webrtc/modules/remote_bitrate_estimator/bwe_simulations.cc - src - 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 "testing/gtest/include/gtest/gtest.h"
 #include "webrtc/base/constructormagic.h"
 #include "webrtc/modules/remote_bitrate_estimator/include/remote_bitrate_estimator.h"
 #include "webrtc/modules/remote_bitrate_estimator/test/bwe_test.h"
 #include "webrtc/modules/remote_bitrate_estimator/test/packet_receiver.h"
 #include "webrtc/modules/remote_bitrate_estimator/test/packet_sender.h"
 #include "webrtc/test/testsupport/fileutils.h"


 namespace webrtc {
 namespace testing {
 namespace bwe {
 #if BWE_TEST_LOGGING_COMPILE_TIME_ENABLE
 // This test fixture is used to instantiate tests running with adaptive video
 // senders.
 class BweSimulation : public BweTest,
                       public ::testing::TestWithParam<BandwidthEstimatorType> {
  public:
   BweSimulation()
       : BweTest(), random_(Clock::GetRealTimeClock()->TimeInMicroseconds()) {}
   virtual ~BweSimulation() {}

  protected:
   void SetUp() override {
     BweTest::SetUp();
     VerboseLogging(true);
   }

   Random random_;

  private:
   RTC_DISALLOW_COPY_AND_ASSIGN(BweSimulation);
 };

 INSTANTIATE_TEST_CASE_P(VideoSendersTest,
                         BweSimulation,
                         ::testing::Values(kRembEstimator,
                                           kFullSendSideEstimator,
                                           kNadaEstimator));

 TEST_P(BweSimulation, SprintUplinkTest) {
   AdaptiveVideoSource source(0, 30, 300, 0, 0);
   VideoSender sender(&uplink_, &source, GetParam());
   RateCounterFilter counter1(&uplink_, 0, "sender_output",
                              bwe_names[GetParam()]);
   TraceBasedDeliveryFilter filter(&uplink_, 0, "link_capacity");
   RateCounterFilter counter2(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   ASSERT_TRUE(filter.Init(test::ResourcePath("sprint-uplink", "rx")));
   RunFor(60 * 1000);
 }

 TEST_P(BweSimulation, Verizon4gDownlinkTest) {
   AdaptiveVideoSource source(0, 30, 300, 0, 0);
   VideoSender sender(&downlink_, &source, GetParam());
   RateCounterFilter counter1(&downlink_, 0, "sender_output",
                              bwe_names[GetParam()] + "_up");
   TraceBasedDeliveryFilter filter(&downlink_, 0, "link_capacity");
   RateCounterFilter counter2(&downlink_, 0, "Receiver",
                              bwe_names[GetParam()] + "_down");
   PacketReceiver receiver(&downlink_, 0, GetParam(), true, true);
   ASSERT_TRUE(filter.Init(test::ResourcePath("verizon4g-downlink", "rx")));
   RunFor(22 * 60 * 1000);
 }

 TEST_P(BweSimulation, Choke1000kbps500kbps1000kbpsBiDirectional) {
   const int kFlowIds[] = {0, 1};
   const size_t kNumFlows = sizeof(kFlowIds) / sizeof(kFlowIds[0]);

   AdaptiveVideoSource source(kFlowIds[0], 30, 300, 0, 0);
   VideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter choke(&uplink_, kFlowIds[0]);
   RateCounterFilter counter(&uplink_, kFlowIds[0], "Receiver_0",
                             bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, kFlowIds[0], GetParam(), true, false);

   AdaptiveVideoSource source2(kFlowIds[1], 30, 300, 0, 0);
   VideoSender sender2(&downlink_, &source2, GetParam());
   ChokeFilter choke2(&downlink_, kFlowIds[1]);
   DelayFilter delay(&downlink_, CreateFlowIds(kFlowIds, kNumFlows));
   RateCounterFilter counter2(&downlink_, kFlowIds[1], "Receiver_1",
                              bwe_names[GetParam()]);
   PacketReceiver receiver2(&downlink_, kFlowIds[1], GetParam(), true, false);

   choke2.set_capacity_kbps(500);
   delay.SetOneWayDelayMs(0);

   choke.set_capacity_kbps(1000);
   choke.set_max_delay_ms(500);
   RunFor(60 * 1000);
   choke.set_capacity_kbps(500);
   RunFor(60 * 1000);
   choke.set_capacity_kbps(1000);
   RunFor(60 * 1000);
 }

