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chromium / chromium / src / 8ed6f86e3e08945205747a74de58972d57851968 / . / net / quic / quic_sent_packet_manager_test.cc
blob: d641472ea08dcb35627fa715409702233da31671 [file] [log] [blame]
// Copyright 2013 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/quic/quic_sent_packet_manager.h"
#include "base/stl_util.h"
#include "net/quic/quic_flags.h"
#include "net/quic/test_tools/quic_config_peer.h"
#include "net/quic/test_tools/quic_sent_packet_manager_peer.h"
#include "net/quic/test_tools/quic_test_utils.h"
#include "testing/gmock/include/gmock/gmock.h"
#include "testing/gtest/include/gtest/gtest.h"
using std::vector;
using testing::AnyNumber;
using testing::ElementsAre;
using testing::IsEmpty;
using testing::Not;
using testing::Pair;
using testing::Pointwise;
using testing::Return;
using testing::StrictMock;
using testing::_;
namespace net {
namespace test {
namespace {
// Default packet length.
const uint32_t kDefaultLength = 1000;
// Stream ID for data sent in CreatePacket().
const QuicStreamId kStreamId = 7;
// Minimum number of consecutive RTOs before path is considered to be degrading.
const size_t kMinTimeoutsBeforePathDegrading = 2;
// Matcher to check the key of the key-value pair it receives as first argument
// equals its second argument.
MATCHER(KeyEq, "") {
return std::tr1::get<0>(arg).first == std::tr1::get<1>(arg);
}
class MockDebugDelegate : public QuicSentPacketManager::DebugDelegate {
public:
MOCK_METHOD2(OnSpuriousPacketRetransmission,
void(TransmissionType transmission_type,
QuicByteCount byte_size));
MOCK_METHOD3(OnPacketLoss,
void(QuicPacketNumber lost_packet_number,
TransmissionType transmission_type,
QuicTime detection_time));
};
class QuicSentPacketManagerTest : public ::testing::TestWithParam<bool> {
protected:
QuicSentPacketManagerTest()
: manager_(Perspective::IS_SERVER,
kDefaultPathId,
&clock_,
&stats_,
kCubic,
kNack,
/*delegate=*/nullptr),
send_algorithm_(new StrictMock<MockSendAlgorithm>),
network_change_visitor_(new StrictMock<MockNetworkChangeVisitor>) {
// These tests only work with pacing enabled.
saved_FLAGS_quic_disable_pacing_ = FLAGS_quic_disable_pacing;
FLAGS_quic_disable_pacing = false;
QuicSentPacketManagerPeer::SetSendAlgorithm(&manager_, send_algorithm_);
// Disable tail loss probes for most tests.
QuicSentPacketManagerPeer::SetMaxTailLossProbes(&manager_, 0);
// Advance the time 1s so the send times are never QuicTime::Zero.
clock_.AdvanceTime(QuicTime::Delta::FromMilliseconds(1000));
manager_.set_network_change_visitor(network_change_visitor_.get());
EXPECT_CALL(*send_algorithm_, HasReliableBandwidthEstimate())
.Times(AnyNumber());
EXPECT_CALL(*send_algorithm_, BandwidthEstimate())
.Times(AnyNumber())
.WillRepeatedly(Return(QuicBandwidth::Zero()));
EXPECT_CALL(*send_algorithm_, InSlowStart()).Times(AnyNumber());
EXPECT_CALL(*send_algorithm_, InRecovery()).Times(AnyNumber());
}
~QuicSentPacketManagerTest() override {
STLDeleteElements(&packets_);
FLAGS_quic_disable_pacing = saved_FLAGS_quic_disable_pacing_;
}
QuicByteCount BytesInFlight() {
return QuicSentPacketManagerPeer::GetBytesInFlight(&manager_);
}
void VerifyUnackedPackets(QuicPacketNumber* packets, size_t num_packets) {
if (num_packets == 0) {
EXPECT_FALSE(manager_.HasUnackedPackets());
EXPECT_EQ(0u, QuicSentPacketManagerPeer::GetNumRetransmittablePackets(
&manager_));
return;
}
EXPECT_TRUE(manager_.HasUnackedPackets());
EXPECT_EQ(packets[0], manager_.GetLeastUnacked());
for (size_t i = 0; i < num_packets; ++i) {
EXPECT_TRUE(manager_.IsUnacked(packets[i])) << packets[i];
}
}
void VerifyRetransmittablePackets(QuicPacketNumber* packets,
size_t num_packets) {
EXPECT_EQ(
num_packets,
QuicSentPacketManagerPeer::GetNumRetransmittablePackets(&manager_));
for (size_t i = 0; i < num_packets; ++i) {
EXPECT_TRUE(manager_.HasRetransmittableFrames(packets[i]))
<< " packets[" << i << "]:" << packets[i];
}
}
void ExpectAck(QuicPacketNumber largest_observed) {
EXPECT_CALL(
*send_algorithm_,
OnCongestionEvent(true, _, ElementsAre(Pair(largest_observed, _)),
IsEmpty()));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
}
void ExpectUpdatedRtt(QuicPacketNumber largest_observed) {
EXPECT_CALL(*send_algorithm_,
OnCongestionEvent(true, _, IsEmpty(), IsEmpty()));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
}
void ExpectAckAndLoss(bool rtt_updated,
QuicPacketNumber largest_observed,
QuicPacketNumber lost_packet) {
EXPECT_CALL(*send_algorithm_,
OnCongestionEvent(rtt_updated, _,
ElementsAre(Pair(largest_observed, _)),
ElementsAre(Pair(lost_packet, _))));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
}
// |packets_acked| and |packets_lost| should be in packet number order.
void ExpectAcksAndLosses(bool rtt_updated,
QuicPacketNumber* packets_acked,
size_t num_packets_acked,
QuicPacketNumber* packets_lost,
size_t num_packets_lost) {
vector<QuicPacketNumber> ack_vector;
for (size_t i = 0; i < num_packets_acked; ++i) {
ack_vector.push_back(packets_acked[i]);
}
vector<QuicPacketNumber> lost_vector;
for (size_t i = 0; i < num_packets_lost; ++i) {
lost_vector.push_back(packets_lost[i]);
}
EXPECT_CALL(
*send_algorithm_,
OnCongestionEvent(rtt_updated, _, Pointwise(KeyEq(), ack_vector),
Pointwise(KeyEq(), lost_vector)));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange())
.Times(AnyNumber());
EXPECT_CALL(*network_change_visitor_, OnRttChange()).Times(AnyNumber());
}
void RetransmitAndSendPacket(QuicPacketNumber old_packet_number,
QuicPacketNumber new_packet_number) {
QuicSentPacketManagerPeer::MarkForRetransmission(
&manager_, old_packet_number, TLP_RETRANSMISSION);
EXPECT_TRUE(manager_.HasPendingRetransmissions());
PendingRetransmission next_retransmission =
manager_.NextPendingRetransmission();
EXPECT_EQ(old_packet_number, next_retransmission.packet_number);
EXPECT_EQ(TLP_RETRANSMISSION, next_retransmission.transmission_type);
EXPECT_CALL(*send_algorithm_,
OnPacketSent(_, BytesInFlight(), new_packet_number,
kDefaultLength, HAS_RETRANSMITTABLE_DATA))
.WillOnce(Return(true));
SerializedPacket packet(CreatePacket(new_packet_number, false));
manager_.OnPacketSent(&packet, old_packet_number, clock_.Now(),
kDefaultLength, TLP_RETRANSMISSION,
HAS_RETRANSMITTABLE_DATA);
EXPECT_TRUE(QuicSentPacketManagerPeer::IsRetransmission(&manager_,
new_packet_number));
}
SerializedPacket CreateDataPacket(QuicPacketNumber packet_number) {
return CreatePacket(packet_number, true);
}
SerializedPacket CreatePacket(QuicPacketNumber packet_number,
bool retransmittable) {
SerializedPacket packet(kDefaultPathId, packet_number,
PACKET_6BYTE_PACKET_NUMBER, nullptr, kDefaultLength,
0u, false, false);
if (retransmittable) {
packet.retransmittable_frames.push_back(
QuicFrame(new QuicStreamFrame(kStreamId, false, 0, StringPiece())));
}
return packet;
