| /* |
| * Copyright 2012 The WebRTC project authors. All Rights Reserved. |
| * |
| * Use of this source code is governed by a BSD-style license |
| * that can be found in the LICENSE file in the root of the source |
| * tree. An additional intellectual property rights grant can be found |
| * in the file PATENTS. All contributing project authors may |
| * be found in the AUTHORS file in the root of the source tree. |
| */ |
| |
| #include <stdint.h> |
| |
| #include <cstdlib> |
| #include <iterator> |
| #include <string> |
| #include <tuple> |
| #include <vector> |
| |
| #include "absl/algorithm/container.h" |
| #include "absl/types/optional.h" |
| #include "api/data_channel_interface.h" |
| #include "api/dtls_transport_interface.h" |
| #include "api/peer_connection_interface.h" |
| #include "api/scoped_refptr.h" |
| #include "api/sctp_transport_interface.h" |
| #include "api/stats/rtc_stats_report.h" |
| #include "api/stats/rtcstats_objects.h" |
| #include "api/units/time_delta.h" |
| #include "p2p/base/transport_description.h" |
| #include "p2p/base/transport_info.h" |
| #include "pc/media_session.h" |
| #include "pc/session_description.h" |
| #include "pc/test/integration_test_helpers.h" |
| #include "pc/test/mock_peer_connection_observers.h" |
| #include "rtc_base/copy_on_write_buffer.h" |
| #include "rtc_base/fake_clock.h" |
| #include "rtc_base/gunit.h" |
| #include "rtc_base/helpers.h" |
| #include "rtc_base/logging.h" |
| #include "rtc_base/numerics/safe_conversions.h" |
| #include "rtc_base/virtual_socket_server.h" |
| #include "test/gmock.h" |
| #include "test/gtest.h" |
| |
| namespace webrtc { |
| |
| namespace { |
| |
| // All tests in this file require SCTP support. |
| #ifdef WEBRTC_HAVE_SCTP |
| |
| #if defined(WEBRTC_ANDROID) |
| // Disable heavy tests running on low-end Android devices. |
| #define DISABLED_ON_ANDROID(t) DISABLED_##t |
| #else |
| #define DISABLED_ON_ANDROID(t) t |
| #endif |
| |
| class DataChannelIntegrationTest |
| : public PeerConnectionIntegrationBaseTest, |
| public ::testing::WithParamInterface<std::tuple<SdpSemantics, bool>> { |
| protected: |
| DataChannelIntegrationTest() |
| : PeerConnectionIntegrationBaseTest(std::get<0>(GetParam())), |
| allow_media_(std::get<1>(GetParam())) {} |
| bool allow_media() { return allow_media_; } |
| |
| bool CreatePeerConnectionWrappers() { |
| if (allow_media_) { |
| return PeerConnectionIntegrationBaseTest::CreatePeerConnectionWrappers(); |
| } |
| return PeerConnectionIntegrationBaseTest:: |
| CreatePeerConnectionWrappersWithoutMediaEngine(); |
| } |
| |
| private: |
| // True if media is allowed to be added |
| const bool allow_media_; |
| }; |
| |
| // Fake clock must be set before threads are started to prevent race on |
| // Set/GetClockForTesting(). |
| // To achieve that, multiple inheritance is used as a mixin pattern |
| // where order of construction is finely controlled. |
| // This also ensures peerconnection is closed before switching back to non-fake |
| // clock, avoiding other races and DCHECK failures such as in rtp_sender.cc. |
| class FakeClockForTest : public rtc::ScopedFakeClock { |
| protected: |
| FakeClockForTest() { |
| // Some things use a time of "0" as a special value, so we need to start out |
| // the fake clock at a nonzero time. |
| // TODO(deadbeef): Fix this. |
| AdvanceTime(TimeDelta::Seconds(1)); |
| } |
| |
| // Explicit handle. |
| ScopedFakeClock& FakeClock() { return *this; } |
| }; |
| |
| class DataChannelIntegrationTestPlanB |
| : public PeerConnectionIntegrationBaseTest { |
| protected: |
| DataChannelIntegrationTestPlanB() |
| : PeerConnectionIntegrationBaseTest(SdpSemantics::kPlanB_DEPRECATED) {} |
| }; |
| |
| class DataChannelIntegrationTestUnifiedPlan |
| : public PeerConnectionIntegrationBaseTest { |
| protected: |
| DataChannelIntegrationTestUnifiedPlan() |
| : PeerConnectionIntegrationBaseTest(SdpSemantics::kUnifiedPlan) {} |
| }; |
| |
| void MakeActiveSctpOffer(cricket::SessionDescription* desc) { |
| auto& transport_infos = desc->transport_infos(); |
| for (auto& transport_info : transport_infos) { |
| transport_info.description.connection_role = cricket::CONNECTIONROLE_ACTIVE; |
| } |
| } |
| |
| // This test causes a PeerConnection to enter Disconnected state, and |
| // sends data on a DataChannel while disconnected. |
| // The data should be surfaced when the connection reestablishes. |
| TEST_P(DataChannelIntegrationTest, DataChannelWhileDisconnected) { |
| CreatePeerConnectionWrappers(); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer(), kDefaultTimeout); |
| std::string data1 = "hello first"; |
| caller()->data_channel()->Send(DataBuffer(data1)); |
| EXPECT_EQ_WAIT(data1, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| // Cause a network outage |
| virtual_socket_server()->set_drop_probability(1.0); |
| EXPECT_EQ_WAIT(PeerConnectionInterface::kIceConnectionDisconnected, |
| caller()->standardized_ice_connection_state(), |
| kDefaultTimeout); |
| std::string data2 = "hello second"; |
| caller()->data_channel()->Send(DataBuffer(data2)); |
| // Remove the network outage. The connection should reestablish. |
| virtual_socket_server()->set_drop_probability(0.0); |
| EXPECT_EQ_WAIT(data2, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| |