 TEST_P(BweSimulation, Choke1000kbps500kbps1000kbps) {
   AdaptiveVideoSource source(0, 30, 300, 0, 0);
   VideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter choke(&uplink_, 0);
   RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, false);

   choke.set_capacity_kbps(1000);
   choke.set_max_delay_ms(500);
   RunFor(60 * 1000);
   choke.set_capacity_kbps(500);
   RunFor(60 * 1000);
   choke.set_capacity_kbps(1000);
   RunFor(60 * 1000);
 }

 TEST_P(BweSimulation, PacerChoke1000kbps500kbps1000kbps) {
   AdaptiveVideoSource source(0, 30, 300, 0, 0);
   PacedVideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter filter(&uplink_, 0);
   RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   filter.set_capacity_kbps(1000);
   filter.set_max_delay_ms(500);
   RunFor(60 * 1000);
   filter.set_capacity_kbps(500);
   RunFor(60 * 1000);
   filter.set_capacity_kbps(1000);
   RunFor(60 * 1000);
 }

 TEST_P(BweSimulation, PacerChoke10000kbps) {
   PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000);
   PacedVideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter filter(&uplink_, 0);
   RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   filter.set_capacity_kbps(10000);
   filter.set_max_delay_ms(500);
   RunFor(60 * 1000);
 }

 TEST_P(BweSimulation, PacerChoke200kbps30kbps200kbps) {
   AdaptiveVideoSource source(0, 30, 300, 0, 0);
   PacedVideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter filter(&uplink_, 0);
   RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   filter.set_capacity_kbps(200);
   filter.set_max_delay_ms(500);
   RunFor(60 * 1000);
   filter.set_capacity_kbps(30);
   RunFor(60 * 1000);
   filter.set_capacity_kbps(200);
   RunFor(60 * 1000);
 }

 TEST_P(BweSimulation, Choke200kbps30kbps200kbps) {
   AdaptiveVideoSource source(0, 30, 300, 0, 0);
   VideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter filter(&uplink_, 0);
   RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   filter.set_capacity_kbps(200);
   filter.set_max_delay_ms(500);
   RunFor(60 * 1000);
   filter.set_capacity_kbps(30);
   RunFor(60 * 1000);
   filter.set_capacity_kbps(200);
   RunFor(60 * 1000);
 }

 TEST_P(BweSimulation, GoogleWifiTrace3Mbps) {
   AdaptiveVideoSource source(0, 30, 300, 0, 0);
   VideoSender sender(&uplink_, &source, GetParam());
   RateCounterFilter counter1(&uplink_, 0, "sender_output",
                              bwe_names[GetParam()]);
   TraceBasedDeliveryFilter filter(&uplink_, 0, "link_capacity");
   filter.set_max_delay_ms(500);
   RateCounterFilter counter2(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   ASSERT_TRUE(filter.Init(test::ResourcePath("google-wifi-3mbps", "rx")));
   RunFor(300 * 1000);
 }

 TEST_P(BweSimulation, LinearIncreasingCapacity) {
   PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000000);
   PacedVideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter filter(&uplink_, 0);
   RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   filter.set_max_delay_ms(500);
   const int kStartingCapacityKbps = 150;
   const int kEndingCapacityKbps = 1500;
   const int kStepKbps = 5;
   const int kStepTimeMs = 1000;

   for (int i = kStartingCapacityKbps; i <= kEndingCapacityKbps;
        i += kStepKbps) {
     filter.set_capacity_kbps(i);
     RunFor(kStepTimeMs);
   }
 }

 TEST_P(BweSimulation, LinearDecreasingCapacity) {
   PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000000);
   PacedVideoSender sender(&uplink_, &source, GetParam());
   ChokeFilter filter(&uplink_, 0);
   RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   filter.set_max_delay_ms(500);
   const int kStartingCapacityKbps = 1500;
   const int kEndingCapacityKbps = 150;
   const int kStepKbps = -5;
   const int kStepTimeMs = 1000;

   for (int i = kStartingCapacityKbps; i >= kEndingCapacityKbps;
        i += kStepKbps) {
     filter.set_capacity_kbps(i);
     RunFor(kStepTimeMs);
   }
 }

 TEST_P(BweSimulation, PacerGoogleWifiTrace3Mbps) {
   PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000);
   PacedVideoSender sender(&uplink_, &source, GetParam());
   RateCounterFilter counter1(&uplink_, 0, "sender_output",
                              bwe_names[GetParam()]);
   TraceBasedDeliveryFilter filter(&uplink_, 0, "link_capacity");
   filter.set_max_delay_ms(500);
   RateCounterFilter counter2(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
   PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
   ASSERT_TRUE(filter.Init(test::ResourcePath("google-wifi-3mbps", "rx")));
   RunFor(300 * 1000);
 }

