// Copyright 2014 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_flow_controller.h" #include "base/format_macros.h" #include "base/strings/stringprintf.h" #include "net/quic/quic_flags.h" #include "net/quic/quic_utils.h" #include "net/quic/test_tools/quic_connection_peer.h" #include "net/quic/test_tools/quic_flow_controller_peer.h" #include "net/quic/test_tools/quic_sent_packet_manager_peer.h" #include "net/quic/test_tools/quic_test_utils.h" #include "net/test/gtest_util.h" #include "testing/gmock/include/gmock/gmock.h" using testing::_; namespace net { namespace test { // Receive window auto-tuning uses RTT in its logic. const int64_t kRtt = 100; class QuicFlowControllerTest : public ::testing::Test { public: QuicFlowControllerTest() : stream_id_(1234), send_window_(kInitialSessionFlowControlWindowForTest), receive_window_(kInitialSessionFlowControlWindowForTest), connection_(&helper_, Perspective::IS_CLIENT) {} void Initialize() { flow_controller_.reset( new QuicFlowController(&connection_, stream_id_, Perspective::IS_CLIENT, send_window_, receive_window_, false)); } protected: QuicStreamId stream_id_; QuicByteCount send_window_; QuicByteCount receive_window_; scoped_ptr flow_controller_; MockConnectionHelper helper_; MockConnection connection_; }; TEST_F(QuicFlowControllerTest, SendingBytes) { Initialize(); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(send_window_, flow_controller_->SendWindowSize()); // Send some bytes, but not enough to block. flow_controller_->AddBytesSent(send_window_ / 2); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_EQ(send_window_ / 2, flow_controller_->SendWindowSize()); // Send enough bytes to block. flow_controller_->AddBytesSent(send_window_ / 2); EXPECT_TRUE(flow_controller_->IsBlocked()); EXPECT_EQ(0u, flow_controller_->SendWindowSize()); // BLOCKED frame should get sent. EXPECT_CALL(connection_, SendBlocked(stream_id_)).Times(1); flow_controller_->MaybeSendBlocked(); // Update the send window, and verify this has unblocked. EXPECT_TRUE(flow_controller_->UpdateSendWindowOffset(2 * send_window_)); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_EQ(send_window_, flow_controller_->SendWindowSize()); // Updating with a smaller offset doesn't change anything. EXPECT_FALSE(flow_controller_->UpdateSendWindowOffset(send_window_ / 10)); EXPECT_EQ(send_window_, flow_controller_->SendWindowSize()); // Try to send more bytes, violating flow control. EXPECT_CALL(connection_, SendConnectionCloseWithDetails( QUIC_FLOW_CONTROL_SENT_TOO_MUCH_DATA, _)); EXPECT_DFATAL(flow_controller_->AddBytesSent(send_window_ * 10), base::StringPrintf("Trying to send an extra %" PRIu64 " bytes", send_window_ * 10)); EXPECT_TRUE(flow_controller_->IsBlocked()); EXPECT_EQ(0u, flow_controller_->SendWindowSize()); } TEST_F(QuicFlowControllerTest, ReceivingBytes) { Initialize(); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Receive some bytes, updating highest received offset, but not enough to // fill flow control receive window. EXPECT_TRUE( flow_controller_->UpdateHighestReceivedOffset(1 + receive_window_ / 2)); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ((receive_window_ / 2) - 1, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Consume enough bytes to send a WINDOW_UPDATE frame. EXPECT_CALL(connection_, SendWindowUpdate(stream_id_, ::testing::_)).Times(1); flow_controller_->AddBytesConsumed(1 + receive_window_ / 2); // Result is that once again we have a fully open receive window. EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); } TEST_F(QuicFlowControllerTest, OnlySendBlockedFrameOncePerOffset) { Initialize(); // Test that we don't send duplicate BLOCKED frames. We should only send one // BLOCKED frame at a given send window offset. EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(send_window_, flow_controller_->SendWindowSize()); // Send enough bytes to block. flow_controller_->AddBytesSent(send_window_); EXPECT_TRUE(flow_controller_->IsBlocked()); EXPECT_EQ(0u, flow_controller_->SendWindowSize()); // Expect that 2 BLOCKED frames should get sent in total. EXPECT_CALL(connection_, SendBlocked(stream_id_)).Times(2); // BLOCKED frame should get