| // This test causes a PeerConnection to enter Disconnected state, |
| // sends data on a DataChannel while disconnected, and then triggers |
| // an ICE restart. |
| // The data should be surfaced when the connection reestablishes. |
| TEST_P(DataChannelIntegrationTest, DataChannelWhileDisconnectedIceRestart) { |
| CreatePeerConnectionWrappers(); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer(), kDefaultTimeout); |
| std::string data1 = "hello first"; |
| caller()->data_channel()->Send(DataBuffer(data1)); |
| EXPECT_EQ_WAIT(data1, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| // Cause a network outage |
| virtual_socket_server()->set_drop_probability(1.0); |
| ASSERT_EQ_WAIT(PeerConnectionInterface::kIceConnectionDisconnected, |
| caller()->standardized_ice_connection_state(), |
| kDefaultTimeout); |
| std::string data2 = "hello second"; |
| caller()->data_channel()->Send(DataBuffer(data2)); |
| |
| // Trigger an ICE restart. The signaling channel is not affected by |
| // the network outage. |
| caller()->SetOfferAnswerOptions(IceRestartOfferAnswerOptions()); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| // Remove the network outage. The connection should reestablish. |
| virtual_socket_server()->set_drop_probability(0.0); |
| EXPECT_EQ_WAIT(data2, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| |
| // This test sets up a call between two parties with audio, video and an SCTP |
| // data channel. |
| TEST_P(DataChannelIntegrationTest, EndToEndCallWithSctpDataChannel) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| // Expect that data channel created on caller side will show up for callee as |
| // well. |
| caller()->CreateDataChannel(); |
| if (allow_media()) { |
| caller()->AddAudioVideoTracks(); |
| callee()->AddAudioVideoTracks(); |
| } |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| if (allow_media()) { |
| // Ensure the existence of the SCTP data channel didn't impede audio/video. |
| MediaExpectations media_expectations; |
| media_expectations.ExpectBidirectionalAudioAndVideo(); |
| ASSERT_TRUE(ExpectNewFrames(media_expectations)); |
| } |
| // Caller data channel should already exist (it created one). Callee data |
| // channel may not exist yet, since negotiation happens in-band, not in SDP. |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| EXPECT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| // Ensure data can be sent in both directions. |
| std::string data = "hello world"; |
| caller()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| callee()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, caller()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| |
| // This test sets up a call between two parties with an SCTP |
| // data channel only, and sends messages of various sizes. |
| TEST_P(DataChannelIntegrationTest, |
| EndToEndCallWithSctpDataChannelVariousSizes) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| // Expect that data channel created on caller side will show up for callee as |
| // well. |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| // Caller data channel should already exist (it created one). Callee data |
| // channel may not exist yet, since negotiation happens in-band, not in SDP. |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| EXPECT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| for (int message_size = 1; message_size < 100000; message_size *= 2) { |
| std::string data(message_size, 'a'); |
| caller()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| callee()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, caller()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| // Specifically probe the area around the MTU size. |
| for (int message_size = 1100; message_size < 1300; message_size += 1) { |
| std::string data(message_size, 'a'); |
| caller()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| callee()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, caller()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| } |
| |
| // This test sets up a call between two parties with an SCTP |
| // data channel only, and sends empty messages |
| TEST_P(DataChannelIntegrationTest, |
| EndToEndCallWithSctpDataChannelEmptyMessages) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| // Expect that data channel created on caller side will show up for callee as |
| // well. |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| // Caller data channel should already exist (it created one). Callee data |
| // channel may not exist yet, since negotiation happens in-band, not in SDP. |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| EXPECT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| // Ensure data can be sent in both directions. |
| // Sending empty string data |
| std::string data = ""; |
| caller()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(1u, callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| EXPECT_TRUE(callee()->data_observer()->last_message().empty()); |
| EXPECT_FALSE(callee()->data_observer()->messages().back().binary); |
| callee()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(1u, caller()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| EXPECT_TRUE(caller()->data_observer()->last_message().empty()); |
