();
   }

  private:
   const int width_;
   const int height_;
   std::unique_ptr<VideoFrame> frame_;
 };

 class EncodedImageCallbackImpl : public EncodedImageCallback {
  public:
   explicit EncodedImageCallbackImpl(Clock* clock)
       : clock_(clock), start_time_ms_(clock_->TimeInMilliseconds()) {}

   virtual ~EncodedImageCallbackImpl() {}

   Result OnEncodedImage(const EncodedImage& encoded_image,
                         const CodecSpecificInfo* codec_specific_info,
                         const RTPFragmentationHeader* fragmentation) override {
     assert(codec_specific_info);
     frame_data_.push_back(
         FrameData(encoded_image._length, *codec_specific_info));
     return Result(Result::OK, encoded_image.Timestamp());
   }

   void Reset() {
     frame_data_.clear();
     start_time_ms_ = clock_->TimeInMilliseconds();
   }

   float FramerateFpsWithinTemporalLayer(int temporal_layer) {
     return CountFramesWithinTemporalLayer(temporal_layer) *
            (1000.0 / interval_ms());
   }

   float BitrateKbpsWithinTemporalLayer(int temporal_layer) {
     return SumPayloadBytesWithinTemporalLayer(temporal_layer) * 8.0 /
            interval_ms();
   }

   Vp8StreamInfo CalculateVp8StreamInfo() {
     Vp8StreamInfo info;
     for (int tl = 0; tl < 3; ++tl) {
       info.framerate_fps[tl] = FramerateFpsWithinTemporalLayer(tl);
       info.bitrate_kbps[tl] = BitrateKbpsWithinTemporalLayer(tl);
     }
     return info;
   }

  private:
   struct FrameData {
     FrameData() : payload_size(0) {}

     FrameData(size_t payload_size, const CodecSpecificInfo& codec_specific_info)
         : payload_size(payload_size),
           codec_specific_info(codec_specific_info) {}

     size_t payload_size;
     CodecSpecificInfo codec_specific_info;
   };

   int64_t interval_ms() {
     int64_t diff = (clock_->TimeInMilliseconds() - start_time_ms_);
     EXPECT_GT(diff, 0);
     return diff;
   }

   int CountFramesWithinTemporalLayer(int temporal_layer) {
     int frames = 0;
     for (size_t i = 0; i < frame_data_.size(); ++i) {
       EXPECT_EQ(kVideoCodecVP8, frame_data_[i].codec_specific_info.codecType);
       const uint8_t temporal_idx =
           frame_data_[i].codec_specific_info.codecSpecific.VP8.temporalIdx;
       if (temporal_idx <= temporal_layer || temporal_idx == kNoTemporalIdx)
         frames++;
     }
     return frames;
   }

   size_t SumPayloadBytesWithinTemporalLayer(int temporal_layer) {
     size_t payload_size = 0;
     for (size_t i = 0; i < frame_data_.size(); ++i) {
       EXPECT_EQ(kVideoCodecVP8, frame_data_[i].codec_specific_info.codecType);
       const uint8_t temporal_idx =
           frame_data_[i].codec_specific_info.codecSpecific.VP8.temporalIdx;
       if (temporal_idx <= temporal_layer || temporal_idx == kNoTemporalIdx)
         payload_size += frame_data_[i].payload_size;
     }
     return payload_size;
   }

   Clock* clock_;
   int64_t start_time_ms_;
   vector<FrameData> frame_data_;
 };

 class TestVideoSender : public ::testing::Test {
  protected:
   // Note: simulated clock starts at 1 seconds, since parts of webrtc use 0 as
   // a special case (e.g. frame rate in media optimization).
   TestVideoSender() : clock_(1000), encoded_frame_callback_(&clock_) {}

   void SetUp() override {
     sender_.reset(new VideoSender(&clock_, &encoded_frame_callback_));
   }

   void AddFrame() {
     assert(generator_.get());
     sender_->AddVideoFrame(*generator_->NextFrame(), nullptr,
                            encoder_ ? absl::optional<VideoEncoder::EncoderInfo>(
                                           encoder_->GetEncoderInfo())
                                     : absl::nullopt);
   }

