// 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/tools/quic/quic_time_wait_list_manager.h" #include #include "net/quic/crypto/crypto_protocol.h" #include "net/quic/crypto/null_encrypter.h" #include "net/quic/crypto/quic_decrypter.h" #include "net/quic/crypto/quic_encrypter.h" #include "net/quic/quic_data_reader.h" #include "net/quic/quic_framer.h" #include "net/quic/quic_packet_writer.h" #include "net/quic/quic_protocol.h" #include "net/quic/quic_utils.h" #include "net/quic/test_tools/quic_test_utils.h" #include "net/tools/quic/test_tools/mock_epoll_server.h" #include "net/tools/quic/test_tools/quic_test_utils.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" using net::test::FramerVisitorCapturingPublicReset; using testing::_; using testing::Args; using testing::Assign; using testing::DoAll; using testing::Matcher; using testing::MatcherInterface; using testing::NiceMock; using testing::Return; using testing::ReturnPointee; using testing::SetArgPointee; using testing::StrictMock; using testing::Truly; namespace net { namespace tools { namespace test { class QuicTimeWaitListManagerPeer { public: static bool ShouldSendResponse(QuicTimeWaitListManager* manager, int received_packet_count) { return manager->ShouldSendResponse(received_packet_count); } static QuicTime::Delta time_wait_period(QuicTimeWaitListManager* manager) { return manager->kTimeWaitPeriod_; } static QuicVersion GetQuicVersionFromConnectionId( QuicTimeWaitListManager* manager, QuicConnectionId connection_id) { return manager->GetQuicVersionFromConnectionId(connection_id); } }; namespace { class MockFakeTimeEpollServer : public FakeTimeEpollServer { public: MOCK_METHOD2(RegisterAlarm, void(int64 timeout_in_us, EpollAlarmCallbackInterface* alarm)); }; class QuicTimeWaitListManagerTest : public ::testing::Test { protected: QuicTimeWaitListManagerTest() : time_wait_list_manager_(&writer_, &visitor_, &epoll_server_, QuicSupportedVersions()), framer_(QuicSupportedVersions(), QuicTime::Zero(), true), connection_id_(45), client_address_(net::test::TestPeerIPAddress(), kTestPort), writer_is_blocked_(false) {} virtual ~QuicTimeWaitListManagerTest() {} virtual void SetUp() { EXPECT_CALL(writer_, IsWriteBlocked()) .WillRepeatedly(ReturnPointee(&writer_is_blocked_)); EXPECT_CALL(writer_, IsWriteBlockedDataBuffered()) .WillRepeatedly(Return(false)); } void AddConnectionId(QuicConnectionId connection_id) { AddConnectionId(connection_id, net::test::QuicVersionMax(), NULL); } void AddConnectionId(QuicConnectionId connection_id, QuicVersion version, QuicEncryptedPacket* packet) { time_wait_list_manager_.AddConnectionIdToTimeWait( connection_id, version, packet); } bool IsConnectionIdInTimeWait(QuicConnectionId connection_id) { return time_wait_list_manager_.IsConnectionIdInTimeWait(connection_id); } void ProcessPacket(QuicConnectionId connection_id, QuicPacketSequenceNumber sequence_number) { time_wait_list_manager_.ProcessPacket(server_address_, client_address_, connection_id, sequence_number); } QuicEncryptedPacket* ConstructEncryptedPacket( EncryptionLevel level, QuicConnectionId connection_id, QuicPacketSequenceNumber sequence_number) { QuicPacketHeader header; header.public_header.connection_id = connection_id; header.public_header.connection_id_length = PACKET_8BYTE_CONNECTION_ID; header.public_header.version_flag = false; header.public_header.reset_flag = false; header.public_header.sequence_number_length = PACKET_6BYTE_SEQUENCE_NUMBER; header.packet_sequence_number = sequence_number; header.entropy_flag = false; header.entropy_hash = 0; header.fec_flag = false; header.is_in_fec_group = NOT_IN_FEC_GROUP; header.fec_group = 0; QuicStreamFrame