}
SerializedPacket CreateFecPacket(QuicPacketNumber packet_number) {
SerializedPacket serialized(kDefaultPathId, packet_number,
PACKET_6BYTE_PACKET_NUMBER, nullptr,
kDefaultLength, 0u, false, false);
serialized.is_fec_packet = true;
return serialized;
}
void SendDataPacket(QuicPacketNumber packet_number) {
EXPECT_CALL(*send_algorithm_,
OnPacketSent(_, BytesInFlight(), packet_number, _, _))
.Times(1)
.WillOnce(Return(true));
SerializedPacket packet(CreateDataPacket(packet_number));
manager_.OnPacketSent(&packet, 0, clock_.Now(), packet.encrypted_length,
NOT_RETRANSMISSION, HAS_RETRANSMITTABLE_DATA);
}
void SendCryptoPacket(QuicPacketNumber packet_number) {
EXPECT_CALL(*send_algorithm_,
OnPacketSent(_, BytesInFlight(), packet_number, kDefaultLength,
HAS_RETRANSMITTABLE_DATA))
.Times(1)
.WillOnce(Return(true));
SerializedPacket packet(CreateDataPacket(packet_number));
packet.retransmittable_frames.push_back(
QuicFrame(new QuicStreamFrame(1, false, 0, StringPiece())));
packet.has_crypto_handshake = IS_HANDSHAKE;
manager_.OnPacketSent(&packet, 0, clock_.Now(), packet.encrypted_length,
NOT_RETRANSMISSION, HAS_RETRANSMITTABLE_DATA);
}
void SendFecPacket(QuicPacketNumber packet_number) {
EXPECT_CALL(*send_algorithm_,
OnPacketSent(_, BytesInFlight(), packet_number, kDefaultLength,
HAS_RETRANSMITTABLE_DATA))
.Times(1)
.WillOnce(Return(true));
SerializedPacket packet(CreateFecPacket(packet_number));
manager_.OnPacketSent(&packet, 0, clock_.Now(), packet.encrypted_length,
NOT_RETRANSMISSION, NO_RETRANSMITTABLE_DATA);
}
void SendAckPacket(QuicPacketNumber packet_number) {
EXPECT_CALL(*send_algorithm_,
OnPacketSent(_, BytesInFlight(), packet_number, kDefaultLength,
NO_RETRANSMITTABLE_DATA))
.Times(1)
.WillOnce(Return(false));
SerializedPacket packet(CreatePacket(packet_number, false));
manager_.OnPacketSent(&packet, 0, clock_.Now(), packet.encrypted_length,
NOT_RETRANSMISSION, NO_RETRANSMITTABLE_DATA);
}
// Based on QuicConnection's WritePendingRetransmissions.
void RetransmitNextPacket(QuicPacketNumber retransmission_packet_number) {
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_CALL(*send_algorithm_,
OnPacketSent(_, _, retransmission_packet_number, kDefaultLength,
HAS_RETRANSMITTABLE_DATA))
.Times(1)
.WillOnce(Return(true));
const PendingRetransmission pending = manager_.NextPendingRetransmission();
SerializedPacket packet(CreatePacket(retransmission_packet_number, false));
manager_.OnPacketSent(&packet, pending.packet_number, clock_.Now(),
kDefaultLength, pending.transmission_type,
HAS_RETRANSMITTABLE_DATA);
}
QuicSentPacketManager manager_;
vector<QuicEncryptedPacket*> packets_;
MockClock clock_;
QuicConnectionStats stats_;
MockSendAlgorithm* send_algorithm_;
scoped_ptr<MockNetworkChangeVisitor> network_change_visitor_;
bool saved_FLAGS_quic_disable_pacing_;
};
TEST_F(QuicSentPacketManagerTest, IsUnacked) {
VerifyUnackedPackets(nullptr, 0);
SendDataPacket(1);
QuicPacketNumber unacked[] = {1};
VerifyUnackedPackets(unacked, arraysize(unacked));
QuicPacketNumber retransmittable[] = {1};
VerifyRetransmittablePackets(retransmittable, arraysize(retransmittable));
}
TEST_F(QuicSentPacketManagerTest, IsUnAckedRetransmit) {
SendDataPacket(1);
RetransmitAndSendPacket(1, 2);
EXPECT_TRUE(QuicSentPacketManagerPeer::IsRetransmission(&manager_, 2));
QuicPacketNumber unacked[] = {1, 2};
VerifyUnackedPackets(unacked, arraysize(unacked));
QuicPacketNumber retransmittable[] = {2};
VerifyRetransmittablePackets(retransmittable, arraysize(retransmittable));
}
TEST_F(QuicSentPacketManagerTest, RetransmitThenAck) {
SendDataPacket(1);
RetransmitAndSendPacket(1, 2);
// Ack 2 but not 1.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 2;
ack_frame.missing_packets.Add(1);
ExpectAck(2);
manager_.OnIncomingAck(ack_frame, clock_.Now());
// Packet 1 is unacked, pending, but not retransmittable.
QuicPacketNumber unacked[] = {1};
VerifyUnackedPackets(unacked, arraysize(unacked));
EXPECT_TRUE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
VerifyRetransmittablePackets(nullptr, 0);
}
TEST_F(QuicSentPacketManagerTest, RetransmitThenAckBeforeSend) {
SendDataPacket(1);
QuicSentPacketManagerPeer::MarkForRetransmission(&manager_, 1,
TLP_RETRANSMISSION);
EXPECT_TRUE(manager_.HasPendingRetransmissions());
// Ack 1.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 1;
ExpectAck(1);
manager_.OnIncomingAck(ack_frame, clock_.Now());
// There should no longer be a pending retransmission.
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// No unacked packets remain.
VerifyUnackedPackets(nullptr, 0);
VerifyRetransmittablePackets(nullptr, 0);
EXPECT_EQ(0u, stats_.packets_spuriously_retransmitted);
}
TEST_F(QuicSentPacketManagerTest, RetransmitThenStopRetransmittingBeforeSend) {
SendDataPacket(1);
QuicSentPacketManagerPeer::MarkForRetransmission(&manager_, 1,
TLP_RETRANSMISSION);
EXPECT_TRUE(manager_.HasPendingRetransmissions());
manager_.CancelRetransmissionsForStream(kStreamId);
// There should no longer be a pending retransmission.
EXPECT_FALSE(manager_.HasPendingRetransmissions());
QuicPacketNumber unacked[] = {1};
VerifyUnackedPackets(unacked, arraysize(unacked));
VerifyRetransmittablePackets(nullptr, 0);
EXPECT_EQ(0u, stats_.packets_spuriously_retransmitted);
}
TEST_F(QuicSentPacketManagerTest, RetransmitThenAckPrevious) {
SendDataPacket(1);
RetransmitAndSendPacket(1, 2);
QuicTime::Delta rtt = QuicTime::Delta::FromMilliseconds(15);
clock_.AdvanceTime(rtt);
// Ack 1 but not 2.
ExpectAck(1);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 1;
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
// 2 remains unacked, but no packets have retransmittable data.
QuicPacketNumber unacked[] = {2};
VerifyUnackedPackets(unacked, arraysize(unacked));
EXPECT_TRUE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
VerifyRetransmittablePackets(nullptr, 0);
EXPECT_EQ(1u, stats_.packets_spuriously_retransmitted);
}
TEST_F(QuicSentPacketManagerTest, RetransmitThenAckPreviousThenNackRetransmit) {
SendDataPacket(1);
RetransmitAndSendPacket(1, 2);
QuicTime::Delta rtt = QuicTime::Delta::FromMilliseconds(15);
clock_.AdvanceTime(rtt);
// First, ACK packet 1 which makes packet 2 non-retransmittable.
ExpectAck(1);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 1;
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
SendDataPacket(3);
SendDataPacket(4);
SendDataPacket(5);
clock_.AdvanceTime(rtt);
// Next, NACK packet 2 three times.
ack_frame.largest_observed = 3;
ack_frame.missing_packets.Add(2);
ExpectAck(3);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
ack_frame.largest_observed = 4;
ExpectAck(4);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
ack_frame.largest_observed = 5;
ExpectAckAndLoss(true, 5, 2);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
// No packets remain unacked.
