/* * Copyright 2013 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 #include "absl/memory/memory.h" #include "api/audio_codecs/L16/audio_decoder_L16.h" #include "api/audio_codecs/L16/audio_encoder_L16.h" #include "api/audio_codecs/audio_codec_pair_id.h" #include "api/audio_codecs/audio_decoder_factory_template.h" #include "api/audio_codecs/audio_encoder_factory_template.h" #include "api/audio_codecs/builtin_audio_decoder_factory.h" #include "api/audio_codecs/builtin_audio_encoder_factory.h" #include "rtc_base/gunit.h" #include "rtc_base/logging.h" #include "rtc_base/stringencode.h" #include "rtc_base/stringutils.h" #ifdef WEBRTC_ANDROID #include "pc/test/androidtestinitializer.h" #endif #include "pc/test/peerconnectiontestwrapper.h" // Notice that mockpeerconnectionobservers.h must be included after the above! #include "pc/test/mockpeerconnectionobservers.h" #include "test/mock_audio_decoder.h" #include "test/mock_audio_decoder_factory.h" using testing::AtLeast; using testing::Invoke; using testing::StrictMock; using testing::Values; using testing::_; using webrtc::DataChannelInterface; using webrtc::FakeConstraints; using webrtc::MediaConstraintsInterface; using webrtc::MediaStreamInterface; using webrtc::PeerConnectionInterface; using webrtc::SdpSemantics; namespace { const int kMaxWait = 10000; } // namespace class PeerConnectionEndToEndBaseTest : public sigslot::has_slots<>, public testing::Test { public: typedef std::vector> DataChannelList; explicit PeerConnectionEndToEndBaseTest(SdpSemantics sdp_semantics) { network_thread_ = rtc::Thread::CreateWithSocketServer(); worker_thread_ = rtc::Thread::Create(); RTC_CHECK(network_thread_->Start()); RTC_CHECK(worker_thread_->Start()); caller_ = new rtc::RefCountedObject( "caller", network_thread_.get(), worker_thread_.get()); callee_ = new rtc::RefCountedObject( "callee", network_thread_.get(), worker_thread_.get()); webrtc::PeerConnectionInterface::IceServer ice_server; ice_server.uri = "stun:stun.l.google.com:19302"; config_.servers.push_back(ice_server); config_.sdp_semantics = sdp_semantics; #ifdef WEBRTC_ANDROID webrtc::InitializeAndroidObjects(); #endif } void CreatePcs( const MediaConstraintsInterface* pc_constraints, rtc::scoped_refptr audio_encoder_factory1, rtc::scoped_refptr audio_decoder_factory1, rtc::scoped_refptr audio_encoder_factory2, rtc::scoped_refptr audio_decoder_factory2) { EXPECT_TRUE(caller_->CreatePc(pc_constraints, config_, audio_encoder_factory1, audio_decoder_factory1)); EXPECT_TRUE(callee_->CreatePc(pc_constraints, config_, audio_encoder_factory2, audio_decoder_factory2)); PeerConnectionTestWrapper::Connect(caller_.get(), callee_.get()); caller_->SignalOnDataChannel.connect( this, &PeerConnectionEndToEndBaseTest::OnCallerAddedDataChanel); callee_->SignalOnDataChannel.connect( this, &PeerConnectionEndToEndBaseTest::OnCalleeAddedDataChannel); } void CreatePcs( const MediaConstraintsInterface* pc_constraints, rtc::scoped_refptr audio_encoder_factory, rtc::scoped_refptr audio_decoder_factory) { CreatePcs(pc_constraints, audio_encoder_factory, audio_decoder_factory, audio_encoder_factory, audio_decoder_factory); } void GetAndAddUserMedia() { cricket::AudioOptions audio_options; FakeConstraints video_constraints; GetAndAddUserMedia(true, audio_options, true, video_constraints); } void GetAndAddUserMedia(bool audio, const cricket::AudioOptions& audio_options, bool video, const FakeConstraints& video_constraints) { caller_->GetAndAddUserMedia(audio, audio_options, video, video_constraints); callee_->GetAndAddUserMedia(audio, audio_options, video, video_constraints); } void Negotiate() { caller_->CreateOffer(NULL); } void WaitForCallEstablished() { caller_->WaitForCallEstablished(); callee_->WaitForCallEstablished(); } void