| EXPECT_FALSE(caller()->data_observer()->messages().back().binary); |
| |
| // Sending empty binary data |
| rtc::CopyOnWriteBuffer empty_buffer; |
| caller()->data_channel()->Send(DataBuffer(empty_buffer, true)); |
| EXPECT_EQ_WAIT(2u, callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| EXPECT_TRUE(callee()->data_observer()->last_message().empty()); |
| EXPECT_TRUE(callee()->data_observer()->messages().back().binary); |
| callee()->data_channel()->Send(DataBuffer(empty_buffer, true)); |
| EXPECT_EQ_WAIT(2u, caller()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| EXPECT_TRUE(caller()->data_observer()->last_message().empty()); |
| EXPECT_TRUE(caller()->data_observer()->messages().back().binary); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, |
| EndToEndCallWithSctpDataChannelLowestSafeMtu) { |
| // The lowest payload size limit that's tested and found safe for this |
| // application. Note that this is not the safe limit under all conditions; |
| // in particular, the default is not the largest DTLS signature, and |
| // this test does not use TURN. |
| const size_t kLowestSafePayloadSizeLimit = 1225; |
| |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| // Expect that data channel created on caller side will show up for callee as |
| // well. |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| // Caller data channel should already exist (it created one). Callee data |
| // channel may not exist yet, since negotiation happens in-band, not in SDP. |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| EXPECT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| virtual_socket_server()->set_max_udp_payload(kLowestSafePayloadSizeLimit); |
| for (int message_size = 1140; message_size < 1240; message_size += 1) { |
| std::string data(message_size, 'a'); |
| caller()->data_channel()->Send(DataBuffer(data)); |
| ASSERT_EQ_WAIT(data, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| callee()->data_channel()->Send(DataBuffer(data)); |
| ASSERT_EQ_WAIT(data, caller()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| } |
| |
| // This test verifies that lowering the MTU of the connection will cause |
| // the datachannel to not transmit reliably. |
| // The purpose of this test is to ensure that we know how a too-small MTU |
| // error manifests itself. |
| TEST_P(DataChannelIntegrationTest, EndToEndCallWithSctpDataChannelHarmfulMtu) { |
| // The lowest payload size limit that's tested and found safe for this |
| // application in this configuration (see test above). |
| const size_t kLowestSafePayloadSizeLimit = 1225; |
| // The size of the smallest message that fails to be delivered. |
| const size_t kMessageSizeThatIsNotDelivered = 1157; |
| |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| EXPECT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| virtual_socket_server()->set_max_udp_payload(kLowestSafePayloadSizeLimit - 1); |
| // Probe for an undelivered or slowly delivered message. The exact |
| // size limit seems to be dependent on the message history, so make the |
| // code easily able to find the current value. |
| bool failure_seen = false; |
| for (size_t message_size = 1110; message_size < 1400; message_size++) { |
| const size_t message_count = |
| callee()->data_observer()->received_message_count(); |
| const std::string data(message_size, 'a'); |
| caller()->data_channel()->Send(DataBuffer(data)); |
| // Wait a very short time for the message to be delivered. |
| // Note: Waiting only 10 ms is too short for Windows bots; they will |
| // flakily fail at a random frame. |
| WAIT(callee()->data_observer()->received_message_count() > message_count, |
| 100); |
| if (callee()->data_observer()->received_message_count() == message_count) { |
| ASSERT_EQ(kMessageSizeThatIsNotDelivered, message_size); |
| failure_seen = true; |
| break; |
| } |
| } |
| ASSERT_TRUE(failure_seen); |
| } |
| |
| // Ensure that when the callee closes an SCTP data channel, the closing |
| // procedure results in the data channel being closed for the caller as well. |
| TEST_P(DataChannelIntegrationTest, CalleeClosesSctpDataChannel) { |
| // Same procedure as above test. |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| if (allow_media()) { |
| caller()->AddAudioVideoTracks(); |
| callee()->AddAudioVideoTracks(); |
| } |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| ASSERT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| // Close the data channel on the callee side, and wait for it to reach the |
| // "closed" state on both sides. |
| callee()->data_channel()->Close(); |
| |
| DataChannelInterface::DataState expected_states[] = { |
| DataChannelInterface::DataState::kConnecting, |
| DataChannelInterface::DataState::kOpen, |
| DataChannelInterface::DataState::kClosing, |
| DataChannelInterface::DataState::kClosed}; |
| |
| EXPECT_EQ_WAIT(DataChannelInterface::DataState::kClosed, |
| caller()->data_observer()->state(), kDefaultTimeout); |
| EXPECT_THAT(caller()->data_observer()->states(), |
| ::testing::ElementsAreArray(expected_states)); |
| |
| EXPECT_EQ_WAIT(DataChannelInterface::DataState::kClosed, |
| callee()->data_observer()->state(), kDefaultTimeout); |
| EXPECT_THAT(callee()->data_observer()->states(), |