   SimulatedClock clock_;
   EncodedImageCallbackImpl encoded_frame_callback_;
   // Used by subclassing tests, need to outlive sender_.
   std::unique_ptr<VideoEncoder> encoder_;
   std::unique_ptr<VideoSender> sender_;
   std::unique_ptr<FrameGenerator> generator_;
 };

 class TestVideoSenderWithMockEncoder : public TestVideoSender {
  public:
   TestVideoSenderWithMockEncoder() {}
   ~TestVideoSenderWithMockEncoder() override {}

  protected:
   void SetUp() override {
     TestVideoSender::SetUp();
     sender_->RegisterExternalEncoder(&encoder_, false);
     webrtc::test::CodecSettings(kVideoCodecVP8, &settings_);
     settings_.numberOfSimulcastStreams = kNumberOfStreams;
     ConfigureStream(kDefaultWidth / 4, kDefaultHeight / 4, 100,
                     &settings_.simulcastStream[0]);
     ConfigureStream(kDefaultWidth / 2, kDefaultHeight / 2, 500,
                     &settings_.simulcastStream[1]);
     ConfigureStream(kDefaultWidth, kDefaultHeight, 1200,
                     &settings_.simulcastStream[2]);
     settings_.plType = kUnusedPayloadType;  // Use the mocked encoder.
     generator_.reset(
         new EmptyFrameGenerator(settings_.width, settings_.height));
     EXPECT_EQ(0, sender_->RegisterSendCodec(&settings_, 1, 1200));
     rate_allocator_.reset(new DefaultVideoBitrateAllocator(settings_));
   }

   void TearDown() override { sender_.reset(); }

   void ExpectIntraRequest(int stream) {
     ExpectEncodeWithFrameTypes(stream, false);
   }

   void ExpectInitialKeyFrames() { ExpectEncodeWithFrameTypes(-1, true); }

   void ExpectEncodeWithFrameTypes(int intra_request_stream, bool first_frame) {
     if (intra_request_stream == -1) {
       // No intra request expected, keyframes on first frame.
       FrameType frame_type = first_frame ? kVideoFrameKey : kVideoFrameDelta;
       EXPECT_CALL(
           encoder_,
           Encode(_, _,
                  Pointee(ElementsAre(frame_type, frame_type, frame_type))))
           .Times(1)
           .WillRepeatedly(Return(0));
       return;
     }
     ASSERT_FALSE(first_frame);
     ASSERT_GE(intra_request_stream, 0);
     ASSERT_LT(intra_request_stream, kNumberOfStreams);
     std::vector<FrameType> frame_types(kNumberOfStreams, kVideoFrameDelta);
     frame_types[intra_request_stream] = kVideoFrameKey;
     EXPECT_CALL(
         encoder_,
         Encode(_, _,
                Pointee(ElementsAreArray(&frame_types[0], frame_types.size()))))
         .Times(1)
         .WillRepeatedly(Return(0));
   }

   static void ConfigureStream(int width,
                               int height,
                               int max_bitrate,
                               SimulcastStream* stream) {
     assert(stream);
     stream->width = width;
     stream->height = height;
     stream->maxBitrate = max_bitrate;
     stream->numberOfTemporalLayers = kNumberOfLayers;
     stream->qpMax = 45;
   }

   VideoCodec settings_;
   NiceMock<MockVideoEncoder> encoder_;
   std::unique_ptr<DefaultVideoBitrateAllocator> rate_allocator_;
 };

 TEST_F(TestVideoSenderWithMockEncoder, TestIntraRequests) {
   // Initial request should be all keyframes.
   ExpectInitialKeyFrames();
   AddFrame();
   EXPECT_EQ(0, sender_->IntraFrameRequest(0));
   ExpectIntraRequest(0);
   AddFrame();
   ExpectIntraRequest(-1);
   AddFrame();

   EXPECT_EQ(0, sender_->IntraFrameRequest(1));
   ExpectIntraRequest(1);
   AddFrame();
   ExpectIntraRequest(-1);
   AddFrame();

   EXPECT_EQ(0, sender_->IntraFrameRequest(2));
   ExpectIntraRequest(2);
   AddFrame();
   ExpectIntraRequest(-1);
   AddFrame();

   EXPECT_EQ(-1, sender_->IntraFrameRequest(3));
   ExpectIntraRequest(-1);
   AddFrame();
 }

 TEST_F(TestVideoSenderWithMockEncoder, TestSetRate) {
   // Let actual fps be half of max, so it can be distinguished from default.
   const uint32_t kActualFrameRate = settings_.maxFramerate / 2;
   const int64_t kFrameIntervalMs = 1000 / kActualFrameRate;
   const uint32_t new_bitrate_kbps = settings_.startBitrate + 300;

   // Initial frame rate is taken from config, as we have no data yet.
   VideoBitrateAllocation new_rate_allocation = rate_allocator_->GetAllocation(
       new_bitrate_kbps * 1000, settings_.maxFramerate);
   EXPECT_CALL(encoder_,
               SetRateAllocation(new_rate_allocation, settings_.maxFramerate))
       .Times(1)
       .WillOnce(Return(0));
   sender_->SetChannelParameters(new_bitrate_kbps * 1000, 0, 200,
                                 rate_allocator_.get(), nullptr);
   AddFrame();
   clock_.AdvanceTimeMilliseconds(kFrameIntervalMs);