stream_frame(1, false, 0, MakeIOVector("data")); QuicFrame frame(&stream_frame); QuicFrames frames; frames.push_back(frame); scoped_ptr packet( framer_.BuildUnsizedDataPacket(header, frames).packet); EXPECT_TRUE(packet != NULL); QuicEncryptedPacket* encrypted = framer_.EncryptPacket(ENCRYPTION_NONE, sequence_number, *packet); EXPECT_TRUE(encrypted != NULL); return encrypted; } NiceMock epoll_server_; StrictMock writer_; StrictMock visitor_; QuicTimeWaitListManager time_wait_list_manager_; QuicFramer framer_; QuicConnectionId connection_id_; IPEndPoint server_address_; IPEndPoint client_address_; bool writer_is_blocked_; }; class ValidatePublicResetPacketPredicate : public MatcherInterface > { public: explicit ValidatePublicResetPacketPredicate(QuicConnectionId connection_id, QuicPacketSequenceNumber number) : connection_id_(connection_id), sequence_number_(number) { } virtual bool MatchAndExplain( const std::tr1::tuple packet_buffer, testing::MatchResultListener* /* listener */) const { FramerVisitorCapturingPublicReset visitor; QuicFramer framer(QuicSupportedVersions(), QuicTime::Zero(), false); framer.set_visitor(&visitor); QuicEncryptedPacket encrypted(std::tr1::get<0>(packet_buffer), std::tr1::get<1>(packet_buffer)); framer.ProcessPacket(encrypted); QuicPublicResetPacket packet = visitor.public_reset_packet(); return connection_id_ == packet.public_header.connection_id && packet.public_header.reset_flag && !packet.public_header.version_flag && sequence_number_ == packet.rejected_sequence_number && net::test::TestPeerIPAddress() == packet.client_address.address() && kTestPort == packet.client_address.port(); } virtual void DescribeTo(::std::ostream* os) const { } virtual void DescribeNegationTo(::std::ostream* os) const { } private: QuicConnectionId connection_id_; QuicPacketSequenceNumber sequence_number_; }; Matcher > PublicResetPacketEq( QuicConnectionId connection_id, QuicPacketSequenceNumber sequence_number) { return MakeMatcher(new ValidatePublicResetPacketPredicate(connection_id, sequence_number)); } TEST_F(QuicTimeWaitListManagerTest, CheckConnectionIdInTimeWait) { EXPECT_FALSE(IsConnectionIdInTimeWait(connection_id_)); AddConnectionId(connection_id_); EXPECT_TRUE(IsConnectionIdInTimeWait(connection_id_)); } TEST_F(QuicTimeWaitListManagerTest, SendConnectionClose) { size_t kConnectionCloseLength = 100; AddConnectionId( connection_id_, net::test::QuicVersionMax(), new QuicEncryptedPacket( new char[kConnectionCloseLength], kConnectionCloseLength, true)); const int kRandomSequenceNumber = 1; EXPECT_CALL(writer_, WritePacket(_, kConnectionCloseLength, server_address_.address(), client_address_)) .WillOnce(Return(WriteResult(WRITE_STATUS_OK, 1))); ProcessPacket(connection_id_, kRandomSequenceNumber); } TEST_F(QuicTimeWaitListManagerTest, SendPublicReset) { AddConnectionId(connection_id_); const int kRandomSequenceNumber = 1; EXPECT_CALL(writer_, WritePacket(_, _, server_address_.address(), client_address_)) .With(Args<0, 1>(PublicResetPacketEq(connection_id_, kRandomSequenceNumber))) .WillOnce(Return(WriteResult(WRITE_STATUS_OK, 0))); ProcessPacket(connection_id_, kRandomSequenceNumber); } TEST_F(QuicTimeWaitListManagerTest, SendPublicResetWithExponentialBackOff) { AddConnectionId(connection_id_); for (int sequence_number = 1; sequence_number < 101; ++sequence_number) { if ((sequence_number & (sequence_number - 1)) == 0) { EXPECT_CALL(writer_, WritePacket(_, _, _, _)) .WillOnce(Return(WriteResult(WRITE_STATUS_OK, 1))); } ProcessPacket(connection_id_, sequence_number); // Send public reset with exponential back off. if ((sequence_number & (sequence_number - 1)) == 