 TEST_P(BweSimulation, SelfFairnessTest) {
   Random prng(Clock::GetRealTimeClock()->TimeInMicroseconds());
   const int kAllFlowIds[] = {0, 1, 2, 3};
   const size_t kNumFlows = sizeof(kAllFlowIds) / sizeof(kAllFlowIds[0]);
   std::unique_ptr<VideoSource> sources[kNumFlows];
   std::unique_ptr<VideoSender> senders[kNumFlows];
   for (size_t i = 0; i < kNumFlows; ++i) {
     // Streams started 20 seconds apart to give them different advantage when
     // competing for the bandwidth.
     sources[i].reset(new AdaptiveVideoSource(kAllFlowIds[i], 30, 300, 0,
                                              i * prng.Rand(39999)));
     senders[i].reset(new VideoSender(&uplink_, sources[i].get(), GetParam()));
   }

   ChokeFilter choke(&uplink_, CreateFlowIds(kAllFlowIds, kNumFlows));
   choke.set_capacity_kbps(1000);

   std::unique_ptr<RateCounterFilter> rate_counters[kNumFlows];
   for (size_t i = 0; i < kNumFlows; ++i) {
     rate_counters[i].reset(
         new RateCounterFilter(&uplink_, CreateFlowIds(&kAllFlowIds[i], 1),
                               "Receiver", bwe_names[GetParam()]));
   }

   RateCounterFilter total_utilization(
       &uplink_, CreateFlowIds(kAllFlowIds, kNumFlows), "total_utilization",
       "Total_link_utilization");

   std::unique_ptr<PacketReceiver> receivers[kNumFlows];
   for (size_t i = 0; i < kNumFlows; ++i) {
     receivers[i].reset(new PacketReceiver(&uplink_, kAllFlowIds[i], GetParam(),
                                           i == 0, false));
   }

   RunFor(30 * 60 * 1000);
 }

 TEST_P(BweSimulation, PacedSelfFairness50msTest) {
   const int64_t kAverageOffsetMs = 20 * 1000;
   const int kNumRmcatFlows = 4;
   int64_t offsets_ms[kNumRmcatFlows];
   offsets_ms[0] = random_.Rand(2 * kAverageOffsetMs);
   for (int i = 1; i < kNumRmcatFlows; ++i) {
     offsets_ms[i] = offsets_ms[i - 1] + random_.Rand(2 * kAverageOffsetMs);
   }
   RunFairnessTest(GetParam(), kNumRmcatFlows, 0, 1000, 3000, 50, 50, 0,
                   offsets_ms);
 }

 TEST_P(BweSimulation, PacedSelfFairness500msTest) {
   const int64_t kAverageOffsetMs = 20 * 1000;
   const int kNumRmcatFlows = 4;
   int64_t offsets_ms[kNumRmcatFlows];
   offsets_ms[0] = random_.Rand(2 * kAverageOffsetMs);
   for (int i = 1; i < kNumRmcatFlows; ++i) {
     offsets_ms[i] = offsets_ms[i - 1] + random_.Rand(2 * kAverageOffsetMs);
   }
   RunFairnessTest(GetParam(), kNumRmcatFlows, 0, 1000, 3000, 500, 50, 0,
                   offsets_ms);
 }

 TEST_P(BweSimulation, PacedSelfFairness1000msTest) {
   const int64_t kAverageOffsetMs = 20 * 1000;
   const int kNumRmcatFlows = 4;
   int64_t offsets_ms[kNumRmcatFlows];
   offsets_ms[0] = random_.Rand(2 * kAverageOffsetMs);
   for (int i = 1; i < kNumRmcatFlows; ++i) {
     offsets_ms[i] = offsets_ms[i - 1] + random_.Rand(2 * kAverageOffsetMs);
   }
   RunFairnessTest(GetParam(), 4, 0, 1000, 3000, 1000, 50, 0, offsets_ms);
 }

 TEST_P(BweSimulation, TcpFairness50msTest) {
   const int64_t kAverageOffsetMs = 20 * 1000;
   int64_t offset_ms[] = {random_.Rand(2 * kAverageOffsetMs), 0};
   RunFairnessTest(GetParam(), 1, 1, 1000, 2000, 50, 50, 0, offset_ms);
 }

 TEST_P(BweSimulation, TcpFairness500msTest) {
   const int64_t kAverageOffsetMs = 20 * 1000;
   int64_t offset_ms[] = {random_.Rand(2 * kAverageOffsetMs), 0};
   RunFairnessTest(GetParam(), 1, 1, 1000, 2000, 500, 50, 0, offset_ms);
 }

 TEST_P(BweSimulation, TcpFairness1000msTest) {
   const int kAverageOffsetMs = 20 * 1000;
   int64_t offset_ms[] = {random_.Rand(2 * kAverageOffsetMs), 0};
   RunFairnessTest(GetParam(), 1, 1, 1000, 2000, 1000, 50, 0, offset_ms);
 }

 // The following test cases begin with "Evaluation" as a referrence to the
 // Internet draft https://tools.ietf.org/html/draft-ietf-rmcat-eval-test-01.

