// Copyright 2013 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "media/audio/audio_manager.h" #include #include #include #include #include "base/bind.h" #include "base/environment.h" #include "base/logging.h" #include "base/run_loop.h" #include "base/single_thread_task_runner.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_util.h" #include "base/synchronization/waitable_event.h" #include "base/test/test_message_loop.h" #include "base/threading/thread_task_runner_handle.h" #include "build/build_config.h" #include "media/audio/audio_device_description.h" #include "media/audio/audio_device_info_accessor_for_tests.h" #include "media/audio/audio_device_name.h" #include "media/audio/audio_output_proxy.h" #include "media/audio/audio_unittest_util.h" #include "media/audio/fake_audio_log_factory.h" #include "media/audio/fake_audio_manager.h" #include "media/audio/test_audio_thread.h" #include "media/base/limits.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" #if defined(USE_ALSA) #include "media/audio/alsa/audio_manager_alsa.h" #endif // defined(USE_ALSA) #if defined(OS_MACOSX) #include "media/audio/mac/audio_manager_mac.h" #include "media/base/mac/audio_latency_mac.h" #endif #if defined(OS_WIN) #include "base/win/scoped_com_initializer.h" #include "media/audio/win/audio_manager_win.h" #endif #if defined(USE_PULSEAUDIO) #include "media/audio/pulse/audio_manager_pulse.h" #include "media/audio/pulse/pulse_util.h" #endif // defined(USE_PULSEAUDIO) #if defined(USE_CRAS) #include "chromeos/audio/audio_devices_pref_handler_stub.h" #include "chromeos/audio/cras_audio_handler.h" #include "chromeos/dbus/dbus_thread_manager.h" #include "chromeos/dbus/fake_cras_audio_client.h" #include "media/audio/cras/audio_manager_cras.h" #endif // defined(USE_CRAS) namespace media { namespace { template struct TestAudioManagerFactory { static std::unique_ptr Create( AudioLogFactory* audio_log_factory) { return std::make_unique(std::make_unique(), audio_log_factory); } }; #if defined(USE_PULSEAUDIO) template <> struct TestAudioManagerFactory { static std::unique_ptr Create( AudioLogFactory* audio_log_factory) { pa_threaded_mainloop* pa_mainloop = nullptr; pa_context* pa_context = nullptr; if (!pulse::InitPulse(&pa_mainloop, &pa_context)) return nullptr; return std::make_unique( std::make_unique(), audio_log_factory, pa_mainloop, pa_context); } }; #endif // defined(USE_PULSEAUDIO) template <> struct TestAudioManagerFactory { static std::unique_ptr Create( AudioLogFactory* audio_log_factory) { return AudioManager::CreateForTesting(std::make_unique()); } }; #if defined(USE_CRAS) using chromeos::AudioNode; using chromeos::AudioNodeList; const uint64_t kJabraSpeaker1Id = 30001; const uint64_t kJabraSpeaker1StableDeviceId = 80001; const uint64_t kJabraSpeaker2Id = 30002; const uint64_t kJabraSpeaker2StableDeviceId = 80002; const uint64_t kHDMIOutputId = 30003; const uint64_t kHDMIOutputStabeDevicelId = 80003; const uint64_t kJabraMic1Id = 40001; const uint64_t kJabraMic1StableDeviceId = 90001; const uint64_t kJabraMic2Id = 40002; const uint64_t kJabraMic2StableDeviceId = 90002; const uint64_t kWebcamMicId = 40003; const uint64_t kWebcamMicStableDeviceId = 90003; const AudioNode kJabraSpeaker1(false, kJabraSpeaker1Id, true, kJabraSpeaker1StableDeviceId, kJabraSpeaker1StableDeviceId ^ 0xFF, "Jabra Speaker", "USB", "Jabra Speaker 1", false, 0); const AudioNode kJabraSpeaker2(false, kJabraSpeaker2Id, true, kJabraSpeaker2StableDeviceId, kJabraSpeaker2StableDeviceId ^ 0xFF, "Jabra Speaker", "USB", "Jabra Speaker 2", false, 0); const AudioNode kHDMIOutput(false, kHDMIOutputId, true, kHDMIOutputStabeDevicelId, kHDMIOutputStabeDevicelId ^ 0xFF, "HDMI