/* * Copyright © 2013 Mozilla Foundation * * This program is made available under an ISC-style license. See the * accompanying file LICENSE for details. */ #define _WIN32_WINNT 0x0600 #define NOMINMAX #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "cubeb/cubeb.h" #include "cubeb-internal.h" #include "cubeb_mixer.h" #include "cubeb_resampler.h" #include "cubeb_strings.h" #include "cubeb_utils.h" // Windows 10 exposes the IAudioClient3 interface to create low-latency streams. // Copy the interface definition from audioclient.h here to make the code simpler // and so that we can still access IAudioClient3 via COM if cubeb was compiled // against an older SDK. #ifndef __IAudioClient3_INTERFACE_DEFINED__ #define __IAudioClient3_INTERFACE_DEFINED__ MIDL_INTERFACE("7ED4EE07-8E67-4CD4-8C1A-2B7A5987AD42") IAudioClient3 : public IAudioClient { public: virtual HRESULT STDMETHODCALLTYPE GetSharedModeEnginePeriod( /* [annotation][in] */ _In_ const WAVEFORMATEX *pFormat, /* [annotation][out] */ _Out_ UINT32 *pDefaultPeriodInFrames, /* [annotation][out] */ _Out_ UINT32 *pFundamentalPeriodInFrames, /* [annotation][out] */ _Out_ UINT32 *pMinPeriodInFrames, /* [annotation][out] */ _Out_ UINT32 *pMaxPeriodInFrames) = 0; virtual HRESULT STDMETHODCALLTYPE GetCurrentSharedModeEnginePeriod( /* [unique][annotation][out] */ _Out_ WAVEFORMATEX **ppFormat, /* [annotation][out] */ _Out_ UINT32 *pCurrentPeriodInFrames) = 0; virtual HRESULT STDMETHODCALLTYPE InitializeSharedAudioStream( /* [annotation][in] */ _In_ DWORD StreamFlags, /* [annotation][in] */ _In_ UINT32 PeriodInFrames, /* [annotation][in] */ _In_ const WAVEFORMATEX *pFormat, /* [annotation][in] */ _In_opt_ LPCGUID AudioSessionGuid) = 0; }; #ifdef __CRT_UUID_DECL // Required for MinGW __CRT_UUID_DECL(IAudioClient3, 0x7ED4EE07, 0x8E67, 0x4CD4, 0x8C, 0x1A, 0x2B, 0x7A, 0x59, 0x87, 0xAD, 0x42) #endif #endif // Copied from audioclient.h in the Windows 10 SDK #ifndef AUDCLNT_E_ENGINE_PERIODICITY_LOCKED #define AUDCLNT_E_ENGINE_PERIODICITY_LOCKED AUDCLNT_ERR(0x028) #endif #ifndef PKEY_Device_FriendlyName DEFINE_PROPERTYKEY(PKEY_Device_FriendlyName, 0xa45c254e, 0xdf1c, 0x4efd, 0x80, 0x20, 0x67, 0xd1, 0x46, 0xa8, 0x50, 0xe0, 14); // DEVPROP_TYPE_STRING #endif #ifndef PKEY_Device_InstanceId DEFINE_PROPERTYKEY(PKEY_Device_InstanceId, 0x78c34fc8, 0x104a, 0x4aca, 0x9e, 0xa4, 0x52, 0x4d, 0x52, 0x99, 0x6e, 0x57, 0x00000100); // VT_LPWSTR #endif namespace { struct com_heap_ptr_deleter { void operator()(void * ptr) const noexcept { CoTaskMemFree(ptr); } }; template using com_heap_ptr = std::unique_ptr; template constexpr size_t ARRAY_LENGTH(T(&)[N]) { return N; } template class no_addref_release : public T { ULONG STDMETHODCALLTYPE AddRef() = 0; ULONG STDMETHODCALLTYPE Release() = 0; }; template class com_ptr { public: com_ptr() noexcept = default; com_ptr(com_ptr const & other) noexcept = delete; com_ptr & operator=(com_ptr const & other) noexcept = delete; T ** operator&() const noexcept = delete; ~com_ptr() noexcept { release(); } com_ptr(com_ptr && other) noexcept : ptr(other.ptr) { other.ptr = nullptr; } com_ptr & operator=(com_ptr && other) noexcept { if (ptr != other.ptr) { release(); ptr = other.ptr; other.ptr = nullptr; } return *this; } explicit operator bool() const noexcept { return nullptr != ptr; } no_addref_release * operator->() const noexcept { return static_cast *>(ptr); } T * get() const noexcept { return ptr; } T ** receive() noexcept { XASSERT(ptr == nullptr); return &ptr; } void ** receive_vpp() noexcept { return reinterpret_cast(receive()); } com_ptr & operator=(std::nullptr_t) noexcept { release(); return *this; } void reset(T * p = nullptr) noexcept { release(); ptr = p; } private: void release() noexcept { T * temp = ptr; if (temp) { ptr = nullptr; temp->Release(); } } T * ptr = nullptr; }; extern cubeb_ops const wasapi_ops; int wasapi_stream_stop(cubeb_stream * stm); int wasapi_stream_start(cubeb_stream * stm); void close_wasapi_stream(cubeb_stream * stm); int setup_wasapi_stream(cubeb_stream * stm); ERole pref_to_role(cubeb_stream_prefs param); static char const * wstr_to_utf8(wchar_t const * str); static std::unique_ptr utf8_to_wstr(char const * str); } class wasapi_collection_notification_client; class monitor_device_notifications; struct cubeb { cubeb_ops const * ops = &wasapi_ops; cubeb_strings * device_ids; /* Device enumerator to get notifications when the device collection change. */ com_ptr device_collection_enumerator; com_ptr collection_notification_client; /* Collection changed for input (capture) devices. */ cubeb_device_collection_changed_callback input_collection_changed_callback = nullptr; void * input_collection_changed_user_ptr = nullptr; /* Collection changed for output (render) devices. */ cubeb_device_collection_changed_callback output_collection_changed_callback = nullptr; void * output_collection_changed_user_ptr = nullptr; }; class wasapi_endpoint_notification_client; /* We have three possible callbacks we can use with a stream: * - input only * - output only * - synchronized input and output * * Returns true when we should continue to play, false otherwise. */ typedef bool (*wasapi_refill_callback)(cubeb_stream * stm); struct cubeb_stream { /* Note: Must match cubeb_stream layout in cubeb.c. */ cubeb * context = nullptr; void * user_ptr = nullptr; /**/ /* Mixer pameters. We need to convert the input stream to this samplerate/channel layout, as WASAPI does not resample nor upmix itself. */ cubeb_stream_params input_mix_params = { CUBEB_SAMPLE_FLOAT32NE, 0, 0, CUBEB_LAYOUT_UNDEFINED, CUBEB_STREAM_PREF_NONE }; cubeb_stream_params output_mix_params = { CUBEB_SAMPLE_FLOAT32NE, 0, 0, CUBEB_LAYOUT_UNDEFINED, CUBEB_STREAM_PREF_NONE }; /* Stream parameters. This is what the client requested, * and what will be presented in the callback. */ cubeb_stream_params input_stream_params = { CUBEB_SAMPLE_FLOAT32NE, 0, 0, CUBEB_LAYOUT_UNDEFINED, CUBEB_STREAM_PREF_NONE }; cubeb_stream_params output_stream_params = { CUBEB_SAMPLE_FLOAT32NE, 0, 0, CUBEB_LAYOUT_UNDEFINED, CUBEB_STREAM_PREF_NONE }; /* A MMDevice role for this stream: either communication or console here. */ ERole role; /* The input and output device, or NULL for default. */ std::unique_ptr input_device; std::unique_ptr output_device; /* The latency initially requested for this stream, in frames. */ unsigned latency = 0; cubeb_state_callback state_callback = nullptr; cubeb_data_callback data_callback = nullptr; wasapi_refill_callback refill_callback = nullptr; /* True when a loopback device is requested with no output device. In this case a dummy output device is opened to drive the loopback, but should not be exposed. */ bool has_dummy_output = false; /* Lifetime considerations: - client, render_client, audio_clock and audio_stream_volume are interface pointer to the IAudioClient. - The lifetime for device_enumerator and notification_client, resampler, mix_buffer are the same as the cubeb_stream instance. */ /* Main handle on the WASAPI stream. */ com_ptr output_client; /* Interface pointer to use the event-driven interface. */ com_ptr render_client; /* Interface