   // Expect no call to encoder_.SetRates if the new bitrate is zero.
   EXPECT_CALL(encoder_, SetRateAllocation(_, _)).Times(0);
   sender_->SetChannelParameters(0, 0, 200, rate_allocator_.get(), nullptr);
   AddFrame();
 }

 TEST_F(TestVideoSenderWithMockEncoder, TestIntraRequestsInternalCapture) {
   // De-register current external encoder.
   sender_->RegisterExternalEncoder(nullptr, false);
   // Register encoder with internal capture.
   sender_->RegisterExternalEncoder(&encoder_, true);
   EXPECT_EQ(0, sender_->RegisterSendCodec(&settings_, 1, 1200));
   // Initial request should be all keyframes.
   ExpectInitialKeyFrames();
   AddFrame();
   ExpectIntraRequest(0);
   EXPECT_EQ(0, sender_->IntraFrameRequest(0));
   ExpectIntraRequest(1);
   EXPECT_EQ(0, sender_->IntraFrameRequest(1));
   ExpectIntraRequest(2);
   EXPECT_EQ(0, sender_->IntraFrameRequest(2));
   // No requests expected since these indices are out of bounds.
   EXPECT_EQ(-1, sender_->IntraFrameRequest(3));
 }

 TEST_F(TestVideoSenderWithMockEncoder, TestEncoderParametersForInternalSource) {
   // De-register current external encoder.
   sender_->RegisterExternalEncoder(nullptr, false);
   // Register encoder with internal capture.
   sender_->RegisterExternalEncoder(&encoder_, true);
   EXPECT_EQ(0, sender_->RegisterSendCodec(&settings_, 1, 1200));
   // Update encoder bitrate parameters. We expect that to immediately call
   // SetRates on the encoder without waiting for AddFrame processing.
   const uint32_t new_bitrate_kbps = settings_.startBitrate + 300;
   VideoBitrateAllocation new_rate_allocation = rate_allocator_->GetAllocation(
       new_bitrate_kbps * 1000, settings_.maxFramerate);
   EXPECT_CALL(encoder_, SetRateAllocation(new_rate_allocation, _))
       .Times(1)
       .WillOnce(Return(0));
   sender_->SetChannelParameters(new_bitrate_kbps * 1000, 0, 200,
                                 rate_allocator_.get(), nullptr);
 }

 TEST_F(TestVideoSenderWithMockEncoder,
        NoRedundantSetChannelParameterOrSetRatesCalls) {
   const uint8_t kLossRate = 4;
   const uint8_t kRtt = 200;
   const int64_t kRateStatsWindowMs = 2000;
   const uint32_t kInputFps = 20;
   int64_t start_time = clock_.TimeInMilliseconds();
   // Expect initial call to SetChannelParameters. Rates are initialized through
   // InitEncode and expects no additional call before the framerate (or bitrate)
   // updates.
   sender_->SetChannelParameters(settings_.startBitrate * 1000, kLossRate, kRtt,
                                 rate_allocator_.get(), nullptr);
   while (clock_.TimeInMilliseconds() < start_time + kRateStatsWindowMs) {
     AddFrame();
     clock_.AdvanceTimeMilliseconds(1000 / kInputFps);
   }

   // Call to SetChannelParameters with changed bitrate should call encoder
   // SetRates but not encoder SetChannelParameters (that are unchanged).
   uint32_t new_bitrate_bps = 2 * settings_.startBitrate * 1000;
   VideoBitrateAllocation new_rate_allocation =
       rate_allocator_->GetAllocation(new_bitrate_bps, kInputFps);
   EXPECT_CALL(encoder_, SetRateAllocation(new_rate_allocation, kInputFps))
       .Times(1)
       .WillOnce(Return(0));
   sender_->SetChannelParameters(new_bitrate_bps, kLossRate, kRtt,
                                 rate_allocator_.get(), nullptr);
   AddFrame();
 }

 class TestVideoSenderWithVp8 : public TestVideoSender {
  public:
   TestVideoSenderWithVp8()
       : codec_bitrate_kbps_(300), available_bitrate_kbps_(1000) {}

   void SetUp() override {
     TestVideoSender::SetUp();

     const char* input_video = "foreman_cif";
     const int width = 352;
     const int height = 288;
     generator_ = FrameGenerator::CreateFromYuvFile(
         std::vector<std::string>(1, test::ResourcePath(input_video, "yuv")),
         width, height, 1);

     codec_ = MakeVp8VideoCodec(width, height, 3);
     codec_.minBitrate = 10;
     codec_.startBitrate = codec_bitrate_kbps_;
     codec_.maxBitrate = codec_bitrate_kbps_;

     rate_allocator_.reset(new SimulcastRateAllocator(codec_));

