modules/video_coding/utility/bandwidth_quality_scaler_unittest.cc - src.git - Git at Google

 /*
  *  Copyright 2021 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 "modules/video_coding/utility/bandwidth_quality_scaler.h"

 #include <memory>
 #include <string>

 #include "rtc_base/checks.h"
 #include "rtc_base/event.h"
 #include "rtc_base/experiments/encoder_info_settings.h"
 #include "rtc_base/task_queue_for_test.h"
 #include "rtc_base/time_utils.h"
 #include "test/field_trial.h"
 #include "test/gtest.h"

 namespace webrtc {

 namespace {
 constexpr int kFramerateFps = 30;
 constexpr int kDefaultBitrateStateUpdateIntervalSeconds = 5;
 constexpr int kDefaultEncodeDeltaTimeMs = 33;  // 1/30(s) => 33(ms)

 }  // namespace

 class FakeBandwidthQualityScalerHandler
     : public BandwidthQualityScalerUsageHandlerInterface {
  public:
   ~FakeBandwidthQualityScalerHandler() override = default;
   void OnReportUsageBandwidthHigh() override {
     adapt_down_event_count_++;
     event_.Set();
   }

   void OnReportUsageBandwidthLow() override {
     adapt_up_event_count_++;
     event_.Set();
   }

   rtc::Event event_;
   int adapt_up_event_count_ = 0;
   int adapt_down_event_count_ = 0;
 };

 class BandwidthQualityScalerUnderTest : public BandwidthQualityScaler {
  public:
   explicit BandwidthQualityScalerUnderTest(
       BandwidthQualityScalerUsageHandlerInterface* handler)
       : BandwidthQualityScaler(handler) {}

   int GetBitrateStateUpdateIntervalMs() {
     return this->kBitrateStateUpdateInterval.ms() + 200;
   }
 };

 class BandwidthQualityScalerTest
     : public ::testing::Test,
       public ::testing::WithParamInterface<std::string> {
  protected:
   enum ScaleDirection {
     kKeepScaleNormalBandwidth,
     kKeepScaleAboveMaxBandwidth,
     kKeepScaleUnderMinBandwidth,
   };

   enum FrameType {
     kKeyFrame,
     kNormalFrame,
     kNormalFrame_Overuse,
     kNormalFrame_Underuse,
   };
   struct FrameConfig {
     FrameConfig(int frame_num,
                 FrameType frame_type,
                 int actual_width,
                 int actual_height)
         : frame_num(frame_num),
           frame_type(frame_type),
           actual_width(actual_width),
           actual_height(actual_height) {}

     int frame_num;
     FrameType frame_type;
     int actual_width;
     int actual_height;
   };

   BandwidthQualityScalerTest()
       : scoped_field_trial_(GetParam()),
         task_queue_("BandwidthQualityScalerTestQueue"),
         handler_(std::make_unique<FakeBandwidthQualityScalerHandler>()) {
     task_queue_.SendTask(
         [this] {
           bandwidth_quality_scaler_ =
               std::unique_ptr<BandwidthQualityScalerUnderTest>(
                   new BandwidthQualityScalerUnderTest(handler_.get()));
           bandwidth_quality_scaler_->SetResolutionBitrateLimits(
               EncoderInfoSettings::
                   GetDefaultSinglecastBitrateLimitsWhenQpIsUntrusted());
           // Only for testing. Set first_timestamp_ in RateStatistics to 0.
           bandwidth_quality_scaler_->ReportEncodeInfo(0, 0, 0, 0);
         },
         RTC_FROM_HERE);
   }

   ~BandwidthQualityScalerTest() {
     task_queue_.SendTask([this] { bandwidth_quality_scaler_ = nullptr; },
                          RTC_FROM_HERE);
   }

   int GetFrameSizeBytes(
       const FrameConfig& config,
       const VideoEncoder::ResolutionBitrateLimits& bitrate_limits) {
     int scale = 8 * kFramerateFps;
     switch (config.frame_type) {
       case FrameType::kKeyFrame: {
         // 4 is experimental value. Based on the test, the number of bytes of
         // the key frame is about four times of the normal frame
         return bitrate_limits.max_bitrate_bps * 4 / scale;
       }
       case FrameType::kNormalFrame_Overuse: {
         return bitrate_limits.max_bitrate_bps * 3 / 2 / scale;
       }
       case FrameType::kNormalFrame_Underuse: {
         return bitrate_limits.min_start_bitrate_bps * 3 / 4 / scale;
       }
       case FrameType::kNormalFrame: {
         return (bitrate_limits.max_bitrate_bps +
                 bitrate_limits.min_start_bitrate_bps) /
                2 / scale;
       }
     }
     return -1;
   }