output", "HDMI", "HDA Intel MID", false, 0); const AudioNode kJabraMic1(true, kJabraMic1Id, true, kJabraMic1StableDeviceId, kJabraMic1StableDeviceId ^ 0xFF, "Jabra Mic", "USB", "Jabra Mic 1", false, 0); const AudioNode kJabraMic2(true, kJabraMic2Id, true, kJabraMic2StableDeviceId, kJabraMic2StableDeviceId ^ 0xFF, "Jabra Mic", "USB", "Jabra Mic 2", false, 0); const AudioNode kUSBCameraMic(true, kWebcamMicId, true, kWebcamMicStableDeviceId, kWebcamMicStableDeviceId ^ 0xFF, "Webcam Mic", "USB", "Logitech Webcam", false, 0); #endif // defined(USE_CRAS) const char kRealDefaultInputDeviceID[] = "input2"; const char kRealDefaultOutputDeviceID[] = "output3"; const char kRealCommunicationsInputDeviceID[] = "input1"; const char kRealCommunicationsOutputDeviceID[] = "output1"; void CheckDescriptionLabels(const AudioDeviceDescriptions& descriptions, const std::string& real_default_id, const std::string& real_communications_id) { std::string real_default_label; std::string real_communications_label; for (const auto& description : descriptions) { if (description.unique_id == real_default_id) real_default_label = description.device_name; else if (description.unique_id == real_communications_id) real_communications_label = description.device_name; } for (const auto& description : descriptions) { if (AudioDeviceDescription::IsDefaultDevice(description.unique_id)) { EXPECT_TRUE(base::EndsWith(description.device_name, real_default_label, base::CompareCase::SENSITIVE)); } else if (description.unique_id == AudioDeviceDescription::kCommunicationsDeviceId) { EXPECT_TRUE(base::EndsWith(description.device_name, real_communications_label, base::CompareCase::SENSITIVE)); } } } } // namespace // Test fixture which allows us to override the default enumeration API on // Windows. class AudioManagerTest : public ::testing::Test { public: void HandleDefaultDeviceIDsTest() { AudioParameters params(AudioParameters::AUDIO_PCM_LOW_LATENCY, CHANNEL_LAYOUT_STEREO, 48000, 16, 2048); // Create a stream with the default device id "". AudioOutputStream* stream = audio_manager_->MakeAudioOutputStreamProxy(params, ""); ASSERT_TRUE(stream); AudioOutputDispatcher* dispatcher1 = reinterpret_cast(stream) ->get_dispatcher_for_testing(); // Closing this stream will put it up for reuse. stream->Close(); stream = audio_manager_->MakeAudioOutputStreamProxy( params, AudioDeviceDescription::kDefaultDeviceId); // Verify both streams are created with the same dispatcher (which is unique // per device). ASSERT_EQ(dispatcher1, reinterpret_cast(stream) ->get_dispatcher_for_testing()); stream->Close(); // Create a non-default device and ensure it gets a different dispatcher. stream = audio_manager_->MakeAudioOutputStreamProxy(params, "123456"); ASSERT_NE(dispatcher1, reinterpret_cast(stream) ->get_dispatcher_for_testing()); stream->Close(); } void GetDefaultOutputStreamParameters(media::AudioParameters* params) { *params = device_info_accessor_->GetDefaultOutputStreamParameters(); } void GetAssociatedOutputDeviceID(const std::string& input_device_id, std::string* output_device_id) { *output_device_id = device_info_accessor_->GetAssociatedOutputDeviceID(input_device_id); } #if defined(USE_CRAS) void TearDown() override { chromeos::CrasAudioHandler::Shutdown(); audio_pref_handler_ = nullptr; chromeos::DBusThreadManager::Shutdown(); } void SetUpCrasAudioHandlerWithTestingNodes(const AudioNodeList& audio_nodes) { chromeos::DBusThreadManager::Initialize(); audio_client_ = static_cast( chromeos::DBusThreadManager::Get()->GetCrasAudioClient()); audio_client_->SetAudioNodesForTesting(audio_nodes); audio_pref_handler_ = new chromeos::AudioDevicesPrefHandlerStub(); chromeos::CrasAudioHandler::Initialize(audio_pref_handler_); cras_audio_handler_ = chromeos::CrasAudioHandler::Get(); base::RunLoop().RunUntilIdle(); } #endif // defined(USE_CRAS) protected: AudioManagerTest() { CreateAudioManagerForTesting(); } ~AudioManagerTest() override { audio_manager_->Shutdown(); } // Helper method which verifies that the device list starts with a valid // default record followed by non-default device names. static void CheckDeviceDescriptions( const AudioDeviceDescriptions& device_descriptions) { DVLOG(2) << "Got " << device_descriptions.size() << " audio devices."; if (!device_descriptions.empty()) { AudioDeviceDescriptions::const_iterator it = device_descriptions.begin(); // The first device in the list should always be the default device. EXPECT_TRUE(base::StartsWith( it->device_name, AudioDeviceDescription::GetDefaultDeviceName(), base::CompareCase::SENSITIVE)); EXPECT_EQ(std::string(AudioDeviceDescription::kDefaultDeviceId), it->unique_id); ++it; // Other devices should have non-empty name and id and should not contain // default name or id. while (it != device_descriptions.end()) { EXPECT_FALSE(it->device_name.empty()); EXPECT_FALSE(it->unique_id.empty()); EXPECT_FALSE(it->group_id.empty()); DVLOG(2) << "Device ID(" << it->unique_id << "), label: " << it->device_name << "group: " << it->group_id; EXPECT_NE(AudioDeviceDescription::GetDefaultDeviceName(), it->device_name); EXPECT_NE(std::string(AudioDeviceDescription::kDefaultDeviceId), it->unique_id); ++it; } } else { // Log a warning so we can see the status on the build bots. No need to // break the test though since this does successfully test the code and // some failure cases. LOG(WARNING) << "No input devices detected"; } } #if defined(USE_CRAS) // Helper method for (USE_CRAS) which verifies that the device list starts // with a valid default record followed by physical device names. static void CheckDeviceDescriptionsCras( const AudioDeviceDescriptions& device_descriptions, const std::map& expectation) { DVLOG(2) << "Got " << device_descriptions.size() << " audio devices."; if (!device_descriptions.empty()) { AudioDeviceDescriptions::const_iterator it = device_descriptions.begin(); // The first device in the list should always be the default device. EXPECT_EQ(AudioDeviceDescription::GetDefaultDeviceName(), it->device_name); EXPECT_EQ(std::string(AudioDeviceDescription::kDefaultDeviceId), it->unique_id); // |device_descriptions|'size should be |expectation|'s size plus one // because of // default device. EXPECT_EQ(device_descriptions.size(), expectation.size() + 1); ++it; // Check other devices that should have non-empty name and id, and should // be contained in expectation. while (it != device_descriptions.end()) { EXPECT_FALSE(it->device_name.empty()); EXPECT_FALSE(it->unique_id.empty()); EXPECT_FALSE(it->group_id.empty()); DVLOG(2) << "Device ID(" << it->unique_id << "), label: " << it->device_name << "group: " << it->group_id; uint64_t key; EXPECT_TRUE(base::StringToUint64(it->unique_id, &key)); EXPECT_TRUE(expectation.find(key) != expectation.end()); EXPECT_EQ(expectation.find(key)->second, it->device_name); ++it; } } else { // Log a warning so we can see the status on the build bots. No need to // break the test though since this does successfully test the code and // some failure cases. LOG(WARNING) << "No input devices detected"; } } #endif // defined(USE_CRAS) bool InputDevicesAvailable() { return device_info_accessor_->HasAudioInputDevices(); } bool OutputDevicesAvailable() { return device_info_accessor_->HasAudioOutputDevices(); } template void CreateAudioManagerForTesting() { // Only one AudioManager may exist at a time, so destroy the one we're // currently holding before creating a new one. // Flush the message loop to run any shutdown tasks posted by AudioManager. if (audio_manager_) { audio_manager_->Shutdown(); audio_manager_.reset(); } audio_manager_ = TestAudioManagerFactory::Create(&fake_audio_log_factory_); // A few AudioManager implementations post initialization tasks to // audio thread. Flush the thread to ensure that |audio_manager_| is // initialized and ready to use before returning from this function. // TODO(alokp): We should perhaps do this in AudioManager::Create(). base::RunLoop().RunUntilIdle(); device_info_accessor_ = std::make_unique(audio_manager_.get()); } base::TestMessageLoop message_loop_; FakeAudioLogFactory fake_audio_log_factory_; std::unique_ptr audio_manager_; std::unique_ptr device_info_accessor_; #if defined(USE_CRAS) chromeos::CrasAudioHandler* cras_audio_handler_ = nullptr; // Not owned. chromeos::FakeCrasAudioClient* audio_client_ = nullptr; // Not owned. scoped_refptr audio_pref_handler_; #endif // defined(USE_CRAS) }; #if defined(USE_CRAS) TEST_F(AudioManagerTest, EnumerateInputDevicesCras) { // Setup the devices without internal mic, so that it doesn't exist // beamforming capable mic. AudioNodeList audio_nodes; audio_nodes.push_back(kJabraMic1); audio_nodes.push_back(kJabraMic2); audio_nodes.push_back(kUSBCameraMic); audio_nodes.push_back(kHDMIOutput); audio_nodes.push_back(kJabraSpeaker1); SetUpCrasAudioHandlerWithTestingNodes(audio_nodes); ABORT_AUDIO_TEST_IF_NOT(InputDevicesAvailable()); // Setup expectation with physical devices. std::map expectation; expectation[kJabraMic1.id] = cras_audio_handler_->GetDeviceFromId(kJabraMic1.id)->display_name; expectation[kJabraMic2.id] = cras_audio_handler_->GetDeviceFromId(kJabraMic2.id)->display_name; expectation[kUSBCameraMic.id] = cras_audio_handler_->GetDeviceFromId(kUSBCameraMic.id)->display_name; DVLOG(2) << "Testing AudioManagerCras."; CreateAudioManagerForTesting(); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioInputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptionsCras(device_descriptions, expectation); } TEST_F(AudioManagerTest, EnumerateOutputDevicesCras) { // Setup the devices without internal mic, so that it doesn't exist // beamforming capable mic. AudioNodeList audio_nodes; audio_nodes.push_back(kJabraMic1); audio_nodes.push_back(kJabraMic2); audio_nodes.push_back(kUSBCameraMic); audio_nodes.push_back(kHDMIOutput); audio_nodes.push_back(kJabraSpeaker1); SetUpCrasAudioHandlerWithTestingNodes(audio_nodes); ABORT_AUDIO_TEST_IF_NOT(OutputDevicesAvailable()); // Setup expectation with physical devices. std::map expectation; expectation[kHDMIOutput.id] = cras_audio_handler_->GetDeviceFromId(kHDMIOutput.id)->display_name; expectation[kJabraSpeaker1.id] = cras_audio_handler_->GetDeviceFromId(kJabraSpeaker1.id)->display_name; DVLOG(2) << "Testing AudioManagerCras."; CreateAudioManagerForTesting(); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioOutputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptionsCras(device_descriptions, expectation); } #else // !defined(USE_CRAS) TEST_F(AudioManagerTest, HandleDefaultDeviceIDs) { // Use a fake manager so we can makeup device ids, this will still use the // AudioManagerBase code. CreateAudioManagerForTesting(); HandleDefaultDeviceIDsTest(); base::RunLoop().RunUntilIdle(); } // Test that devices can be enumerated. TEST_F(AudioManagerTest, EnumerateInputDevices) { ABORT_AUDIO_TEST_IF_NOT(InputDevicesAvailable()); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioInputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptions(device_descriptions); } // Test that devices can be