/* * Copyright (c) 2020 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 "test/pc/e2e/test_peer_factory.h" #include #include "absl/memory/memory.h" #include "absl/strings/string_view.h" #include "api/task_queue/default_task_queue_factory.h" #include "api/test/create_time_controller.h" #include "api/test/pclf/media_configuration.h" #include "api/test/pclf/peer_configurer.h" #include "api/test/time_controller.h" #include "api/transport/field_trial_based_config.h" #include "api/video_codecs/builtin_video_decoder_factory.h" #include "api/video_codecs/builtin_video_encoder_factory.h" #include "media/engine/webrtc_media_engine.h" #include "media/engine/webrtc_media_engine_defaults.h" #include "modules/audio_processing/aec_dump/aec_dump_factory.h" #include "p2p/client/basic_port_allocator.h" #include "rtc_base/thread.h" #include "test/pc/e2e/analyzer/video/quality_analyzing_video_encoder.h" #include "test/pc/e2e/echo/echo_emulation.h" #include "test/testsupport/copy_to_file_audio_capturer.h" namespace webrtc { namespace webrtc_pc_e2e { namespace { using EmulatedSFUConfigMap = ::webrtc::webrtc_pc_e2e::QualityAnalyzingVideoEncoder::EmulatedSFUConfigMap; constexpr int16_t kGeneratedAudioMaxAmplitude = 32000; constexpr int kDefaultSamplingFrequencyInHz = 48000; // Sets mandatory entities in injectable components like `pcf_dependencies` // and `pc_dependencies` if they are omitted. Also setup required // dependencies, that won't be specially provided by factory and will be just // transferred to peer connection creation code. void SetMandatoryEntities(InjectableComponents* components, TimeController& time_controller) { RTC_DCHECK(components->pcf_dependencies); RTC_DCHECK(components->pc_dependencies); // Setup required peer connection factory dependencies. if (components->pcf_dependencies->task_queue_factory == nullptr) { components->pcf_dependencies->task_queue_factory = time_controller.CreateTaskQueueFactory(); } if (components->pcf_dependencies->call_factory == nullptr) { components->pcf_dependencies->call_factory = CreateTimeControllerBasedCallFactory(&time_controller); } if (components->pcf_dependencies->event_log_factory == nullptr) { components->pcf_dependencies->event_log_factory = std::make_unique( components->pcf_dependencies->task_queue_factory.get()); } if (!components->pcf_dependencies->trials) { components->pcf_dependencies->trials = std::make_unique(); } } // Returns mapping from stream label to optional spatial index. // If we have stream label "Foo" and mapping contains // 1. `absl::nullopt` means all simulcast/SVC streams are required // 2. Concrete value means that particular simulcast/SVC stream have to be // analyzed. EmulatedSFUConfigMap CalculateRequiredSpatialIndexPerStream( const std::vector& video_configs) { EmulatedSFUConfigMap result; for (auto& video_config : video_configs) { // Stream label should be set by fixture implementation here. RTC_DCHECK(video_config.stream_label); bool res = result .insert({*video_config.stream_label, video_config.emulated_sfu_config}) .second; RTC_DCHECK(res) << "Duplicate video_config.stream_label=" << *video_config.stream_label; } return result; } std::unique_ptr CreateAudioRenderer( const absl::optional& config) { if (!config) { // Return default renderer because we always require some renderer. return TestAudioDeviceModule::CreateDiscardRenderer( kDefaultSamplingFrequencyInHz); } if (config->output_file_name) { return TestAudioDeviceModule::CreateBoundedWavFileWriter( config->output_file_name.value(), config->sampling_frequency_in_hz); } return TestAudioDeviceModule::CreateDiscardRenderer( config->sampling_frequency_in_hz); } std::unique_ptr CreateAudioCapturer( const absl::optional& audio_config) { if (!audio_config) { // If we have no audio config we still need to provide some audio device. // In such case use generated capturer. Despite of we provided audio here, // in test media setup audio stream won't be added into peer connection. return TestAudioDeviceModule::CreatePulsedNoiseCapturer( kGeneratedAudioMaxAmplitude, kDefaultSamplingFrequencyInHz); } switch (audio_config->mode) { case AudioConfig::Mode::kGenerated: return TestAudioDeviceModule::CreatePulsedNoiseCapturer( kGeneratedAudioMaxAmplitude, audio_config->sampling_frequency_in_hz); case AudioConfig::Mode::kFile: RTC_DCHECK(audio_config->input_file_name); return