pointer to use the volume facilities. */ com_ptr audio_stream_volume; /* Interface pointer to use the stream audio clock. */ com_ptr audio_clock; /* Frames written to the stream since it was opened. Reset on device change. Uses mix_params.rate. */ UINT64 frames_written = 0; /* Frames written to the (logical) stream since it was first created. Updated on device change. Uses stream_params.rate. */ UINT64 total_frames_written = 0; /* Last valid reported stream position. Used to ensure the position reported by stream_get_position increases monotonically. */ UINT64 prev_position = 0; /* Device enumerator to be able to be notified when the default device change. */ com_ptr device_enumerator; /* Device notification client, to be able to be notified when the default audio device changes and route the audio to the new default audio output device */ com_ptr notification_client; /* Main andle to the WASAPI capture stream. */ com_ptr input_client; /* Interface to use the event driven capture interface */ com_ptr capture_client; /* This event is set by the stream_stop and stream_destroy function, so the render loop can exit properly. */ HANDLE shutdown_event = 0; /* Set by OnDefaultDeviceChanged when a stream reconfiguration is required. The reconfiguration is handled by the render loop thread. */ HANDLE reconfigure_event = 0; /* This is set by WASAPI when we should refill the stream. */ HANDLE refill_event = 0; /* This is set by WASAPI when we should read from the input stream. In * practice, we read from the input stream in the output callback, so * this is not used, but it is necessary to start getting input data. */ HANDLE input_available_event = 0; /* Each cubeb_stream has its own thread. */ HANDLE thread = 0; /* The lock protects all members that are touched by the render thread or change during a device reset, including: audio_clock, audio_stream_volume, client, frames_written, mix_params, total_frames_written, prev_position. */ owned_critical_section stream_reset_lock; /* Maximum number of frames that can be passed down in a callback. */ uint32_t input_buffer_frame_count = 0; /* Maximum number of frames that can be requested in a callback. */ uint32_t output_buffer_frame_count = 0; /* Resampler instance. Resampling will only happen if necessary. */ std::unique_ptr resampler = { nullptr, cubeb_resampler_destroy }; /* Mixer interfaces */ std::unique_ptr output_mixer = { nullptr, cubeb_mixer_destroy }; std::unique_ptr input_mixer = { nullptr, cubeb_mixer_destroy }; /* A buffer for up/down mixing multi-channel audio output. */ std::vector mix_buffer; /* WASAPI input works in "packets". We re-linearize the audio packets * into this buffer before handing it to the resampler. */ std::unique_ptr linear_input_buffer; /* Bytes per sample. This multiplied by the number of channels is the number * of bytes per frame. */ size_t bytes_per_sample = 0; /* WAVEFORMATEXTENSIBLE sub-format: either PCM or float. */ GUID waveformatextensible_sub_format = GUID_NULL; /* Stream volume. Set via stream_set_volume and used to reset volume on device changes. */ float volume = 1.0; /* True if the stream is draining. */ bool draining = false; /* True when we've destroyed the stream. This pointer is leaked on stream * destruction if we could not join the thread. */ std::atomic*> emergency_bailout { nullptr }; /* Synchronizes render thread start to ensure safe access to emergency_bailout. */ HANDLE thread_ready_event = 0; }; class monitor_device_notifications { public: monitor_device_notifications(cubeb * context) : cubeb_context(context) { create_thread(); } ~monitor_device_notifications() { SetEvent(shutdown); WaitForSingleObject(thread, INFINITE); CloseHandle(thread); CloseHandle(input_changed); CloseHandle(output_changed); CloseHandle(shutdown); } void notify(EDataFlow flow) { XASSERT(cubeb_context); if (flow == eCapture && cubeb_context->input_collection_changed_callback) { bool res = SetEvent(input_changed); if (!res) { LOG("Failed to set input changed event"); } return; } if (flow == eRender && cubeb_context->output_collection_changed_callback) { bool res = SetEvent(output_changed); if (!res) { LOG("Failed to set output changed event"); } } } private: static unsigned int __stdcall thread_proc(LPVOID args) { XASSERT(args); static_cast(args) ->notification_thread_loop(); return 0; } void notification_thread_loop() { struct auto_com { auto_com() { HRESULT hr = CoInitializeEx(nullptr, COINIT_MULTITHREADED); XASSERT(SUCCEEDED(hr)); } ~auto_com() { CoUninitialize(); } } com; HANDLE wait_array[3] = { input_changed, output_changed, shutdown, }; while (true) { Sleep(200); DWORD wait_result = WaitForMultipleObjects(ARRAY_LENGTH(wait_array), wait_array, FALSE, INFINITE); if (wait_result == WAIT_OBJECT_0) { // input changed cubeb_context->input_collection_changed_callback(cubeb_context, cubeb_context->input_collection_changed_user_ptr); } else if (wait_result == WAIT_OBJECT_0 + 1) { // output changed cubeb_context->output_collection_changed_callback(cubeb_context, cubeb_context->output_collection_changed_user_ptr); } else if (wait_result == WAIT_OBJECT_0 + 2) { // shutdown break; } else { LOG("Unexpected result %lu", wait_result); } } // loop } void create_thread() { output_changed = CreateEvent(nullptr, 0, 0, nullptr); if (!output_changed) { LOG("Failed to create output changed event."); return; } input_changed = CreateEvent(nullptr, 0, 0, nullptr); if (!input_changed) { LOG("Failed to create input changed event."); return; } shutdown = CreateEvent(nullptr, 0, 0, nullptr); if (!shutdown) { LOG("Failed to create shutdown event."); return; } thread = (HANDLE) _beginthreadex(nullptr, 256 * 1024, thread_proc, this, STACK_SIZE_PARAM_IS_A_RESERVATION, nullptr); if (!thread) { LOG("Failed to create thread."); return; } } HANDLE thread = INVALID_HANDLE_VALUE; HANDLE output_changed = INVALID_HANDLE_VALUE; HANDLE input_changed = INVALID_HANDLE_VALUE; HANDLE shutdown = INVALID_HANDLE_VALUE; cubeb * cubeb_context = nullptr; }; class wasapi_collection_notification_client : public IMMNotificationClient { public: /* The implementation of MSCOM was copied from MSDN. */ ULONG STDMETHODCALLTYPE AddRef() { return InterlockedIncrement(&ref_count); } ULONG STDMETHODCALLTYPE Release() { ULONG ulRef = InterlockedDecrement(&ref_count); if (0 == ulRef) { delete this; } return ulRef; } HRESULT STDMETHODCALLTYPE QueryInterface(REFIID riid, VOID **ppvInterface) { if (__uuidof(IUnknown) == riid) { AddRef(); *ppvInterface = (IUnknown*)this; } else if (__uuidof(IMMNotificationClient) == riid) { AddRef(); *ppvInterface = (IMMNotificationClient*)this; } else { *ppvInterface = NULL; return E_NOINTERFACE; } return S_OK; } wasapi_collection_notification_client(cubeb * context) : ref_count(1) , cubeb_context(context) , monitor_notifications(context) { XASSERT(cubeb_context); } virtual ~wasapi_collection_notification_client() { } HRESULT STDMETHODCALLTYPE OnDefaultDeviceChanged(EDataFlow flow, ERole role, LPCWSTR device_id) { LOG("collection: Audio device default changed, id = %S.", device_id); return S_OK; } /* The remaining methods are not