| ::testing::ElementsAreArray(expected_states)); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, SctpDataChannelConfigSentToOtherSide) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| DataChannelInit init; |
| init.id = 53; |
| init.maxRetransmits = 52; |
| caller()->CreateDataChannel("data-channel", &init); |
| if (allow_media()) { |
| caller()->AddAudioVideoTracks(); |
| callee()->AddAudioVideoTracks(); |
| } |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| // Since "negotiated" is false, the "id" parameter should be ignored. |
| EXPECT_NE(init.id, callee()->data_channel()->id()); |
| EXPECT_EQ("data-channel", callee()->data_channel()->label()); |
| EXPECT_EQ(init.maxRetransmits, callee()->data_channel()->maxRetransmits()); |
| EXPECT_FALSE(callee()->data_channel()->negotiated()); |
| } |
| |
| // Test sctp's ability to process unordered data stream, where data actually |
| // arrives out of order using simulated delays. Previously there have been some |
| // bugs in this area. |
| TEST_P(DataChannelIntegrationTest, StressTestUnorderedSctpDataChannel) { |
| // Introduce random network delays. |
| // Otherwise it's not a true "unordered" test. |
| virtual_socket_server()->set_delay_mean(20); |
| virtual_socket_server()->set_delay_stddev(5); |
| virtual_socket_server()->UpdateDelayDistribution(); |
| // Normal procedure, but with unordered data channel config. |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| DataChannelInit init; |
| init.ordered = false; |
| caller()->CreateDataChannel(&init); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| ASSERT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| static constexpr int kNumMessages = 100; |
| // Deliberately chosen to be larger than the MTU so messages get fragmented. |
| static constexpr size_t kMaxMessageSize = 4096; |
| // Create and send random messages. |
| std::vector<std::string> sent_messages; |
| for (int i = 0; i < kNumMessages; ++i) { |
| size_t length = |
| (rand() % kMaxMessageSize) + 1; // NOLINT (rand_r instead of rand) |
| std::string message; |
| ASSERT_TRUE(rtc::CreateRandomString(length, &message)); |
| caller()->data_channel()->Send(DataBuffer(message)); |
| callee()->data_channel()->Send(DataBuffer(message)); |
| sent_messages.push_back(message); |
| } |
| |
| // Wait for all messages to be received. |
| EXPECT_EQ_WAIT(rtc::checked_cast<size_t>(kNumMessages), |
| caller()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| EXPECT_EQ_WAIT(rtc::checked_cast<size_t>(kNumMessages), |
| callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| |
| // Sort and compare to make sure none of the messages were corrupted. |
| std::vector<std::string> caller_received_messages; |
| absl::c_transform(caller()->data_observer()->messages(), |
| std::back_inserter(caller_received_messages), |
| [](const auto& a) { return a.data; }); |
| |
| std::vector<std::string> callee_received_messages; |
| absl::c_transform(callee()->data_observer()->messages(), |
| std::back_inserter(callee_received_messages), |
| [](const auto& a) { return a.data; }); |
| |
| absl::c_sort(sent_messages); |
| absl::c_sort(caller_received_messages); |
| absl::c_sort(callee_received_messages); |
| EXPECT_EQ(sent_messages, caller_received_messages); |
| EXPECT_EQ(sent_messages, callee_received_messages); |
| } |
| |
| // Repeatedly open and close data channels on a peer connection to check that |
| // the channels are properly negotiated and SCTP stream IDs properly recycled. |
| TEST_P(DataChannelIntegrationTest, StressTestOpenCloseChannelNoDelay) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| |
| int channel_id = 0; |
| const size_t kChannelCount = 8; |
| const size_t kIterations = 10; |
| bool has_negotiated = false; |
| |
| DataChannelInit init; |
| for (size_t repeats = 0; repeats < kIterations; ++repeats) { |
| RTC_LOG(LS_INFO) << "Iteration " << (repeats + 1) << "/" << kIterations; |
| |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| rtc::StringBuilder sb; |
| sb << "channel-" << channel_id++; |
| caller()->CreateDataChannel(sb.Release(), &init); |
| } |
| ASSERT_EQ(caller()->data_channels().size(), kChannelCount); |
| |
| if (!has_negotiated) { |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| has_negotiated = true; |
| } |
| |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| ASSERT_EQ_WAIT(caller()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kOpen, kDefaultTimeout); |
| RTC_LOG(LS_INFO) << "Caller Channel " |
| << caller()->data_channels()[i]->label() << " with id " |
| << caller()->data_channels()[i]->id() << " is open."; |
| } |
| ASSERT_EQ_WAIT(callee()->data_channels().size(), kChannelCount, |
| kDefaultTimeout); |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| ASSERT_EQ_WAIT(callee()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kOpen, kDefaultTimeout); |
| RTC_LOG(LS_INFO) << "Callee Channel " |
| << callee()->data_channels()[i]->label() << " with id " |
| << callee()->data_channels()[i]->id() << " is open."; |
| } |
| |
| // Closing from both sides to attempt creating races. |
| // A real application would likely only close from one side. |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| if (i % 3 == 0) { |
| callee()->data_channels()[i]->Close(); |
| caller()->data_channels()[i]->Close(); |
| } else { |
| caller()->data_channels()[i]->Close(); |
| callee()->data_channels()[i]->Close(); |