     encoder_ = VP8Encoder::Create();
     sender_->RegisterExternalEncoder(encoder_.get(), false);
     EXPECT_EQ(0, sender_->RegisterSendCodec(&codec_, 1, 1200));
   }

   static VideoCodec MakeVp8VideoCodec(int width,
                                       int height,
                                       int temporal_layers) {
     VideoCodec codec;
     webrtc::test::CodecSettings(kVideoCodecVP8, &codec);
     codec.width = width;
     codec.height = height;
     codec.VP8()->numberOfTemporalLayers = temporal_layers;
     return codec;
   }

   void InsertFrames(float framerate, float seconds) {
     for (int i = 0; i < seconds * framerate; ++i) {
       clock_.AdvanceTimeMilliseconds(1000.0f / framerate);
       AddFrame();
       // SetChannelParameters needs to be called frequently to propagate
       // framerate from the media optimization into the encoder.
       // Note: SetChannelParameters fails if less than 2 frames are in the
       // buffer since it will fail to calculate the framerate.
       if (i != 0) {
         EXPECT_EQ(VCM_OK, sender_->SetChannelParameters(
                               available_bitrate_kbps_ * 1000, 0, 200,
                               rate_allocator_.get(), nullptr));
       }
     }
   }

   Vp8StreamInfo SimulateWithFramerate(float framerate) {
     const float short_simulation_interval = 5.0;
     const float long_simulation_interval = 10.0;
     // It appears that this 5 seconds simulation is needed to allow
     // bitrate and framerate to stabilize.
     InsertFrames(framerate, short_simulation_interval);
     encoded_frame_callback_.Reset();

     InsertFrames(framerate, long_simulation_interval);
     return encoded_frame_callback_.CalculateVp8StreamInfo();
   }

  protected:
   VideoCodec codec_;
   int codec_bitrate_kbps_;
   int available_bitrate_kbps_;
   std::unique_ptr<SimulcastRateAllocator> rate_allocator_;
 };

 #if defined(WEBRTC_ANDROID) || defined(WEBRTC_IOS)
 #define MAYBE_FixedTemporalLayersStrategy DISABLED_FixedTemporalLayersStrategy
 #else
 #define MAYBE_FixedTemporalLayersStrategy FixedTemporalLayersStrategy
 #endif
 TEST_F(TestVideoSenderWithVp8, MAYBE_FixedTemporalLayersStrategy) {
   const int low_b =
       codec_bitrate_kbps_ *
       webrtc::SimulcastRateAllocator::GetTemporalRateAllocation(3, 0);
   const int mid_b =
       codec_bitrate_kbps_ *
       webrtc::SimulcastRateAllocator::GetTemporalRateAllocation(3, 1);
   const int high_b =
       codec_bitrate_kbps_ *
       webrtc::SimulcastRateAllocator::GetTemporalRateAllocation(3, 2);
   {
     Vp8StreamInfo expected = {{7.5, 15.0, 30.0}, {low_b, mid_b, high_b}};
     EXPECT_THAT(SimulateWithFramerate(30.0), MatchesVp8StreamInfo(expected));
   }
   {
     Vp8StreamInfo expected = {{3.75, 7.5, 15.0}, {low_b, mid_b, high_b}};
     EXPECT_THAT(SimulateWithFramerate(15.0), MatchesVp8StreamInfo(expected));
   }
 }

 }  // namespace
 }  // namespace vcm
 }  // 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.
	*/

	#include <memory>
	#include <vector>

	#include "api/test/mock_video_encoder.h"
	#include "api/video/i420_buffer.h"
	#include "api/video_codecs/vp8_temporal_layers.h"
	#include "modules/video_coding/codecs/vp8/include/vp8.h"
	#include "modules/video_coding/include/mock/mock_vcm_callbacks.h"
	#include "modules/video_coding/include/video_coding.h"
	#include "modules/video_coding/utility/default_video_bitrate_allocator.h"
	#include "modules/video_coding/utility/simulcast_rate_allocator.h"
	#include "modules/video_coding/video_coding_impl.h"
	#include "system_wrappers/include/clock.h"
	#include "test/frame_generator.h"
	#include "test/gtest.h"
	#include "test/testsupport/fileutils.h"
	#include "test/video_codec_settings.h"

	using ::testing::_;
	using ::testing::AllOf;
	using ::testing::ElementsAre;
	using ::testing::ElementsAreArray;
	using ::testing::Field;
	using ::testing::NiceMock;
	using ::testing::Pointee;
	using ::testing::Return;
	using ::testing::FloatEq;
	using std::vector;
	using webrtc::test::FrameGenerator;

	namespace webrtc {
	namespace vcm {
	namespace {
	static const int kDefaultHeight = 720;
	static const int kDefaultWidth = 1280;
	static const int kMaxNumberOfTemporalLayers = 3;
	static const int kNumberOfLayers = 3;
	static const int kNumberOfStreams = 3;
	static const int kUnusedPayloadType = 10;

	struct Vp8StreamInfo {
	float framerate_fps[kMaxNumberOfTemporalLayers];
	int bitrate_kbps[kMaxNumberOfTemporalLayers];
	};

