quic/test_tools/simulator/quic_endpoint_test.cc - quiche - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "net/third_party/quiche/src/quic/test_tools/simulator/quic_endpoint.h"

 #include <utility>

 #include "net/third_party/quiche/src/quic/platform/api/quic_flags.h"
 #include "net/third_party/quiche/src/quic/platform/api/quic_test.h"
 #include "net/third_party/quiche/src/quic/test_tools/quic_connection_peer.h"
 #include "net/third_party/quiche/src/quic/test_tools/quic_test_utils.h"
 #include "net/third_party/quiche/src/quic/test_tools/simulator/simulator.h"
 #include "net/third_party/quiche/src/quic/test_tools/simulator/switch.h"

 using ::testing::_;
 using ::testing::NiceMock;
 using ::testing::Return;

 namespace quic {
 namespace simulator {

 const QuicBandwidth kDefaultBandwidth =
     QuicBandwidth::FromKBitsPerSecond(10 * 1000);
 const QuicTime::Delta kDefaultPropagationDelay =
     QuicTime::Delta::FromMilliseconds(20);
 const QuicByteCount kDefaultBdp = kDefaultBandwidth * kDefaultPropagationDelay;

 // A simple test harness where all hosts are connected to a switch with
 // identical links.
 class QuicEndpointTest : public QuicTest {
  public:
   QuicEndpointTest()
       : simulator_(), switch_(&simulator_, "Switch", 8, kDefaultBdp * 2) {}

  protected:
   Simulator simulator_;
   Switch switch_;

   std::unique_ptr<SymmetricLink> Link(Endpoint* a, Endpoint* b) {
     return std::make_unique<SymmetricLink>(a, b, kDefaultBandwidth,
                                            kDefaultPropagationDelay);
   }

   std::unique_ptr<SymmetricLink> CustomLink(Endpoint* a,
                                             Endpoint* b,
                                             uint64_t extra_rtt_ms) {
     return std::make_unique<SymmetricLink>(
         a, b, kDefaultBandwidth,
         kDefaultPropagationDelay +
             QuicTime::Delta::FromMilliseconds(extra_rtt_ms));
   }
 };

 // Test transmission from one host to another.
 TEST_F(QuicEndpointTest, OneWayTransmission) {
   QuicEndpoint endpoint_a(&simulator_, "Endpoint A", "Endpoint B",
                           Perspective::IS_CLIENT, test::TestConnectionId(42));
   QuicEndpoint endpoint_b(&simulator_, "Endpoint B", "Endpoint A",
                           Perspective::IS_SERVER, test::TestConnectionId(42));
   auto link_a = Link(&endpoint_a, switch_.port(1));
   auto link_b = Link(&endpoint_b, switch_.port(2));

   // First transmit a small, packet-size chunk of data.
   endpoint_a.AddBytesToTransfer(600);
   QuicTime end_time =
       simulator_.GetClock()->Now() + QuicTime::Delta::FromMilliseconds(1000);
   simulator_.RunUntil(
       [this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

   EXPECT_EQ(600u, endpoint_a.bytes_transferred());
   ASSERT_EQ(600u, endpoint_b.bytes_received());
   EXPECT_FALSE(endpoint_a.wrong_data_received());
   EXPECT_FALSE(endpoint_b.wrong_data_received());

   // After a small chunk succeeds, try to transfer 2 MiB.
   endpoint_a.AddBytesToTransfer(2 * 1024 * 1024);
   end_time = simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(5);
   simulator_.RunUntil(
       [this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

   const QuicByteCount total_bytes_transferred = 600 + 2 * 1024 * 1024;
   EXPECT_EQ(total_bytes_transferred, endpoint_a.bytes_transferred());
   EXPECT_EQ(total_bytes_transferred, endpoint_b.bytes_received());
   EXPECT_EQ(0u, endpoint_a.write_blocked_count());
   EXPECT_FALSE(endpoint_a.wrong_data_received());
   EXPECT_FALSE(endpoint_b.wrong_data_received());
 }

 // Test the situation in which the writer becomes write-blocked.
 TEST_F(QuicEndpointTest, WriteBlocked) {
   QuicEndpoint endpoint_a(&simulator_, "Endpoint A", "Endpoint B",
                           Perspective::IS_CLIENT, test::TestConnectionId(42));
   QuicEndpoint endpoint_b(&simulator_, "Endpoint B", "Endpoint A",
                           Perspective::IS_SERVER, test::TestConnectionId(42));
   auto link_a = Link(&endpoint_a, switch_.port(1));
   auto link_b = Link(&endpoint_b, switch_.port(2));