 TEST_P(BweSimulation, Evaluation1) {
   RunVariableCapacity1SingleFlow(GetParam());
 }

 TEST_P(BweSimulation, Evaluation2) {
   const size_t kNumFlows = 2;
   RunVariableCapacity2MultipleFlows(GetParam(), kNumFlows);
 }

 TEST_P(BweSimulation, Evaluation3) {
   RunBidirectionalFlow(GetParam());
 }

 TEST_P(BweSimulation, Evaluation4) {
   RunSelfFairness(GetParam());
 }

 TEST_P(BweSimulation, Evaluation5) {
   RunRoundTripTimeFairness(GetParam());
 }

 TEST_P(BweSimulation, Evaluation6) {
   RunLongTcpFairness(GetParam());
 }

 // Different calls to the Evaluation7 will create the same FileSizes
 // and StartingTimes as long as the seeds remain unchanged. This is essential
 // when calling it with multiple estimators for comparison purposes.
 TEST_P(BweSimulation, Evaluation7) {
   const int kNumTcpFiles = 10;
   RunMultipleShortTcpFairness(GetParam(),
                               BweTest::GetFileSizesBytes(kNumTcpFiles),
                               BweTest::GetStartingTimesMs(kNumTcpFiles));
 }

 TEST_P(BweSimulation, Evaluation8) {
   RunPauseResumeFlows(GetParam());
 }

 // Following test cases begin with "GccComparison" run the
 // evaluation test cases for both GCC and other calling RMCAT.

 TEST_P(BweSimulation, GccComparison1) {
   RunVariableCapacity1SingleFlow(GetParam());
   BweTest gcc_test(false);
   gcc_test.RunVariableCapacity1SingleFlow(kFullSendSideEstimator);
 }

 TEST_P(BweSimulation, GccComparison2) {
   const size_t kNumFlows = 2;
   RunVariableCapacity2MultipleFlows(GetParam(), kNumFlows);
   BweTest gcc_test(false);
   gcc_test.RunVariableCapacity2MultipleFlows(kFullSendSideEstimator, kNumFlows);
 }

 TEST_P(BweSimulation, GccComparison3) {
   RunBidirectionalFlow(GetParam());
   BweTest gcc_test(false);
   gcc_test.RunBidirectionalFlow(kFullSendSideEstimator);
 }

 TEST_P(BweSimulation, GccComparison4) {
   RunSelfFairness(GetParam());
   BweTest gcc_test(false);
   gcc_test.RunSelfFairness(GetParam());
 }

 TEST_P(BweSimulation, GccComparison5) {
   RunRoundTripTimeFairness(GetParam());
   BweTest gcc_test(false);
   gcc_test.RunRoundTripTimeFairness(kFullSendSideEstimator);
 }

 TEST_P(BweSimulation, GccComparison6) {
   RunLongTcpFairness(GetParam());
   BweTest gcc_test(false);
   gcc_test.RunLongTcpFairness(kFullSendSideEstimator);
 }

 TEST_P(BweSimulation, GccComparison7) {
   const int kNumTcpFiles = 10;

   std::vector<int> tcp_file_sizes_bytes =
       BweTest::GetFileSizesBytes(kNumTcpFiles);
   std::vector<int64_t> tcp_starting_times_ms =
       BweTest::GetStartingTimesMs(kNumTcpFiles);

   RunMultipleShortTcpFairness(GetParam(), tcp_file_sizes_bytes,
                               tcp_starting_times_ms);

   BweTest gcc_test(false);
   gcc_test.RunMultipleShortTcpFairness(
       kFullSendSideEstimator, tcp_file_sizes_bytes, tcp_starting_times_ms);
 }

 TEST_P(BweSimulation, GccComparison8) {
   RunPauseResumeFlows(GetParam());
   BweTest gcc_test(false);
   gcc_test.RunPauseResumeFlows(kFullSendSideEstimator);
 }

 TEST_P(BweSimulation, GccComparisonChoke) {
   int array[] = {1000, 500, 1000};
   std::vector<int> capacities_kbps(array, array + 3);
   RunChoke(GetParam(), capacities_kbps);

   BweTest gcc_test(false);
   gcc_test.RunChoke(kFullSendSideEstimator, capacities_kbps);
 }