TestAudioDeviceModule::CreateWavFileReader( audio_config->input_file_name.value(), /*repeat=*/true); } } rtc::scoped_refptr CreateAudioDeviceModule( absl::optional audio_config, absl::optional remote_audio_config, absl::optional echo_emulation_config, TaskQueueFactory* task_queue_factory) { std::unique_ptr renderer = CreateAudioRenderer(remote_audio_config); std::unique_ptr capturer = CreateAudioCapturer(audio_config); RTC_DCHECK(renderer); RTC_DCHECK(capturer); // Setup echo emulation if required. if (echo_emulation_config) { capturer = std::make_unique(std::move(capturer), *echo_emulation_config); renderer = std::make_unique( std::move(renderer), static_cast(capturer.get())); } // Setup input stream dumping if required. if (audio_config && audio_config->input_dump_file_name) { capturer = std::make_unique( std::move(capturer), audio_config->input_dump_file_name.value()); } return TestAudioDeviceModule::Create(task_queue_factory, std::move(capturer), std::move(renderer), /*speed=*/1.f); } std::unique_ptr CreateMediaEngine( PeerConnectionFactoryComponents* pcf_dependencies, rtc::scoped_refptr audio_device_module) { cricket::MediaEngineDependencies media_deps; media_deps.task_queue_factory = pcf_dependencies->task_queue_factory.get(); media_deps.adm = audio_device_module; media_deps.audio_processing = pcf_dependencies->audio_processing; media_deps.audio_mixer = pcf_dependencies->audio_mixer; media_deps.video_encoder_factory = std::move(pcf_dependencies->video_encoder_factory); media_deps.video_decoder_factory = std::move(pcf_dependencies->video_decoder_factory); webrtc::SetMediaEngineDefaults(&media_deps); RTC_DCHECK(pcf_dependencies->trials); media_deps.trials = pcf_dependencies->trials.get(); return cricket::CreateMediaEngine(std::move(media_deps)); } void WrapVideoEncoderFactory( absl::string_view peer_name, double bitrate_multiplier, EmulatedSFUConfigMap stream_to_sfu_config, PeerConnectionFactoryComponents* pcf_dependencies, VideoQualityAnalyzerInjectionHelper* video_analyzer_helper) { std::unique_ptr video_encoder_factory; if (pcf_dependencies->video_encoder_factory != nullptr) { video_encoder_factory = std::move(pcf_dependencies->video_encoder_factory); } else { video_encoder_factory = CreateBuiltinVideoEncoderFactory(); } pcf_dependencies->video_encoder_factory = video_analyzer_helper->WrapVideoEncoderFactory( peer_name, std::move(video_encoder_factory), bitrate_multiplier, std::move(stream_to_sfu_config)); } void WrapVideoDecoderFactory( absl::string_view peer_name, PeerConnectionFactoryComponents* pcf_dependencies, VideoQualityAnalyzerInjectionHelper* video_analyzer_helper) { std::unique_ptr video_decoder_factory; if (pcf_dependencies->video_decoder_factory != nullptr) { video_decoder_factory = std::move(pcf_dependencies->video_decoder_factory); } else { video_decoder_factory = CreateBuiltinVideoDecoderFactory(); } pcf_dependencies->video_decoder_factory = video_analyzer_helper->WrapVideoDecoderFactory( peer_name, std::move(video_decoder_factory)); } // Creates PeerConnectionFactoryDependencies objects, providing entities // from InjectableComponents::PeerConnectionFactoryComponents. PeerConnectionFactoryDependencies CreatePCFDependencies( std::unique_ptr pcf_dependencies, std::unique_ptr media_engine, rtc::Thread* signaling_thread, rtc::Thread* worker_thread, rtc::Thread* network_thread) { PeerConnectionFactoryDependencies pcf_deps; pcf_deps.signaling_thread = signaling_thread; pcf_deps.worker_thread = worker_thread; pcf_deps.network_thread = network_thread; pcf_deps.media_engine = std::move(media_engine); pcf_deps.call_factory = std::move(pcf_dependencies->call_factory); pcf_deps.event_log_factory = std::move(pcf_dependencies->event_log_factory); pcf_deps.task_queue_factory = std::move(pcf_dependencies->task_queue_factory); if (pcf_dependencies->fec_controller_factory != nullptr) { pcf_deps.fec_controller_factory = std::move(pcf_dependencies->fec_controller_factory); } if (pcf_dependencies->network_controller_factory != nullptr) { pcf_deps.network_controller_factory = std::move(pcf_dependencies->network_controller_factory); } if (pcf_dependencies->neteq_factory != nullptr) { pcf_deps.neteq_factory = std::move(pcf_dependencies->neteq_factory); } if (pcf_dependencies->trials != nullptr) { pcf_deps.trials = std::move(pcf_dependencies->trials); } return pcf_deps; } // Creates PeerConnectionDependencies objects, providing entities // from