   // Will be owned by the sent packet manager.
   auto* sender = new NiceMock<test::MockSendAlgorithm>();
   EXPECT_CALL(*sender, CanSend(_)).WillRepeatedly(Return(true));
   EXPECT_CALL(*sender, PacingRate(_))
       .WillRepeatedly(Return(10 * kDefaultBandwidth));
   EXPECT_CALL(*sender, BandwidthEstimate())
       .WillRepeatedly(Return(10 * kDefaultBandwidth));
   EXPECT_CALL(*sender, GetCongestionWindow())
       .WillRepeatedly(Return(kMaxOutgoingPacketSize *
                              GetQuicFlag(FLAGS_quic_max_congestion_window)));
   test::QuicConnectionPeer::SetSendAlgorithm(endpoint_a.connection(), sender);

   // First transmit a small, packet-size chunk of data.
   QuicByteCount bytes_to_transfer = 3 * 1024 * 1024;
   endpoint_a.AddBytesToTransfer(bytes_to_transfer);
   QuicTime end_time =
       simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(30);
   simulator_.RunUntil([this, &endpoint_b, bytes_to_transfer, end_time]() {
     return endpoint_b.bytes_received() == bytes_to_transfer ||
            simulator_.GetClock()->Now() >= end_time;
   });

   EXPECT_EQ(bytes_to_transfer, endpoint_a.bytes_transferred());
   EXPECT_EQ(bytes_to_transfer, endpoint_b.bytes_received());
   EXPECT_GT(endpoint_a.write_blocked_count(), 0u);
   EXPECT_FALSE(endpoint_a.wrong_data_received());
   EXPECT_FALSE(endpoint_b.wrong_data_received());
 }

 // Test transmission of 1 MiB of data between two hosts simultaneously in both
 // directions.
 TEST_F(QuicEndpointTest, TwoWayTransmission) {
   QuicEndpoint endpoint_a(&simulator_, "Endpoint A", "Endpoint B",
                           Perspective::IS_CLIENT, test::TestConnectionId(42));
   QuicEndpoint endpoint_b(&simulator_, "Endpoint B", "Endpoint A",
                           Perspective::IS_SERVER, test::TestConnectionId(42));
   auto link_a = Link(&endpoint_a, switch_.port(1));
   auto link_b = Link(&endpoint_b, switch_.port(2));

   endpoint_a.RecordTrace();
   endpoint_b.RecordTrace();

   endpoint_a.AddBytesToTransfer(1024 * 1024);
   endpoint_b.AddBytesToTransfer(1024 * 1024);
   QuicTime end_time =
       simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(5);
   simulator_.RunUntil(
       [this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

   EXPECT_EQ(1024u * 1024u, endpoint_a.bytes_transferred());
   EXPECT_EQ(1024u * 1024u, endpoint_b.bytes_transferred());
   EXPECT_EQ(1024u * 1024u, endpoint_a.bytes_received());
   EXPECT_EQ(1024u * 1024u, endpoint_b.bytes_received());
   EXPECT_FALSE(endpoint_a.wrong_data_received());
   EXPECT_FALSE(endpoint_b.wrong_data_received());
 }

 // Simulate three hosts trying to send data to a fourth one simultaneously.
 TEST_F(QuicEndpointTest, Competition) {
   // TODO(63765788): Turn back on this flag when the issue if fixed.
   SetQuicReloadableFlag(quic_bbr_one_mss_conservation, false);
   auto endpoint_a = std::make_unique<QuicEndpoint>(
       &simulator_, "Endpoint A", "Endpoint D (A)", Perspective::IS_CLIENT,
       test::TestConnectionId(42));
   auto endpoint_b = std::make_unique<QuicEndpoint>(
       &simulator_, "Endpoint B", "Endpoint D (B)", Perspective::IS_CLIENT,
       test::TestConnectionId(43));
   auto endpoint_c = std::make_unique<QuicEndpoint>(
       &simulator_, "Endpoint C", "Endpoint D (C)", Perspective::IS_CLIENT,
       test::TestConnectionId(44));
   auto endpoint_d_a = std::make_unique<QuicEndpoint>(
       &simulator_, "Endpoint D (A)", "Endpoint A", Perspective::IS_SERVER,
       test::TestConnectionId(42));
   auto endpoint_d_b = std::make_unique<QuicEndpoint>(
       &simulator_, "Endpoint D (B)", "Endpoint B", Perspective::IS_SERVER,
       test::TestConnectionId(43));
   auto endpoint_d_c = std::make_unique<QuicEndpoint>(
       &simulator_, "Endpoint D (C)", "Endpoint C", Perspective::IS_SERVER,
       test::TestConnectionId(44));
   QuicEndpointMultiplexer endpoint_d(
       "Endpoint D",
       {endpoint_d_a.get(), endpoint_d_b.get(), endpoint_d_c.get()});