WaitForConnection() { caller_->WaitForConnection(); callee_->WaitForConnection(); } void OnCallerAddedDataChanel(DataChannelInterface* dc) { caller_signaled_data_channels_.push_back(dc); } void OnCalleeAddedDataChannel(DataChannelInterface* dc) { callee_signaled_data_channels_.push_back(dc); } // Tests that |dc1| and |dc2| can send to and receive from each other. void TestDataChannelSendAndReceive(DataChannelInterface* dc1, DataChannelInterface* dc2) { std::unique_ptr dc1_observer( new webrtc::MockDataChannelObserver(dc1)); std::unique_ptr dc2_observer( new webrtc::MockDataChannelObserver(dc2)); static const std::string kDummyData = "abcdefg"; webrtc::DataBuffer buffer(kDummyData); EXPECT_TRUE(dc1->Send(buffer)); EXPECT_EQ_WAIT(kDummyData, dc2_observer->last_message(), kMaxWait); EXPECT_TRUE(dc2->Send(buffer)); EXPECT_EQ_WAIT(kDummyData, dc1_observer->last_message(), kMaxWait); EXPECT_EQ(1U, dc1_observer->received_message_count()); EXPECT_EQ(1U, dc2_observer->received_message_count()); } void WaitForDataChannelsToOpen(DataChannelInterface* local_dc, const DataChannelList& remote_dc_list, size_t remote_dc_index) { EXPECT_EQ_WAIT(DataChannelInterface::kOpen, local_dc->state(), kMaxWait); ASSERT_TRUE_WAIT(remote_dc_list.size() > remote_dc_index, kMaxWait); EXPECT_EQ_WAIT(DataChannelInterface::kOpen, remote_dc_list[remote_dc_index]->state(), kMaxWait); EXPECT_EQ(local_dc->id(), remote_dc_list[remote_dc_index]->id()); } void CloseDataChannels(DataChannelInterface* local_dc, const DataChannelList& remote_dc_list, size_t remote_dc_index) { local_dc->Close(); EXPECT_EQ_WAIT(DataChannelInterface::kClosed, local_dc->state(), kMaxWait); EXPECT_EQ_WAIT(DataChannelInterface::kClosed, remote_dc_list[remote_dc_index]->state(), kMaxWait); } protected: std::unique_ptr network_thread_; std::unique_ptr worker_thread_; rtc::scoped_refptr caller_; rtc::scoped_refptr callee_; DataChannelList caller_signaled_data_channels_; DataChannelList callee_signaled_data_channels_; webrtc::PeerConnectionInterface::RTCConfiguration config_; }; class PeerConnectionEndToEndTest : public PeerConnectionEndToEndBaseTest, public ::testing::WithParamInterface { protected: PeerConnectionEndToEndTest() : PeerConnectionEndToEndBaseTest(GetParam()) {} }; namespace { std::unique_ptr CreateForwardingMockDecoder( std::unique_ptr real_decoder) { class ForwardingMockDecoder : public StrictMock { public: explicit ForwardingMockDecoder(std::unique_ptr decoder) : decoder_(std::move(decoder)) {} private: std::unique_ptr decoder_; }; const auto dec = real_decoder.get(); // For lambda capturing. auto mock_decoder = absl::make_unique(std::move(real_decoder)); EXPECT_CALL(*mock_decoder, Channels()) .Times(AtLeast(1)) .WillRepeatedly(Invoke([dec] { return dec->Channels(); })); EXPECT_CALL(*mock_decoder, DecodeInternal(_, _, _, _, _)) .Times(AtLeast(1)) .WillRepeatedly( Invoke([dec](const uint8_t* encoded, size_t encoded_len, int sample_rate_hz, int16_t* decoded, webrtc::AudioDecoder::SpeechType* speech_type) { return dec->Decode(encoded, encoded_len, sample_rate_hz, std::numeric_limits::max(), decoded, speech_type); })); EXPECT_CALL(*mock_decoder, Die()); EXPECT_CALL(*mock_decoder, HasDecodePlc()).WillRepeatedly(Invoke([dec] { return dec->HasDecodePlc(); })); EXPECT_CALL(*mock_decoder, IncomingPacket(_, _, _, _, _)) .Times(AtLeast(1)) .WillRepeatedly(Invoke([dec](const uint8_t* payload, size_t payload_len, uint16_t rtp_sequence_number, uint32_t rtp_timestamp, uint32_t arrival_timestamp) { return dec->IncomingPacket(payload, payload_len, rtp_sequence_number, rtp_timestamp, arrival_timestamp); })); EXPECT_CALL(*mock_decoder, PacketDuration(_, _)) .Times(AtLeast(1)) .WillRepeatedly(Invoke([dec](const uint8_t* encoded, size_t encoded_len) { return