	MATCHER_P(MatchesVp8StreamInfo, expected, "") {
	bool res = true;
	for (int tl = 0; tl < kMaxNumberOfTemporalLayers; ++tl) {
	if (fabs(expected.framerate_fps[tl] - arg.framerate_fps[tl]) > 0.5) {
	*result_listener << " framerate_fps[" << tl
	<< "] = " << arg.framerate_fps[tl] << " (expected "
	<< expected.framerate_fps[tl] << ") ";
	res = false;
	}
	if (abs(expected.bitrate_kbps[tl] - arg.bitrate_kbps[tl]) > 10) {
	*result_listener << " bitrate_kbps[" << tl
	<< "] = " << arg.bitrate_kbps[tl] << " (expected "
	<< expected.bitrate_kbps[tl] << ") ";
	res = false;
	}
	}
	return res;
	}

	class EmptyFrameGenerator : public FrameGenerator {
	public:
	EmptyFrameGenerator(int width, int height) : width_(width), height_(height) {}
	VideoFrame* NextFrame() override {
	frame_.reset(new VideoFrame(I420Buffer::Create(width_, height_),
	webrtc::kVideoRotation_0, 0));
	return frame_.get();
	}

	private:
	const int width_;
	const int height_;
	std::unique_ptr<VideoFrame> frame_;
	};

	class EncodedImageCallbackImpl : public EncodedImageCallback {
	public:
	explicit EncodedImageCallbackImpl(Clock* clock)
	: clock_(clock), start_time_ms_(clock_->TimeInMilliseconds()) {}

	virtual ~EncodedImageCallbackImpl() {}

	Result OnEncodedImage(const EncodedImage& encoded_image,
	const CodecSpecificInfo* codec_specific_info,
	const RTPFragmentationHeader* fragmentation) override {
	assert(codec_specific_info);
	frame_data_.push_back(
	FrameData(encoded_image._length, *codec_specific_info));
	return Result(Result::OK, encoded_image.Timestamp());
	}

	void Reset() {
	frame_data_.clear();
	start_time_ms_ = clock_->TimeInMilliseconds();
	}

	float FramerateFpsWithinTemporalLayer(int temporal_layer) {
	return CountFramesWithinTemporalLayer(temporal_layer) *
	(1000.0 / interval_ms());
	}

	float BitrateKbpsWithinTemporalLayer(int temporal_layer) {
	return SumPayloadBytesWithinTemporalLayer(temporal_layer) * 8.0 /
	interval_ms();
	}

	Vp8StreamInfo CalculateVp8StreamInfo() {
	Vp8StreamInfo info;
	for (int tl = 0; tl < 3; ++tl) {
	info.framerate_fps[tl] = FramerateFpsWithinTemporalLayer(tl);
	info.bitrate_kbps[tl] = BitrateKbpsWithinTemporalLayer(tl);
	}
	return info;
	}

	private:
	struct FrameData {
	FrameData() : payload_size(0) {}

	FrameData(size_t payload_size, const CodecSpecificInfo& codec_specific_info)
	: payload_size(payload_size),
	codec_specific_info(codec_specific_info) {}

	size_t payload_size;
	CodecSpecificInfo codec_specific_info;
	};

	int64_t interval_ms() {
	int64_t diff = (clock_->TimeInMilliseconds() - start_time_ms_);
	EXPECT_GT(diff, 0);
	return diff;
	}

	int CountFramesWithinTemporalLayer(int temporal_layer) {
	int frames = 0;
	for (size_t i = 0; i < frame_data_.size(); ++i) {
	EXPECT_EQ(kVideoCodecVP8, frame_data_[i].codec_specific_info.codecType);
	const uint8_t temporal_idx =
	frame_data_[i].codec_specific_info.codecSpecific.VP8.temporalIdx;
	if (temporal_idx <= temporal_layer \|\| temporal_idx == kNoTemporalIdx)
	frames++;
	}
	return frames;
	}

	size_t SumPayloadBytesWithinTemporalLayer(int temporal_layer) {
	size_t payload_size = 0;
	for (size_t i = 0; i < frame_data_.size(); ++i) {
	EXPECT_EQ(kVideoCodecVP8, frame_data_[i].codec_specific_info.codecType);
	const uint8_t temporal_idx =
	frame_data_[i].codec_specific_info.codecSpecific.VP8.temporalIdx;
	if (temporal_idx <= temporal_layer \|\| temporal_idx == kNoTemporalIdx)
	payload_size += frame_data_[i].payload_size;
	}
	return payload_size;
	}