implemented, they simply log when called (if log is enabled), for debugging. */ HRESULT STDMETHODCALLTYPE OnDeviceAdded(LPCWSTR device_id) { LOG("collection: Audio device added."); return S_OK; }; HRESULT STDMETHODCALLTYPE OnDeviceRemoved(LPCWSTR device_id) { LOG("collection: Audio device removed."); return S_OK; } HRESULT STDMETHODCALLTYPE OnDeviceStateChanged(LPCWSTR device_id, DWORD new_state) { XASSERT(cubeb_context->output_collection_changed_callback || cubeb_context->input_collection_changed_callback); LOG("collection: Audio device state changed, id = %S, state = %lu.", device_id, new_state); EDataFlow flow; HRESULT hr = GetDataFlow(device_id, &flow); if (FAILED(hr)) { return hr; } monitor_notifications.notify(flow); return S_OK; } HRESULT STDMETHODCALLTYPE OnPropertyValueChanged(LPCWSTR device_id, const PROPERTYKEY key) { //Audio device property value changed. return S_OK; } private: HRESULT GetDataFlow(LPCWSTR device_id, EDataFlow * flow) { com_ptr device; com_ptr endpoint; HRESULT hr = cubeb_context->device_collection_enumerator ->GetDevice(device_id, device.receive()); if (FAILED(hr)) { LOG("collection: Could not get device: %lx", hr); return hr; } hr = device->QueryInterface(IID_PPV_ARGS(endpoint.receive())); if (FAILED(hr)) { LOG("collection: Could not get endpoint: %lx", hr); return hr; } return endpoint->GetDataFlow(flow); } /* refcount for this instance, necessary to implement MSCOM semantics. */ LONG ref_count; cubeb * cubeb_context = nullptr; monitor_device_notifications monitor_notifications; }; class wasapi_endpoint_notification_client : public IMMNotificationClient { public: /* The implementation of MSCOM was copied from MSDN. */ ULONG STDMETHODCALLTYPE AddRef() { return InterlockedIncrement(&ref_count); } ULONG STDMETHODCALLTYPE Release() { ULONG ulRef = InterlockedDecrement(&ref_count); if (0 == ulRef) { delete this; } return ulRef; } HRESULT STDMETHODCALLTYPE QueryInterface(REFIID riid, VOID **ppvInterface) { if (__uuidof(IUnknown) == riid) { AddRef(); *ppvInterface = (IUnknown*)this; } else if (__uuidof(IMMNotificationClient) == riid) { AddRef(); *ppvInterface = (IMMNotificationClient*)this; } else { *ppvInterface = NULL; return E_NOINTERFACE; } return S_OK; } wasapi_endpoint_notification_client(HANDLE event, ERole role) : ref_count(1) , reconfigure_event(event) , role(role) { } virtual ~wasapi_endpoint_notification_client() { } HRESULT STDMETHODCALLTYPE OnDefaultDeviceChanged(EDataFlow flow, ERole role, LPCWSTR device_id) { LOG("endpoint: Audio device default changed."); /* we only support a single stream type for now. */ if (flow != eRender && role != this->role) { return S_OK; } BOOL ok = SetEvent(reconfigure_event); if (!ok) { LOG("endpoint: SetEvent on reconfigure_event failed: %lx", GetLastError()); } return S_OK; } /* The remaining methods are not implemented, they simply log when called (if log is enabled), for debugging. */ HRESULT STDMETHODCALLTYPE OnDeviceAdded(LPCWSTR device_id) { LOG("endpoint: Audio device added."); return S_OK; }; HRESULT STDMETHODCALLTYPE OnDeviceRemoved(LPCWSTR device_id) { LOG("endpoint: Audio device removed."); return S_OK; } HRESULT STDMETHODCALLTYPE OnDeviceStateChanged(LPCWSTR device_id, DWORD new_state) { LOG("endpoint: Audio device state changed."); return S_OK; } HRESULT STDMETHODCALLTYPE OnPropertyValueChanged(LPCWSTR device_id, const PROPERTYKEY key) { //Audio device property value changed. return S_OK; } private: /* refcount for this instance, necessary to implement MSCOM semantics. */ LONG ref_count; HANDLE reconfigure_event; ERole