   absl::optional<VideoEncoder::ResolutionBitrateLimits>
   GetDefaultSuitableBitrateLimit(int frame_size_pixels) {
     return EncoderInfoSettings::
         GetSinglecastBitrateLimitForResolutionWhenQpIsUntrusted(
             frame_size_pixels,
             EncoderInfoSettings::
                 GetDefaultSinglecastBitrateLimitsWhenQpIsUntrusted());
   }

   void TriggerBandwidthQualityScalerTest(
       const std::vector<FrameConfig>& frame_configs) {
     task_queue_.SendTask(
         [frame_configs, this] {
           RTC_CHECK(!frame_configs.empty());

           int total_frame_nums = 0;
           for (const FrameConfig& frame_config : frame_configs) {
             total_frame_nums += frame_config.frame_num;
           }

           EXPECT_EQ(kFramerateFps * kDefaultBitrateStateUpdateIntervalSeconds,
                     total_frame_nums);

           uint32_t time_send_to_scaler_ms_ = rtc::TimeMillis();
           for (size_t i = 0; i < frame_configs.size(); ++i) {
             const FrameConfig& config = frame_configs[i];
             absl::optional<VideoEncoder::ResolutionBitrateLimits>
                 suitable_bitrate = GetDefaultSuitableBitrateLimit(
                     config.actual_width * config.actual_height);
             EXPECT_TRUE(suitable_bitrate);
             for (int j = 0; j <= config.frame_num; ++j) {
               time_send_to_scaler_ms_ += kDefaultEncodeDeltaTimeMs;
               int frame_size_bytes =
                   GetFrameSizeBytes(config, suitable_bitrate.value());
               RTC_CHECK(frame_size_bytes > 0);
               bandwidth_quality_scaler_->ReportEncodeInfo(
                   frame_size_bytes, time_send_to_scaler_ms_,
                   config.actual_width, config.actual_height);
             }
           }
         },
         RTC_FROM_HERE);
   }

   test::ScopedFieldTrials scoped_field_trial_;
   TaskQueueForTest task_queue_;
   std::unique_ptr<BandwidthQualityScalerUnderTest> bandwidth_quality_scaler_;
   std::unique_ptr<FakeBandwidthQualityScalerHandler> handler_;
 };

 INSTANTIATE_TEST_SUITE_P(
     FieldTrials,
     BandwidthQualityScalerTest,
     ::testing::Values("WebRTC-Video-BandwidthQualityScalerSettings/"
                       "bitrate_state_update_interval_s_:1/",
                       "WebRTC-Video-BandwidthQualityScalerSettings/"
                       "bitrate_state_update_interval_s_:2/"));

 TEST_P(BandwidthQualityScalerTest, AllNormalFrame_640x360) {
   const std::vector<FrameConfig> frame_configs{
       FrameConfig(150, FrameType::kNormalFrame, 640, 360)};
   TriggerBandwidthQualityScalerTest(frame_configs);

   // When resolution is 640*360, experimental working bitrate range is
   // [500000,800000] bps. Encoded bitrate is 654253, so it falls in the range
   // without any operation(up/down).
   EXPECT_FALSE(handler_->event_.Wait(
       bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
   EXPECT_EQ(0, handler_->adapt_down_event_count_);
   EXPECT_EQ(0, handler_->adapt_up_event_count_);
 }

 TEST_P(BandwidthQualityScalerTest, AllNoramlFrame_AboveMaxBandwidth_640x360) {
   const std::vector<FrameConfig> frame_configs{
       FrameConfig(150, FrameType::kNormalFrame_Overuse, 640, 360)};
   TriggerBandwidthQualityScalerTest(frame_configs);

   // When resolution is 640*360, experimental working bitrate range is
   // [500000,800000] bps. Encoded bitrate is 1208000 > 800000 * 0.95, so it
   // triggers adapt_up_event_count_.
   EXPECT_TRUE(handler_->event_.Wait(
       bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
   EXPECT_EQ(0, handler_->adapt_down_event_count_);
   EXPECT_EQ(1, handler_->adapt_up_event_count_);
 }

 TEST_P(BandwidthQualityScalerTest, AllNormalFrame_Underuse_640x360) {
   const std::vector<FrameConfig> frame_configs{
       FrameConfig(150, FrameType::kNormalFrame_Underuse, 640, 360)};
   TriggerBandwidthQualityScalerTest(frame_configs);