	Clock* clock_;
	int64_t start_time_ms_;
	vector<FrameData> frame_data_;
	};

	class TestVideoSender : public ::testing::Test {
	protected:
	// Note: simulated clock starts at 1 seconds, since parts of webrtc use 0 as
	// a special case (e.g. frame rate in media optimization).
	TestVideoSender() : clock_(1000), encoded_frame_callback_(&clock_) {}

	void SetUp() override {
	sender_.reset(new VideoSender(&clock_, &encoded_frame_callback_));
	}

	void AddFrame() {
	assert(generator_.get());
	sender_->AddVideoFrame(*generator_->NextFrame(), nullptr,
	encoder_ ? absl::optional<VideoEncoder::EncoderInfo>(
	encoder_->GetEncoderInfo())
	: absl::nullopt);
	}

	SimulatedClock clock_;
	EncodedImageCallbackImpl encoded_frame_callback_;
	// Used by subclassing tests, need to outlive sender_.
	std::unique_ptr<VideoEncoder> encoder_;
	std::unique_ptr<VideoSender> sender_;
	std::unique_ptr<FrameGenerator> generator_;
	};

	class TestVideoSenderWithMockEncoder : public TestVideoSender {
	public:
	TestVideoSenderWithMockEncoder() {}
	~TestVideoSenderWithMockEncoder() override {}

	protected:
	void SetUp() override {
	TestVideoSender::SetUp();
	sender_->RegisterExternalEncoder(&encoder_, false);
	webrtc::test::CodecSettings(kVideoCodecVP8, &settings_);
	settings_.numberOfSimulcastStreams = kNumberOfStreams;
	ConfigureStream(kDefaultWidth / 4, kDefaultHeight / 4, 100,
	&settings_.simulcastStream[0]);
	ConfigureStream(kDefaultWidth / 2, kDefaultHeight / 2, 500,
	&settings_.simulcastStream[1]);
	ConfigureStream(kDefaultWidth, kDefaultHeight, 1200,
	&settings_.simulcastStream[2]);
	settings_.plType = kUnusedPayloadType; // Use the mocked encoder.
	generator_.reset(
	new EmptyFrameGenerator(settings_.width, settings_.height));
	EXPECT_EQ(0, sender_->RegisterSendCodec(&settings_, 1, 1200));
	rate_allocator_.reset(new DefaultVideoBitrateAllocator(settings_));
	}

	void TearDown() override { sender_.reset(); }

	void ExpectIntraRequest(int stream) {
	ExpectEncodeWithFrameTypes(stream, false);
	}

	void ExpectInitialKeyFrames() { ExpectEncodeWithFrameTypes(-1, true); }

	void ExpectEncodeWithFrameTypes(int intra_request_stream, bool first_frame) {
	if (intra_request_stream == -1) {
	// No intra request expected, keyframes on first frame.
	FrameType frame_type = first_frame ? kVideoFrameKey : kVideoFrameDelta;
	EXPECT_CALL(
	encoder_,
	Encode(_, _,
	Pointee(ElementsAre(frame_type, frame_type, frame_type))))
	.Times(1)
	.WillRepeatedly(Return(0));
	return;
	}
	ASSERT_FALSE(first_frame);
	ASSERT_GE(intra_request_stream, 0);
	ASSERT_LT(intra_request_stream, kNumberOfStreams);
	std::vector<FrameType> frame_types(kNumberOfStreams, kVideoFrameDelta);
	frame_types[intra_request_stream] = kVideoFrameKey;
	EXPECT_CALL(
	encoder_,
	Encode(_, _,
	Pointee(ElementsAreArray(&frame_types[0], frame_types.size()))))
	.Times(1)
	.WillRepeatedly(Return(0));
	}

	static void ConfigureStream(int width,
	int height,
	int max_bitrate,
	SimulcastStream* stream) {
	assert(stream);
	stream->width = width;
	stream->height = height;
	stream->maxBitrate = max_bitrate;
	stream->numberOfTemporalLayers = kNumberOfLayers;
	stream->qpMax = 45;
	}

	VideoCodec settings_;
	NiceMock<MockVideoEncoder> encoder_;
	std::unique_ptr<DefaultVideoBitrateAllocator> rate_allocator_;
	};

	TEST_F(TestVideoSenderWithMockEncoder, TestIntraRequests) {
	// Initial request should be all keyframes.
	ExpectInitialKeyFrames();
	AddFrame();
	EXPECT_EQ(0, sender_->IntraFrameRequest(0));
	ExpectIntraRequest(0);
	AddFrame();
	ExpectIntraRequest(-1);
	AddFrame();

	EXPECT_EQ(0, sender_->IntraFrameRequest(1));
	ExpectIntraRequest(1);
	AddFrame();
	ExpectIntraRequest(-1);
	AddFrame();