| } |
| } |
| |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| ASSERT_EQ_WAIT(caller()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kClosed, kDefaultTimeout); |
| ASSERT_EQ_WAIT(callee()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kClosed, kDefaultTimeout); |
| } |
| |
| caller()->data_channels().clear(); |
| caller()->data_observers().clear(); |
| callee()->data_channels().clear(); |
| callee()->data_observers().clear(); |
| } |
| } |
| |
| // Repeatedly open and close data channels on a peer connection to check that |
| // the channels are properly negotiated and SCTP stream IDs properly recycled. |
| // Some delay is added for better coverage. |
| TEST_P(DataChannelIntegrationTest, StressTestOpenCloseChannelWithDelay) { |
| // Simulate some network delay |
| virtual_socket_server()->set_delay_mean(20); |
| virtual_socket_server()->set_delay_stddev(5); |
| virtual_socket_server()->UpdateDelayDistribution(); |
| |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| |
| int channel_id = 0; |
| const size_t kChannelCount = 8; |
| const size_t kIterations = 10; |
| bool has_negotiated = false; |
| |
| DataChannelInit init; |
| for (size_t repeats = 0; repeats < kIterations; ++repeats) { |
| RTC_LOG(LS_INFO) << "Iteration " << (repeats + 1) << "/" << kIterations; |
| |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| rtc::StringBuilder sb; |
| sb << "channel-" << channel_id++; |
| caller()->CreateDataChannel(sb.Release(), &init); |
| } |
| ASSERT_EQ(caller()->data_channels().size(), kChannelCount); |
| |
| if (!has_negotiated) { |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| has_negotiated = true; |
| } |
| |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| ASSERT_EQ_WAIT(caller()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kOpen, kDefaultTimeout); |
| RTC_LOG(LS_INFO) << "Caller Channel " |
| << caller()->data_channels()[i]->label() << " with id " |
| << caller()->data_channels()[i]->id() << " is open."; |
| } |
| ASSERT_EQ_WAIT(callee()->data_channels().size(), kChannelCount, |
| kDefaultTimeout); |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| ASSERT_EQ_WAIT(callee()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kOpen, kDefaultTimeout); |
| RTC_LOG(LS_INFO) << "Callee Channel " |
| << callee()->data_channels()[i]->label() << " with id " |
| << callee()->data_channels()[i]->id() << " is open."; |
| } |
| |
| // Closing from both sides to attempt creating races. |
| // A real application would likely only close from one side. |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| if (i % 3 == 0) { |
| callee()->data_channels()[i]->Close(); |
| caller()->data_channels()[i]->Close(); |
| } else { |
| caller()->data_channels()[i]->Close(); |
| callee()->data_channels()[i]->Close(); |
| } |
| } |
| |
| for (size_t i = 0; i < kChannelCount; ++i) { |
| ASSERT_EQ_WAIT(caller()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kClosed, kDefaultTimeout); |
| ASSERT_EQ_WAIT(callee()->data_channels()[i]->state(), |
| DataChannelInterface::DataState::kClosed, kDefaultTimeout); |
| } |
| |
| caller()->data_channels().clear(); |
| caller()->data_observers().clear(); |
| callee()->data_channels().clear(); |
| callee()->data_observers().clear(); |
| } |
| } |
| |
| // This test sets up a call between two parties with audio, and video. When |
| // audio and video are setup and flowing, an SCTP data channel is negotiated. |
| TEST_P(DataChannelIntegrationTest, AddSctpDataChannelInSubsequentOffer) { |
| // This test can't be performed without media. |
| if (!allow_media()) { |
| return; |
| } |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| // Do initial offer/answer with audio/video. |
| caller()->AddAudioVideoTracks(); |
| callee()->AddAudioVideoTracks(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| // Create data channel and do new offer and answer. |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| // Caller data channel should already exist (it created one). Callee data |
| // channel may not exist yet, since negotiation happens in-band, not in SDP. |
| ASSERT_NE(nullptr, caller()->data_channel()); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| EXPECT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| // Ensure data can be sent in both directions. |
| std::string data = "hello world"; |
| caller()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| callee()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, caller()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| |
| // Set up a connection initially just using SCTP data channels, later |
| // upgrading to audio/video, ensuring frames are received end-to-end. |
| // Effectively the inverse of the test above. This was broken in M57; see |
| // https://crbug.com/711243 |
| TEST_P(DataChannelIntegrationTest, SctpDataChannelToAudioVideoUpgrade) { |
| // This test can't be performed without media. |
| if (!allow_media()) { |
| return; |
| } |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| // Do initial offer/answer with just data channel. |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| // Wait until data can be sent over the data channel. |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| ASSERT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| // Do subsequent offer/answer with two-way audio and video. Audio and video |