   // When resolution is 640*360, experimental working bitrate range is
   // [500000,800000] bps. Encoded bitrate is 377379 < 500000 * 0.8, so it
   // triggers adapt_down_event_count_.
   EXPECT_TRUE(handler_->event_.Wait(
       bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
   EXPECT_EQ(1, handler_->adapt_down_event_count_);
   EXPECT_EQ(0, handler_->adapt_up_event_count_);
 }

 TEST_P(BandwidthQualityScalerTest, FixedFrameTypeTest1_640x360) {
   const std::vector<FrameConfig> frame_configs{
       FrameConfig(5, FrameType::kNormalFrame_Underuse, 640, 360),
       FrameConfig(110, FrameType::kNormalFrame, 640, 360),
       FrameConfig(20, FrameType::kNormalFrame_Overuse, 640, 360),
       FrameConfig(15, FrameType::kKeyFrame, 640, 360),
   };
   TriggerBandwidthQualityScalerTest(frame_configs);

   // When resolution is 640*360, experimental working bitrate range is
   // [500000,800000] bps. Encoded bitrate is 1059462 > 800000 * 0.95, so it
   // triggers adapt_up_event_count_.
   EXPECT_TRUE(handler_->event_.Wait(
       bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
   EXPECT_EQ(0, handler_->adapt_down_event_count_);
   EXPECT_EQ(1, handler_->adapt_up_event_count_);
 }

 TEST_P(BandwidthQualityScalerTest, FixedFrameTypeTest2_640x360) {
   const std::vector<FrameConfig> frame_configs{
       FrameConfig(10, FrameType::kNormalFrame_Underuse, 640, 360),
       FrameConfig(50, FrameType::kNormalFrame, 640, 360),
       FrameConfig(5, FrameType::kKeyFrame, 640, 360),
       FrameConfig(85, FrameType::kNormalFrame_Overuse, 640, 360),
   };
   TriggerBandwidthQualityScalerTest(frame_configs);

   // When resolution is 640*360, experimental working bitrate range is
   // [500000,800000] bps. Encoded bitrate is 1059462 > 800000 * 0.95, so it
   // triggers adapt_up_event_count_.
   EXPECT_TRUE(handler_->event_.Wait(
       bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
   EXPECT_EQ(0, handler_->adapt_down_event_count_);
   EXPECT_EQ(1, handler_->adapt_up_event_count_);
 }

 }  // namespace webrtc
	/*
	* Copyright 2021 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 "modules/video_coding/utility/bandwidth_quality_scaler.h"

	#include <memory>
	#include <string>

	#include "rtc_base/checks.h"
	#include "rtc_base/event.h"
	#include "rtc_base/experiments/encoder_info_settings.h"
	#include "rtc_base/task_queue_for_test.h"
	#include "rtc_base/time_utils.h"
	#include "test/field_trial.h"
	#include "test/gtest.h"

	namespace webrtc {

	namespace {
	constexpr int kFramerateFps = 30;
	constexpr int kDefaultBitrateStateUpdateIntervalSeconds = 5;
	constexpr int kDefaultEncodeDeltaTimeMs = 33; // 1/30(s) => 33(ms)

	} // namespace

	class FakeBandwidthQualityScalerHandler
	: public BandwidthQualityScalerUsageHandlerInterface {
	public:
	~FakeBandwidthQualityScalerHandler() override = default;
	void OnReportUsageBandwidthHigh() override {
	adapt_down_event_count_++;
	event_.Set();
	}

	void OnReportUsageBandwidthLow() override {
	adapt_up_event_count_++;
	event_.Set();
	}

	rtc::Event event_;
	int adapt_up_event_count_ = 0;
	int adapt_down_event_count_ = 0;
	};

	class BandwidthQualityScalerUnderTest : public BandwidthQualityScaler {
	public:
	explicit BandwidthQualityScalerUnderTest(
	BandwidthQualityScalerUsageHandlerInterface* handler)
	: BandwidthQualityScaler(handler) {}

	int GetBitrateStateUpdateIntervalMs() {
	return this->kBitrateStateUpdateInterval.ms() + 200;
	}
	};

	class BandwidthQualityScalerTest
	: public ::testing::Test,
	public ::testing::WithParamInterface<std::string> {
	protected:
	enum ScaleDirection {
	kKeepScaleNormalBandwidth,
	kKeepScaleAboveMaxBandwidth,
	kKeepScaleUnderMinBandwidth,
	};

	enum FrameType {
	kKeyFrame,
	kNormalFrame,
	kNormalFrame_Overuse,
	kNormalFrame_Underuse,
	};
	struct FrameConfig {
	FrameConfig(int frame_num,
	FrameType frame_type,
	int actual_width,
	int actual_height)
	: frame_num(frame_num),
	frame_type(frame_type),
	actual_width(actual_width),
	actual_height(actual_height) {}

	int frame_num;
	FrameType frame_type;
	int actual_width;
	int actual_height;
	};