role; }; namespace { char const * intern_device_id(cubeb * ctx, wchar_t const * id) { XASSERT(id); char const * tmp = wstr_to_utf8(id); if (!tmp) return nullptr; char const * interned = cubeb_strings_intern(ctx->device_ids, tmp); free((void *) tmp); return interned; } bool has_input(cubeb_stream * stm) { return stm->input_stream_params.rate != 0; } bool has_output(cubeb_stream * stm) { return stm->output_stream_params.rate != 0; } double stream_to_mix_samplerate_ratio(cubeb_stream_params & stream, cubeb_stream_params & mixer) { return double(stream.rate) / mixer.rate; } /* Convert the channel layout into the corresponding KSAUDIO_CHANNEL_CONFIG. See more: https://msdn.microsoft.com/en-us/library/windows/hardware/ff537083(v=vs.85).aspx */ cubeb_channel_layout mask_to_channel_layout(WAVEFORMATEX const * fmt) { cubeb_channel_layout mask = 0; if (fmt->wFormatTag == WAVE_FORMAT_EXTENSIBLE) { WAVEFORMATEXTENSIBLE const * ext = reinterpret_cast(fmt); mask = ext->dwChannelMask; } else if (fmt->wFormatTag == WAVE_FORMAT_PCM || fmt->wFormatTag == WAVE_FORMAT_IEEE_FLOAT) { if (fmt->nChannels == 1) { mask = CHANNEL_FRONT_CENTER; } else if (fmt->nChannels == 2) { mask = CHANNEL_FRONT_LEFT | CHANNEL_FRONT_RIGHT; } } return mask; } uint32_t get_rate(cubeb_stream * stm) { return has_input(stm) ? stm->input_stream_params.rate : stm->output_stream_params.rate; } uint32_t hns_to_frames(uint32_t rate, REFERENCE_TIME hns) { return std::ceil((hns - 1) / 10000000.0 * rate); } uint32_t hns_to_frames(cubeb_stream * stm, REFERENCE_TIME hns) { return hns_to_frames(get_rate(stm), hns); } REFERENCE_TIME frames_to_hns(cubeb_stream * stm, uint32_t frames) { return std::ceil(frames * 10000000.0 / get_rate(stm)); } /* This returns the size of a frame in the stream, before the eventual upmix occurs. */ static size_t frames_to_bytes_before_mix(cubeb_stream * stm, size_t frames) { // This is called only when we has a output client. XASSERT(has_output(stm)); return stm->output_stream_params.channels * stm->bytes_per_sample * frames; } /* This function handles the processing of the input and output audio, * converting it to rate and channel layout specified at initialization. * It then calls the data callback, via the resampler. */ long refill(cubeb_stream * stm, void * input_buffer, long input_frames_count, void * output_buffer, long output_frames_needed) { XASSERT(!stm->draining); /* If we need to upmix after resampling, resample into the mix buffer to avoid a copy. Avoid exposing output if it is a dummy stream. */ void * dest = nullptr; if (has_output(stm) && !stm->has_dummy_output) { if (stm->output_mixer) { dest = stm->mix_buffer.data(); } else { dest = output_buffer; } } long out_frames = cubeb_resampler_fill(stm->resampler.get(), input_buffer, &input_frames_count, dest, output_frames_needed); /* TODO: Report out_frames < 0 as an error via the API. */ XASSERT(out_frames >= 0); { auto_lock lock(stm->stream_reset_lock); stm->frames_written += out_frames; } /* Go in draining mode if we got fewer frames than requested. If the stream has no output we still expect the callback to return number of frames read from input, otherwise we stop. */ if ((out_frames < output_frames_needed) || (!has_output(stm) && out_frames < input_frames_count)) { LOG("start draining."); stm->draining = true; } /* If this is not true, there will be glitches. It is alright to have produced less frames if we are draining, though. */ XASSERT(out_frames == output_frames_needed || stm->draining || !has_output(stm) || stm->has_dummy_output); // We don't