0) { EXPECT_TRUE(QuicTimeWaitListManagerPeer::ShouldSendResponse( &time_wait_list_manager_, sequence_number)); } else { EXPECT_FALSE(QuicTimeWaitListManagerPeer::ShouldSendResponse( &time_wait_list_manager_, sequence_number)); } } } TEST_F(QuicTimeWaitListManagerTest, CleanUpOldConnectionIds) { const int kConnectionIdCount = 100; const int kOldConnectionIdCount = 31; // Add connection_ids such that their expiry time is kTimeWaitPeriod_. epoll_server_.set_now_in_usec(0); for (int connection_id = 1; connection_id <= kOldConnectionIdCount; ++connection_id) { AddConnectionId(connection_id); } // Add remaining connection_ids such that their add time is // 2 * kTimeWaitPeriod. const QuicTime::Delta time_wait_period = QuicTimeWaitListManagerPeer::time_wait_period(&time_wait_list_manager_); epoll_server_.set_now_in_usec(time_wait_period.ToMicroseconds()); for (int connection_id = kOldConnectionIdCount + 1; connection_id <= kConnectionIdCount; ++connection_id) { AddConnectionId(connection_id); } QuicTime::Delta offset = QuicTime::Delta::FromMicroseconds(39); // Now set the current time as time_wait_period + offset usecs. epoll_server_.set_now_in_usec(time_wait_period.Add(offset).ToMicroseconds()); // After all the old connection_ids are cleaned up, check the next alarm // interval. int64 next_alarm_time = epoll_server_.ApproximateNowInUsec() + time_wait_period.Subtract(offset).ToMicroseconds(); EXPECT_CALL(epoll_server_, RegisterAlarm(next_alarm_time, _)); time_wait_list_manager_.CleanUpOldConnectionIds(); for (int connection_id = 1; connection_id <= kConnectionIdCount; ++connection_id) { EXPECT_EQ(connection_id > kOldConnectionIdCount, IsConnectionIdInTimeWait(connection_id)) << "kOldConnectionIdCount: " << kOldConnectionIdCount << " connection_id: " << connection_id; } } TEST_F(QuicTimeWaitListManagerTest, SendQueuedPackets) { QuicConnectionId connection_id = 1; AddConnectionId(connection_id); QuicPacketSequenceNumber sequence_number = 234; scoped_ptr packet(ConstructEncryptedPacket( ENCRYPTION_NONE, connection_id, sequence_number)); // Let first write through. EXPECT_CALL(writer_, WritePacket(_, _, server_address_.address(), client_address_)) .With(Args<0, 1>(PublicResetPacketEq(connection_id, sequence_number))) .WillOnce(Return(WriteResult(WRITE_STATUS_OK, packet->length()))); ProcessPacket(connection_id, sequence_number); // write block for the next packet. EXPECT_CALL(writer_, WritePacket(_, _, server_address_.address(), client_address_)) .With(Args<0, 1>(PublicResetPacketEq(connection_id, sequence_number))) .WillOnce(DoAll( Assign(&writer_is_blocked_, true), Return(WriteResult(WRITE_STATUS_BLOCKED, EAGAIN)))); EXPECT_CALL(visitor_, OnWriteBlocked(&time_wait_list_manager_)); ProcessPacket(connection_id, sequence_number); // 3rd packet. No public reset should be sent; ProcessPacket(connection_id, sequence_number); // write packet should not be called since we are write blocked but the // should be queued. QuicConnectionId other_connection_id = 2; AddConnectionId(other_connection_id); QuicPacketSequenceNumber other_sequence_number = 23423; scoped_ptr other_packet( ConstructEncryptedPacket( ENCRYPTION_NONE, other_connection_id, other_sequence_number)); EXPECT_CALL(writer_, WritePacket(_, _, _, _)) .Times(0); EXPECT_CALL(visitor_, OnWriteBlocked(&time_wait_list_manager_)); ProcessPacket(other_connection_id, other_sequence_number); // Now expect all the write blocked public reset packets to be sent again. writer_is_blocked_ = false; EXPECT_CALL(writer_, WritePacket(_, _, server_address_.address(), client_address_)) .With(Args<0, 1>(PublicResetPacketEq(connection_id, sequence_number))) .WillOnce(Return(WriteResult(WRITE_STATUS_OK, packet->length()))); EXPECT_CALL(writer_, WritePacket(_, _, server_address_.address(), client_address_)) .With(Args<0, 