	BandwidthQualityScalerTest()
	: scoped_field_trial_(GetParam()),
	task_queue_("BandwidthQualityScalerTestQueue"),
	handler_(std::make_unique<FakeBandwidthQualityScalerHandler>()) {
	task_queue_.SendTask(
	[this] {
	bandwidth_quality_scaler_ =
	std::unique_ptr<BandwidthQualityScalerUnderTest>(
	new BandwidthQualityScalerUnderTest(handler_.get()));
	bandwidth_quality_scaler_->SetResolutionBitrateLimits(
	EncoderInfoSettings::
	GetDefaultSinglecastBitrateLimitsWhenQpIsUntrusted());
	// Only for testing. Set first_timestamp_ in RateStatistics to 0.
	bandwidth_quality_scaler_->ReportEncodeInfo(0, 0, 0, 0);
	},
	RTC_FROM_HERE);
	}

	~BandwidthQualityScalerTest() {
	task_queue_.SendTask([this] { bandwidth_quality_scaler_ = nullptr; },
	RTC_FROM_HERE);
	}

	int GetFrameSizeBytes(
	const FrameConfig& config,
	const VideoEncoder::ResolutionBitrateLimits& bitrate_limits) {
	int scale = 8 * kFramerateFps;
	switch (config.frame_type) {
	case FrameType::kKeyFrame: {
	// 4 is experimental value. Based on the test, the number of bytes of
	// the key frame is about four times of the normal frame
	return bitrate_limits.max_bitrate_bps * 4 / scale;
	}
	case FrameType::kNormalFrame_Overuse: {
	return bitrate_limits.max_bitrate_bps * 3 / 2 / scale;
	}
	case FrameType::kNormalFrame_Underuse: {
	return bitrate_limits.min_start_bitrate_bps * 3 / 4 / scale;
	}
	case FrameType::kNormalFrame: {
	return (bitrate_limits.max_bitrate_bps +
	bitrate_limits.min_start_bitrate_bps) /
	2 / scale;
	}
	}
	return -1;
	}

	absl::optional<VideoEncoder::ResolutionBitrateLimits>
	GetDefaultSuitableBitrateLimit(int frame_size_pixels) {
	return EncoderInfoSettings::
	GetSinglecastBitrateLimitForResolutionWhenQpIsUntrusted(
	frame_size_pixels,
	EncoderInfoSettings::
	GetDefaultSinglecastBitrateLimitsWhenQpIsUntrusted());
	}

	void TriggerBandwidthQualityScalerTest(
	const std::vector<FrameConfig>& frame_configs) {
	task_queue_.SendTask(
	[frame_configs, this] {
	RTC_CHECK(!frame_configs.empty());

	int total_frame_nums = 0;
	for (const FrameConfig& frame_config : frame_configs) {
	total_frame_nums += frame_config.frame_num;
	}

	EXPECT_EQ(kFramerateFps * kDefaultBitrateStateUpdateIntervalSeconds,
	total_frame_nums);

	uint32_t time_send_to_scaler_ms_ = rtc::TimeMillis();
	for (size_t i = 0; i < frame_configs.size(); ++i) {
	const FrameConfig& config = frame_configs[i];
	absl::optional<VideoEncoder::ResolutionBitrateLimits>
	suitable_bitrate = GetDefaultSuitableBitrateLimit(
	config.actual_width * config.actual_height);
	EXPECT_TRUE(suitable_bitrate);
	for (int j = 0; j <= config.frame_num; ++j) {
	time_send_to_scaler_ms_ += kDefaultEncodeDeltaTimeMs;
	int frame_size_bytes =
	GetFrameSizeBytes(config, suitable_bitrate.value());
	RTC_CHECK(frame_size_bytes > 0);
	bandwidth_quality_scaler_->ReportEncodeInfo(
	frame_size_bytes, time_send_to_scaler_ms_,
	config.actual_width, config.actual_height);
	}
	}
	},
	RTC_FROM_HERE);
	}

	test::ScopedFieldTrials scoped_field_trial_;
	TaskQueueForTest task_queue_;
	std::unique_ptr<BandwidthQualityScalerUnderTest> bandwidth_quality_scaler_;
	std::unique_ptr<FakeBandwidthQualityScalerHandler> handler_;
	};