dec->PacketDuration(encoded, encoded_len); })); EXPECT_CALL(*mock_decoder, SampleRateHz()) .Times(AtLeast(1)) .WillRepeatedly(Invoke([dec] { return dec->SampleRateHz(); })); return std::move(mock_decoder); } rtc::scoped_refptr CreateForwardingMockDecoderFactory( webrtc::AudioDecoderFactory* real_decoder_factory) { rtc::scoped_refptr mock_decoder_factory = new rtc::RefCountedObject>; EXPECT_CALL(*mock_decoder_factory, GetSupportedDecoders()) .Times(AtLeast(1)) .WillRepeatedly(Invoke([real_decoder_factory] { return real_decoder_factory->GetSupportedDecoders(); })); EXPECT_CALL(*mock_decoder_factory, IsSupportedDecoder(_)) .Times(AtLeast(1)) .WillRepeatedly( Invoke([real_decoder_factory](const webrtc::SdpAudioFormat& format) { return real_decoder_factory->IsSupportedDecoder(format); })); EXPECT_CALL(*mock_decoder_factory, MakeAudioDecoderMock(_, _, _)) .Times(AtLeast(2)) .WillRepeatedly( Invoke([real_decoder_factory]( const webrtc::SdpAudioFormat& format, absl::optional codec_pair_id, std::unique_ptr* return_value) { auto real_decoder = real_decoder_factory->MakeAudioDecoder(format, codec_pair_id); *return_value = real_decoder ? CreateForwardingMockDecoder(std::move(real_decoder)) : nullptr; })); return mock_decoder_factory; } struct AudioEncoderUnicornSparklesRainbow { using Config = webrtc::AudioEncoderL16::Config; static absl::optional SdpToConfig(webrtc::SdpAudioFormat format) { if (STR_CASE_CMP(format.name.c_str(), "UnicornSparklesRainbow") == 0) { const webrtc::SdpAudioFormat::Parameters expected_params = { {"num_horns", "1"}}; EXPECT_EQ(expected_params, format.parameters); format.parameters.clear(); format.name = "L16"; return webrtc::AudioEncoderL16::SdpToConfig(format); } else { return absl::nullopt; } } static void AppendSupportedEncoders( std::vector* specs) { std::vector new_specs; webrtc::AudioEncoderL16::AppendSupportedEncoders(&new_specs); for (auto& spec : new_specs) { spec.format.name = "UnicornSparklesRainbow"; EXPECT_TRUE(spec.format.parameters.empty()); spec.format.parameters.emplace("num_horns", "1"); specs->push_back(spec); } } static webrtc::AudioCodecInfo QueryAudioEncoder(const Config& config) { return webrtc::AudioEncoderL16::QueryAudioEncoder(config); } static std::unique_ptr MakeAudioEncoder( const Config& config, int payload_type, absl::optional codec_pair_id = absl::nullopt) { return webrtc::AudioEncoderL16::MakeAudioEncoder(config, payload_type, codec_pair_id); } }; struct AudioDecoderUnicornSparklesRainbow { using Config = webrtc::AudioDecoderL16::Config; static absl::optional SdpToConfig(webrtc::SdpAudioFormat format) { if (STR_CASE_CMP(format.name.c_str(), "UnicornSparklesRainbow") == 0) { const webrtc::SdpAudioFormat::Parameters expected_params = { {"num_horns", "1"}}; EXPECT_EQ(expected_params, format.parameters); format.parameters.clear(); format.name = "L16"; return webrtc::AudioDecoderL16::SdpToConfig(format); } else { return absl::nullopt; } } static void AppendSupportedDecoders( std::vector* specs) { std::vector new_specs; webrtc::AudioDecoderL16::AppendSupportedDecoders(&new_specs); for (auto& spec : new_specs) { spec.format.name = "UnicornSparklesRainbow"; EXPECT_TRUE(spec.format.parameters.empty()); spec.format.parameters.emplace("num_horns", "1"); specs->push_back(spec); } } static std::unique_ptr MakeAudioDecoder( const Config& config, absl::optional codec_pair_id = absl::nullopt) { return webrtc::AudioDecoderL16::MakeAudioDecoder(config, codec_pair_id); } }; } // namespace TEST_P(PeerConnectionEndToEndTest, Call) { rtc::scoped_refptr real_decoder_factory = webrtc::CreateBuiltinAudioDecoderFactory(); CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), CreateForwardingMockDecoderFactory(real_decoder_factory.get())); GetAndAddUserMedia(); Negotiate(); WaitForCallEstablished(); } TEST_P(PeerConnectionEndToEndTest, CallWithLegacySdp) { FakeConstraints