1>(PublicResetPacketEq(other_connection_id, other_sequence_number))) .WillOnce(Return(WriteResult(WRITE_STATUS_OK, other_packet->length()))); time_wait_list_manager_.OnCanWrite(); } TEST_F(QuicTimeWaitListManagerTest, GetQuicVersionFromMap) { const int kConnectionId1 = 123; const int kConnectionId2 = 456; const int kConnectionId3 = 789; AddConnectionId(kConnectionId1, net::test::QuicVersionMin(), NULL); AddConnectionId(kConnectionId2, net::test::QuicVersionMax(), NULL); AddConnectionId(kConnectionId3, net::test::QuicVersionMax(), NULL); EXPECT_EQ(net::test::QuicVersionMin(), QuicTimeWaitListManagerPeer::GetQuicVersionFromConnectionId( &time_wait_list_manager_, kConnectionId1)); EXPECT_EQ(net::test::QuicVersionMax(), QuicTimeWaitListManagerPeer::GetQuicVersionFromConnectionId( &time_wait_list_manager_, kConnectionId2)); EXPECT_EQ(net::test::QuicVersionMax(), QuicTimeWaitListManagerPeer::GetQuicVersionFromConnectionId( &time_wait_list_manager_, kConnectionId3)); } TEST_F(QuicTimeWaitListManagerTest, AddConnectionIdTwice) { // Add connection_ids such that their expiry time is kTimeWaitPeriod_. epoll_server_.set_now_in_usec(0); AddConnectionId(connection_id_); EXPECT_TRUE(IsConnectionIdInTimeWait(connection_id_)); size_t kConnectionCloseLength = 100; AddConnectionId( connection_id_, net::test::QuicVersionMax(), new QuicEncryptedPacket( new char[kConnectionCloseLength], kConnectionCloseLength, true)); EXPECT_TRUE(IsConnectionIdInTimeWait(connection_id_)); EXPECT_CALL(writer_, WritePacket(_, kConnectionCloseLength, server_address_.address(), client_address_)) .WillOnce(Return(WriteResult(WRITE_STATUS_OK, 1))); const int kRandomSequenceNumber = 1; ProcessPacket(connection_id_, kRandomSequenceNumber); const QuicTime::Delta time_wait_period = QuicTimeWaitListManagerPeer::time_wait_period(&time_wait_list_manager_); QuicTime::Delta offset = QuicTime::Delta::FromMicroseconds(39); // Now set the current time as time_wait_period + offset usecs. epoll_server_.set_now_in_usec(time_wait_period.Add(offset).ToMicroseconds()); // After the connection_ids are cleaned up, check the next alarm interval. int64 next_alarm_time = epoll_server_.ApproximateNowInUsec() + time_wait_period.ToMicroseconds(); EXPECT_CALL(epoll_server_, RegisterAlarm(next_alarm_time, _)); time_wait_list_manager_.CleanUpOldConnectionIds(); EXPECT_FALSE(IsConnectionIdInTimeWait(connection_id_)); } TEST_F(QuicTimeWaitListManagerTest, ConnectionIdsOrderedByTime) { // Simple randomization: the values of connection_ids are swapped based on the // current seconds on the clock. If the container is broken, the test will be // 50% flaky. int odd_second = static_cast(epoll_server_.ApproximateNowInUsec()) % 2; EXPECT_TRUE(odd_second == 0 || odd_second == 1); const QuicConnectionId kConnectionId1 = odd_second; const QuicConnectionId kConnectionId2 = 1 - odd_second; // 1 will hash lower than 2, but we add it later. They should come out in the // add order, not hash order. epoll_server_.set_now_in_usec(0); AddConnectionId(kConnectionId1); epoll_server_.set_now_in_usec(10); AddConnectionId(kConnectionId2); const QuicTime::Delta time_wait_period = QuicTimeWaitListManagerPeer::time_wait_period(&time_wait_list_manager_); epoll_server_.set_now_in_usec(time_wait_period.ToMicroseconds() + 1); EXPECT_CALL(epoll_server_, RegisterAlarm(_, _)); time_wait_list_manager_.CleanUpOldConnectionIds(); EXPECT_FALSE(IsConnectionIdInTimeWait(kConnectionId1)); EXPECT_TRUE(IsConnectionIdInTimeWait(kConnectionId2)); } } // namespace } // namespace test } // namespace tools } // namespace net