bother mixing dummy output as it will be silenced, otherwise mix output if needed if (!stm->has_dummy_output && has_output(stm) && stm->output_mixer) { XASSERT(dest == stm->mix_buffer.data()); size_t dest_size = out_frames * stm->output_stream_params.channels * stm->bytes_per_sample; XASSERT(dest_size <= stm->mix_buffer.size()); size_t output_buffer_size = out_frames * stm->output_mix_params.channels * stm->bytes_per_sample; int ret = cubeb_mixer_mix(stm->output_mixer.get(), out_frames, dest, dest_size, output_buffer, output_buffer_size); if (ret < 0) { LOG("Error remixing content (%d)", ret); } } return out_frames; } int wasapi_stream_reset_default_device(cubeb_stream * stm); /* This helper grabs all the frames available from a capture client, put them in * linear_input_buffer. linear_input_buffer should be cleared before the * callback exits. This helper does not work with exclusive mode streams. */ bool get_input_buffer(cubeb_stream * stm) { XASSERT(has_input(stm)); HRESULT hr; BYTE * input_packet = NULL; DWORD flags; UINT64 dev_pos; UINT32 next; /* Get input packets until we have captured enough frames, and put them in a * contiguous buffer. */ uint32_t offset = 0; // If the input stream is event driven we should only ever expect to read a // single packet each time. However, if we're pulling from the stream we may // need to grab multiple packets worth of frames that have accumulated (so // need a loop). for (hr = stm->capture_client->GetNextPacketSize(&next); next > 0; hr = stm->capture_client->GetNextPacketSize(&next)) { if (hr == AUDCLNT_E_DEVICE_INVALIDATED) { // Application can recover from this error. More info // https://msdn.microsoft.com/en-us/library/windows/desktop/dd316605(v=vs.85).aspx LOG("Device invalidated error, reset default device"); wasapi_stream_reset_default_device(stm); return true; } if (FAILED(hr)) { LOG("cannot get next packet size: %lx", hr); return false; } UINT32 frames; hr = stm->capture_client->GetBuffer(&input_packet, &frames, &flags, &dev_pos, NULL); if (FAILED(hr)) { LOG("GetBuffer failed for capture: %lx", hr); return false; } XASSERT(frames == next); UINT32 input_stream_samples = frames * stm->input_stream_params.channels; // We do not explicitly handle the AUDCLNT_BUFFERFLAGS_DATA_DISCONTINUITY // flag. There a two primary (non exhaustive) scenarios we anticipate this // flag being set in: // - The first GetBuffer after Start has this flag undefined. In this // case the flag may be set but is meaningless and can be ignored. // - If a glitch is introduced into the input. This should not happen // for event based inputs, and should be mitigated by using a dummy // stream to drive input in the case of input only loopback. Without // a dummy output, input only loopback would glitch on silence. However, // the dummy input should push silence to the loopback and prevent // discontinuities. See https://blogs.msdn.microsoft.com/matthew_van_eerde/2008/12/16/sample-wasapi-loopback-capture-record-what-you-hear/ // As the first scenario can be ignored, and we anticipate the second // scenario is mitigated, we ignore the flag. // For more info: https://msdn.microsoft.com/en-us/library/windows/desktop/dd370859(v=vs.85).aspx, // https://msdn.microsoft.com/en-us/library/windows/desktop/dd371458(v=vs.85).aspx if (flags & AUDCLNT_BUFFERFLAGS_SILENT) { LOG("insert silence: ps=%u", frames); stm->linear_input_buffer->push_silence(input_stream_samples); } else { if (stm->input_mixer) { bool ok = stm->linear_input_buffer->reserve( stm->linear_input_buffer->length() + input_stream_samples); XASSERT(ok); size_t