VerifyUnackedPackets(nullptr, 0);
EXPECT_FALSE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
VerifyRetransmittablePackets(nullptr, 0);
// Verify that the retransmission alarm would not fire,
// since there is no retransmittable data outstanding.
EXPECT_EQ(QuicTime::Zero(), manager_.GetRetransmissionTime());
}
TEST_F(QuicSentPacketManagerTest,
DISABLED_RetransmitTwiceThenAckPreviousBeforeSend) {
SendDataPacket(1);
RetransmitAndSendPacket(1, 2);
// Fire the RTO, which will mark 2 for retransmission (but will not send it).
EXPECT_CALL(*send_algorithm_, OnRetransmissionTimeout(true));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
// Ack 1 but not 2, before 2 is able to be sent.
// Since 1 has been retransmitted, it has already been lost, and so the
// send algorithm is not informed that it has been ACK'd.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 1;
ExpectUpdatedRtt(1);
EXPECT_CALL(*send_algorithm_, RevertRetransmissionTimeout());
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
// Since 2 was marked for retransmit, when 1 is acked, 2 is kept for RTT.
QuicPacketNumber unacked[] = {2};
VerifyUnackedPackets(unacked, arraysize(unacked));
EXPECT_FALSE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
VerifyRetransmittablePackets(nullptr, 0);
// Verify that the retransmission alarm would not fire,
// since there is no retransmittable data outstanding.
EXPECT_EQ(QuicTime::Zero(), manager_.GetRetransmissionTime());
}
TEST_F(QuicSentPacketManagerTest, RetransmitTwiceThenAckFirst) {
StrictMock<MockDebugDelegate> debug_delegate;
EXPECT_CALL(debug_delegate, OnSpuriousPacketRetransmission(TLP_RETRANSMISSION,
kDefaultLength))
.Times(2);
manager_.set_debug_delegate(&debug_delegate);
SendDataPacket(1);
RetransmitAndSendPacket(1, 2);
RetransmitAndSendPacket(2, 3);
QuicTime::Delta rtt = QuicTime::Delta::FromMilliseconds(15);
clock_.AdvanceTime(rtt);
// Ack 1 but not 2 or 3.
ExpectAck(1);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 1;
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
// 2 and 3 remain unacked, but no packets have retransmittable data.
QuicPacketNumber unacked[] = {2, 3};
VerifyUnackedPackets(unacked, arraysize(unacked));
EXPECT_TRUE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
VerifyRetransmittablePackets(nullptr, 0);
// Ensure packet 2 is lost when 4 is sent and 3 and 4 are acked.
SendDataPacket(4);
ack_frame.largest_observed = 4;
ack_frame.missing_packets.Add(2);
QuicPacketNumber acked[] = {3, 4};
ExpectAcksAndLosses(true, acked, arraysize(acked), nullptr, 0);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
QuicPacketNumber unacked2[] = {2};
VerifyUnackedPackets(unacked2, arraysize(unacked2));
EXPECT_TRUE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
SendDataPacket(5);
ack_frame.largest_observed = 5;
ExpectAckAndLoss(true, 5, 2);
EXPECT_CALL(debug_delegate, OnPacketLoss(2, LOSS_RETRANSMISSION, _));
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
VerifyUnackedPackets(nullptr, 0);
EXPECT_FALSE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
EXPECT_EQ(2u, stats_.packets_spuriously_retransmitted);
}
TEST_F(QuicSentPacketManagerTest, LoseButDontRetransmitRevivedPacket) {
StrictMock<MockDebugDelegate> debug_delegate;
manager_.set_debug_delegate(&debug_delegate);
SendDataPacket(1);
SendDataPacket(2);
SendFecPacket(3);
SendDataPacket(4);
// Ack 2 and 3, and mark 1 as revived.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 3;
ack_frame.missing_packets.Add(1);
ack_frame.latest_revived_packet = 1;
QuicPacketNumber acked[] = {2, 3};
ExpectAcksAndLosses(true, acked, arraysize(acked), nullptr, 0);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_FALSE(manager_.HasPendingRetransmissions());
QuicPacketNumber unacked[] = {1, 4};
VerifyUnackedPackets(unacked, arraysize(unacked));
EXPECT_TRUE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
QuicPacketNumber retransmittable[] = {4};
VerifyRetransmittablePackets(retransmittable, arraysize(retransmittable));
// Ack the 4th packet and expect the 1st to be considered lost.
if (FLAGS_quic_log_loss_event) {
EXPECT_CALL(debug_delegate, OnPacketLoss(1, LOSS_RETRANSMISSION, _));
}
ack_frame.largest_observed = 4;
ExpectAckAndLoss(true, 4, 1);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_FALSE(manager_.HasPendingRetransmissions());
VerifyRetransmittablePackets(nullptr, 0);
}
TEST_F(QuicSentPacketManagerTest, MarkLostThenReviveAndDontRetransmitPacket) {
SendDataPacket(1);
SendDataPacket(2);
SendDataPacket(3);
SendDataPacket(4);
SendFecPacket(5);
// Ack 2, 3, and 4, and expect the 1st to be considered lost.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 4;
ack_frame.missing_packets.Add(1);
QuicPacketNumber acked[] = {2, 3, 4};
QuicPacketNumber lost[] = {1};
ExpectAcksAndLosses(true, acked, arraysize(acked), lost, arraysize(lost));
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_TRUE(manager_.HasPendingRetransmissions());
QuicPacketNumber unacked[] = {1, 5};
VerifyUnackedPackets(unacked, arraysize(unacked));
QuicPacketNumber retransmittable[] = {1};
VerifyRetransmittablePackets(retransmittable, arraysize(retransmittable));
// Ack 5th packet (FEC) and revive 1st packet. 1st packet should now be
// removed from pending retransmissions map.
ack_frame.largest_observed = 5;
ack_frame.latest_revived_packet = 1;
ExpectAck(5);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_FALSE(manager_.HasPendingRetransmissions());
VerifyRetransmittablePackets(nullptr, 0);
}
TEST_F(QuicSentPacketManagerTest, AckPreviousTransmissionThenTruncatedAck) {
SendDataPacket(1);
RetransmitAndSendPacket(1, 2);
RetransmitAndSendPacket(2, 3);
RetransmitAndSendPacket(3, 4);
SendDataPacket(5);
SendDataPacket(6);
SendDataPacket(7);
SendDataPacket(8);
SendDataPacket(9);
// Ack previous transmission
{
QuicAckFrame ack_frame;
ack_frame.largest_observed = 2;
ack_frame.missing_packets.Add(1);
ExpectAck(2);
manager_.OnIncomingAck(ack_frame, clock_.Now());
EXPECT_TRUE(manager_.IsUnacked(4));
}
// Truncated ack with 4 NACKs
{
QuicAckFrame ack_frame;
ack_frame.largest_observed = 6;
ack_frame.missing_packets.Add(3, 7);
ack_frame.is_truncated = true;
ExpectAckAndLoss(true, 1, 3);
manager_.OnIncomingAck(ack_frame, clock_.Now());
}
// High water mark will be raised.
QuicPacketNumber unacked[] = {4, 5, 6, 7, 8, 9};
VerifyUnackedPackets(unacked, arraysize(unacked));
QuicPacketNumber retransmittable[] = {5, 6, 7, 8, 9};
VerifyRetransmittablePackets(retransmittable, arraysize(retransmittable));
}
TEST_F(QuicSentPacketManagerTest, GetLeastUnacked) {
EXPECT_EQ(1u, manager_.GetLeastUnacked());
}
TEST_F(QuicSentPacketManagerTest, GetLeastUnackedUnacked) {
SendDataPacket(1);
EXPECT_EQ(1u, manager_.GetLeastUnacked());
}
TEST_F(QuicSentPacketManagerTest, GetLeastUnackedUnackedFec) {
SendFecPacket(1);
EXPECT_EQ(1u, manager_.GetLeastUnacked());
}
TEST_F(QuicSentPacketManagerTest, GetLeastUnackedAndDiscard) {
VerifyUnackedPackets(nullptr, 0);
SendFecPacket(1);
EXPECT_EQ(1u, manager_.GetLeastUnacked());
SendFecPacket(2);
EXPECT_EQ(1u, manager_.GetLeastUnacked());
SendFecPacket(3);
EXPECT_EQ(1u, manager_.GetLeastUnacked());
QuicPacketNumber unacked[] = {1, 2, 3};
VerifyUnackedPackets(unacked, arraysize(unacked));
VerifyRetransmittablePackets(nullptr, 0);
// Ack 2, so there's an rtt update.