enumerated. TEST_F(AudioManagerTest, EnumerateOutputDevices) { ABORT_AUDIO_TEST_IF_NOT(OutputDevicesAvailable()); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioOutputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptions(device_descriptions); } // Run additional tests for Windows since enumeration can be done using // two different APIs. MMDevice is default for Vista and higher and Wave // is default for XP and lower. #if defined(OS_WIN) // Override default enumeration API and force usage of Windows MMDevice. // This test will only run on Windows Vista and higher. TEST_F(AudioManagerTest, EnumerateInputDevicesWinMMDevice) { ABORT_AUDIO_TEST_IF_NOT(InputDevicesAvailable()); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioInputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptions(device_descriptions); } TEST_F(AudioManagerTest, EnumerateOutputDevicesWinMMDevice) { ABORT_AUDIO_TEST_IF_NOT(OutputDevicesAvailable()); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioOutputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptions(device_descriptions); } #endif // defined(OS_WIN) #if defined(USE_PULSEAUDIO) // On Linux, there are two implementations available and both can // sometimes be tested on a single system. These tests specifically // test Pulseaudio. TEST_F(AudioManagerTest, EnumerateInputDevicesPulseaudio) { ABORT_AUDIO_TEST_IF_NOT(InputDevicesAvailable()); CreateAudioManagerForTesting(); if (audio_manager_.get()) { AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioInputDeviceDescriptions( &device_descriptions); CheckDeviceDescriptions(device_descriptions); } else { LOG(WARNING) << "No pulseaudio on this system."; } } TEST_F(AudioManagerTest, EnumerateOutputDevicesPulseaudio) { ABORT_AUDIO_TEST_IF_NOT(OutputDevicesAvailable()); CreateAudioManagerForTesting(); if (audio_manager_.get()) { AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioOutputDeviceDescriptions( &device_descriptions); CheckDeviceDescriptions(device_descriptions); } else { LOG(WARNING) << "No pulseaudio on this system."; } } #endif // defined(USE_PULSEAUDIO) #if defined(USE_ALSA) // On Linux, there are two implementations available and both can // sometimes be tested on a single system. These tests specifically // test Alsa. TEST_F(AudioManagerTest, EnumerateInputDevicesAlsa) { ABORT_AUDIO_TEST_IF_NOT(InputDevicesAvailable()); DVLOG(2) << "Testing AudioManagerAlsa."; CreateAudioManagerForTesting(); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioInputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptions(device_descriptions); } TEST_F(AudioManagerTest, EnumerateOutputDevicesAlsa) { ABORT_AUDIO_TEST_IF_NOT(OutputDevicesAvailable()); DVLOG(2) << "Testing AudioManagerAlsa."; CreateAudioManagerForTesting(); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioOutputDeviceDescriptions(&device_descriptions); CheckDeviceDescriptions(device_descriptions); } #endif // defined(USE_ALSA) TEST_F(AudioManagerTest, GetDefaultOutputStreamParameters) { #if defined(OS_WIN) || defined(OS_MACOSX) ABORT_AUDIO_TEST_IF_NOT(InputDevicesAvailable()); AudioParameters params; GetDefaultOutputStreamParameters(¶ms); EXPECT_TRUE(params.IsValid()); #endif // defined(OS_WIN) || defined(OS_MACOSX) } TEST_F(AudioManagerTest, GetAssociatedOutputDeviceID) { #if defined(OS_WIN) || defined(OS_MACOSX) ABORT_AUDIO_TEST_IF_NOT(InputDevicesAvailable() && OutputDevicesAvailable()); AudioDeviceDescriptions device_descriptions; device_info_accessor_->GetAudioInputDeviceDescriptions(&device_descriptions); bool found_an_associated_device = false; for (const auto& description : device_descriptions) { EXPECT_FALSE(description.unique_id.empty()); EXPECT_FALSE(description.device_name.empty()); EXPECT_FALSE(description.group_id.empty()); std::string