/* * 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 "pc/peer_connection_factory.h" #include #include #include #include #include "api/audio/audio_mixer.h" #include "api/audio_codecs/builtin_audio_decoder_factory.h" #include "api/audio_codecs/builtin_audio_encoder_factory.h" #include "api/create_peerconnection_factory.h" #include "api/data_channel_interface.h" #include "api/enable_media.h" #include "api/environment/environment_factory.h" #include "api/jsep.h" #include "api/media_stream_interface.h" #include "api/task_queue/default_task_queue_factory.h" #include "api/test/mock_packet_socket_factory.h" #include "api/video_codecs/video_decoder_factory_template.h" #include "api/video_codecs/video_decoder_factory_template_dav1d_adapter.h" #include "api/video_codecs/video_decoder_factory_template_libvpx_vp8_adapter.h" #include "api/video_codecs/video_decoder_factory_template_libvpx_vp9_adapter.h" #include "api/video_codecs/video_decoder_factory_template_open_h264_adapter.h" #include "api/video_codecs/video_encoder_factory_template.h" #include "api/video_codecs/video_encoder_factory_template_libaom_av1_adapter.h" #include "api/video_codecs/video_encoder_factory_template_libvpx_vp8_adapter.h" #include "api/video_codecs/video_encoder_factory_template_libvpx_vp9_adapter.h" #include "api/video_codecs/video_encoder_factory_template_open_h264_adapter.h" #include "media/base/fake_frame_source.h" #include "modules/audio_device/include/audio_device.h" #include "modules/audio_processing/include/audio_processing.h" #include "p2p/base/fake_port_allocator.h" #include "p2p/base/port.h" #include "p2p/base/port_allocator.h" #include "p2p/base/port_interface.h" #include "pc/test/fake_audio_capture_module.h" #include "pc/test/fake_video_track_source.h" #include "pc/test/mock_peer_connection_observers.h" #include "rtc_base/gunit.h" #include "rtc_base/internal/default_socket_server.h" #include "rtc_base/rtc_certificate_generator.h" #include "rtc_base/socket_address.h" #include "rtc_base/time_utils.h" #include "test/gmock.h" #include "test/gtest.h" #include "test/scoped_key_value_config.h" #ifdef WEBRTC_ANDROID #include "pc/test/android_test_initializer.h" #endif #include "pc/test/fake_rtc_certificate_generator.h" #include "pc/test/fake_video_track_renderer.h" namespace webrtc { namespace { using ::testing::_; using ::testing::AtLeast; using ::testing::InvokeWithoutArgs; using ::testing::NiceMock; using ::testing::Return; using ::testing::UnorderedElementsAre; static const char kStunIceServer[] = "stun:stun.l.google.com:19302"; static const char kTurnIceServer[] = "turn:test.com:1234"; static const char kTurnIceServerWithTransport[] = "turn:hello.com?transport=tcp"; static const char kSecureTurnIceServer[] = "turns:hello.com?transport=tcp"; static const char kSecureTurnIceServerWithoutTransportParam[] = "turns:hello.com:443"; static const char kSecureTurnIceServerWithoutTransportAndPortParam[] = "turns:hello.com"; static const char kTurnIceServerWithNoUsernameInUri[] = "turn:test.com:1234"; static const char kTurnPassword[] = "turnpassword"; static const int kDefaultStunPort = 3478; static const int kDefaultStunTlsPort = 5349; static const char kTurnUsername[] = "test"; static const char kStunIceServerWithIPv4Address[] = "stun:1.2.3.4:1234"; static const char kStunIceServerWithIPv4AddressWithoutPort[] = "stun:1.2.3.4"; static const char kStunIceServerWithIPv6Address[] = "stun:[2401:fa00:4::]:1234"; static const char kStunIceServerWithIPv6AddressWithoutPort[] = "stun:[2401:fa00:4::]"; static const char kTurnIceServerWithIPv6Address[] = "turn:[2401:fa00:4::]:1234"; class NullPeerConnectionObserver : public PeerConnectionObserver { public: virtual ~NullPeerConnectionObserver() = default; void OnSignalingChange( PeerConnectionInterface::SignalingState new_state) override {} void OnAddStream(rtc::scoped_refptr stream) override {} void OnRemoveStream( rtc::scoped_refptr stream) override {} void OnDataChannel( rtc::scoped_refptr data_channel) override {} void OnRenegotiationNeeded() override {} void OnIceConnectionChange( PeerConnectionInterface::IceConnectionState new_state) override {} void OnIceGatheringChange( PeerConnectionInterface::IceGatheringState new_state) override {} void OnIceCandidate(const IceCandidateInterface* candidate) override {} }; class MockNetworkManager : public rtc::NetworkManager { public: MOCK_METHOD(void, StartUpdating, (), (override)); MOCK_METHOD(void, StopUpdating, (), (override)); MOCK_METHOD(std::vector, GetNetworks, (), (const override)); MOCK_METHOD(std::vector, GetAnyAddressNetworks, (), (override)); }; class PeerConnectionFactoryTest : public ::testing::Test { public: PeerConnectionFactoryTest() : socket_server_(rtc::CreateDefaultSocketServer()), main_thread_(socket_server_.get()) {} private: void SetUp() { #ifdef WEBRTC_ANDROID InitializeAndroidObjects(); #endif // Use fake audio device module since we're only testing the interface // level, and using a real one could make tests flaky e.g. when run in // parallel. factory_ = CreatePeerConnectionFactory( rtc::Thread::Current(), rtc::Thread::Current(), rtc::Thread::Current(), rtc::scoped_refptr(FakeAudioCaptureModule::Create()), CreateBuiltinAudioEncoderFactory(), CreateBuiltinAudioDecoderFactory(), std::make_unique>(), std::make_unique>(), nullptr /* audio_mixer */, nullptr /* audio_processing */); ASSERT_TRUE(factory_.get() != NULL); packet_socket_factory_.reset( new rtc::BasicPacketSocketFactory(socket_server_.get())); port_allocator_.reset(new cricket::FakePortAllocator( rtc::Thread::Current(), packet_socket_factory_.get(), &field_trials_)); raw_port_allocator_ = port_allocator_.get(); } protected: void VerifyStunServers(cricket::ServerAddresses stun_servers) { EXPECT_EQ(stun_servers, raw_port_allocator_->stun_servers()); } void VerifyTurnServers(std::vector turn_servers) { EXPECT_EQ(turn_servers.size(), raw_port_allocator_->turn_servers().size()); for (size_t i = 0; i < turn_servers.size(); ++i) { ASSERT_EQ(1u, turn_servers[i].ports.size()); EXPECT_EQ(1u, raw_port_allocator_->turn_servers()[i].ports.size()); EXPECT_EQ( turn_servers[i].ports[0].address.ToString(), raw_port_allocator_->turn_servers()[i].ports[0].address.ToString()); EXPECT_EQ(turn_servers[i].ports[0].proto, raw_port_allocator_->turn_servers()[i].ports[0].proto); EXPECT_EQ(turn_servers[i].credentials.username, raw_port_allocator_->turn_servers()[i].credentials.username); EXPECT_EQ(turn_servers[i].credentials.password, raw_port_allocator_->turn_servers()[i].credentials.password); } } void VerifyAudioCodecCapability(const RtpCodecCapability& codec) { EXPECT_EQ(codec.kind, cricket::MEDIA_TYPE_AUDIO); EXPECT_FALSE(codec.name.empty()); EXPECT_GT(codec.clock_rate, 0); EXPECT_GT(codec.num_channels, 0); } void VerifyVideoCodecCapability(const RtpCodecCapability& codec, bool sender) { EXPECT_EQ(codec.kind, cricket::MEDIA_TYPE_VIDEO); EXPECT_FALSE(codec.name.empty()); EXPECT_GT(codec.clock_rate, 0); if (sender) { if (codec.name == "VP8" || codec.name == "H264") { EXPECT_THAT( codec.scalability_modes, UnorderedElementsAre(ScalabilityMode::kL1T1, ScalabilityMode::kL1T2, ScalabilityMode::kL1T3)) << "Codec: " << codec.name; } else if (codec.name == "VP9" || codec.name == "AV1") { EXPECT_THAT( codec.scalability_modes, UnorderedElementsAre( // clang-format off