	EXPECT_EQ(0, sender_->IntraFrameRequest(2));
	ExpectIntraRequest(2);
	AddFrame();
	ExpectIntraRequest(-1);
	AddFrame();

	EXPECT_EQ(-1, sender_->IntraFrameRequest(3));
	ExpectIntraRequest(-1);
	AddFrame();
	}

	TEST_F(TestVideoSenderWithMockEncoder, TestSetRate) {
	// Let actual fps be half of max, so it can be distinguished from default.
	const uint32_t kActualFrameRate = settings_.maxFramerate / 2;
	const int64_t kFrameIntervalMs = 1000 / kActualFrameRate;
	const uint32_t new_bitrate_kbps = settings_.startBitrate + 300;

	// Initial frame rate is taken from config, as we have no data yet.
	VideoBitrateAllocation new_rate_allocation = rate_allocator_->GetAllocation(
	new_bitrate_kbps * 1000, settings_.maxFramerate);
	EXPECT_CALL(encoder_,
	SetRateAllocation(new_rate_allocation, settings_.maxFramerate))
	.Times(1)
	.WillOnce(Return(0));
	sender_->SetChannelParameters(new_bitrate_kbps * 1000, 0, 200,
	rate_allocator_.get(), nullptr);
	AddFrame();
	clock_.AdvanceTimeMilliseconds(kFrameIntervalMs);

	// Expect no call to encoder_.SetRates if the new bitrate is zero.
	EXPECT_CALL(encoder_, SetRateAllocation(_, _)).Times(0);
	sender_->SetChannelParameters(0, 0, 200, rate_allocator_.get(), nullptr);
	AddFrame();
	}

	TEST_F(TestVideoSenderWithMockEncoder, TestIntraRequestsInternalCapture) {
	// De-register current external encoder.
	sender_->RegisterExternalEncoder(nullptr, false);
	// Register encoder with internal capture.
	sender_->RegisterExternalEncoder(&encoder_, true);
	EXPECT_EQ(0, sender_->RegisterSendCodec(&settings_, 1, 1200));
	// Initial request should be all keyframes.
	ExpectInitialKeyFrames();
	AddFrame();
	ExpectIntraRequest(0);
	EXPECT_EQ(0, sender_->IntraFrameRequest(0));
	ExpectIntraRequest(1);
	EXPECT_EQ(0, sender_->IntraFrameRequest(1));
	ExpectIntraRequest(2);
	EXPECT_EQ(0, sender_->IntraFrameRequest(2));
	// No requests expected since these indices are out of bounds.
	EXPECT_EQ(-1, sender_->IntraFrameRequest(3));
	}

	TEST_F(TestVideoSenderWithMockEncoder, TestEncoderParametersForInternalSource) {
	// De-register current external encoder.
	sender_->RegisterExternalEncoder(nullptr, false);
	// Register encoder with internal capture.
	sender_->RegisterExternalEncoder(&encoder_, true);
	EXPECT_EQ(0, sender_->RegisterSendCodec(&settings_, 1, 1200));
	// Update encoder bitrate parameters. We expect that to immediately call
	// SetRates on the encoder without waiting for AddFrame processing.
	const uint32_t new_bitrate_kbps = settings_.startBitrate + 300;
	VideoBitrateAllocation new_rate_allocation = rate_allocator_->GetAllocation(
	new_bitrate_kbps * 1000, settings_.maxFramerate);
	EXPECT_CALL(encoder_, SetRateAllocation(new_rate_allocation, _))
	.Times(1)
	.WillOnce(Return(0));
	sender_->SetChannelParameters(new_bitrate_kbps * 1000, 0, 200,
	rate_allocator_.get(), nullptr);
	}

	TEST_F(TestVideoSenderWithMockEncoder,
	NoRedundantSetChannelParameterOrSetRatesCalls) {
	const uint8_t kLossRate = 4;
	const uint8_t kRtt = 200;
	const int64_t kRateStatsWindowMs = 2000;
	const uint32_t kInputFps = 20;
	int64_t start_time = clock_.TimeInMilliseconds();
	// Expect initial call to SetChannelParameters. Rates are initialized through
	// InitEncode and expects no additional call before the framerate (or bitrate)
	// updates.
	sender_->SetChannelParameters(settings_.startBitrate * 1000, kLossRate, kRtt,
	rate_allocator_.get(), nullptr);
	while (clock_.TimeInMilliseconds() < start_time + kRateStatsWindowMs) {
	AddFrame();
	clock_.AdvanceTimeMilliseconds(1000 / kInputFps);
	}