   // Create links with slightly different RTTs in order to avoid pathological
   // side-effects of packets entering the queue at the exactly same time.
   auto link_a = CustomLink(endpoint_a.get(), switch_.port(1), 0);
   auto link_b = CustomLink(endpoint_b.get(), switch_.port(2), 1);
   auto link_c = CustomLink(endpoint_c.get(), switch_.port(3), 2);
   auto link_d = Link(&endpoint_d, switch_.port(4));

   endpoint_a->AddBytesToTransfer(2 * 1024 * 1024);
   endpoint_b->AddBytesToTransfer(2 * 1024 * 1024);
   endpoint_c->AddBytesToTransfer(2 * 1024 * 1024);
   QuicTime end_time =
       simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(12);
   simulator_.RunUntil(
       [this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

   for (QuicEndpoint* endpoint :
        {endpoint_a.get(), endpoint_b.get(), endpoint_c.get()}) {
     EXPECT_EQ(2u * 1024u * 1024u, endpoint->bytes_transferred());
     EXPECT_GE(endpoint->connection()->GetStats().packets_lost, 0u);
   }
   for (QuicEndpoint* endpoint :
        {endpoint_d_a.get(), endpoint_d_b.get(), endpoint_d_c.get()}) {
     EXPECT_EQ(2u * 1024u * 1024u, endpoint->bytes_received());
     EXPECT_FALSE(endpoint->wrong_data_received());
   }
 }

 }  // namespace simulator
 }  // namespace quic
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "net/third_party/quiche/src/quic/test_tools/simulator/quic_endpoint.h"

	#include <utility>

	#include "net/third_party/quiche/src/quic/platform/api/quic_flags.h"
	#include "net/third_party/quiche/src/quic/platform/api/quic_test.h"
	#include "net/third_party/quiche/src/quic/test_tools/quic_connection_peer.h"
	#include "net/third_party/quiche/src/quic/test_tools/quic_test_utils.h"
	#include "net/third_party/quiche/src/quic/test_tools/simulator/simulator.h"
	#include "net/third_party/quiche/src/quic/test_tools/simulator/switch.h"

	using ::testing::_;
	using ::testing::NiceMock;
	using ::testing::Return;

	namespace quic {
	namespace simulator {

	const QuicBandwidth kDefaultBandwidth =
	QuicBandwidth::FromKBitsPerSecond(10 * 1000);
	const QuicTime::Delta kDefaultPropagationDelay =
	QuicTime::Delta::FromMilliseconds(20);
	const QuicByteCount kDefaultBdp = kDefaultBandwidth * kDefaultPropagationDelay;

	// A simple test harness where all hosts are connected to a switch with
	// identical links.
	class QuicEndpointTest : public QuicTest {
	public:
	QuicEndpointTest()
	: simulator_(), switch_(&simulator_, "Switch", 8, kDefaultBdp * 2) {}

	protected:
	Simulator simulator_;
	Switch switch_;

	std::unique_ptr<SymmetricLink> Link(Endpoint* a, Endpoint* b) {
	return std::make_unique<SymmetricLink>(a, b, kDefaultBandwidth,
	kDefaultPropagationDelay);
	}

	std::unique_ptr<SymmetricLink> CustomLink(Endpoint* a,
	Endpoint* b,
	uint64_t extra_rtt_ms) {
	return std::make_unique<SymmetricLink>(
	a, b, kDefaultBandwidth,
	kDefaultPropagationDelay +
	QuicTime::Delta::FromMilliseconds(extra_rtt_ms));
	}
	};