ScalabilityMode::kL1T1, ScalabilityMode::kL1T2, ScalabilityMode::kL1T3, ScalabilityMode::kL2T1, ScalabilityMode::kL2T1h, ScalabilityMode::kL2T1_KEY, ScalabilityMode::kL2T2, ScalabilityMode::kL2T2h, ScalabilityMode::kL2T2_KEY, ScalabilityMode::kL2T2_KEY_SHIFT, ScalabilityMode::kL2T3, ScalabilityMode::kL2T3h, ScalabilityMode::kL2T3_KEY, ScalabilityMode::kL3T1, ScalabilityMode::kL3T1h, ScalabilityMode::kL3T1_KEY, ScalabilityMode::kL3T2, ScalabilityMode::kL3T2h, ScalabilityMode::kL3T2_KEY, ScalabilityMode::kL3T3, ScalabilityMode::kL3T3h, ScalabilityMode::kL3T3_KEY, ScalabilityMode::kS2T1, ScalabilityMode::kS2T1h, ScalabilityMode::kS2T2, ScalabilityMode::kS2T2h, ScalabilityMode::kS2T3, ScalabilityMode::kS2T3h, ScalabilityMode::kS3T1, ScalabilityMode::kS3T1h, ScalabilityMode::kS3T2, ScalabilityMode::kS3T2h, ScalabilityMode::kS3T3, ScalabilityMode::kS3T3h) // clang-format on ) << "Codec: " << codec.name; } else { EXPECT_TRUE(codec.scalability_modes.empty()); } } else { EXPECT_TRUE(codec.scalability_modes.empty()); } } test::ScopedKeyValueConfig field_trials_; std::unique_ptr socket_server_; rtc::AutoSocketServerThread main_thread_; rtc::scoped_refptr factory_; NullPeerConnectionObserver observer_; std::unique_ptr packet_socket_factory_; std::unique_ptr port_allocator_; // Since the PC owns the port allocator after it's been initialized, // this should only be used when known to be safe. cricket::FakePortAllocator* raw_port_allocator_; }; // Since there is no public PeerConnectionFactory API to control RTX usage, need // to reconstruct factory with our own ConnectionContext. rtc::scoped_refptr CreatePeerConnectionFactoryWithRtxDisabled() { PeerConnectionFactoryDependencies pcf_dependencies; pcf_dependencies.signaling_thread = rtc::Thread::Current(); pcf_dependencies.worker_thread = rtc::Thread::Current(); pcf_dependencies.network_thread = rtc::Thread::Current(); pcf_dependencies.task_queue_factory = CreateDefaultTaskQueueFactory(); pcf_dependencies.adm = FakeAudioCaptureModule::Create(); pcf_dependencies.audio_encoder_factory = CreateBuiltinAudioEncoderFactory(); pcf_dependencies.audio_decoder_factory = CreateBuiltinAudioDecoderFactory(); pcf_dependencies.video_encoder_factory = std::make_unique>(); pcf_dependencies.video_decoder_factory = std::make_unique>(), EnableMedia(pcf_dependencies); rtc::scoped_refptr context = ConnectionContext::Create(CreateEnvironment(), &pcf_dependencies); context->set_use_rtx(false); return rtc::make_ref_counted(context, &pcf_dependencies); } // Verify creation of PeerConnection using internal ADM, video factory and // internal libjingle threads. // TODO(henrika): disabling this test since relying on real audio can result in // flaky tests and focus on details that are out of scope for you might expect // for a PeerConnectionFactory unit test. // See https://bugs.chromium.org/p/webrtc/issues/detail?id=7806 for details. TEST(PeerConnectionFactoryTestInternal, DISABLED_CreatePCUsingInternalModules) { #ifdef WEBRTC_ANDROID InitializeAndroidObjects(); #endif rtc::scoped_refptr factory( CreatePeerConnectionFactory( nullptr /* network_thread */, nullptr /* worker_thread */, nullptr /* signaling_thread */, nullptr /* default_adm */, CreateBuiltinAudioEncoderFactory(), CreateBuiltinAudioDecoderFactory(), nullptr /* video_encoder_factory */, nullptr /* video_decoder_factory */, nullptr /* audio_mixer */, nullptr /* audio_processing */)); NullPeerConnectionObserver observer; PeerConnectionInterface::RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; std::unique_ptr cert_generator( new FakeRTCCertificateGenerator()); PeerConnectionDependencies pc_dependencies(&observer); pc_dependencies.cert_generator = std::move(cert_generator); auto