	INSTANTIATE_TEST_SUITE_P(
	FieldTrials,
	BandwidthQualityScalerTest,
	::testing::Values("WebRTC-Video-BandwidthQualityScalerSettings/"
	"bitrate_state_update_interval_s_:1/",
	"WebRTC-Video-BandwidthQualityScalerSettings/"
	"bitrate_state_update_interval_s_:2/"));

	TEST_P(BandwidthQualityScalerTest, AllNormalFrame_640x360) {
	const std::vector<FrameConfig> frame_configs{
	FrameConfig(150, FrameType::kNormalFrame, 640, 360)};
	TriggerBandwidthQualityScalerTest(frame_configs);

	// When resolution is 640*360, experimental working bitrate range is
	// [500000,800000] bps. Encoded bitrate is 654253, so it falls in the range
	// without any operation(up/down).
	EXPECT_FALSE(handler_->event_.Wait(
	bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
	EXPECT_EQ(0, handler_->adapt_down_event_count_);
	EXPECT_EQ(0, handler_->adapt_up_event_count_);
	}

	TEST_P(BandwidthQualityScalerTest, AllNoramlFrame_AboveMaxBandwidth_640x360) {
	const std::vector<FrameConfig> frame_configs{
	FrameConfig(150, FrameType::kNormalFrame_Overuse, 640, 360)};
	TriggerBandwidthQualityScalerTest(frame_configs);

	// When resolution is 640*360, experimental working bitrate range is
	// [500000,800000] bps. Encoded bitrate is 1208000 > 800000 * 0.95, so it
	// triggers adapt_up_event_count_.
	EXPECT_TRUE(handler_->event_.Wait(
	bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
	EXPECT_EQ(0, handler_->adapt_down_event_count_);
	EXPECT_EQ(1, handler_->adapt_up_event_count_);
	}

	TEST_P(BandwidthQualityScalerTest, AllNormalFrame_Underuse_640x360) {
	const std::vector<FrameConfig> frame_configs{
	FrameConfig(150, FrameType::kNormalFrame_Underuse, 640, 360)};
	TriggerBandwidthQualityScalerTest(frame_configs);

	// When resolution is 640*360, experimental working bitrate range is
	// [500000,800000] bps. Encoded bitrate is 377379 < 500000 * 0.8, so it
	// triggers adapt_down_event_count_.
	EXPECT_TRUE(handler_->event_.Wait(
	bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
	EXPECT_EQ(1, handler_->adapt_down_event_count_);
	EXPECT_EQ(0, handler_->adapt_up_event_count_);
	}

	TEST_P(BandwidthQualityScalerTest, FixedFrameTypeTest1_640x360) {
	const std::vector<FrameConfig> frame_configs{
	FrameConfig(5, FrameType::kNormalFrame_Underuse, 640, 360),
	FrameConfig(110, FrameType::kNormalFrame, 640, 360),
	FrameConfig(20, FrameType::kNormalFrame_Overuse, 640, 360),
	FrameConfig(15, FrameType::kKeyFrame, 640, 360),
	};
	TriggerBandwidthQualityScalerTest(frame_configs);

	// When resolution is 640*360, experimental working bitrate range is
	// [500000,800000] bps. Encoded bitrate is 1059462 > 800000 * 0.95, so it
	// triggers adapt_up_event_count_.
	EXPECT_TRUE(handler_->event_.Wait(
	bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
	EXPECT_EQ(0, handler_->adapt_down_event_count_);
	EXPECT_EQ(1, handler_->adapt_up_event_count_);
	}

	TEST_P(BandwidthQualityScalerTest, FixedFrameTypeTest2_640x360) {
	const std::vector<FrameConfig> frame_configs{
	FrameConfig(10, FrameType::kNormalFrame_Underuse, 640, 360),
	FrameConfig(50, FrameType::kNormalFrame, 640, 360),
	FrameConfig(5, FrameType::kKeyFrame, 640, 360),
	FrameConfig(85, FrameType::kNormalFrame_Overuse, 640, 360),
	};
	TriggerBandwidthQualityScalerTest(frame_configs);

	// When resolution is 640*360, experimental working bitrate range is
	// [500000,800000] bps. Encoded bitrate is 1059462 > 800000 * 0.95, so it
	// triggers adapt_up_event_count_.
	EXPECT_TRUE(handler_->event_.Wait(
	bandwidth_quality_scaler_->GetBitrateStateUpdateIntervalMs()));
	EXPECT_EQ(0, handler_->adapt_down_event_count_);
	EXPECT_EQ(1, handler_->adapt_up_event_count_);
	}

	} // namespace webrtc