InjectableComponents::PeerConnectionComponents. PeerConnectionDependencies CreatePCDependencies( MockPeerConnectionObserver* observer, uint32_t port_allocator_extra_flags, std::unique_ptr pc_dependencies) { PeerConnectionDependencies pc_deps(observer); auto port_allocator = std::make_unique( pc_dependencies->network_manager, pc_dependencies->packet_socket_factory); // This test does not support TCP int flags = port_allocator_extra_flags | cricket::PORTALLOCATOR_DISABLE_TCP; port_allocator->set_flags(port_allocator->flags() | flags); pc_deps.allocator = std::move(port_allocator); if (pc_dependencies->async_resolver_factory != nullptr) { pc_deps.async_resolver_factory = std::move(pc_dependencies->async_resolver_factory); } if (pc_dependencies->cert_generator != nullptr) { pc_deps.cert_generator = std::move(pc_dependencies->cert_generator); } if (pc_dependencies->tls_cert_verifier != nullptr) { pc_deps.tls_cert_verifier = std::move(pc_dependencies->tls_cert_verifier); } if (pc_dependencies->ice_transport_factory != nullptr) { pc_deps.ice_transport_factory = std::move(pc_dependencies->ice_transport_factory); } return pc_deps; } } // namespace absl::optional RemotePeerAudioConfig::Create( absl::optional config) { if (!config) { return absl::nullopt; } return RemotePeerAudioConfig(config.value()); } std::unique_ptr TestPeerFactory::CreateTestPeer( std::unique_ptr configurer, std::unique_ptr observer, absl::optional remote_audio_config, absl::optional echo_emulation_config) { std::unique_ptr components = configurer->ReleaseComponents(); std::unique_ptr params = configurer->ReleaseParams(); std::unique_ptr configurable_params = configurer->ReleaseConfigurableParams(); std::vector video_sources = configurer->ReleaseVideoSources(); RTC_DCHECK(components); RTC_DCHECK(params); RTC_DCHECK(configurable_params); RTC_DCHECK_EQ(configurable_params->video_configs.size(), video_sources.size()); SetMandatoryEntities(components.get(), time_controller_); params->rtc_configuration.sdp_semantics = SdpSemantics::kUnifiedPlan; // Create peer connection factory. if (components->pcf_dependencies->audio_processing == nullptr) { components->pcf_dependencies->audio_processing = webrtc::AudioProcessingBuilder().Create(); } if (params->aec_dump_path) { components->pcf_dependencies->audio_processing->CreateAndAttachAecDump( *params->aec_dump_path, -1, task_queue_); } rtc::scoped_refptr audio_device_module = CreateAudioDeviceModule( params->audio_config, remote_audio_config, echo_emulation_config, components->pcf_dependencies->task_queue_factory.get()); WrapVideoEncoderFactory( params->name.value(), params->video_encoder_bitrate_multiplier, CalculateRequiredSpatialIndexPerStream( configurable_params->video_configs), components->pcf_dependencies.get(), video_analyzer_helper_); WrapVideoDecoderFactory(params->name.value(), components->pcf_dependencies.get(), video_analyzer_helper_); std::unique_ptr media_engine = CreateMediaEngine(components->pcf_dependencies.get(), audio_device_module); std::unique_ptr owned_worker_thread = components->worker_thread != nullptr ? nullptr : time_controller_.CreateThread("worker_thread"); if (components->worker_thread == nullptr) { components->worker_thread = owned_worker_thread.get(); } // Store `webrtc::AudioProcessing` into local variable before move of // `components->pcf_dependencies` rtc::scoped_refptr audio_processing = components->pcf_dependencies->audio_processing; PeerConnectionFactoryDependencies pcf_deps = CreatePCFDependencies( std::move(components->pcf_dependencies), std::move(media_engine), signaling_thread_, components->worker_thread, components->network_thread); rtc::scoped_refptr peer_connection_factory = CreateModularPeerConnectionFactory(std::move(pcf_deps)); // Create peer connection. PeerConnectionDependencies pc_deps = CreatePCDependencies(observer.get(), params->port_allocator_extra_flags, std::move(components->pc_dependencies)); rtc::scoped_refptr peer_connection = peer_connection_factory ->CreatePeerConnectionOrError(params->rtc_configuration, std::move(pc_deps)) .MoveValue(); peer_connection->SetBitrate(params->bitrate_settings); return absl::WrapUnique( new TestPeer(peer_connection_factory, peer_connection, std::move(observer), std::move(*params), std::move(*configurable_params), std::move(video_sources), audio_processing, std::move(owned_worker_thread))); } } // namespace webrtc_pc_e2e } // namespace webrtc