 #endif  // BWE_TEST_LOGGING_COMPILE_TIME_ENABLE
 }  // namespace bwe
 }  // namespace testing
 }  // 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 "testing/gtest/include/gtest/gtest.h"
	#include "webrtc/base/constructormagic.h"
	#include "webrtc/modules/remote_bitrate_estimator/include/remote_bitrate_estimator.h"
	#include "webrtc/modules/remote_bitrate_estimator/test/bwe_test.h"
	#include "webrtc/modules/remote_bitrate_estimator/test/packet_receiver.h"
	#include "webrtc/modules/remote_bitrate_estimator/test/packet_sender.h"
	#include "webrtc/test/testsupport/fileutils.h"


	namespace webrtc {
	namespace testing {
	namespace bwe {
	#if BWE_TEST_LOGGING_COMPILE_TIME_ENABLE
	// This test fixture is used to instantiate tests running with adaptive video
	// senders.
	class BweSimulation : public BweTest,
	public ::testing::TestWithParam<BandwidthEstimatorType> {
	public:
	BweSimulation()
	: BweTest(), random_(Clock::GetRealTimeClock()->TimeInMicroseconds()) {}
	virtual ~BweSimulation() {}

	protected:
	void SetUp() override {
	BweTest::SetUp();
	VerboseLogging(true);
	}

	Random random_;

	private:
	RTC_DISALLOW_COPY_AND_ASSIGN(BweSimulation);
	};

	INSTANTIATE_TEST_CASE_P(VideoSendersTest,
	BweSimulation,
	::testing::Values(kRembEstimator,
	kFullSendSideEstimator,
	kNadaEstimator));

	TEST_P(BweSimulation, SprintUplinkTest) {
	AdaptiveVideoSource source(0, 30, 300, 0, 0);
	VideoSender sender(&uplink_, &source, GetParam());
	RateCounterFilter counter1(&uplink_, 0, "sender_output",
	bwe_names[GetParam()]);
	TraceBasedDeliveryFilter filter(&uplink_, 0, "link_capacity");
	RateCounterFilter counter2(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	ASSERT_TRUE(filter.Init(test::ResourcePath("sprint-uplink", "rx")));
	RunFor(60 * 1000);
	}

	TEST_P(BweSimulation, Verizon4gDownlinkTest) {
	AdaptiveVideoSource source(0, 30, 300, 0, 0);
	VideoSender sender(&downlink_, &source, GetParam());
	RateCounterFilter counter1(&downlink_, 0, "sender_output",
	bwe_names[GetParam()] + "_up");
	TraceBasedDeliveryFilter filter(&downlink_, 0, "link_capacity");
	RateCounterFilter counter2(&downlink_, 0, "Receiver",
	bwe_names[GetParam()] + "_down");
	PacketReceiver receiver(&downlink_, 0, GetParam(), true, true);
	ASSERT_TRUE(filter.Init(test::ResourcePath("verizon4g-downlink", "rx")));
	RunFor(22 * 60 * 1000);
	}

	TEST_P(BweSimulation, Choke1000kbps500kbps1000kbpsBiDirectional) {
	const int kFlowIds[] = {0, 1};
	const size_t kNumFlows = sizeof(kFlowIds) / sizeof(kFlowIds[0]);

	AdaptiveVideoSource source(kFlowIds[0], 30, 300, 0, 0);
	VideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter choke(&uplink_, kFlowIds[0]);
	RateCounterFilter counter(&uplink_, kFlowIds[0], "Receiver_0",
	bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, kFlowIds[0], GetParam(), true, false);

	AdaptiveVideoSource source2(kFlowIds[1], 30, 300, 0, 0);
	VideoSender sender2(&downlink_, &source2, GetParam());
	ChokeFilter choke2(&downlink_, kFlowIds[1]);
	DelayFilter delay(&downlink_, CreateFlowIds(kFlowIds, kNumFlows));
	RateCounterFilter counter2(&downlink_, kFlowIds[1], "Receiver_1",
	bwe_names[GetParam()]);
	PacketReceiver receiver2(&downlink_, kFlowIds[1], GetParam(), true, false);

	choke2.set_capacity_kbps(500);
	delay.SetOneWayDelayMs(0);

	choke.set_capacity_kbps(1000);
	choke.set_max_delay_ms(500);
	RunFor(60 * 1000);
	choke.set_capacity_kbps(500);
	RunFor(60 * 1000);
	choke.set_capacity_kbps(1000);
	RunFor(60 * 1000);
	}

	TEST_P(BweSimulation, Choke1000kbps500kbps1000kbps) {
	AdaptiveVideoSource source(0, 30, 300, 0, 0);
	VideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter choke(&uplink_, 0);
	RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, false);

	choke.set_capacity_kbps(1000);
	choke.set_max_delay_ms(500);
	RunFor(60 * 1000);
	choke.set_capacity_kbps(500);
	RunFor(60 * 1000);
	choke.set_capacity_kbps(1000);
	RunFor(60 * 1000);
	}

