test/network/cross_traffic_unittest.cc - src/ - Git at Google

 /*
  *  Copyright 2019 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 "test/network/cross_traffic.h"

 #include <atomic>
 #include <memory>
 #include <utility>
 #include <vector>

 #include "absl/memory/memory.h"
 #include "absl/types/optional.h"
 #include "api/test/network_emulation_manager.h"
 #include "api/test/simulated_network.h"
 #include "call/simulated_network.h"
 #include "rtc_base/event.h"
 #include "rtc_base/logging.h"
 #include "rtc_base/network_constants.h"
 #include "test/gmock.h"
 #include "test/gtest.h"
 #include "test/network/network_emulation_manager.h"
 #include "test/network/traffic_route.h"
 #include "test/time_controller/simulated_time_controller.h"

 namespace webrtc {
 namespace test {
 namespace {

 constexpr uint32_t kTestIpAddress = 0xC0A80011;  // 192.168.0.17

 class CountingReceiver : public EmulatedNetworkReceiverInterface {
  public:
   void OnPacketReceived(EmulatedIpPacket packet) override {
     packets_count_++;
     total_packets_size_ += packet.size();
   }

   std::atomic<int> packets_count_{0};
   std::atomic<uint64_t> total_packets_size_{0};
 };
 struct TrafficCounterFixture {
   SimulatedClock clock{0};
   CountingReceiver counter;
   TaskQueueForTest task_queue_;
   EmulatedEndpointImpl endpoint{EmulatedEndpointImpl::Options{
                                     /*id=*/1,
                                     rtc::IPAddress(kTestIpAddress),
                                     EmulatedEndpointConfig(),
                                     EmulatedNetworkStatsGatheringMode::kDefault,
                                 },
                                 /*is_enabled=*/true, task_queue_.Get(), &clock};
 };

 }  // namespace

 TEST(CrossTrafficTest, TriggerPacketBurst) {
   TrafficCounterFixture fixture;
   CrossTrafficRouteImpl traffic(&fixture.clock, &fixture.counter,
                                 &fixture.endpoint);
   traffic.TriggerPacketBurst(100, 1000);

   EXPECT_EQ(fixture.counter.packets_count_, 100);
   EXPECT_EQ(fixture.counter.total_packets_size_, 100 * 1000ul);
 }

 TEST(CrossTrafficTest, PulsedPeaksCrossTraffic) {
   TrafficCounterFixture fixture;
   CrossTrafficRouteImpl traffic(&fixture.clock, &fixture.counter,
                                 &fixture.endpoint);

   PulsedPeaksConfig config;
   config.peak_rate = DataRate::KilobitsPerSec(1000);
   config.min_packet_size = DataSize::Bytes(1);
   config.min_packet_interval = TimeDelta::Millis(25);
   config.send_duration = TimeDelta::Millis(500);
   config.hold_duration = TimeDelta::Millis(250);
   PulsedPeaksCrossTraffic pulsed_peaks(config, &traffic);
   const auto kRunTime = TimeDelta::Seconds(1);
   while (fixture.clock.TimeInMilliseconds() < kRunTime.ms()) {
     pulsed_peaks.Process(Timestamp::Millis(fixture.clock.TimeInMilliseconds()));
     fixture.clock.AdvanceTimeMilliseconds(1);
   }

   RTC_LOG(LS_INFO) << fixture.counter.packets_count_ << " packets; "
                    << fixture.counter.total_packets_size_ << " bytes";
   // Using 50% duty cycle.
   const auto kExpectedDataSent = kRunTime * config.peak_rate * 0.5;
   EXPECT_NEAR(fixture.counter.total_packets_size_, kExpectedDataSent.bytes(),
               kExpectedDataSent.bytes() * 0.1);
 }

 TEST(CrossTrafficTest, RandomWalkCrossTraffic) {
   TrafficCounterFixture fixture;
   CrossTrafficRouteImpl traffic(&fixture.clock, &fixture.counter,
                                 &fixture.endpoint);

   RandomWalkConfig config;
   config.peak_rate = DataRate::KilobitsPerSec(1000);
   config.min_packet_size = DataSize::Bytes(1);
   config.min_packet_interval = TimeDelta::Millis(25);
   config.update_interval = TimeDelta::Millis(500);
   config.variance = 0.0;
   config.bias = 1.0;