| // should end up bundled on the DTLS/ICE transport already used for data. |
| caller()->AddAudioVideoTracks(); |
| callee()->AddAudioVideoTracks(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| MediaExpectations media_expectations; |
| media_expectations.ExpectBidirectionalAudioAndVideo(); |
| ASSERT_TRUE(ExpectNewFrames(media_expectations)); |
| } |
| |
| static void MakeSpecCompliantSctpOffer(cricket::SessionDescription* desc) { |
| cricket::SctpDataContentDescription* dcd_offer = |
| GetFirstSctpDataContentDescription(desc); |
| // See https://crbug.com/webrtc/11211 - this function is a no-op |
| ASSERT_TRUE(dcd_offer); |
| dcd_offer->set_use_sctpmap(false); |
| dcd_offer->set_protocol("UDP/DTLS/SCTP"); |
| } |
| |
| // Test that the data channel works when a spec-compliant SCTP m= section is |
| // offered (using "a=sctp-port" instead of "a=sctpmap", and using |
| // "UDP/DTLS/SCTP" as the protocol). |
| TEST_P(DataChannelIntegrationTest, |
| DataChannelWorksWhenSpecCompliantSctpOfferReceived) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->SetGeneratedSdpMunger(MakeSpecCompliantSctpOffer); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel() != nullptr, kDefaultTimeout); |
| EXPECT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| |
| // Ensure data can be sent in both directions. |
| std::string data = "hello world"; |
| caller()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| callee()->data_channel()->Send(DataBuffer(data)); |
| EXPECT_EQ_WAIT(data, caller()->data_observer()->last_message(), |
| kDefaultTimeout); |
| } |
| |
| // Test that after closing PeerConnections, they stop sending any packets |
| // (ICE, DTLS, RTP...). |
| TEST_P(DataChannelIntegrationTest, ClosingConnectionStopsPacketFlow) { |
| // This test can't be performed without media. |
| if (!allow_media()) { |
| return; |
| } |
| // Set up audio/video/data, wait for some frames to be received. |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->AddAudioVideoTracks(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| MediaExpectations media_expectations; |
| media_expectations.CalleeExpectsSomeAudioAndVideo(); |
| ASSERT_TRUE(ExpectNewFrames(media_expectations)); |
| // Close PeerConnections. |
| ClosePeerConnections(); |
| // Pump messages for a second, and ensure no new packets end up sent. |
| uint32_t sent_packets_a = virtual_socket_server()->sent_packets(); |
| WAIT(false, 1000); |
| uint32_t sent_packets_b = virtual_socket_server()->sent_packets(); |
| EXPECT_EQ(sent_packets_a, sent_packets_b); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, DtlsRoleIsSetNormally) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| ASSERT_FALSE(caller()->pc()->GetSctpTransport()); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| ASSERT_TRUE(caller()->pc()->GetSctpTransport()); |
| ASSERT_TRUE( |
| caller()->pc()->GetSctpTransport()->Information().dtls_transport()); |
| EXPECT_TRUE(caller() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role()); |
| EXPECT_EQ(caller() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role(), |
| DtlsTransportTlsRole::kServer); |
| EXPECT_EQ(callee() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role(), |
| DtlsTransportTlsRole::kClient); |
| // ID should be assigned according to the odd/even rule based on role; |
| // client gets even numbers, server gets odd ones. RFC 8832 section 6. |
| // TODO(hta): Test multiple channels. |
| EXPECT_EQ(caller()->data_channel()->id(), 1); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, DtlsRoleIsSetWhenReversed) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| callee()->SetReceivedSdpMunger(MakeActiveSctpOffer); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| EXPECT_TRUE(caller() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role()); |
| EXPECT_EQ(caller() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role(), |
| DtlsTransportTlsRole::kClient); |
| EXPECT_EQ(callee() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role(), |
| DtlsTransportTlsRole::kServer); |
| // ID should be assigned according to the odd/even rule based on role; |
| // client gets even numbers, server gets odd ones. RFC 8832 section 6. |
| // TODO(hta): Test multiple channels. |
| EXPECT_EQ(caller()->data_channel()->id(), 0); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, |
| DtlsRoleIsSetWhenReversedWithChannelCollision) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| |
| callee()->SetReceivedSdpMunger([this](cricket::SessionDescription* desc) { |
| MakeActiveSctpOffer(desc); |
| callee()->CreateDataChannel(); |
| }); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| ASSERT_EQ_WAIT(callee()->data_channels().size(), 2U, kDefaultTimeout); |
| ASSERT_EQ_WAIT(caller()->data_channels().size(), 2U, kDefaultTimeout); |
| EXPECT_TRUE(caller() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role()); |
| EXPECT_EQ(caller() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role(), |
| DtlsTransportTlsRole::kClient); |
| EXPECT_EQ(callee() |
| ->pc() |
| ->GetSctpTransport() |
| ->Information() |
| .dtls_transport() |
| ->Information() |
| .role(), |
| DtlsTransportTlsRole::kServer); |