	// Call to SetChannelParameters with changed bitrate should call encoder
	// SetRates but not encoder SetChannelParameters (that are unchanged).
	uint32_t new_bitrate_bps = 2 * settings_.startBitrate * 1000;
	VideoBitrateAllocation new_rate_allocation =
	rate_allocator_->GetAllocation(new_bitrate_bps, kInputFps);
	EXPECT_CALL(encoder_, SetRateAllocation(new_rate_allocation, kInputFps))
	.Times(1)
	.WillOnce(Return(0));
	sender_->SetChannelParameters(new_bitrate_bps, kLossRate, kRtt,
	rate_allocator_.get(), nullptr);
	AddFrame();
	}

	class TestVideoSenderWithVp8 : public TestVideoSender {
	public:
	TestVideoSenderWithVp8()
	: codec_bitrate_kbps_(300), available_bitrate_kbps_(1000) {}

	void SetUp() override {
	TestVideoSender::SetUp();

	const char* input_video = "foreman_cif";
	const int width = 352;
	const int height = 288;
	generator_ = FrameGenerator::CreateFromYuvFile(
	std::vector<std::string>(1, test::ResourcePath(input_video, "yuv")),
	width, height, 1);

	codec_ = MakeVp8VideoCodec(width, height, 3);
	codec_.minBitrate = 10;
	codec_.startBitrate = codec_bitrate_kbps_;
	codec_.maxBitrate = codec_bitrate_kbps_;

	rate_allocator_.reset(new SimulcastRateAllocator(codec_));

	encoder_ = VP8Encoder::Create();
	sender_->RegisterExternalEncoder(encoder_.get(), false);
	EXPECT_EQ(0, sender_->RegisterSendCodec(&codec_, 1, 1200));
	}

	static VideoCodec MakeVp8VideoCodec(int width,
	int height,
	int temporal_layers) {
	VideoCodec codec;
	webrtc::test::CodecSettings(kVideoCodecVP8, &codec);
	codec.width = width;
	codec.height = height;
	codec.VP8()->numberOfTemporalLayers = temporal_layers;
	return codec;
	}

	void InsertFrames(float framerate, float seconds) {
	for (int i = 0; i < seconds * framerate; ++i) {
	clock_.AdvanceTimeMilliseconds(1000.0f / framerate);
	AddFrame();
	// SetChannelParameters needs to be called frequently to propagate
	// framerate from the media optimization into the encoder.
	// Note: SetChannelParameters fails if less than 2 frames are in the
	// buffer since it will fail to calculate the framerate.
	if (i != 0) {
	EXPECT_EQ(VCM_OK, sender_->SetChannelParameters(
	available_bitrate_kbps_ * 1000, 0, 200,
	rate_allocator_.get(), nullptr));
	}
	}
	}

	Vp8StreamInfo SimulateWithFramerate(float framerate) {
	const float short_simulation_interval = 5.0;
	const float long_simulation_interval = 10.0;
	// It appears that this 5 seconds simulation is needed to allow
	// bitrate and framerate to stabilize.
	InsertFrames(framerate, short_simulation_interval);
	encoded_frame_callback_.Reset();

	InsertFrames(framerate, long_simulation_interval);
	return encoded_frame_callback_.CalculateVp8StreamInfo();
	}

	protected:
	VideoCodec codec_;
	int codec_bitrate_kbps_;
	int available_bitrate_kbps_;
	std::unique_ptr<SimulcastRateAllocator> rate_allocator_;
	};

	#if defined(WEBRTC_ANDROID) \|\| defined(WEBRTC_IOS)
	#define MAYBE_FixedTemporalLayersStrategy DISABLED_FixedTemporalLayersStrategy
	#else
	#define MAYBE_FixedTemporalLayersStrategy FixedTemporalLayersStrategy
	#endif
	TEST_F(TestVideoSenderWithVp8, MAYBE_FixedTemporalLayersStrategy) {
	const int low_b =
	codec_bitrate_kbps_ *
	webrtc::SimulcastRateAllocator::GetTemporalRateAllocation(3, 0);
	const int mid_b =
	codec_bitrate_kbps_ *
	webrtc::SimulcastRateAllocator::GetTemporalRateAllocation(3, 1);
	const int high_b =
	codec_bitrate_kbps_ *
	webrtc::SimulcastRateAllocator::GetTemporalRateAllocation(3, 2);
	{
	Vp8StreamInfo expected = {{7.5, 15.0, 30.0}, {low_b, mid_b, high_b}};
	EXPECT_THAT(SimulateWithFramerate(30.0), MatchesVp8StreamInfo(expected));
	}
	{
	Vp8StreamInfo expected = {{3.75, 7.5, 15.0}, {low_b, mid_b, high_b}};
	EXPECT_THAT(SimulateWithFramerate(15.0), MatchesVp8StreamInfo(expected));
	}
	}

	} // namespace
	} // namespace vcm
	} // namespace webrtc