sent. flow_controller_->MaybeSendBlocked(); // BLOCKED frame should not get sent again until our send offset changes. flow_controller_->MaybeSendBlocked(); flow_controller_->MaybeSendBlocked(); flow_controller_->MaybeSendBlocked(); flow_controller_->MaybeSendBlocked(); flow_controller_->MaybeSendBlocked(); // Update the send window, then send enough bytes to block again. EXPECT_TRUE(flow_controller_->UpdateSendWindowOffset(2 * send_window_)); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_EQ(send_window_, flow_controller_->SendWindowSize()); flow_controller_->AddBytesSent(send_window_); EXPECT_TRUE(flow_controller_->IsBlocked()); EXPECT_EQ(0u, flow_controller_->SendWindowSize()); // BLOCKED frame should get sent as send offset has changed. flow_controller_->MaybeSendBlocked(); } TEST_F(QuicFlowControllerTest, ReceivingBytesFastIncreasesFlowWindow) { ValueRestore old_flag(&FLAGS_quic_auto_tune_receive_window, true); // This test will generate two WINDOW_UPDATE frames. EXPECT_CALL(connection_, SendWindowUpdate(stream_id_, ::testing::_)).Times(2); Initialize(); flow_controller_->set_auto_tune_receive_window(true); // Make sure clock is inititialized. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(1)); QuicSentPacketManager* manager = QuicConnectionPeer::GetSentPacketManager(&connection_); RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(manager); rtt_stats->UpdateRtt(QuicTime::Delta::FromMilliseconds(kRtt), QuicTime::Delta::Zero(), QuicTime::Zero()); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); QuicByteCount threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); QuicStreamOffset receive_offset = threshold + 1; // Receive some bytes, updating highest received offset, but not enough to // fill flow control receive window. EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest - receive_offset, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Consume enough bytes to send a WINDOW_UPDATE frame. flow_controller_->AddBytesConsumed(threshold + 1); // Result is that once again we have a fully open receive window. EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Move time forward, but by less than two RTTs. Then receive and consume // some more, forcing a second WINDOW_UPDATE with an increased max window // size. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(2 * kRtt - 1)); receive_offset += threshold + 1; EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); flow_controller_->AddBytesConsumed(threshold + 1); EXPECT_FALSE(flow_controller_->FlowControlViolation()); QuicByteCount new_threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); EXPECT_GT(new_threshold, threshold); } TEST_F(QuicFlowControllerTest, ReceivingBytesFastStatusQuo) { ValueRestore old_flag(&FLAGS_quic_auto_tune_receive_window, false); // This test will generate two WINDOW_UPDATE frames. EXPECT_CALL(connection_, SendWindowUpdate(stream_id_, ::testing::_)).Times(2); Initialize(); flow_controller_->set_auto_tune_receive_window(true); // Make sure clock is inititialized. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(1)); QuicSentPacketManager* manager = QuicConnectionPeer::GetSentPacketManager(&connection_); RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(manager); rtt_stats->UpdateRtt(QuicTime::Delta::FromMilliseconds(kRtt), QuicTime::Delta::Zero(), QuicTime::Zero()); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); QuicByteCount threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); QuicStreamOffset receive_offset = threshold + 1; // Receive some bytes, updating highest received offset, but not enough to // fill flow control receive window. EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest - receive_offset, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Consume enough bytes to send a WINDOW_UPDATE frame. flow_controller_->AddBytesConsumed(threshold + 1); // Result is that once again we have a fully open receive window. EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Move time forward, but by less than two RTTs. Then receive and consume // some more, forcing a second WINDOW_UPDATE with an increased max window // size. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(2 * kRtt - 1)); receive_offset += threshold + 1; EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); flow_controller_->AddBytesConsumed(threshold + 1); EXPECT_FALSE(flow_controller_->FlowControlViolation()); QuicByteCount new_threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); EXPECT_EQ(new_threshold, threshold); } TEST_F(QuicFlowControllerTest, ReceivingBytesNormalStableFlowWindow) { ValueRestore old_flag(&FLAGS_quic_auto_tune_receive_window, true); // This test will generate two WINDOW_UPDATE frames. EXPECT_CALL(connection_, SendWindowUpdate(stream_id_, ::testing::_)).Times(2); Initialize(); flow_controller_->set_auto_tune_receive_window(true); // Make sure clock is inititialized. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(1)); QuicSentPacketManager* manager = QuicConnectionPeer::GetSentPacketManager(&connection_); RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(manager); rtt_stats->UpdateRtt(QuicTime::Delta::FromMilliseconds(kRtt), QuicTime::Delta::Zero(), QuicTime::Zero()); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); QuicByteCount threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); QuicStreamOffset receive_offset = threshold + 1; // Receive some bytes, updating highest received offset, but not enough to // fill flow control receive window. EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest - receive_offset, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); flow_controller_->AddBytesConsumed(threshold + 1); // Result is that once again we have a fully open receive window. EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Move time forward, but by more than two RTTs. Then receive and consume // some more, forcing a second WINDOW_UPDATE with unchanged max window size. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(2 * kRtt + 1)); receive_offset += threshold + 1; EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); flow_controller_->AddBytesConsumed(threshold + 1); EXPECT_FALSE(flow_controller_->FlowControlViolation()); QuicByteCount new_threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); EXPECT_EQ(new_threshold, threshold); } TEST_F(QuicFlowControllerTest, ReceivingBytesNormalStatusQuo) { ValueRestore old_flag(&FLAGS_quic_auto_tune_receive_window, false); // This test will generate two WINDOW_UPDATE frames. EXPECT_CALL(connection_, SendWindowUpdate(stream_id_, ::testing::_)).Times(2); Initialize(); flow_controller_->set_auto_tune_receive_window(true); // Make sure clock is inititialized. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(1)); QuicSentPacketManager* manager = QuicConnectionPeer::GetSentPacketManager(&connection_); RttStats* rtt_stats = QuicSentPacketManagerPeer::GetRttStats(manager); rtt_stats->UpdateRtt(QuicTime::Delta::FromMilliseconds(kRtt), QuicTime::Delta::Zero(), QuicTime::Zero()); EXPECT_FALSE(flow_controller_->IsBlocked()); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); QuicByteCount threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); QuicStreamOffset receive_offset = threshold + 1; // Receive some bytes, updating highest received offset, but not enough to // fill flow control receive window. EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest - receive_offset, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); flow_controller_->AddBytesConsumed(threshold + 1); // Result is that once again we have a fully open receive window. EXPECT_FALSE(flow_controller_->FlowControlViolation()); EXPECT_EQ(kInitialSessionFlowControlWindowForTest, QuicFlowControllerPeer::ReceiveWindowSize(flow_controller_.get())); // Move time forward, but by more than two RTTs. Then receive and consume // some more, forcing a second WINDOW_UPDATE with unchanged max window size. connection_.AdvanceTime(QuicTime::Delta::FromMilliseconds(2 * kRtt + 1)); receive_offset += threshold + 1; EXPECT_TRUE(flow_controller_->UpdateHighestReceivedOffset(receive_offset)); flow_controller_->AddBytesConsumed(threshold + 1); EXPECT_FALSE(flow_controller_->FlowControlViolation()); QuicByteCount new_threshold = QuicFlowControllerPeer::WindowUpdateThreshold(flow_controller_.get()); EXPECT_EQ(new_threshold, threshold); } } // namespace test } // namespace net