ExpectAck(2);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 2;
ack_frame.missing_packets.Add(1);
manager_.OnIncomingAck(ack_frame, clock_.Now());
EXPECT_EQ(1u, manager_.GetLeastUnacked());
}
TEST_F(QuicSentPacketManagerTest, GetSentTime) {
VerifyUnackedPackets(nullptr, 0);
QuicTime sent_time = clock_.Now();
SendFecPacket(1);
QuicTime sent_time2 = clock_.Now();
SendFecPacket(2);
QuicPacketNumber unacked[] = {1, 2};
VerifyUnackedPackets(unacked, arraysize(unacked));
VerifyRetransmittablePackets(nullptr, 0);
EXPECT_TRUE(manager_.HasUnackedPackets());
EXPECT_EQ(sent_time, QuicSentPacketManagerPeer::GetSentTime(&manager_, 1));
EXPECT_EQ(sent_time2, QuicSentPacketManagerPeer::GetSentTime(&manager_, 2));
}
TEST_F(QuicSentPacketManagerTest, AckAckAndUpdateRtt) {
SendDataPacket(1);
SendAckPacket(2);
// Now ack the ack and expect an RTT update.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 2;
ack_frame.ack_delay_time = QuicTime::Delta::FromMilliseconds(5);
ExpectAck(1);
manager_.OnIncomingAck(ack_frame, clock_.Now());
SendAckPacket(3);
// Now ack the ack and expect only an RTT update.
ack_frame.largest_observed = 3;
ExpectUpdatedRtt(3);
manager_.OnIncomingAck(ack_frame, clock_.Now());
}
TEST_F(QuicSentPacketManagerTest, Rtt) {
QuicPacketNumber packet_number = 1;
QuicTime::Delta expected_rtt = QuicTime::Delta::FromMilliseconds(15);
SendDataPacket(packet_number);
clock_.AdvanceTime(QuicTime::Delta::FromMilliseconds(20));
ExpectAck(packet_number);
QuicAckFrame ack_frame;
ack_frame.largest_observed = packet_number;
ack_frame.ack_delay_time = QuicTime::Delta::FromMilliseconds(5);
manager_.OnIncomingAck(ack_frame, clock_.Now());
EXPECT_EQ(expected_rtt,
QuicSentPacketManagerPeer::GetRttStats(&manager_)->latest_rtt());
}
TEST_F(QuicSentPacketManagerTest, RttWithInvalidDelta) {
// Expect that the RTT is equal to the local time elapsed, since the
// ack_delay_time is larger than the local time elapsed
// and is hence invalid.
QuicPacketNumber packet_number = 1;
QuicTime::Delta expected_rtt = QuicTime::Delta::FromMilliseconds(10);
SendDataPacket(packet_number);
clock_.AdvanceTime(expected_rtt);
ExpectAck(packet_number);
QuicAckFrame ack_frame;
ack_frame.largest_observed = packet_number;
ack_frame.ack_delay_time = QuicTime::Delta::FromMilliseconds(11);
manager_.OnIncomingAck(ack_frame, clock_.Now());
EXPECT_EQ(expected_rtt,
QuicSentPacketManagerPeer::GetRttStats(&manager_)->latest_rtt());
}
TEST_F(QuicSentPacketManagerTest, RttWithInfiniteDelta) {
// Expect that the RTT is equal to the local time elapsed, since the
// ack_delay_time is infinite, and is hence invalid.
QuicPacketNumber packet_number = 1;
QuicTime::Delta expected_rtt = QuicTime::Delta::FromMilliseconds(10);
SendDataPacket(packet_number);
clock_.AdvanceTime(expected_rtt);
ExpectAck(packet_number);
QuicAckFrame ack_frame;
ack_frame.largest_observed = packet_number;
ack_frame.ack_delay_time = QuicTime::Delta::Infinite();
manager_.OnIncomingAck(ack_frame, clock_.Now());
EXPECT_EQ(expected_rtt,
QuicSentPacketManagerPeer::GetRttStats(&manager_)->latest_rtt());
}
TEST_F(QuicSentPacketManagerTest, RttZeroDelta) {
// Expect that the RTT is the time between send and receive since the
// ack_delay_time is zero.
QuicPacketNumber packet_number = 1;
QuicTime::Delta expected_rtt = QuicTime::Delta::FromMilliseconds(10);
SendDataPacket(packet_number);
clock_.AdvanceTime(expected_rtt);
ExpectAck(packet_number);
QuicAckFrame ack_frame;
ack_frame.largest_observed = packet_number;
ack_frame.ack_delay_time = QuicTime::Delta::Zero();
manager_.OnIncomingAck(ack_frame, clock_.Now());
EXPECT_EQ(expected_rtt,
QuicSentPacketManagerPeer::GetRttStats(&manager_)->latest_rtt());
}
TEST_F(QuicSentPacketManagerTest, TailLossProbeTimeout) {
QuicSentPacketManagerPeer::SetMaxTailLossProbes(&manager_, 2);
// Send 1 packet.
QuicPacketNumber packet_number = 1;
SendDataPacket(packet_number);
// The first tail loss probe retransmits 1 packet.
manager_.OnRetransmissionTimeout();
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
manager_.MaybeRetransmitTailLossProbe();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
RetransmitNextPacket(2);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// The second tail loss probe retransmits 1 packet.
manager_.OnRetransmissionTimeout();
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
manager_.MaybeRetransmitTailLossProbe();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
RetransmitNextPacket(3);
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Infinite()));
EXPECT_EQ(QuicTime::Delta::Infinite(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// Ack the third and ensure the first two are still pending.
ExpectAck(3);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 3;
ack_frame.missing_packets.Add(1, 3);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_TRUE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
// Acking two more packets will lose both of them due to nacks.
ack_frame.largest_observed = 5;
QuicPacketNumber lost[] = {1, 2};
ExpectAcksAndLosses(false, nullptr, 0, lost, arraysize(lost));
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_FALSE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
EXPECT_EQ(2u, stats_.tlp_count);
EXPECT_EQ(0u, stats_.rto_count);
}
TEST_F(QuicSentPacketManagerTest, TailLossProbeThenRTO) {
QuicSentPacketManagerPeer::SetMaxTailLossProbes(&manager_, 2);
// Send 100 packets.
const size_t kNumSentPackets = 100;
for (size_t i = 1; i <= kNumSentPackets; ++i) {
SendDataPacket(i);
}
QuicTime rto_packet_time = clock_.Now();
// Advance the time.
clock_.AdvanceTime(manager_.GetRetransmissionTime().Subtract(clock_.Now()));
// The first tail loss probe retransmits 1 packet.
manager_.OnRetransmissionTimeout();
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
manager_.MaybeRetransmitTailLossProbe();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
RetransmitNextPacket(101);
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Infinite()));
EXPECT_EQ(QuicTime::Delta::Infinite(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
clock_.AdvanceTime(manager_.GetRetransmissionTime().Subtract(clock_.Now()));
// The second tail loss probe retransmits 1 packet.
manager_.OnRetransmissionTimeout();
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_TRUE(manager_.MaybeRetransmitTailLossProbe());
EXPECT_TRUE(manager_.HasPendingRetransmissions());
RetransmitNextPacket(102);
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Infinite()));
EXPECT_EQ(QuicTime::Delta::Infinite(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
// Ensure the RTO is set based on the correct packet.
rto_packet_time = clock_.Now();
EXPECT_CALL(*send_algorithm_, RetransmissionDelay())
.WillOnce(Return(QuicTime::Delta::FromSeconds(1)));
EXPECT_EQ(rto_packet_time.Add(QuicTime::Delta::FromSeconds(1)),
manager_.GetRetransmissionTime());
// Advance the time enough to ensure all packets are RTO'd.
clock_.AdvanceTime(QuicTime::Delta::FromMilliseconds(1000));
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(2u, stats_.tlp_count);
EXPECT_EQ(1u, stats_.rto_count);
// Send and Ack the RTO and ensure OnRetransmissionTimeout is called.