| // ID should be assigned according to the odd/even rule based on role; |
| // client gets even numbers, server gets odd ones. RFC 8832 section 6. |
| ASSERT_EQ(caller()->data_channels().size(), 2U); |
| ASSERT_EQ(callee()->data_channels().size(), 2U); |
| EXPECT_EQ(caller()->data_channels()[0]->id(), 0); |
| EXPECT_EQ(caller()->data_channels()[1]->id(), 1); |
| EXPECT_EQ(callee()->data_channels()[0]->id(), 1); |
| EXPECT_EQ(callee()->data_channels()[1]->id(), 0); |
| } |
| |
| // Test that transport stats are generated by the RTCStatsCollector for a |
| // connection that only involves data channels. This is a regression test for |
| // crbug.com/826972. |
| TEST_P(DataChannelIntegrationTest, |
| TransportStatsReportedForDataChannelOnlyConnection) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel(), kDefaultTimeout); |
| |
| auto caller_report = caller()->NewGetStats(); |
| EXPECT_EQ(1u, caller_report->GetStatsOfType<RTCTransportStats>().size()); |
| auto callee_report = callee()->NewGetStats(); |
| EXPECT_EQ(1u, callee_report->GetStatsOfType<RTCTransportStats>().size()); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, QueuedPacketsGetDeliveredInReliableMode) { |
| CreatePeerConnectionWrappers(); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel(), kDefaultTimeout); |
| |
| caller()->data_channel()->Send(DataBuffer("hello first")); |
| ASSERT_EQ_WAIT(1u, callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| // Cause a temporary network outage |
| virtual_socket_server()->set_drop_probability(1.0); |
| for (int i = 1; i <= 10; i++) { |
| caller()->data_channel()->Send(DataBuffer("Sent while blocked")); |
| } |
| // Nothing should be delivered during outage. Short wait. |
| EXPECT_EQ_WAIT(1u, callee()->data_observer()->received_message_count(), 10); |
| // Reverse outage |
| virtual_socket_server()->set_drop_probability(0.0); |
| // All packets should be delivered. |
| EXPECT_EQ_WAIT(11u, callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, QueuedPacketsGetDroppedInUnreliableMode) { |
| CreatePeerConnectionWrappers(); |
| ConnectFakeSignaling(); |
| DataChannelInit init; |
| init.maxRetransmits = 0; |
| init.ordered = false; |
| caller()->CreateDataChannel(&init); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel(), kDefaultTimeout); |
| caller()->data_channel()->Send(DataBuffer("hello first")); |
| ASSERT_EQ_WAIT(1u, callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| // Cause a temporary network outage |
| virtual_socket_server()->set_drop_probability(1.0); |
| // Send a few packets. Note that all get dropped only when all packets |
| // fit into the receiver receive window/congestion window, so that they |
| // actually get sent. |
| for (int i = 1; i <= 10; i++) { |
| caller()->data_channel()->Send(DataBuffer("Sent while blocked")); |
| } |
| // Nothing should be delivered during outage. |
| // We do a short wait to verify that delivery count is still 1. |
| WAIT(false, 10); |
| EXPECT_EQ(1u, callee()->data_observer()->received_message_count()); |
| // Reverse the network outage. |
| virtual_socket_server()->set_drop_probability(0.0); |
| // Send a new packet, and wait for it to be delivered. |
| caller()->data_channel()->Send(DataBuffer("After block")); |
| EXPECT_EQ_WAIT("After block", callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| // Some messages should be lost, but first and last message should have |
| // been delivered. |
| // First, check that the protocol guarantee is preserved. |
| EXPECT_GT(11u, callee()->data_observer()->received_message_count()); |
| EXPECT_LE(2u, callee()->data_observer()->received_message_count()); |
| // Then, check that observed behavior (lose all messages) has not changed |
| EXPECT_EQ(2u, callee()->data_observer()->received_message_count()); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, |
| QueuedPacketsGetDroppedInLifetimeLimitedMode) { |
| CreatePeerConnectionWrappers(); |
| ConnectFakeSignaling(); |
| DataChannelInit init; |
| init.maxRetransmitTime = 1; |
| init.ordered = false; |
| caller()->CreateDataChannel(&init); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel(), kDefaultTimeout); |
| caller()->data_channel()->Send(DataBuffer("hello first")); |
| ASSERT_EQ_WAIT(1u, callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| // Cause a temporary network outage |
| virtual_socket_server()->set_drop_probability(1.0); |
| for (int i = 1; i <= 200; i++) { |
| caller()->data_channel()->Send(DataBuffer("Sent while blocked")); |
| } |
| // Nothing should be delivered during outage. |
| // We do a short wait to verify that delivery count is still 1, |
| // and to make sure max packet lifetime (which is in ms) is exceeded. |
| WAIT(false, 10); |
| EXPECT_EQ(1u, callee()->data_observer()->received_message_count()); |
| // Reverse the network outage. |
| virtual_socket_server()->set_drop_probability(0.0); |
| // Send a new packet, and wait for it to be delivered. |
| caller()->data_channel()->Send(DataBuffer("After block")); |
| EXPECT_EQ_WAIT("After block", callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| // Some messages should be lost, but first and last message should have |
| // been delivered. |
| // First, check that the protocol guarantee is preserved. |
| EXPECT_GT(202u, callee()->data_observer()->received_message_count()); |