	TEST_P(BweSimulation, PacerChoke1000kbps500kbps1000kbps) {
	AdaptiveVideoSource source(0, 30, 300, 0, 0);
	PacedVideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter filter(&uplink_, 0);
	RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	filter.set_capacity_kbps(1000);
	filter.set_max_delay_ms(500);
	RunFor(60 * 1000);
	filter.set_capacity_kbps(500);
	RunFor(60 * 1000);
	filter.set_capacity_kbps(1000);
	RunFor(60 * 1000);
	}

	TEST_P(BweSimulation, PacerChoke10000kbps) {
	PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000);
	PacedVideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter filter(&uplink_, 0);
	RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	filter.set_capacity_kbps(10000);
	filter.set_max_delay_ms(500);
	RunFor(60 * 1000);
	}

	TEST_P(BweSimulation, PacerChoke200kbps30kbps200kbps) {
	AdaptiveVideoSource source(0, 30, 300, 0, 0);
	PacedVideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter filter(&uplink_, 0);
	RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	filter.set_capacity_kbps(200);
	filter.set_max_delay_ms(500);
	RunFor(60 * 1000);
	filter.set_capacity_kbps(30);
	RunFor(60 * 1000);
	filter.set_capacity_kbps(200);
	RunFor(60 * 1000);
	}

	TEST_P(BweSimulation, Choke200kbps30kbps200kbps) {
	AdaptiveVideoSource source(0, 30, 300, 0, 0);
	VideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter filter(&uplink_, 0);
	RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	filter.set_capacity_kbps(200);
	filter.set_max_delay_ms(500);
	RunFor(60 * 1000);
	filter.set_capacity_kbps(30);
	RunFor(60 * 1000);
	filter.set_capacity_kbps(200);
	RunFor(60 * 1000);
	}

	TEST_P(BweSimulation, GoogleWifiTrace3Mbps) {
	AdaptiveVideoSource source(0, 30, 300, 0, 0);
	VideoSender sender(&uplink_, &source, GetParam());
	RateCounterFilter counter1(&uplink_, 0, "sender_output",
	bwe_names[GetParam()]);
	TraceBasedDeliveryFilter filter(&uplink_, 0, "link_capacity");
	filter.set_max_delay_ms(500);
	RateCounterFilter counter2(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	ASSERT_TRUE(filter.Init(test::ResourcePath("google-wifi-3mbps", "rx")));
	RunFor(300 * 1000);
	}

	TEST_P(BweSimulation, LinearIncreasingCapacity) {
	PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000000);
	PacedVideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter filter(&uplink_, 0);
	RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	filter.set_max_delay_ms(500);
	const int kStartingCapacityKbps = 150;
	const int kEndingCapacityKbps = 1500;
	const int kStepKbps = 5;
	const int kStepTimeMs = 1000;

	for (int i = kStartingCapacityKbps; i <= kEndingCapacityKbps;
	i += kStepKbps) {
	filter.set_capacity_kbps(i);
	RunFor(kStepTimeMs);
	}
	}

	TEST_P(BweSimulation, LinearDecreasingCapacity) {
	PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000000);
	PacedVideoSender sender(&uplink_, &source, GetParam());
	ChokeFilter filter(&uplink_, 0);
	RateCounterFilter counter(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	filter.set_max_delay_ms(500);
	const int kStartingCapacityKbps = 1500;
	const int kEndingCapacityKbps = 150;
	const int kStepKbps = -5;
	const int kStepTimeMs = 1000;

	for (int i = kStartingCapacityKbps; i >= kEndingCapacityKbps;
	i += kStepKbps) {
	filter.set_capacity_kbps(i);
	RunFor(kStepTimeMs);
	}
	}

	TEST_P(BweSimulation, PacerGoogleWifiTrace3Mbps) {
	PeriodicKeyFrameSource source(0, 30, 300, 0, 0, 1000);
	PacedVideoSender sender(&uplink_, &source, GetParam());
	RateCounterFilter counter1(&uplink_, 0, "sender_output",
	bwe_names[GetParam()]);
	TraceBasedDeliveryFilter filter(&uplink_, 0, "link_capacity");
	filter.set_max_delay_ms(500);
	RateCounterFilter counter2(&uplink_, 0, "Receiver", bwe_names[GetParam()]);
	PacketReceiver receiver(&uplink_, 0, GetParam(), true, true);
	ASSERT_TRUE(filter.Init(test::ResourcePath("google-wifi-3mbps", "rx")));
	RunFor(300 * 1000);
	}