EXPECT_EQ(102 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(103);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 103;
ack_frame.missing_packets.Add(0, 103);
EXPECT_CALL(*send_algorithm_, OnRetransmissionTimeout(true));
EXPECT_CALL(*send_algorithm_,
OnCongestionEvent(true, _, ElementsAre(Pair(103, _)), _));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
// All packets before 103 should be lost.
EXPECT_EQ(0u, QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
}
TEST_F(QuicSentPacketManagerTest, CryptoHandshakeTimeout) {
// Send 2 crypto packets and 3 data packets.
const size_t kNumSentCryptoPackets = 2;
for (size_t i = 1; i <= kNumSentCryptoPackets; ++i) {
SendCryptoPacket(i);
}
const size_t kNumSentDataPackets = 3;
for (size_t i = 1; i <= kNumSentDataPackets; ++i) {
SendDataPacket(kNumSentCryptoPackets + i);
}
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// The first retransmits 2 packets.
manager_.OnRetransmissionTimeout();
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
RetransmitNextPacket(6);
RetransmitNextPacket(7);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// The second retransmits 2 packets.
manager_.OnRetransmissionTimeout();
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
RetransmitNextPacket(8);
RetransmitNextPacket(9);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Now ack the two crypto packets and the speculatively encrypted request,
// and ensure the first four crypto packets get abandoned, but not lost.
QuicPacketNumber acked[] = {3, 4, 5, 8, 9};
ExpectAcksAndLosses(true, acked, arraysize(acked), nullptr, 0);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 9;
ack_frame.missing_packets.Add(1, 3);
ack_frame.missing_packets.Add(6, 8);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_FALSE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
}
TEST_F(QuicSentPacketManagerTest, CryptoHandshakeTimeoutVersionNegotiation) {
// Send 2 crypto packets and 3 data packets.
const size_t kNumSentCryptoPackets = 2;
for (size_t i = 1; i <= kNumSentCryptoPackets; ++i) {
SendCryptoPacket(i);
}
const size_t kNumSentDataPackets = 3;
for (size_t i = 1; i <= kNumSentDataPackets; ++i) {
SendDataPacket(kNumSentCryptoPackets + i);
}
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// The first retransmission timeout retransmits 2 crypto packets.
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(6);
RetransmitNextPacket(7);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Now act like a version negotiation packet arrived, which would cause all
// unacked packets to be retransmitted.
manager_.RetransmitUnackedPackets(ALL_UNACKED_RETRANSMISSION);
// Ensure the first two pending packets are the crypto retransmits.
ASSERT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(6u, manager_.NextPendingRetransmission().packet_number);
RetransmitNextPacket(8);
EXPECT_EQ(7u, manager_.NextPendingRetransmission().packet_number);
RetransmitNextPacket(9);
EXPECT_TRUE(manager_.HasPendingRetransmissions());
// Send 3 more data packets and ensure the least unacked is raised.
RetransmitNextPacket(10);
RetransmitNextPacket(11);
RetransmitNextPacket(12);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_EQ(1u, manager_.GetLeastUnacked());
// Least unacked isn't raised until an ack is received, so ack the
// crypto packets.
QuicPacketNumber acked[] = {8, 9};
ExpectAcksAndLosses(true, acked, arraysize(acked), nullptr, 0);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 9;
for (QuicPacketNumber i = 1; i < 8; ++i) {
ack_frame.missing_packets.Add(i);
}
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_EQ(10u, manager_.GetLeastUnacked());
}
TEST_F(QuicSentPacketManagerTest, CryptoHandshakeSpuriousRetransmission) {
// Send 1 crypto packet.
SendCryptoPacket(1);
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Retransmit the crypto packet as 2.
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(2);
// Retransmit the crypto packet as 3.
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(3);
// Now ack the second crypto packet, and ensure the first gets removed, but
// the third does not.
ExpectUpdatedRtt(2);
QuicAckFrame ack_frame;
ack_frame.largest_observed = 2;
ack_frame.missing_packets.Add(1);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_FALSE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
QuicPacketNumber unacked[] = {3};
VerifyUnackedPackets(unacked, arraysize(unacked));
}
TEST_F(QuicSentPacketManagerTest, CryptoHandshakeTimeoutUnsentDataPacket) {
// Send 2 crypto packets and 1 data packet.
const size_t kNumSentCryptoPackets = 2;
for (size_t i = 1; i <= kNumSentCryptoPackets; ++i) {
SendCryptoPacket(i);
}
SendDataPacket(3);
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Retransmit 2 crypto packets, but not the serialized packet.
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(4);
RetransmitNextPacket(5);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
}
TEST_F(QuicSentPacketManagerTest,
CryptoHandshakeRetransmissionThenRetransmitAll) {
// Send 1 crypto packet.
SendCryptoPacket(1);
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Retransmit the crypto packet as 2.
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(2);
// Now retransmit all the unacked packets, which occurs when there is a
// version negotiation.
manager_.RetransmitUnackedPackets(ALL_UNACKED_RETRANSMISSION);
QuicPacketNumber unacked[] = {1, 2};
VerifyUnackedPackets(unacked, arraysize(unacked));
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
EXPECT_FALSE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
}
TEST_F(QuicSentPacketManagerTest,
CryptoHandshakeRetransmissionThenNeuterAndAck) {
// Send 1 crypto packet.
SendCryptoPacket(1);
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Retransmit the crypto packet as 2.
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(2);
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Retransmit the crypto packet as 3.
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(3);
EXPECT_TRUE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
// Now neuter all unacked unencrypted packets, which occurs when the
// connection goes forward secure.
manager_.NeuterUnencryptedPackets();
EXPECT_FALSE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
QuicPacketNumber unacked[] = {1, 2, 3};
VerifyUnackedPackets(unacked, arraysize(unacked));
VerifyRetransmittablePackets(nullptr, 0);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_FALSE(QuicSentPacketManagerPeer::HasUnackedCryptoPackets(&manager_));
EXPECT_FALSE(QuicSentPacketManagerPeer::HasPendingPackets(&manager_));
// Ensure both packets get discarded when packet 2 is acked.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 3;
ack_frame.missing_packets.Add(1, 3);
ExpectUpdatedRtt(3);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
VerifyUnackedPackets(nullptr, 0);
VerifyRetransmittablePackets(nullptr, 0);
}
TEST_F(QuicSentPacketManagerTest, RetransmissionTimeout) {
StrictMock<MockDebugDelegate> debug_delegate;
manager_.set_debug_delegate(&debug_delegate);
// Send 100 packets.
const size_t kNumSentPackets = 100;
for (size_t i = 1; i <= kNumSentPackets; ++i) {
SendDataPacket(i);
}
EXPECT_FALSE(manager_.MaybeRetransmitTailLossProbe());
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(100 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(101);
RetransmitNextPacket(102);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// Ack a retransmission.
QuicAckFrame ack_frame;
ack_frame.ack_delay_time = QuicTime::Delta::Zero();
ack_frame.largest_observed = 102;
ack_frame.missing_packets.Add(0, 102);
// Ensure no packets are lost.
EXPECT_CALL(*send_algorithm_,
OnCongestionEvent(true, _, ElementsAre(Pair(102, _)),
/*lost_packets=*/IsEmpty()));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, OnRetransmissionTimeout(true));
// RTO's use loss detection instead of immediately declaring retransmitted
// packets lost.
if (FLAGS_quic_log_loss_event) {
for (int i = 1; i <= 99; ++i) {
EXPECT_CALL(debug_delegate, OnPacketLoss(i, LOSS_RETRANSMISSION, _));
}
}
manager_.OnIncomingAck(ack_frame, clock_.Now());
}
TEST_F(QuicSentPacketManagerTest, NewRetransmissionTimeout) {
QuicConfig client_config;
QuicTagVector options;
options.push_back(kNRTO);
QuicSentPacketManagerPeer::SetPerspective(&manager_, Perspective::IS_CLIENT);
client_config.SetConnectionOptionsToSend(options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
EXPECT_CALL(*send_algorithm_, PacingRate())
.WillRepeatedly(Return(QuicBandwidth::Zero()));
EXPECT_CALL(*send_algorithm_, GetCongestionWindow())
.WillOnce(Return(10 * kDefaultTCPMSS));
manager_.SetFromConfig(client_config);
EXPECT_TRUE(QuicSentPacketManagerPeer::GetUseNewRto(&manager_));
// Send 100 packets.
const size_t kNumSentPackets = 100;
for (size_t i = 1; i <= kNumSentPackets; ++i) {
SendDataPacket(i);
}
EXPECT_FALSE(manager_.MaybeRetransmitTailLossProbe());
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(100 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(101);
RetransmitNextPacket(102);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// Ack a retransmission and expect no call to OnRetransmissionTimeout.