	// Test transmission from one host to another.
	TEST_F(QuicEndpointTest, OneWayTransmission) {
	QuicEndpoint endpoint_a(&simulator_, "Endpoint A", "Endpoint B",
	Perspective::IS_CLIENT, test::TestConnectionId(42));
	QuicEndpoint endpoint_b(&simulator_, "Endpoint B", "Endpoint A",
	Perspective::IS_SERVER, test::TestConnectionId(42));
	auto link_a = Link(&endpoint_a, switch_.port(1));
	auto link_b = Link(&endpoint_b, switch_.port(2));

	// First transmit a small, packet-size chunk of data.
	endpoint_a.AddBytesToTransfer(600);
	QuicTime end_time =
	simulator_.GetClock()->Now() + QuicTime::Delta::FromMilliseconds(1000);
	simulator_.RunUntil(
	[this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

	EXPECT_EQ(600u, endpoint_a.bytes_transferred());
	ASSERT_EQ(600u, endpoint_b.bytes_received());
	EXPECT_FALSE(endpoint_a.wrong_data_received());
	EXPECT_FALSE(endpoint_b.wrong_data_received());

	// After a small chunk succeeds, try to transfer 2 MiB.
	endpoint_a.AddBytesToTransfer(2 * 1024 * 1024);
	end_time = simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(5);
	simulator_.RunUntil(
	[this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

	const QuicByteCount total_bytes_transferred = 600 + 2 * 1024 * 1024;
	EXPECT_EQ(total_bytes_transferred, endpoint_a.bytes_transferred());
	EXPECT_EQ(total_bytes_transferred, endpoint_b.bytes_received());
	EXPECT_EQ(0u, endpoint_a.write_blocked_count());
	EXPECT_FALSE(endpoint_a.wrong_data_received());
	EXPECT_FALSE(endpoint_b.wrong_data_received());
	}

	// Test the situation in which the writer becomes write-blocked.
	TEST_F(QuicEndpointTest, WriteBlocked) {
	QuicEndpoint endpoint_a(&simulator_, "Endpoint A", "Endpoint B",
	Perspective::IS_CLIENT, test::TestConnectionId(42));
	QuicEndpoint endpoint_b(&simulator_, "Endpoint B", "Endpoint A",
	Perspective::IS_SERVER, test::TestConnectionId(42));
	auto link_a = Link(&endpoint_a, switch_.port(1));
	auto link_b = Link(&endpoint_b, switch_.port(2));

	// Will be owned by the sent packet manager.
	auto* sender = new NiceMock<test::MockSendAlgorithm>();
	EXPECT_CALL(*sender, CanSend(_)).WillRepeatedly(Return(true));
	EXPECT_CALL(*sender, PacingRate(_))
	.WillRepeatedly(Return(10 * kDefaultBandwidth));
	EXPECT_CALL(*sender, BandwidthEstimate())
	.WillRepeatedly(Return(10 * kDefaultBandwidth));
	EXPECT_CALL(*sender, GetCongestionWindow())
	.WillRepeatedly(Return(kMaxOutgoingPacketSize *
	GetQuicFlag(FLAGS_quic_max_congestion_window)));
	test::QuicConnectionPeer::SetSendAlgorithm(endpoint_a.connection(), sender);

	// First transmit a small, packet-size chunk of data.
	QuicByteCount bytes_to_transfer = 3 * 1024 * 1024;
	endpoint_a.AddBytesToTransfer(bytes_to_transfer);
	QuicTime end_time =
	simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(30);
	simulator_.RunUntil([this, &endpoint_b, bytes_to_transfer, end_time]() {
	return endpoint_b.bytes_received() == bytes_to_transfer \|\|
	simulator_.GetClock()->Now() >= end_time;
	});

	EXPECT_EQ(bytes_to_transfer, endpoint_a.bytes_transferred());
	EXPECT_EQ(bytes_to_transfer, endpoint_b.bytes_received());
	EXPECT_GT(endpoint_a.write_blocked_count(), 0u);
	EXPECT_FALSE(endpoint_a.wrong_data_received());
	EXPECT_FALSE(endpoint_b.wrong_data_received());
	}