	TEST_P(BweSimulation, SelfFairnessTest) {
	Random prng(Clock::GetRealTimeClock()->TimeInMicroseconds());
	const int kAllFlowIds[] = {0, 1, 2, 3};
	const size_t kNumFlows = sizeof(kAllFlowIds) / sizeof(kAllFlowIds[0]);
	std::unique_ptr<VideoSource> sources[kNumFlows];
	std::unique_ptr<VideoSender> senders[kNumFlows];
	for (size_t i = 0; i < kNumFlows; ++i) {
	// Streams started 20 seconds apart to give them different advantage when
	// competing for the bandwidth.
	sources[i].reset(new AdaptiveVideoSource(kAllFlowIds[i], 30, 300, 0,
	i * prng.Rand(39999)));
	senders[i].reset(new VideoSender(&uplink_, sources[i].get(), GetParam()));
	}

	ChokeFilter choke(&uplink_, CreateFlowIds(kAllFlowIds, kNumFlows));
	choke.set_capacity_kbps(1000);

	std::unique_ptr<RateCounterFilter> rate_counters[kNumFlows];
	for (size_t i = 0; i < kNumFlows; ++i) {
	rate_counters[i].reset(
	new RateCounterFilter(&uplink_, CreateFlowIds(&kAllFlowIds[i], 1),
	"Receiver", bwe_names[GetParam()]));
	}

	RateCounterFilter total_utilization(
	&uplink_, CreateFlowIds(kAllFlowIds, kNumFlows), "total_utilization",
	"Total_link_utilization");

	std::unique_ptr<PacketReceiver> receivers[kNumFlows];
	for (size_t i = 0; i < kNumFlows; ++i) {
	receivers[i].reset(new PacketReceiver(&uplink_, kAllFlowIds[i], GetParam(),
	i == 0, false));
	}

	RunFor(30 * 60 * 1000);
	}

	TEST_P(BweSimulation, PacedSelfFairness50msTest) {
	const int64_t kAverageOffsetMs = 20 * 1000;
	const int kNumRmcatFlows = 4;
	int64_t offsets_ms[kNumRmcatFlows];
	offsets_ms[0] = random_.Rand(2 * kAverageOffsetMs);
	for (int i = 1; i < kNumRmcatFlows; ++i) {
	offsets_ms[i] = offsets_ms[i - 1] + random_.Rand(2 * kAverageOffsetMs);
	}
	RunFairnessTest(GetParam(), kNumRmcatFlows, 0, 1000, 3000, 50, 50, 0,
	offsets_ms);
	}

	TEST_P(BweSimulation, PacedSelfFairness500msTest) {
	const int64_t kAverageOffsetMs = 20 * 1000;
	const int kNumRmcatFlows = 4;
	int64_t offsets_ms[kNumRmcatFlows];
	offsets_ms[0] = random_.Rand(2 * kAverageOffsetMs);
	for (int i = 1; i < kNumRmcatFlows; ++i) {
	offsets_ms[i] = offsets_ms[i - 1] + random_.Rand(2 * kAverageOffsetMs);
	}
	RunFairnessTest(GetParam(), kNumRmcatFlows, 0, 1000, 3000, 500, 50, 0,
	offsets_ms);
	}

	TEST_P(BweSimulation, PacedSelfFairness1000msTest) {
	const int64_t kAverageOffsetMs = 20 * 1000;
	const int kNumRmcatFlows = 4;
	int64_t offsets_ms[kNumRmcatFlows];
	offsets_ms[0] = random_.Rand(2 * kAverageOffsetMs);
	for (int i = 1; i < kNumRmcatFlows; ++i) {
	offsets_ms[i] = offsets_ms[i - 1] + random_.Rand(2 * kAverageOffsetMs);
	}
	RunFairnessTest(GetParam(), 4, 0, 1000, 3000, 1000, 50, 0, offsets_ms);
	}

	TEST_P(BweSimulation, TcpFairness50msTest) {
	const int64_t kAverageOffsetMs = 20 * 1000;
	int64_t offset_ms[] = {random_.Rand(2 * kAverageOffsetMs), 0};
	RunFairnessTest(GetParam(), 1, 1, 1000, 2000, 50, 50, 0, offset_ms);
	}

	TEST_P(BweSimulation, TcpFairness500msTest) {
	const int64_t kAverageOffsetMs = 20 * 1000;
	int64_t offset_ms[] = {random_.Rand(2 * kAverageOffsetMs), 0};
	RunFairnessTest(GetParam(), 1, 1, 1000, 2000, 500, 50, 0, offset_ms);
	}

	TEST_P(BweSimulation, TcpFairness1000msTest) {
	const int kAverageOffsetMs = 20 * 1000;
	int64_t offset_ms[] = {random_.Rand(2 * kAverageOffsetMs), 0};
	RunFairnessTest(GetParam(), 1, 1, 1000, 2000, 1000, 50, 0, offset_ms);
	}

	// The following test cases begin with "Evaluation" as a referrence to the
	// Internet draft https://tools.ietf.org/html/draft-ietf-rmcat-eval-test-01.