| EXPECT_LE(2u, callee()->data_observer()->received_message_count()); |
| // Then, check that observed behavior (lose some messages) has not changed |
| // DcSctp loses all messages. This is correct. |
| EXPECT_EQ(2u, callee()->data_observer()->received_message_count()); |
| } |
| |
| TEST_P(DataChannelIntegrationTest, |
| DISABLED_ON_ANDROID(SomeQueuedPacketsGetDroppedInMaxRetransmitsMode)) { |
| CreatePeerConnectionWrappers(); |
| ConnectFakeSignaling(); |
| DataChannelInit init; |
| init.maxRetransmits = 0; |
| init.ordered = false; |
| caller()->CreateDataChannel(&init); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel(), kDefaultTimeout); |
| caller()->data_channel()->Send(DataBuffer("hello first")); |
| ASSERT_EQ_WAIT(1u, callee()->data_observer()->received_message_count(), |
| kDefaultTimeout); |
| // Cause a temporary network outage |
| virtual_socket_server()->set_drop_probability(1.0); |
| // Fill the SCTP socket buffer until queued data starts to build. |
| constexpr size_t kBufferedDataInSctpSocket = 2'000'000; |
| size_t packet_counter = 0; |
| while (caller()->data_channel()->buffered_amount() < |
| kBufferedDataInSctpSocket && |
| packet_counter < 10000) { |
| packet_counter++; |
| caller()->data_channel()->Send(DataBuffer("Sent while blocked")); |
| } |
| if (caller()->data_channel()->buffered_amount() > kBufferedDataInSctpSocket) { |
| RTC_LOG(LS_INFO) << "Buffered data after " << packet_counter << " packets"; |
| } else { |
| RTC_LOG(LS_INFO) << "No buffered data after " << packet_counter |
| << " packets"; |
| } |
| // Nothing should be delivered during outage. |
| // We do a short wait to verify that delivery count is still 1. |
| WAIT(false, 10); |
| EXPECT_EQ(1u, callee()->data_observer()->received_message_count()); |
| // Reverse the network outage. |
| virtual_socket_server()->set_drop_probability(0.0); |
| // Send a new packet, and wait for it to be delivered. |
| caller()->data_channel()->Send(DataBuffer("After block")); |
| EXPECT_EQ_WAIT("After block", callee()->data_observer()->last_message(), |
| kDefaultTimeout); |
| // Some messages should be lost, but first and last message should have |
| // been delivered. |
| // Due to the fact that retransmissions are only counted when the packet |
| // goes on the wire, NOT when they are stalled in queue due to |
| // congestion, we expect some of the packets to be delivered, because |
| // congestion prevented them from being sent. |
| // Citation: https://tools.ietf.org/html/rfc7496#section-3.1 |
| |
| // First, check that the protocol guarantee is preserved. |
| EXPECT_GT(packet_counter, |
| callee()->data_observer()->received_message_count()); |
| EXPECT_LE(2u, callee()->data_observer()->received_message_count()); |
| // Then, check that observed behavior (lose between 100 and 200 messages) |
| // has not changed. |
| // Usrsctp behavior is different on Android (177) and other platforms (122). |
| // Dcsctp loses 432 packets. |
| EXPECT_GT(2 + packet_counter - 100, |
| callee()->data_observer()->received_message_count()); |
| EXPECT_LT(2 + packet_counter - 500, |
| callee()->data_observer()->received_message_count()); |
| } |
| |
| INSTANTIATE_TEST_SUITE_P(DataChannelIntegrationTest, |
| DataChannelIntegrationTest, |
| Combine(Values(SdpSemantics::kPlanB_DEPRECATED, |
| SdpSemantics::kUnifiedPlan), |
| testing::Bool())); |
| |
| TEST_F(DataChannelIntegrationTestUnifiedPlan, |
| EndToEndCallWithBundledSctpDataChannel) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->AddAudioVideoTracks(); |
| callee()->AddAudioVideoTracks(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(caller()->pc()->GetSctpTransport(), kDefaultTimeout); |
| ASSERT_EQ_WAIT(SctpTransportState::kConnected, |
| caller()->pc()->GetSctpTransport()->Information().state(), |
| kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| } |
| |
| TEST_F(DataChannelIntegrationTestUnifiedPlan, |
| EndToEndCallWithDataChannelOnlyConnects) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_channel(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| ASSERT_TRUE(caller()->data_observer()->IsOpen()); |
| } |
| |
| TEST_F(DataChannelIntegrationTestUnifiedPlan, DataChannelClosesWhenClosed) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| caller()->data_channel()->Close(); |
| ASSERT_TRUE_WAIT(!callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| } |
| |
| TEST_F(DataChannelIntegrationTestUnifiedPlan, |
| DataChannelClosesWhenClosedReverse) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| callee()->data_channel()->Close(); |
| ASSERT_TRUE_WAIT(!caller()->data_observer()->IsOpen(), kDefaultTimeout); |
| } |
| |
| TEST_F(DataChannelIntegrationTestUnifiedPlan, |
| DataChannelClosesWhenPeerConnectionClosed) { |
| ASSERT_TRUE(CreatePeerConnectionWrappers()); |
| ConnectFakeSignaling(); |
| caller()->CreateDataChannel(); |
| caller()->CreateAndSetAndSignalOffer(); |
| ASSERT_TRUE_WAIT(SignalingStateStable(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer(), kDefaultTimeout); |
| ASSERT_TRUE_WAIT(callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| caller()->pc()->Close(); |
| ASSERT_TRUE_WAIT(!callee()->data_observer()->IsOpen(), kDefaultTimeout); |
| } |
| |
| #endif // WEBRTC_HAVE_SCTP |
| |
| } // namespace |
| |
| } // namespace webrtc |