output_device_id; GetAssociatedOutputDeviceID(description.unique_id, &output_device_id); if (!output_device_id.empty()) { DVLOG(2) << description.unique_id << " matches with " << output_device_id; found_an_associated_device = true; } } EXPECT_TRUE(found_an_associated_device); #endif // defined(OS_WIN) || defined(OS_MACOSX) } #endif // defined(USE_CRAS) class TestAudioManager : public FakeAudioManager { // For testing the default implementation of GetGroupId(Input|Output) // input$i is associated to output$i, if both exist. // Default input is input1. // Default output is output2. public: TestAudioManager(std::unique_ptr audio_thread, AudioLogFactory* audio_log_factory) : FakeAudioManager(std::move(audio_thread), audio_log_factory) {} std::string GetDefaultInputDeviceID() override { return kRealDefaultInputDeviceID; } std::string GetDefaultOutputDeviceID() override { return kRealDefaultOutputDeviceID; } std::string GetCommunicationsInputDeviceID() override { return kRealCommunicationsInputDeviceID; } std::string GetCommunicationsOutputDeviceID() override { return kRealCommunicationsOutputDeviceID; } std::string GetAssociatedOutputDeviceID( const std::string& input_id) override { if (input_id == "input1") return "output1"; DCHECK_EQ(std::string(kRealDefaultInputDeviceID), "input2"); if (input_id == AudioDeviceDescription::kDefaultDeviceId || input_id == kRealDefaultInputDeviceID) return "output2"; return std::string(); } private: void GetAudioInputDeviceNames(AudioDeviceNames* device_names) override { DCHECK(device_names->empty()); device_names->emplace_back(AudioDeviceName::CreateDefault()); device_names->emplace_back("Input 1", "input1"); device_names->emplace_back("Input 2", "input2"); device_names->emplace_back("Input 3", "input3"); } void GetAudioOutputDeviceNames(AudioDeviceNames* device_names) override { DCHECK(device_names->empty()); device_names->emplace_back(AudioDeviceName::CreateDefault()); device_names->emplace_back("Output 1", "output1"); device_names->emplace_back("Output 2", "output2"); device_names->emplace_back("Output 3", "output3"); } }; TEST_F(AudioManagerTest, GroupId) { CreateAudioManagerForTesting(); // Groups: // input1, output1 // input2, output2, default input // input3 // output3, default output AudioDeviceDescriptions inputs; device_info_accessor_->GetAudioInputDeviceDescriptions(&inputs); AudioDeviceDescriptions outputs; device_info_accessor_->GetAudioOutputDeviceDescriptions(&outputs); // default input EXPECT_EQ(inputs[0].group_id, outputs[2].group_id); // default input and default output are not associated EXPECT_NE(inputs[0].group_id, outputs[0].group_id); // default output EXPECT_EQ(outputs[0].group_id, outputs[3].group_id); // real inputs and outputs that are associated EXPECT_EQ(inputs[1].group_id, outputs[1].group_id); EXPECT_EQ(inputs[2].group_id, outputs[2].group_id); // real inputs and outputs that are not associated EXPECT_NE(inputs[3].group_id, outputs[3].group_id); // group IDs of different devices should differ. EXPECT_NE(inputs[1].group_id, inputs[2].group_id); EXPECT_NE(inputs[1].group_id, inputs[3].group_id); EXPECT_NE(inputs[2].group_id, inputs[3].group_id); EXPECT_NE(outputs[1].group_id, outputs[2].group_id); EXPECT_NE(outputs[1].group_id, outputs[3].group_id); EXPECT_NE(outputs[2].group_id, outputs[3].group_id); } TEST_F(AudioManagerTest, DefaultCommunicationsLabelsContainRealLabels) { CreateAudioManagerForTesting(); std::string default_input_id = device_info_accessor_->GetDefaultInputDeviceID(); EXPECT_EQ(default_input_id, kRealDefaultInputDeviceID); std::string default_output_id = device_info_accessor_->GetDefaultOutputDeviceID(); EXPECT_EQ(default_output_id, kRealDefaultOutputDeviceID); std::string communications_input_id = device_info_accessor_->GetCommunicationsInputDeviceID(); EXPECT_EQ(communications_input_id, kRealCommunicationsInputDeviceID); std::string communications_output_id = device_info_accessor_->GetCommunicationsOutputDeviceID(); EXPECT_EQ(communications_output_id, kRealCommunicationsOutputDeviceID); AudioDeviceDescriptions inputs; device_info_accessor_->GetAudioInputDeviceDescriptions(&inputs); CheckDescriptionLabels(inputs, default_input_id, communications_input_id); AudioDeviceDescriptions outputs; device_info_accessor_->GetAudioOutputDeviceDescriptions(&outputs); CheckDescriptionLabels(outputs, default_output_id, communications_output_id); } #if defined(OS_MACOSX) || defined(USE_CRAS) class TestAudioSourceCallback : public AudioOutputStream::AudioSourceCallback { public: TestAudioSourceCallback(int expected_frames_per_buffer, base::WaitableEvent* event) : expected_frames_per_buffer_(expected_frames_per_buffer), event_(event) {} ~TestAudioSourceCallback() override {} int OnMoreData(base::TimeDelta, base::TimeTicks, int, AudioBus* dest) override { EXPECT_EQ(dest->frames(), expected_frames_per_buffer_); event_->Signal(); return 0; } void OnError() override { FAIL(); } private: const int expected_frames_per_buffer_; base::WaitableEvent* event_; DISALLOW_COPY_AND_ASSIGN(TestAudioSourceCallback); }; // Test that we can create an AudioOutputStream with kMinAudioBufferSize and // kMaxAudioBufferSize and that the callback AudioBus is the expected size. TEST_F(AudioManagerTest, CheckMinMaxAudioBufferSizeCallbacks) { ABORT_AUDIO_TEST_IF_NOT(OutputDevicesAvailable()); #if defined(OS_MACOSX) CreateAudioManagerForTesting(); #elif defined(USE_CRAS) CreateAudioManagerForTesting(); #endif DCHECK(audio_manager_); AudioParameters default_params; GetDefaultOutputStreamParameters(&default_params); ASSERT_LT(default_params.frames_per_buffer(), media::limits::kMaxAudioBufferSize); #if defined(OS_MACOSX) // On OSX the preferred output buffer size is higher than the minimum // but users may request the minimum size explicitly. ASSERT_GT(default_params.frames_per_buffer(), GetMinAudioBufferSizeMacOS(media::limits::kMinAudioBufferSize, default_params.sample_rate())); #elif defined(USE_CRAS) // On CRAS the preferred output buffer size varies per board and may be as low // as the minimum for some boards. ASSERT_GE(default_params.frames_per_buffer(), media::limits::kMinAudioBufferSize); #else NOTREACHED(); #endif AudioOutputStream* stream; base::WaitableEvent event(base::WaitableEvent::ResetPolicy::AUTOMATIC, base::WaitableEvent::InitialState::NOT_SIGNALED); // Create an output stream with the minimum buffer size parameters and ensure // that no errors are returned. AudioParameters min_params = default_params; min_params.set_frames_per_buffer(media::limits::kMinAudioBufferSize); stream = audio_manager_->MakeAudioOutputStreamProxy(min_params, ""); ASSERT_TRUE(stream); EXPECT_TRUE(stream->Open()); event.Reset(); TestAudioSourceCallback min_source(min_params.frames_per_buffer(), &event); stream->Start(&min_source); event.Wait(); stream->Stop(); stream->Close(); // Verify the same for the maximum buffer size. AudioParameters max_params = default_params; max_params.set_frames_per_buffer(media::limits::kMaxAudioBufferSize); stream = audio_manager_->MakeAudioOutputStreamProxy(max_params, ""); ASSERT_TRUE(stream); EXPECT_TRUE(stream->Open()); event.Reset(); TestAudioSourceCallback max_source(max_params.frames_per_buffer(), &event); stream->Start(&max_source); event.Wait(); stream->Stop(); stream->Close(); } #endif } // namespace media