result = factory->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); EXPECT_TRUE(result.ok()); } TEST_F(PeerConnectionFactoryTest, CheckRtpSenderAudioCapabilities) { RtpCapabilities audio_capabilities = factory_->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_AUDIO); EXPECT_FALSE(audio_capabilities.codecs.empty()); for (const auto& codec : audio_capabilities.codecs) { VerifyAudioCodecCapability(codec); } EXPECT_FALSE(audio_capabilities.header_extensions.empty()); for (const auto& header_extension : audio_capabilities.header_extensions) { EXPECT_FALSE(header_extension.uri.empty()); } } TEST_F(PeerConnectionFactoryTest, CheckRtpSenderVideoCapabilities) { RtpCapabilities video_capabilities = factory_->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_VIDEO); EXPECT_FALSE(video_capabilities.codecs.empty()); for (const auto& codec : video_capabilities.codecs) { VerifyVideoCodecCapability(codec, true); } EXPECT_FALSE(video_capabilities.header_extensions.empty()); for (const auto& header_extension : video_capabilities.header_extensions) { EXPECT_FALSE(header_extension.uri.empty()); } } TEST_F(PeerConnectionFactoryTest, CheckRtpSenderRtxEnabledCapabilities) { RtpCapabilities video_capabilities = factory_->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_VIDEO); const auto it = std::find_if( video_capabilities.codecs.begin(), video_capabilities.codecs.end(), [](const auto& c) { return c.name == cricket::kRtxCodecName; }); EXPECT_TRUE(it != video_capabilities.codecs.end()); } TEST(PeerConnectionFactoryTestInternal, CheckRtpSenderRtxDisabledCapabilities) { auto factory = CreatePeerConnectionFactoryWithRtxDisabled(); RtpCapabilities video_capabilities = factory->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_VIDEO); const auto it = std::find_if( video_capabilities.codecs.begin(), video_capabilities.codecs.end(), [](const auto& c) { return c.name == cricket::kRtxCodecName; }); EXPECT_TRUE(it == video_capabilities.codecs.end()); } TEST_F(PeerConnectionFactoryTest, CheckRtpSenderDataCapabilities) { RtpCapabilities data_capabilities = factory_->GetRtpSenderCapabilities(cricket::MEDIA_TYPE_DATA); EXPECT_TRUE(data_capabilities.codecs.empty()); EXPECT_TRUE(data_capabilities.header_extensions.empty()); } TEST_F(PeerConnectionFactoryTest, CheckRtpReceiverAudioCapabilities) { RtpCapabilities audio_capabilities = factory_->GetRtpReceiverCapabilities(cricket::MEDIA_TYPE_AUDIO); EXPECT_FALSE(audio_capabilities.codecs.empty()); for (const auto& codec : audio_capabilities.codecs) { VerifyAudioCodecCapability(codec); } EXPECT_FALSE(audio_capabilities.header_extensions.empty()); for (const auto& header_extension : audio_capabilities.header_extensions) { EXPECT_FALSE(header_extension.uri.empty()); } } TEST_F(PeerConnectionFactoryTest, CheckRtpReceiverVideoCapabilities) { RtpCapabilities video_capabilities = factory_->GetRtpReceiverCapabilities(cricket::MEDIA_TYPE_VIDEO); EXPECT_FALSE(video_capabilities.codecs.empty()); for (const auto& codec : video_capabilities.codecs) { VerifyVideoCodecCapability(codec, false); } EXPECT_FALSE(video_capabilities.header_extensions.empty()); for (const auto& header_extension : video_capabilities.header_extensions) { EXPECT_FALSE(header_extension.uri.empty()); } } TEST_F(PeerConnectionFactoryTest, CheckRtpReceiverRtxEnabledCapabilities) { RtpCapabilities video_capabilities = factory_->GetRtpReceiverCapabilities(cricket::MEDIA_TYPE_VIDEO); const auto it = std::find_if( video_capabilities.codecs.begin(), video_capabilities.codecs.end(), [](const auto& c) { return c.name == cricket::kRtxCodecName; }); EXPECT_TRUE(it != video_capabilities.codecs.end()); } TEST(PeerConnectionFactoryTestInternal, CheckRtpReceiverRtxDisabledCapabilities) { auto factory = CreatePeerConnectionFactoryWithRtxDisabled(); RtpCapabilities video_capabilities = factory->GetRtpReceiverCapabilities(cricket::MEDIA_TYPE_VIDEO); const auto it = std::find_if( video_capabilities.codecs.begin(), video_capabilities.codecs.end(), [](const auto& c) { return c.name == cricket::kRtxCodecName; }); EXPECT_TRUE(it == video_capabilities.codecs.end()); } TEST_F(PeerConnectionFactoryTest, CheckRtpReceiverDataCapabilities) { RtpCapabilities data_capabilities = factory_->GetRtpReceiverCapabilities(cricket::MEDIA_TYPE_DATA); EXPECT_TRUE(data_capabilities.codecs.empty()); EXPECT_TRUE(data_capabilities.header_extensions.empty()); } // This test verifies creation of PeerConnection with valid STUN and TURN // configuration. Also verifies the URL's parsed correctly as expected. TEST_F(PeerConnectionFactoryTest, CreatePCUsingIceServers) { PeerConnectionInterface::RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; PeerConnectionInterface::IceServer ice_server; ice_server.uri = kStunIceServer; config.servers.push_back(ice_server); ice_server.uri = kTurnIceServer; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); ice_server.uri = kTurnIceServerWithTransport; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); PeerConnectionDependencies pc_dependencies(&observer_); pc_dependencies.cert_generator = std::make_unique(); pc_dependencies.allocator = std::move(port_allocator_); auto result = factory_->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); ASSERT_TRUE(result.ok()); cricket::ServerAddresses stun_servers; rtc::SocketAddress stun1("stun.l.google.com", 19302); stun_servers.insert(stun1); VerifyStunServers(stun_servers); std::vector turn_servers; cricket::RelayServerConfig turn1("test.com", 1234, kTurnUsername, kTurnPassword, cricket::PROTO_UDP); turn_servers.push_back(turn1); cricket::RelayServerConfig turn2("hello.com", kDefaultStunPort, kTurnUsername, kTurnPassword, cricket::PROTO_TCP); turn_servers.push_back(turn2); VerifyTurnServers(turn_servers); } // This test verifies creation of PeerConnection with valid STUN and TURN // configuration. Also verifies the list of URL's parsed correctly as expected. TEST_F(PeerConnectionFactoryTest, CreatePCUsingIceServersUrls) { PeerConnectionInterface::RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; PeerConnectionInterface::IceServer ice_server; ice_server.urls.push_back(kStunIceServer); ice_server.urls.push_back(kTurnIceServer); ice_server.urls.push_back(kTurnIceServerWithTransport); ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); PeerConnectionDependencies pc_dependencies(&observer_); pc_dependencies.cert_generator = std::make_unique(); pc_dependencies.allocator = std::move(port_allocator_); auto result = factory_->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); ASSERT_TRUE(result.ok()); cricket::ServerAddresses stun_servers; rtc::SocketAddress stun1("stun.l.google.com", 19302); stun_servers.insert(stun1); VerifyStunServers(stun_servers); std::vector turn_servers; cricket::RelayServerConfig turn1("test.com", 1234, kTurnUsername, kTurnPassword, cricket::PROTO_UDP); turn_servers.push_back(turn1); cricket::RelayServerConfig turn2("hello.com", kDefaultStunPort, kTurnUsername, kTurnPassword, cricket::PROTO_TCP); turn_servers.push_back(turn2); VerifyTurnServers(turn_servers); } TEST_F(PeerConnectionFactoryTest, CreatePCUsingNoUsernameInUri) { PeerConnectionInterface::RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; PeerConnectionInterface::IceServer ice_server; ice_server.uri = kStunIceServer; config.servers.push_back(ice_server); ice_server.uri = kTurnIceServerWithNoUsernameInUri; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); PeerConnectionDependencies pc_dependencies(&observer_); pc_dependencies.cert_generator = std::make_unique(); pc_dependencies.allocator = std::move(port_allocator_); auto result = factory_->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); ASSERT_TRUE(result.ok()); std::vector turn_servers; cricket::RelayServerConfig turn("test.com", 1234, kTurnUsername, kTurnPassword, cricket::PROTO_UDP); turn_servers.push_back(turn); VerifyTurnServers(turn_servers); } // This test verifies the PeerConnection created properly with TURN url which // has transport parameter in it. TEST_F(PeerConnectionFactoryTest, CreatePCUsingTurnUrlWithTransportParam) { PeerConnectionInterface::RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; PeerConnectionInterface::IceServer ice_server; ice_server.uri = kTurnIceServerWithTransport; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); PeerConnectionDependencies pc_dependencies(&observer_); pc_dependencies.cert_generator = std::make_unique(); pc_dependencies.allocator = std::move(port_allocator_); auto result = factory_->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); ASSERT_TRUE(result.ok()); std::vector turn_servers; cricket::RelayServerConfig turn("hello.com", kDefaultStunPort, kTurnUsername, kTurnPassword, cricket::PROTO_TCP); turn_servers.push_back(turn); VerifyTurnServers(turn_servers); } TEST_F(PeerConnectionFactoryTest, CreatePCUsingSecureTurnUrl) { PeerConnectionInterface::RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; PeerConnectionInterface::IceServer ice_server; ice_server.uri = kSecureTurnIceServer; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); ice_server.uri = kSecureTurnIceServerWithoutTransportParam; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); ice_server.uri = kSecureTurnIceServerWithoutTransportAndPortParam; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); PeerConnectionDependencies pc_dependencies(&observer_); pc_dependencies.cert_generator = std::make_unique(); pc_dependencies.allocator = std::move(port_allocator_); auto result = factory_->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); ASSERT_TRUE(result.ok()); std::vector turn_servers; cricket::RelayServerConfig turn1("hello.com", kDefaultStunTlsPort, kTurnUsername, kTurnPassword, cricket::PROTO_TLS); turn_servers.push_back(turn1); // TURNS with transport param should be default to tcp. cricket::RelayServerConfig turn2("hello.com", 443, kTurnUsername, kTurnPassword, cricket::PROTO_TLS); turn_servers.push_back(turn2); cricket::RelayServerConfig turn3("hello.com", kDefaultStunTlsPort, kTurnUsername, kTurnPassword, cricket::PROTO_TLS); turn_servers.push_back(turn3); VerifyTurnServers(turn_servers); } TEST_F(PeerConnectionFactoryTest, CreatePCUsingIPLiteralAddress) { PeerConnectionInterface::RTCConfiguration config; config.sdp_semantics = SdpSemantics::kUnifiedPlan; PeerConnectionInterface::IceServer ice_server; ice_server.uri = kStunIceServerWithIPv4Address; config.servers.push_back(ice_server); ice_server.uri = kStunIceServerWithIPv4AddressWithoutPort; config.servers.push_back(ice_server); ice_server.uri = kStunIceServerWithIPv6Address; config.servers.push_back(ice_server); ice_server.uri = kStunIceServerWithIPv6AddressWithoutPort; config.servers.push_back(ice_server); ice_server.uri = kTurnIceServerWithIPv6Address; ice_server.username = kTurnUsername; ice_server.password = kTurnPassword; config.servers.push_back(ice_server); PeerConnectionDependencies pc_dependencies(&observer_); pc_dependencies.cert_generator = std::make_unique(); pc_dependencies.allocator = std::move(port_allocator_); auto result = factory_->CreatePeerConnectionOrError(config, std::move(pc_dependencies)); ASSERT_TRUE(result.ok()); cricket::ServerAddresses stun_servers; rtc::SocketAddress stun1("1.2.3.4", 1234); stun_servers.insert(stun1); rtc::SocketAddress stun2("1.2.3.4", 3478); stun_servers.insert(stun2); // Default port rtc::SocketAddress stun3("2401:fa00:4::", 1234); stun_servers.insert(stun3); rtc::SocketAddress stun4("2401:fa00:4::", 3478); stun_servers.insert(stun4); // Default port VerifyStunServers(stun_servers); std::vector turn_servers; cricket::RelayServerConfig turn1("2401:fa00:4::", 1234, kTurnUsername, kTurnPassword, cricket::PROTO_UDP); turn_servers.push_back(turn1); VerifyTurnServers(turn_servers); } // This test verifies the captured stream is rendered locally using a // local video track. TEST_F(PeerConnectionFactoryTest, LocalRendering) { rtc::scoped_refptr source = FakeVideoTrackSource::Create(/*is_screencast=*/false); cricket::FakeFrameSource frame_source(1280, 720, rtc::kNumMicrosecsPerSec / 30); ASSERT_TRUE(source.get() != NULL); rtc::scoped_refptr track( factory_->CreateVideoTrack(source, "testlabel")); ASSERT_TRUE(track.get() != NULL); FakeVideoTrackRenderer local_renderer(track.get()); EXPECT_EQ(0, local_renderer.num_rendered_frames()); source->InjectFrame(frame_source.GetFrame()); EXPECT_EQ(1, local_renderer.num_rendered_frames()); EXPECT_FALSE(local_renderer.black_frame()); track->set_enabled(false); source->InjectFrame(frame_source.GetFrame()); EXPECT_EQ(2, local_renderer.num_rendered_frames()); EXPECT_TRUE(local_renderer.black_frame()); track->set_enabled(true); source->InjectFrame(frame_source.GetFrame()); EXPECT_EQ(3, local_renderer.num_rendered_frames()); EXPECT_FALSE(local_renderer.black_frame()); } TEST(PeerConnectionFactoryDependenciesTest, UsesNetworkManager) { constexpr TimeDelta kWaitTimeout = TimeDelta::Seconds(10); auto mock_network_manager = std::make_unique>(); rtc::Event called; EXPECT_CALL(*mock_network_manager, StartUpdating()) .Times(AtLeast(1)) .WillRepeatedly(InvokeWithoutArgs([&] { called.Set(); })); PeerConnectionFactoryDependencies pcf_dependencies; pcf_dependencies.network_manager = std::move(mock_network_manager); rtc::scoped_refptr pcf = CreateModularPeerConnectionFactory(std::move(pcf_dependencies)); PeerConnectionInterface::RTCConfiguration config; config.ice_candidate_pool_size = 2; NullPeerConnectionObserver observer; auto pc = pcf->CreatePeerConnectionOrError( config, PeerConnectionDependencies(&observer)); ASSERT_TRUE(pc.ok()); called.Wait(kWaitTimeout); } TEST(PeerConnectionFactoryDependenciesTest, UsesPacketSocketFactory) { constexpr TimeDelta kWaitTimeout = TimeDelta::Seconds(10); auto mock_socket_factory = std::make_unique>(); rtc::Event called; EXPECT_CALL(*mock_socket_factory, CreateUdpSocket(_, _, _)) .WillOnce(InvokeWithoutArgs([&] { called.Set(); return nullptr; })) .WillRepeatedly(Return(nullptr)); PeerConnectionFactoryDependencies pcf_dependencies; pcf_dependencies.packet_socket_factory = std::move(mock_socket_factory); rtc::scoped_refptr pcf = CreateModularPeerConnectionFactory(std::move(pcf_dependencies)); // By default, localhost addresses are ignored, which makes tests fail if test // machine is offline. PeerConnectionFactoryInterface::Options options; options.network_ignore_mask = 0; pcf->SetOptions(options); PeerConnectionInterface::RTCConfiguration config; config.ice_candidate_pool_size = 2; NullPeerConnectionObserver observer; auto pc = pcf->CreatePeerConnectionOrError( config, PeerConnectionDependencies(&observer)); ASSERT_TRUE(pc.ok()); called.Wait(kWaitTimeout); } } // namespace } // namespace webrtc