pc_constraints; pc_constraints.AddMandatory(MediaConstraintsInterface::kEnableDtlsSrtp, false); CreatePcs(&pc_constraints, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::CreateBuiltinAudioDecoderFactory()); GetAndAddUserMedia(); Negotiate(); WaitForCallEstablished(); } TEST_P(PeerConnectionEndToEndTest, CallWithCustomCodec) { class IdLoggingAudioEncoderFactory : public webrtc::AudioEncoderFactory { public: IdLoggingAudioEncoderFactory( rtc::scoped_refptr real_factory, std::vector* const codec_ids) : fact_(real_factory), codec_ids_(codec_ids) {} std::vector GetSupportedEncoders() override { return fact_->GetSupportedEncoders(); } absl::optional QueryAudioEncoder( const webrtc::SdpAudioFormat& format) override { return fact_->QueryAudioEncoder(format); } std::unique_ptr MakeAudioEncoder( int payload_type, const webrtc::SdpAudioFormat& format, absl::optional codec_pair_id) override { EXPECT_TRUE(codec_pair_id.has_value()); codec_ids_->push_back(*codec_pair_id); return fact_->MakeAudioEncoder(payload_type, format, codec_pair_id); } private: const rtc::scoped_refptr fact_; std::vector* const codec_ids_; }; class IdLoggingAudioDecoderFactory : public webrtc::AudioDecoderFactory { public: IdLoggingAudioDecoderFactory( rtc::scoped_refptr real_factory, std::vector* const codec_ids) : fact_(real_factory), codec_ids_(codec_ids) {} std::vector GetSupportedDecoders() override { return fact_->GetSupportedDecoders(); } bool IsSupportedDecoder(const webrtc::SdpAudioFormat& format) override { return fact_->IsSupportedDecoder(format); } std::unique_ptr MakeAudioDecoder( const webrtc::SdpAudioFormat& format, absl::optional codec_pair_id) override { EXPECT_TRUE(codec_pair_id.has_value()); codec_ids_->push_back(*codec_pair_id); return fact_->MakeAudioDecoder(format, codec_pair_id); } private: const rtc::scoped_refptr fact_; std::vector* const codec_ids_; }; std::vector encoder_id1, encoder_id2, decoder_id1, decoder_id2; CreatePcs(nullptr, rtc::scoped_refptr( new rtc::RefCountedObject( webrtc::CreateAudioEncoderFactory< AudioEncoderUnicornSparklesRainbow>(), &encoder_id1)), rtc::scoped_refptr( new rtc::RefCountedObject( webrtc::CreateAudioDecoderFactory< AudioDecoderUnicornSparklesRainbow>(), &decoder_id1)), rtc::scoped_refptr( new rtc::RefCountedObject( webrtc::CreateAudioEncoderFactory< AudioEncoderUnicornSparklesRainbow>(), &encoder_id2)), rtc::scoped_refptr( new rtc::RefCountedObject( webrtc::CreateAudioDecoderFactory< AudioDecoderUnicornSparklesRainbow>(), &decoder_id2))); GetAndAddUserMedia(); Negotiate(); WaitForCallEstablished(); // Each codec factory has been used to create one codec. The first pair got // the same ID because they were passed to the same PeerConnectionFactory, // and the second pair got the same ID---but these two IDs are not equal, // because each PeerConnectionFactory has its own ID. EXPECT_EQ(1U, encoder_id1.size()); EXPECT_EQ(1U, encoder_id2.size()); EXPECT_EQ(encoder_id1, decoder_id1); EXPECT_EQ(encoder_id2, decoder_id2); EXPECT_NE(encoder_id1, encoder_id2); } #ifdef HAVE_SCTP // Verifies that a DataChannel created before the negotiation can transition to // "OPEN" and transfer data. TEST_P(PeerConnectionEndToEndTest, CreateDataChannelBeforeNegotiate) { CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::MockAudioDecoderFactory::CreateEmptyFactory()); webrtc::DataChannelInit init; rtc::scoped_refptr caller_dc( caller_->CreateDataChannel("data", init)); rtc::scoped_refptr callee_dc( callee_->CreateDataChannel("data", init)); Negotiate(); WaitForConnection(); WaitForDataChannelsToOpen(caller_dc, callee_signaled_data_channels_, 0); WaitForDataChannelsToOpen(callee_dc, caller_signaled_data_channels_, 