   RandomWalkCrossTraffic random_walk(config, &traffic);
   const auto kRunTime = TimeDelta::Seconds(1);
   while (fixture.clock.TimeInMilliseconds() < kRunTime.ms()) {
     random_walk.Process(Timestamp::Millis(fixture.clock.TimeInMilliseconds()));
     fixture.clock.AdvanceTimeMilliseconds(1);
   }

   RTC_LOG(LS_INFO) << fixture.counter.packets_count_ << " packets; "
                    << fixture.counter.total_packets_size_ << " bytes";
   // Sending at peak rate since bias = 1.
   const auto kExpectedDataSent = kRunTime * config.peak_rate;
   EXPECT_NEAR(fixture.counter.total_packets_size_, kExpectedDataSent.bytes(),
               kExpectedDataSent.bytes() * 0.1);
 }

 TEST(TcpMessageRouteTest, DeliveredOnLossyNetwork) {
   NetworkEmulationManagerImpl net(TimeMode::kSimulated,
                                   EmulatedNetworkStatsGatheringMode::kDefault);
   BuiltInNetworkBehaviorConfig send;
   // 800 kbps means that the 100 kB message would be delivered in ca 1 second
   // under ideal conditions and no overhead.
   send.link_capacity_kbps = 100 * 8;
   send.loss_percent = 50;
   send.queue_delay_ms = 100;
   send.delay_standard_deviation_ms = 20;
   send.allow_reordering = true;
   auto ret = send;
   ret.loss_percent = 10;

   auto* tcp_route =
       net.CreateTcpRoute(net.CreateRoute({net.CreateEmulatedNode(send)}),
                          net.CreateRoute({net.CreateEmulatedNode(ret)}));
   int deliver_count = 0;
   // 100 kB is more than what fits into a single packet.
   constexpr size_t kMessageSize = 100000;

   tcp_route->SendMessage(kMessageSize, [&] {
     RTC_LOG(LS_INFO) << "Received at " << ToString(net.Now());
     deliver_count++;
   });

   // If there was no loss, we would have delivered the message in ca 1 second,
   // with 50% it should take much longer.
   net.time_controller()->AdvanceTime(TimeDelta::Seconds(5));
   ASSERT_EQ(deliver_count, 0);
   // But given enough time the messsage will be delivered, but only once.
   net.time_controller()->AdvanceTime(TimeDelta::Seconds(60));
   EXPECT_EQ(deliver_count, 1);
 }

 }  // namespace test
 }  // namespace webrtc
	/*
	* Copyright 2019 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 "test/network/cross_traffic.h"

	#include <atomic>
	#include <memory>
	#include <utility>
	#include <vector>

	#include "absl/memory/memory.h"
	#include "absl/types/optional.h"
	#include "api/test/network_emulation_manager.h"
	#include "api/test/simulated_network.h"
	#include "call/simulated_network.h"
	#include "rtc_base/event.h"
	#include "rtc_base/logging.h"
	#include "rtc_base/network_constants.h"
	#include "test/gmock.h"
	#include "test/gtest.h"
	#include "test/network/network_emulation_manager.h"
	#include "test/network/traffic_route.h"
	#include "test/time_controller/simulated_time_controller.h"

	namespace webrtc {
	namespace test {
	namespace {

	constexpr uint32_t kTestIpAddress = 0xC0A80011; // 192.168.0.17

	class CountingReceiver : public EmulatedNetworkReceiverInterface {
	public:
	void OnPacketReceived(EmulatedIpPacket packet) override {
	packets_count_++;
	total_packets_size_ += packet.size();
	}

	std::atomic<int> packets_count_{0};
	std::atomic<uint64_t> total_packets_size_{0};
	};
	struct TrafficCounterFixture {
	SimulatedClock clock{0};
	CountingReceiver counter;
	TaskQueueForTest task_queue_;
	EmulatedEndpointImpl endpoint{EmulatedEndpointImpl::Options{
	/id=/1,
	rtc::IPAddress(kTestIpAddress),
	EmulatedEndpointConfig(),
	EmulatedNetworkStatsGatheringMode::kDefault,
	},
	/is_enabled=/true, task_queue_.Get(), &clock};
	};

	} // namespace

	TEST(CrossTrafficTest, TriggerPacketBurst) {
	TrafficCounterFixture fixture;
	CrossTrafficRouteImpl traffic(&fixture.clock, &fixture.counter,
	&fixture.endpoint);
	traffic.TriggerPacketBurst(100, 1000);

	EXPECT_EQ(fixture.counter.packets_count_, 100);
	EXPECT_EQ(fixture.counter.total_packets_size_, 100 * 1000ul);
	}