QuicAckFrame ack_frame;
ack_frame.ack_delay_time = QuicTime::Delta::Zero();
ack_frame.largest_observed = 102;
ack_frame.missing_packets.Add(0, 102);
// This will include packets in the lost packet map.
EXPECT_CALL(*send_algorithm_,
OnCongestionEvent(true, _, ElementsAre(Pair(102, _)),
/*lost_packets=*/Not(IsEmpty())));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.OnIncomingAck(ack_frame, clock_.Now());
}
TEST_F(QuicSentPacketManagerTest, TwoRetransmissionTimeoutsAckSecond) {
// Send 1 packet.
SendDataPacket(1);
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(2);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// Rto a second time.
EXPECT_CALL(*network_change_visitor_, OnPathDegrading());
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(2 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(3);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// Ack a retransmission and ensure OnRetransmissionTimeout is called.
EXPECT_CALL(*send_algorithm_, OnRetransmissionTimeout(true));
QuicAckFrame ack_frame;
ack_frame.ack_delay_time = QuicTime::Delta::Zero();
ack_frame.largest_observed = 2;
ack_frame.missing_packets.Add(1);
ExpectAck(2);
manager_.OnIncomingAck(ack_frame, clock_.Now());
// The original packet and newest should be outstanding.
EXPECT_EQ(2 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
}
TEST_F(QuicSentPacketManagerTest, TwoRetransmissionTimeoutsAckFirst) {
// Send 1 packet.
SendDataPacket(1);
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(2);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// Rto a second time.
EXPECT_CALL(*network_change_visitor_, OnPathDegrading());
manager_.OnRetransmissionTimeout();
EXPECT_TRUE(manager_.HasPendingRetransmissions());
EXPECT_EQ(2 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(3);
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// Ack a retransmission and ensure OnRetransmissionTimeout is called.
EXPECT_CALL(*send_algorithm_, OnRetransmissionTimeout(true));
QuicAckFrame ack_frame;
ack_frame.ack_delay_time = QuicTime::Delta::Zero();
ack_frame.largest_observed = 3;
ack_frame.missing_packets.Add(1, 3);
ExpectAck(3);
manager_.OnIncomingAck(ack_frame, clock_.Now());
// The first two packets should still be outstanding.
EXPECT_EQ(2 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
}
TEST_F(QuicSentPacketManagerTest, OnPathDegrading) {
SendDataPacket(1);
QuicTime::Delta delay = QuicTime::Delta::FromMilliseconds(500);
EXPECT_CALL(*send_algorithm_, RetransmissionDelay())
.WillRepeatedly(Return(delay));
for (size_t i = 1; i < kMinTimeoutsBeforePathDegrading; ++i) {
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(i + 2);
}
// Next RTO should cause network_change_visitor_'s OnPathDegrading method
// to be called.
EXPECT_CALL(*network_change_visitor_, OnPathDegrading());
manager_.OnRetransmissionTimeout();
}
TEST_F(QuicSentPacketManagerTest, GetTransmissionTime) {
EXPECT_EQ(QuicTime::Zero(), manager_.GetRetransmissionTime());
}
TEST_F(QuicSentPacketManagerTest, GetTransmissionTimeCryptoHandshake) {
SendCryptoPacket(1);
// Check the min.
RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(&manager_);
rtt_stats->set_initial_rtt_us(1 * kNumMicrosPerMilli);
EXPECT_EQ(clock_.Now().Add(QuicTime::Delta::FromMilliseconds(10)),
manager_.GetRetransmissionTime());
// Test with a standard smoothed RTT.
rtt_stats->set_initial_rtt_us(100 * kNumMicrosPerMilli);
QuicTime::Delta srtt =
QuicTime::Delta::FromMicroseconds(rtt_stats->initial_rtt_us());
QuicTime expected_time = clock_.Now().Add(srtt.Multiply(1.5));
EXPECT_EQ(expected_time, manager_.GetRetransmissionTime());
// Retransmit the packet by invoking the retransmission timeout.
clock_.AdvanceTime(srtt.Multiply(1.5));
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(2);
// The retransmission time should now be twice as far in the future.
expected_time = clock_.Now().Add(srtt.Multiply(2).Multiply(1.5));
EXPECT_EQ(expected_time, manager_.GetRetransmissionTime());
}
TEST_F(QuicSentPacketManagerTest, GetTransmissionTimeTailLossProbe) {
QuicSentPacketManagerPeer::SetMaxTailLossProbes(&manager_, 2);
SendDataPacket(1);
SendDataPacket(2);
// Check the min.
RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(&manager_);
rtt_stats->set_initial_rtt_us(1 * kNumMicrosPerMilli);
EXPECT_EQ(clock_.Now().Add(QuicTime::Delta::FromMilliseconds(10)),
manager_.GetRetransmissionTime());
// Test with a standard smoothed RTT.
rtt_stats->set_initial_rtt_us(100 * kNumMicrosPerMilli);
QuicTime::Delta srtt =
QuicTime::Delta::FromMicroseconds(rtt_stats->initial_rtt_us());
QuicTime::Delta expected_tlp_delay = srtt.Multiply(2);
QuicTime expected_time = clock_.Now().Add(expected_tlp_delay);
EXPECT_EQ(expected_time, manager_.GetRetransmissionTime());
// Retransmit the packet by invoking the retransmission timeout.
clock_.AdvanceTime(expected_tlp_delay);
manager_.OnRetransmissionTimeout();
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_TRUE(manager_.MaybeRetransmitTailLossProbe());
EXPECT_TRUE(manager_.HasPendingRetransmissions());
RetransmitNextPacket(3);
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Infinite()));
EXPECT_EQ(QuicTime::Delta::Infinite(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
expected_time = clock_.Now().Add(expected_tlp_delay);
EXPECT_EQ(expected_time, manager_.GetRetransmissionTime());
}
TEST_F(QuicSentPacketManagerTest, GetTransmissionTimeSpuriousRTO) {
QuicSentPacketManagerPeer::GetRttStats(&manager_)
->UpdateRtt(QuicTime::Delta::FromMilliseconds(100),
QuicTime::Delta::Zero(), QuicTime::Zero());
SendDataPacket(1);
SendDataPacket(2);
SendDataPacket(3);
SendDataPacket(4);
QuicTime::Delta expected_rto_delay = QuicTime::Delta::FromMilliseconds(500);
EXPECT_CALL(*send_algorithm_, RetransmissionDelay())
.WillRepeatedly(Return(expected_rto_delay));
QuicTime expected_time = clock_.Now().Add(expected_rto_delay);
EXPECT_EQ(expected_time, manager_.GetRetransmissionTime());
// Retransmit the packet by invoking the retransmission timeout.
clock_.AdvanceTime(expected_rto_delay);
manager_.OnRetransmissionTimeout();
// All packets are still considered inflight.
EXPECT_EQ(4 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
RetransmitNextPacket(5);
RetransmitNextPacket(6);
// All previous packets are inflight, plus two rto retransmissions.
EXPECT_EQ(6 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
EXPECT_FALSE(manager_.HasPendingRetransmissions());
// The delay should double the second time.
expected_time = clock_.Now().Add(expected_rto_delay).Add(expected_rto_delay);
// Once we always base the timer on the right edge, leaving the older packets
// in flight doesn't change the timeout.
EXPECT_EQ(expected_time, manager_.GetRetransmissionTime());
// Ack a packet before the first RTO and ensure the RTO timeout returns to the
// original value and OnRetransmissionTimeout is not called or reverted.
QuicAckFrame ack_frame;
ack_frame.largest_observed = 2;
ack_frame.missing_packets.Add(1);
ExpectAck(2);
manager_.OnIncomingAck(ack_frame, clock_.ApproximateNow());
EXPECT_FALSE(manager_.HasPendingRetransmissions());
EXPECT_EQ(5 * kDefaultLength,
QuicSentPacketManagerPeer::GetBytesInFlight(&manager_));
// Wait 2RTTs from now for the RTO, since it's the max of the RTO time
// and the TLP time. In production, there would always be two TLP's first.