0); TestDataChannelSendAndReceive(caller_dc, callee_signaled_data_channels_[0]); TestDataChannelSendAndReceive(callee_dc, caller_signaled_data_channels_[0]); CloseDataChannels(caller_dc, callee_signaled_data_channels_, 0); CloseDataChannels(callee_dc, caller_signaled_data_channels_, 0); } // Verifies that a DataChannel created after the negotiation can transition to // "OPEN" and transfer data. TEST_P(PeerConnectionEndToEndTest, CreateDataChannelAfterNegotiate) { CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::MockAudioDecoderFactory::CreateEmptyFactory()); webrtc::DataChannelInit init; // This DataChannel is for creating the data content in the negotiation. rtc::scoped_refptr dummy( caller_->CreateDataChannel("data", init)); Negotiate(); WaitForConnection(); // Wait for the data channel created pre-negotiation to be opened. WaitForDataChannelsToOpen(dummy, callee_signaled_data_channels_, 0); // Create new DataChannels after the negotiation and verify their states. rtc::scoped_refptr caller_dc( caller_->CreateDataChannel("hello", init)); rtc::scoped_refptr callee_dc( callee_->CreateDataChannel("hello", init)); WaitForDataChannelsToOpen(caller_dc, callee_signaled_data_channels_, 1); WaitForDataChannelsToOpen(callee_dc, caller_signaled_data_channels_, 0); TestDataChannelSendAndReceive(caller_dc, callee_signaled_data_channels_[1]); TestDataChannelSendAndReceive(callee_dc, caller_signaled_data_channels_[0]); CloseDataChannels(caller_dc, callee_signaled_data_channels_, 1); CloseDataChannels(callee_dc, caller_signaled_data_channels_, 0); } // Verifies that DataChannel IDs are even/odd based on the DTLS roles. TEST_P(PeerConnectionEndToEndTest, DataChannelIdAssignment) { CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::MockAudioDecoderFactory::CreateEmptyFactory()); webrtc::DataChannelInit init; rtc::scoped_refptr caller_dc_1( caller_->CreateDataChannel("data", init)); rtc::scoped_refptr callee_dc_1( callee_->CreateDataChannel("data", init)); Negotiate(); WaitForConnection(); EXPECT_EQ(1, caller_dc_1->id() % 2); EXPECT_EQ(0, callee_dc_1->id() % 2); rtc::scoped_refptr caller_dc_2( caller_->CreateDataChannel("data", init)); rtc::scoped_refptr callee_dc_2( callee_->CreateDataChannel("data", init)); EXPECT_EQ(1, caller_dc_2->id() % 2); EXPECT_EQ(0, callee_dc_2->id() % 2); } // Verifies that the message is received by the right remote DataChannel when // there are multiple DataChannels. TEST_P(PeerConnectionEndToEndTest, MessageTransferBetweenTwoPairsOfDataChannels) { CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::MockAudioDecoderFactory::CreateEmptyFactory()); webrtc::DataChannelInit init; rtc::scoped_refptr caller_dc_1( caller_->CreateDataChannel("data", init)); rtc::scoped_refptr caller_dc_2( caller_->CreateDataChannel("data", init)); Negotiate(); WaitForConnection(); WaitForDataChannelsToOpen(caller_dc_1, callee_signaled_data_channels_, 0); WaitForDataChannelsToOpen(caller_dc_2, callee_signaled_data_channels_, 1); std::unique_ptr dc_1_observer( new webrtc::MockDataChannelObserver(callee_signaled_data_channels_[0])); std::unique_ptr dc_2_observer( new webrtc::MockDataChannelObserver(callee_signaled_data_channels_[1])); const std::string message_1 = "hello 1"; const std::string message_2 = "hello 2"; caller_dc_1->Send(webrtc::DataBuffer(message_1)); EXPECT_EQ_WAIT(message_1, dc_1_observer->last_message(), kMaxWait); caller_dc_2->Send(webrtc::DataBuffer(message_2)); EXPECT_EQ_WAIT(message_2, dc_2_observer->last_message(), kMaxWait); EXPECT_EQ(1U, dc_1_observer->received_message_count()); EXPECT_EQ(1U, dc_2_observer->received_message_count()); } // Verifies that a DataChannel added from an OPEN message functions after // a channel has been previously closed (webrtc issue 