	TEST(CrossTrafficTest, PulsedPeaksCrossTraffic) {
	TrafficCounterFixture fixture;
	CrossTrafficRouteImpl traffic(&fixture.clock, &fixture.counter,
	&fixture.endpoint);

	PulsedPeaksConfig config;
	config.peak_rate = DataRate::KilobitsPerSec(1000);
	config.min_packet_size = DataSize::Bytes(1);
	config.min_packet_interval = TimeDelta::Millis(25);
	config.send_duration = TimeDelta::Millis(500);
	config.hold_duration = TimeDelta::Millis(250);
	PulsedPeaksCrossTraffic pulsed_peaks(config, &traffic);
	const auto kRunTime = TimeDelta::Seconds(1);
	while (fixture.clock.TimeInMilliseconds() < kRunTime.ms()) {
	pulsed_peaks.Process(Timestamp::Millis(fixture.clock.TimeInMilliseconds()));
	fixture.clock.AdvanceTimeMilliseconds(1);
	}

	RTC_LOG(LS_INFO) << fixture.counter.packets_count_ << " packets; "
	<< fixture.counter.total_packets_size_ << " bytes";
	// Using 50% duty cycle.
	const auto kExpectedDataSent = kRunTime * config.peak_rate * 0.5;
	EXPECT_NEAR(fixture.counter.total_packets_size_, kExpectedDataSent.bytes(),
	kExpectedDataSent.bytes() * 0.1);
	}

	TEST(CrossTrafficTest, RandomWalkCrossTraffic) {
	TrafficCounterFixture fixture;
	CrossTrafficRouteImpl traffic(&fixture.clock, &fixture.counter,
	&fixture.endpoint);

	RandomWalkConfig config;
	config.peak_rate = DataRate::KilobitsPerSec(1000);
	config.min_packet_size = DataSize::Bytes(1);
	config.min_packet_interval = TimeDelta::Millis(25);
	config.update_interval = TimeDelta::Millis(500);
	config.variance = 0.0;
	config.bias = 1.0;

	RandomWalkCrossTraffic random_walk(config, &traffic);
	const auto kRunTime = TimeDelta::Seconds(1);
	while (fixture.clock.TimeInMilliseconds() < kRunTime.ms()) {
	random_walk.Process(Timestamp::Millis(fixture.clock.TimeInMilliseconds()));
	fixture.clock.AdvanceTimeMilliseconds(1);
	}

	RTC_LOG(LS_INFO) << fixture.counter.packets_count_ << " packets; "
	<< fixture.counter.total_packets_size_ << " bytes";
	// Sending at peak rate since bias = 1.
	const auto kExpectedDataSent = kRunTime * config.peak_rate;
	EXPECT_NEAR(fixture.counter.total_packets_size_, kExpectedDataSent.bytes(),
	kExpectedDataSent.bytes() * 0.1);
	}

	TEST(TcpMessageRouteTest, DeliveredOnLossyNetwork) {
	NetworkEmulationManagerImpl net(TimeMode::kSimulated,
	EmulatedNetworkStatsGatheringMode::kDefault);
	BuiltInNetworkBehaviorConfig send;
	// 800 kbps means that the 100 kB message would be delivered in ca 1 second
	// under ideal conditions and no overhead.
	send.link_capacity_kbps = 100 * 8;
	send.loss_percent = 50;
	send.queue_delay_ms = 100;
	send.delay_standard_deviation_ms = 20;
	send.allow_reordering = true;
	auto ret = send;
	ret.loss_percent = 10;

	auto* tcp_route =
	net.CreateTcpRoute(net.CreateRoute({net.CreateEmulatedNode(send)}),
	net.CreateRoute({net.CreateEmulatedNode(ret)}));
	int deliver_count = 0;
	// 100 kB is more than what fits into a single packet.
	constexpr size_t kMessageSize = 100000;

	tcp_route->SendMessage(kMessageSize, [&] {
	RTC_LOG(LS_INFO) << "Received at " << ToString(net.Now());
	deliver_count++;
	});

	// If there was no loss, we would have delivered the message in ca 1 second,
	// with 50% it should take much longer.
	net.time_controller()->AdvanceTime(TimeDelta::Seconds(5));
	ASSERT_EQ(deliver_count, 0);
	// But given enough time the messsage will be delivered, but only once.
	net.time_controller()->AdvanceTime(TimeDelta::Seconds(60));
	EXPECT_EQ(deliver_count, 1);
	}

	} // namespace test
	} // namespace webrtc