// Since retransmission was spurious, smoothed_rtt_ is expired, and replaced
// by the latest RTT sample of 500ms.
expected_time = clock_.Now().Add(QuicTime::Delta::FromMilliseconds(1000));
// Once we always base the timer on the right edge, leaving the older packets
// in flight doesn't change the timeout.
EXPECT_EQ(expected_time, manager_.GetRetransmissionTime());
}
TEST_F(QuicSentPacketManagerTest, GetTransmissionDelayMin) {
SendDataPacket(1);
EXPECT_CALL(*send_algorithm_, RetransmissionDelay())
.WillRepeatedly(Return(QuicTime::Delta::FromMilliseconds(1)));
QuicTime::Delta delay = QuicTime::Delta::FromMilliseconds(200);
// If the delay is smaller than the min, ensure it exponentially backs off
// from the min.
EXPECT_CALL(*network_change_visitor_, OnPathDegrading());
for (int i = 0; i < 5; ++i) {
EXPECT_EQ(delay,
QuicSentPacketManagerPeer::GetRetransmissionDelay(&manager_));
delay = delay.Add(delay);
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(i + 2);
}
}
TEST_F(QuicSentPacketManagerTest, GetTransmissionDelayMax) {
EXPECT_CALL(*send_algorithm_, RetransmissionDelay())
.WillOnce(Return(QuicTime::Delta::FromSeconds(500)));
EXPECT_EQ(QuicTime::Delta::FromSeconds(60),
QuicSentPacketManagerPeer::GetRetransmissionDelay(&manager_));
}
TEST_F(QuicSentPacketManagerTest, GetTransmissionDelay) {
SendDataPacket(1);
QuicTime::Delta delay = QuicTime::Delta::FromMilliseconds(500);
EXPECT_CALL(*send_algorithm_, RetransmissionDelay())
.WillRepeatedly(Return(delay));
// Delay should back off exponentially.
EXPECT_CALL(*network_change_visitor_, OnPathDegrading());
for (int i = 0; i < 5; ++i) {
EXPECT_EQ(delay,
QuicSentPacketManagerPeer::GetRetransmissionDelay(&manager_));
delay = delay.Add(delay);
manager_.OnRetransmissionTimeout();
RetransmitNextPacket(i + 2);
}
}
TEST_F(QuicSentPacketManagerTest, GetLossDelay) {
MockLossAlgorithm* loss_algorithm = new MockLossAlgorithm();
QuicSentPacketManagerPeer::SetLossAlgorithm(&manager_, loss_algorithm);
EXPECT_CALL(*loss_algorithm, GetLossTimeout())
.WillRepeatedly(Return(QuicTime::Zero()));
SendDataPacket(1);
SendDataPacket(2);
// Handle an ack which causes the loss algorithm to be evaluated and
// set the loss timeout.
ExpectAck(2);
EXPECT_CALL(*loss_algorithm, DetectLosses(_, _, _, _));
QuicAckFrame ack_frame;
ack_frame.largest_observed = 2;
ack_frame.missing_packets.Add(1);
manager_.OnIncomingAck(ack_frame, clock_.Now());
QuicTime timeout(clock_.Now().Add(QuicTime::Delta::FromMilliseconds(10)));
EXPECT_CALL(*loss_algorithm, GetLossTimeout())
.WillRepeatedly(Return(timeout));
EXPECT_EQ(timeout, manager_.GetRetransmissionTime());
// Fire the retransmission timeout and ensure the loss detection algorithm
// is invoked.
EXPECT_CALL(*loss_algorithm, DetectLosses(_, _, _, _));
manager_.OnRetransmissionTimeout();
}
TEST_F(QuicSentPacketManagerTest, NegotiateTimeLossDetectionFromOptions) {
EXPECT_EQ(kNack, QuicSentPacketManagerPeer::GetLossAlgorithm(&manager_)
->GetLossDetectionType());
QuicConfig config;
QuicTagVector options;
options.push_back(kTIME);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.SetFromConfig(config);
EXPECT_EQ(kTime, QuicSentPacketManagerPeer::GetLossAlgorithm(&manager_)
->GetLossDetectionType());
}
TEST_F(QuicSentPacketManagerTest, NegotiateCongestionControlFromOptions) {
ValueRestore<bool> old_flag(&FLAGS_quic_allow_bbr, true);
QuicConfig config;
QuicTagVector options;
options.push_back(kRENO);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.SetFromConfig(config);
EXPECT_EQ(kReno, QuicSentPacketManagerPeer::GetSendAlgorithm(manager_)
->GetCongestionControlType());
// TODO(rtenneti): Enable the following code after BBR code is checked in.
#if 0
options.clear();
options.push_back(kTBBR);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.SetFromConfig(config);
EXPECT_EQ(kBBR, QuicSentPacketManagerPeer::GetSendAlgorithm(
manager_)->GetCongestionControlType());
#endif
options.clear();
options.push_back(kBYTE);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.SetFromConfig(config);
EXPECT_EQ(kCubicBytes, QuicSentPacketManagerPeer::GetSendAlgorithm(manager_)
->GetCongestionControlType());
options.clear();
options.push_back(kRENO);
options.push_back(kBYTE);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.SetFromConfig(config);
EXPECT_EQ(kRenoBytes, QuicSentPacketManagerPeer::GetSendAlgorithm(manager_)
->GetCongestionControlType());
}
TEST_F(QuicSentPacketManagerTest, NegotiateNumConnectionsFromOptions) {
QuicConfig config;
QuicTagVector options;
options.push_back(k1CON);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetNumEmulatedConnections(1));
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(config);
QuicSentPacketManagerPeer::SetPerspective(&manager_, Perspective::IS_CLIENT);
QuicConfig client_config;
client_config.SetConnectionOptionsToSend(options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetNumEmulatedConnections(1));
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(client_config);
}
TEST_F(QuicSentPacketManagerTest, NegotiateNConnectionFromOptions) {
// By default, changing the number of open streams does nothing.
manager_.SetNumOpenStreams(5);
QuicConfig config;
QuicTagVector options;
options.push_back(kNCON);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(config);
EXPECT_CALL(*send_algorithm_, SetNumEmulatedConnections(5));
manager_.SetNumOpenStreams(5);
}
TEST_F(QuicSentPacketManagerTest, NegotiateNoTLPFromOptionsAtServer) {
QuicConfig config;
QuicTagVector options;
options.push_back(kNTLP);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(config);
EXPECT_EQ(0u, QuicSentPacketManagerPeer::GetMaxTailLossProbes(&manager_));
}
TEST_F(QuicSentPacketManagerTest, NegotiateNoTLPFromOptionsAtClient) {
QuicConfig client_config;
QuicTagVector options;
options.push_back(kNTLP);
QuicSentPacketManagerPeer::SetPerspective(&manager_, Perspective::IS_CLIENT);
client_config.SetConnectionOptionsToSend(options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(client_config);
EXPECT_EQ(0u, QuicSentPacketManagerPeer::GetMaxTailLossProbes(&manager_));
}
TEST_F(QuicSentPacketManagerTest, NegotiateTLPRttFromOptionsAtServer) {
QuicConfig config;
QuicTagVector options;
options.push_back(kTLPR);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(config);
EXPECT_TRUE(
QuicSentPacketManagerPeer::GetEnableHalfRttTailLossProbe(&manager_));
}
TEST_F(QuicSentPacketManagerTest, NegotiateTLPRttFromOptionsAtClient) {
QuicConfig client_config;
QuicTagVector options;
options.push_back(kTLPR);
QuicSentPacketManagerPeer::SetPerspective(&manager_, Perspective::IS_CLIENT);
client_config.SetConnectionOptionsToSend(options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(client_config);
EXPECT_TRUE(
QuicSentPacketManagerPeer::GetEnableHalfRttTailLossProbe(&manager_));
}
TEST_F(QuicSentPacketManagerTest, NegotiateNewRTOFromOptionsAtServer) {
EXPECT_FALSE(QuicSentPacketManagerPeer::GetUseNewRto(&manager_));
QuicConfig config;
QuicTagVector options;
options.push_back(kNRTO);
QuicConfigPeer::SetReceivedConnectionOptions(&config, options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(config);
EXPECT_TRUE(QuicSentPacketManagerPeer::GetUseNewRto(&manager_));
}
TEST_F(QuicSentPacketManagerTest, NegotiateNewRTOFromOptionsAtClient) {
EXPECT_FALSE(QuicSentPacketManagerPeer::GetUseNewRto(&manager_));
QuicConfig client_config;
QuicTagVector options;
options.push_back(kNRTO);
QuicSentPacketManagerPeer::SetPerspective(&manager_, Perspective::IS_CLIENT);
client_config.SetConnectionOptionsToSend(options);
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
manager_.SetFromConfig(client_config);
EXPECT_TRUE(QuicSentPacketManagerPeer::GetUseNewRto(&manager_));
}
TEST_F(QuicSentPacketManagerTest,
NegotiateConservativeReceiveWindowFromOptions) {
EXPECT_EQ(kDefaultSocketReceiveBuffer,
QuicSentPacketManagerPeer::GetReceiveWindow(&manager_));
// Try to set a size below the minimum and ensure it gets set to the min.