	// Test transmission of 1 MiB of data between two hosts simultaneously in both
	// directions.
	TEST_F(QuicEndpointTest, TwoWayTransmission) {
	QuicEndpoint endpoint_a(&simulator_, "Endpoint A", "Endpoint B",
	Perspective::IS_CLIENT, test::TestConnectionId(42));
	QuicEndpoint endpoint_b(&simulator_, "Endpoint B", "Endpoint A",
	Perspective::IS_SERVER, test::TestConnectionId(42));
	auto link_a = Link(&endpoint_a, switch_.port(1));
	auto link_b = Link(&endpoint_b, switch_.port(2));

	endpoint_a.RecordTrace();
	endpoint_b.RecordTrace();

	endpoint_a.AddBytesToTransfer(1024 * 1024);
	endpoint_b.AddBytesToTransfer(1024 * 1024);
	QuicTime end_time =
	simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(5);
	simulator_.RunUntil(
	[this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

	EXPECT_EQ(1024u * 1024u, endpoint_a.bytes_transferred());
	EXPECT_EQ(1024u * 1024u, endpoint_b.bytes_transferred());
	EXPECT_EQ(1024u * 1024u, endpoint_a.bytes_received());
	EXPECT_EQ(1024u * 1024u, endpoint_b.bytes_received());
	EXPECT_FALSE(endpoint_a.wrong_data_received());
	EXPECT_FALSE(endpoint_b.wrong_data_received());
	}

	// Simulate three hosts trying to send data to a fourth one simultaneously.
	TEST_F(QuicEndpointTest, Competition) {
	// TODO(63765788): Turn back on this flag when the issue if fixed.
	SetQuicReloadableFlag(quic_bbr_one_mss_conservation, false);
	auto endpoint_a = std::make_unique<QuicEndpoint>(
	&simulator_, "Endpoint A", "Endpoint D (A)", Perspective::IS_CLIENT,
	test::TestConnectionId(42));
	auto endpoint_b = std::make_unique<QuicEndpoint>(
	&simulator_, "Endpoint B", "Endpoint D (B)", Perspective::IS_CLIENT,
	test::TestConnectionId(43));
	auto endpoint_c = std::make_unique<QuicEndpoint>(
	&simulator_, "Endpoint C", "Endpoint D (C)", Perspective::IS_CLIENT,
	test::TestConnectionId(44));
	auto endpoint_d_a = std::make_unique<QuicEndpoint>(
	&simulator_, "Endpoint D (A)", "Endpoint A", Perspective::IS_SERVER,
	test::TestConnectionId(42));
	auto endpoint_d_b = std::make_unique<QuicEndpoint>(
	&simulator_, "Endpoint D (B)", "Endpoint B", Perspective::IS_SERVER,
	test::TestConnectionId(43));
	auto endpoint_d_c = std::make_unique<QuicEndpoint>(
	&simulator_, "Endpoint D (C)", "Endpoint C", Perspective::IS_SERVER,
	test::TestConnectionId(44));
	QuicEndpointMultiplexer endpoint_d(
	"Endpoint D",
	{endpoint_d_a.get(), endpoint_d_b.get(), endpoint_d_c.get()});

	// Create links with slightly different RTTs in order to avoid pathological
	// side-effects of packets entering the queue at the exactly same time.
	auto link_a = CustomLink(endpoint_a.get(), switch_.port(1), 0);
	auto link_b = CustomLink(endpoint_b.get(), switch_.port(2), 1);
	auto link_c = CustomLink(endpoint_c.get(), switch_.port(3), 2);
	auto link_d = Link(&endpoint_d, switch_.port(4));

	endpoint_a->AddBytesToTransfer(2 * 1024 * 1024);
	endpoint_b->AddBytesToTransfer(2 * 1024 * 1024);
	endpoint_c->AddBytesToTransfer(2 * 1024 * 1024);
	QuicTime end_time =
	simulator_.GetClock()->Now() + QuicTime::Delta::FromSeconds(12);
	simulator_.RunUntil(
	[this, end_time]() { return simulator_.GetClock()->Now() >= end_time; });

	for (QuicEndpoint* endpoint :
	{endpoint_a.get(), endpoint_b.get(), endpoint_c.get()}) {
	EXPECT_EQ(2u * 1024u * 1024u, endpoint->bytes_transferred());
	EXPECT_GE(endpoint->connection()->GetStats().packets_lost, 0u);
	}
	for (QuicEndpoint* endpoint :
	{endpoint_d_a.get(), endpoint_d_b.get(), endpoint_d_c.get()}) {
	EXPECT_EQ(2u * 1024u * 1024u, endpoint->bytes_received());
	EXPECT_FALSE(endpoint->wrong_data_received());
	}
	}

	} // namespace simulator
	} // namespace quic