3778). // This previously failed because the new channel re-used the ID of the closed // channel, and the closed channel was incorrectly still assigned to the ID. TEST_P(PeerConnectionEndToEndTest, DataChannelFromOpenWorksAfterPreviousChannelClosed) { CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::MockAudioDecoderFactory::CreateEmptyFactory()); webrtc::DataChannelInit init; rtc::scoped_refptr caller_dc( caller_->CreateDataChannel("data", init)); Negotiate(); WaitForConnection(); WaitForDataChannelsToOpen(caller_dc, callee_signaled_data_channels_, 0); int first_channel_id = caller_dc->id(); // Wait for the local side to say it's closed, but not the remote side. // Previously, the channel on which Close is called reported being closed // prematurely, and this caused issues; see bugs.webrtc.org/4453. caller_dc->Close(); EXPECT_EQ_WAIT(DataChannelInterface::kClosed, caller_dc->state(), kMaxWait); // Create a new channel and ensure it works after closing the previous one. caller_dc = caller_->CreateDataChannel("data2", init); WaitForDataChannelsToOpen(caller_dc, callee_signaled_data_channels_, 1); // Since the second channel was created after the first finished closing, it // should be able to re-use the first one's ID. EXPECT_EQ(first_channel_id, caller_dc->id()); TestDataChannelSendAndReceive(caller_dc, callee_signaled_data_channels_[1]); CloseDataChannels(caller_dc, callee_signaled_data_channels_, 1); } // Similar to the above test, but don't wait for the first channel to finish // closing before creating the second one. TEST_P(PeerConnectionEndToEndTest, DataChannelFromOpenWorksWhilePreviousChannelClosing) { CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::MockAudioDecoderFactory::CreateEmptyFactory()); webrtc::DataChannelInit init; rtc::scoped_refptr caller_dc( caller_->CreateDataChannel("data", init)); Negotiate(); WaitForConnection(); WaitForDataChannelsToOpen(caller_dc, callee_signaled_data_channels_, 0); int first_channel_id = caller_dc->id(); caller_dc->Close(); // Immediately create a new channel, before waiting for the previous one to // transition to "closed". caller_dc = caller_->CreateDataChannel("data2", init); WaitForDataChannelsToOpen(caller_dc, callee_signaled_data_channels_, 1); // Since the second channel was created while the first was still closing, // it should have been assigned a different ID. EXPECT_NE(first_channel_id, caller_dc->id()); TestDataChannelSendAndReceive(caller_dc, callee_signaled_data_channels_[1]); CloseDataChannels(caller_dc, callee_signaled_data_channels_, 1); } // This tests that if a data channel is closed remotely while not referenced // by the application (meaning only the PeerConnection contributes to its // reference count), no memory access violation will occur. // See: https://code.google.com/p/chromium/issues/detail?id=565048 TEST_P(PeerConnectionEndToEndTest, CloseDataChannelRemotelyWhileNotReferenced) { CreatePcs(nullptr, webrtc::CreateBuiltinAudioEncoderFactory(), webrtc::MockAudioDecoderFactory::CreateEmptyFactory()); webrtc::DataChannelInit init; rtc::scoped_refptr caller_dc( caller_->CreateDataChannel("data", init)); Negotiate(); WaitForConnection(); WaitForDataChannelsToOpen(caller_dc, callee_signaled_data_channels_, 0); // This removes the reference to the remote data channel that we hold. callee_signaled_data_channels_.clear(); caller_dc->Close(); EXPECT_EQ_WAIT(DataChannelInterface::kClosed, caller_dc->state(), kMaxWait); // Wait for a bit longer so the remote data channel will receive the // close message and be destroyed. rtc::Thread::Current()->ProcessMessages(100); } #endif // HAVE_SCTP INSTANTIATE_TEST_CASE_P(PeerConnectionEndToEndTest, PeerConnectionEndToEndTest, Values(SdpSemantics::kPlanB, SdpSemantics::kUnifiedPlan));