	TEST_P(BweSimulation, Evaluation1) {
	RunVariableCapacity1SingleFlow(GetParam());
	}

	TEST_P(BweSimulation, Evaluation2) {
	const size_t kNumFlows = 2;
	RunVariableCapacity2MultipleFlows(GetParam(), kNumFlows);
	}

	TEST_P(BweSimulation, Evaluation3) {
	RunBidirectionalFlow(GetParam());
	}

	TEST_P(BweSimulation, Evaluation4) {
	RunSelfFairness(GetParam());
	}

	TEST_P(BweSimulation, Evaluation5) {
	RunRoundTripTimeFairness(GetParam());
	}

	TEST_P(BweSimulation, Evaluation6) {
	RunLongTcpFairness(GetParam());
	}

	// Different calls to the Evaluation7 will create the same FileSizes
	// and StartingTimes as long as the seeds remain unchanged. This is essential
	// when calling it with multiple estimators for comparison purposes.
	TEST_P(BweSimulation, Evaluation7) {
	const int kNumTcpFiles = 10;
	RunMultipleShortTcpFairness(GetParam(),
	BweTest::GetFileSizesBytes(kNumTcpFiles),
	BweTest::GetStartingTimesMs(kNumTcpFiles));
	}

	TEST_P(BweSimulation, Evaluation8) {
	RunPauseResumeFlows(GetParam());
	}

	// Following test cases begin with "GccComparison" run the
	// evaluation test cases for both GCC and other calling RMCAT.

	TEST_P(BweSimulation, GccComparison1) {
	RunVariableCapacity1SingleFlow(GetParam());
	BweTest gcc_test(false);
	gcc_test.RunVariableCapacity1SingleFlow(kFullSendSideEstimator);
	}

	TEST_P(BweSimulation, GccComparison2) {
	const size_t kNumFlows = 2;
	RunVariableCapacity2MultipleFlows(GetParam(), kNumFlows);
	BweTest gcc_test(false);
	gcc_test.RunVariableCapacity2MultipleFlows(kFullSendSideEstimator, kNumFlows);
	}

	TEST_P(BweSimulation, GccComparison3) {
	RunBidirectionalFlow(GetParam());
	BweTest gcc_test(false);
	gcc_test.RunBidirectionalFlow(kFullSendSideEstimator);
	}

	TEST_P(BweSimulation, GccComparison4) {
	RunSelfFairness(GetParam());
	BweTest gcc_test(false);
	gcc_test.RunSelfFairness(GetParam());
	}

	TEST_P(BweSimulation, GccComparison5) {
	RunRoundTripTimeFairness(GetParam());
	BweTest gcc_test(false);
	gcc_test.RunRoundTripTimeFairness(kFullSendSideEstimator);
	}

	TEST_P(BweSimulation, GccComparison6) {
	RunLongTcpFairness(GetParam());
	BweTest gcc_test(false);
	gcc_test.RunLongTcpFairness(kFullSendSideEstimator);
	}

	TEST_P(BweSimulation, GccComparison7) {
	const int kNumTcpFiles = 10;

	std::vector<int> tcp_file_sizes_bytes =
	BweTest::GetFileSizesBytes(kNumTcpFiles);
	std::vector<int64_t> tcp_starting_times_ms =
	BweTest::GetStartingTimesMs(kNumTcpFiles);

	RunMultipleShortTcpFairness(GetParam(), tcp_file_sizes_bytes,
	tcp_starting_times_ms);

	BweTest gcc_test(false);
	gcc_test.RunMultipleShortTcpFairness(
	kFullSendSideEstimator, tcp_file_sizes_bytes, tcp_starting_times_ms);
	}

	TEST_P(BweSimulation, GccComparison8) {
	RunPauseResumeFlows(GetParam());
	BweTest gcc_test(false);
	gcc_test.RunPauseResumeFlows(kFullSendSideEstimator);
	}

	TEST_P(BweSimulation, GccComparisonChoke) {
	int array[] = {1000, 500, 1000};
	std::vector<int> capacities_kbps(array, array + 3);
	RunChoke(GetParam(), capacities_kbps);

	BweTest gcc_test(false);
	gcc_test.RunChoke(kFullSendSideEstimator, capacities_kbps);
	}

	#endif // BWE_TEST_LOGGING_COMPILE_TIME_ENABLE
	} // namespace bwe
	} // namespace testing
	} // namespace webrtc