QuicConfig client_config;
QuicConfigPeer::SetReceivedSocketReceiveBuffer(&client_config, 1024);
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
EXPECT_CALL(*send_algorithm_,
SetMaxCongestionWindow(kMinSocketReceiveBuffer * 0.6));
EXPECT_CALL(*send_algorithm_, PacingRate())
.WillRepeatedly(Return(QuicBandwidth::Zero()));
EXPECT_CALL(*send_algorithm_, GetCongestionWindow())
.WillOnce(Return(10 * kDefaultTCPMSS));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.SetFromConfig(client_config);
EXPECT_EQ(kMinSocketReceiveBuffer,
QuicSentPacketManagerPeer::GetReceiveWindow(&manager_));
// Ensure the smaller send window only allows 16 packets to be sent.
for (QuicPacketNumber i = 1; i <= 16; ++i) {
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Zero()));
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_CALL(*send_algorithm_, OnPacketSent(_, BytesInFlight(), i, 1024,
HAS_RETRANSMITTABLE_DATA))
.WillOnce(Return(true));
SerializedPacket packet(CreatePacket(i, true));
manager_.OnPacketSent(&packet, 0, clock_.Now(), 1024, NOT_RETRANSMISSION,
HAS_RETRANSMITTABLE_DATA);
}
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Infinite()));
EXPECT_EQ(QuicTime::Delta::Infinite(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
}
TEST_F(QuicSentPacketManagerTest, ReceiveWindowLimited) {
EXPECT_EQ(kDefaultSocketReceiveBuffer,
QuicSentPacketManagerPeer::GetReceiveWindow(&manager_));
// Ensure the smaller send window only allows 256 * 0.95 packets to be sent.
for (QuicPacketNumber i = 1; i <= 244; ++i) {
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Zero()));
EXPECT_EQ(QuicTime::Delta::Zero(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
EXPECT_CALL(*send_algorithm_, OnPacketSent(_, BytesInFlight(), i, 1024,
HAS_RETRANSMITTABLE_DATA))
.WillOnce(Return(true));
SerializedPacket packet(CreatePacket(i, true));
manager_.OnPacketSent(&packet, 0, clock_.Now(), 1024, NOT_RETRANSMISSION,
HAS_RETRANSMITTABLE_DATA);
}
EXPECT_CALL(*send_algorithm_, TimeUntilSend(_, _, _))
.WillOnce(Return(QuicTime::Delta::Infinite()));
EXPECT_EQ(QuicTime::Delta::Infinite(),
manager_.TimeUntilSend(clock_.Now(), HAS_RETRANSMITTABLE_DATA));
}
TEST_F(QuicSentPacketManagerTest, UseInitialRoundTripTimeToSend) {
uint32_t initial_rtt_us = 325000;
EXPECT_NE(initial_rtt_us,
manager_.GetRttStats()->smoothed_rtt().ToMicroseconds());
QuicConfig config;
config.SetInitialRoundTripTimeUsToSend(initial_rtt_us);
EXPECT_CALL(*send_algorithm_, SetFromConfig(_, _));
EXPECT_CALL(*network_change_visitor_, OnCongestionWindowChange());
EXPECT_CALL(*network_change_visitor_, OnRttChange());
manager_.SetFromConfig(config);
EXPECT_EQ(0, manager_.GetRttStats()->smoothed_rtt().ToMicroseconds());
EXPECT_EQ(initial_rtt_us, manager_.GetRttStats()->initial_rtt_us());
}
TEST_F(QuicSentPacketManagerTest, ResumeConnectionState) {
// The sent packet manager should use the RTT from CachedNetworkParameters if
// it is provided.
const int kRttMs = 1234;
CachedNetworkParameters cached_network_params;
cached_network_params.set_min_rtt_ms(kRttMs);
EXPECT_CALL(*send_algorithm_, ResumeConnectionState(_, false));
manager_.ResumeConnectionState(cached_network_params, false);
EXPECT_EQ(kRttMs * kNumMicrosPerMilli,
static_cast<uint64_t>(manager_.GetRttStats()->initial_rtt_us()));
}
TEST_F(QuicSentPacketManagerTest, ConnectionMigrationUnspecifiedChange) {
RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(&manager_);
int64_t default_init_rtt = rtt_stats->initial_rtt_us();
rtt_stats->set_initial_rtt_us(default_init_rtt * 2);
EXPECT_EQ(2 * default_init_rtt, rtt_stats->initial_rtt_us());
QuicSentPacketManagerPeer::SetConsecutiveRtoCount(&manager_, 1);
EXPECT_EQ(1u, manager_.consecutive_rto_count());
QuicSentPacketManagerPeer::SetConsecutiveTlpCount(&manager_, 2);
EXPECT_EQ(2u, manager_.consecutive_tlp_count());
EXPECT_CALL(*send_algorithm_, OnConnectionMigration());
manager_.OnConnectionMigration(UNSPECIFIED_CHANGE);
EXPECT_EQ(default_init_rtt, rtt_stats->initial_rtt_us());
EXPECT_EQ(0u, manager_.consecutive_rto_count());
EXPECT_EQ(0u, manager_.consecutive_tlp_count());
}
TEST_F(QuicSentPacketManagerTest, ConnectionMigrationIPSubnetChange) {
RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(&manager_);
int64_t default_init_rtt = rtt_stats->initial_rtt_us();
rtt_stats->set_initial_rtt_us(default_init_rtt * 2);
EXPECT_EQ(2 * default_init_rtt, rtt_stats->initial_rtt_us());
QuicSentPacketManagerPeer::SetConsecutiveRtoCount(&manager_, 1);
EXPECT_EQ(1u, manager_.consecutive_rto_count());
QuicSentPacketManagerPeer::SetConsecutiveTlpCount(&manager_, 2);
EXPECT_EQ(2u, manager_.consecutive_tlp_count());
manager_.OnConnectionMigration(IPV4_SUBNET_CHANGE);
EXPECT_EQ(2 * default_init_rtt, rtt_stats->initial_rtt_us());
EXPECT_EQ(1u, manager_.consecutive_rto_count());
EXPECT_EQ(2u, manager_.consecutive_tlp_count());
}
TEST_F(QuicSentPacketManagerTest, ConnectionMigrationPortChange) {
RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(&manager_);
int64_t default_init_rtt = rtt_stats->initial_rtt_us();
rtt_stats->set_initial_rtt_us(default_init_rtt * 2);
EXPECT_EQ(2 * default_init_rtt, rtt_stats->initial_rtt_us());
QuicSentPacketManagerPeer::SetConsecutiveRtoCount(&manager_, 1);
EXPECT_EQ(1u, manager_.consecutive_rto_count());
QuicSentPacketManagerPeer::SetConsecutiveTlpCount(&manager_, 2);
EXPECT_EQ(2u, manager_.consecutive_tlp_count());
manager_.OnConnectionMigration(PORT_CHANGE);
EXPECT_EQ(2 * default_init_rtt, rtt_stats->initial_rtt_us());
EXPECT_EQ(1u, manager_.consecutive_rto_count());
EXPECT_EQ(2u, manager_.consecutive_tlp_count());
}
} // namespace
} // namespace test
} // namespace net