input_packet_size = frames * stm->input_mix_params.channels * cubeb_sample_size(stm->input_mix_params.format); size_t linear_input_buffer_size = input_stream_samples * cubeb_sample_size(stm->input_stream_params.format); cubeb_mixer_mix(stm->input_mixer.get(), frames, input_packet, input_packet_size, stm->linear_input_buffer->end(), linear_input_buffer_size); stm->linear_input_buffer->set_length( stm->linear_input_buffer->length() + input_stream_samples); } else { stm->linear_input_buffer->push( input_packet, input_stream_samples); } } hr = stm->capture_client->ReleaseBuffer(frames); if (FAILED(hr)) { LOG("FAILED to release intput buffer"); return false; } offset += input_stream_samples; } XASSERT(stm->linear_input_buffer->length() >= offset); return true; } /* Get an output buffer from the render_client. It has to be released before * exiting the callback. */ bool get_output_buffer(cubeb_stream * stm, void *& buffer, size_t & frame_count) { UINT32 padding_out; HRESULT hr; XASSERT(has_output(stm)); hr = stm->output_client->GetCurrentPadding(&padding_out); if (hr == AUDCLNT_E_DEVICE_INVALIDATED) { // Application can recover from this error. More info // https://msdn.microsoft.com/en-us/library/windows/desktop/dd316605(v=vs.85).aspx LOG("Device invalidated error, reset default device"); wasapi_stream_reset_default_device(stm); return true; } if (FAILED(hr)) { LOG("Failed to get padding: %lx", hr); return false; } XASSERT(padding_out <= stm->output_buffer_frame_count); if (stm->draining) { if (padding_out == 0) { LOG("Draining finished."); stm->state_callback(stm, stm->user_ptr, CUBEB_STATE_DRAINED); return false; } LOG("Draining."); return true; } frame_count = stm->output_buffer_frame_count - padding_out; BYTE * output_buffer; hr = stm->render_client->GetBuffer(frame_count, &output_buffer); if (FAILED(hr)) { LOG("cannot get render buffer"); return false; } buffer = output_buffer; return true; } /** * This function gets input data from a input device, and pass it along with an * output buffer to the resamplers. */ bool refill_callback_duplex(cubeb_stream * stm) { HRESULT hr; void * output_buffer = nullptr; size_t output_frames = 0; size_t input_frames; bool rv; XASSERT(has_input(stm) && has_output(stm)); rv = get_input_buffer(stm); if (!rv) { return rv; } input_frames = stm->linear_input_buffer->length() / stm->input_stream_params.channels; if (!input_frames) { return true; } rv = get_output_buffer(stm, output_buffer, output_frames); if (!rv) { hr = stm->render_client->ReleaseBuffer(output_frames, 0); return rv; } /* This can only happen when debugging, and having breakpoints set in the * callback in a way that it makes the stream underrun. */ if (output_frames == 0) { return true; } /* Wait for draining is not important on duplex. */ if (stm->draining) { return false; } if (stm->has_dummy_output) { ALOGV("Duplex callback (dummy output): input frames: %Iu, output frames: %Iu", input_frames, output_frames); // We don't want to expose the dummy output to the callback so don't pass // the output buffer (it will be released later with silence in it) refill(stm, stm->linear_input_buffer->data(), input_frames, nullptr, 0); } else { ALOGV("Duplex callback: input frames: %Iu, output frames: %Iu", input_frames, output_frames); refill(stm, stm->linear_input_buffer->data(), input_frames, output_buffer, output_frames); } stm->linear_input_buffer->clear(); if (stm->has_dummy_output) { // If output is a dummy output, make sure it's silent hr = stm->render_client->ReleaseBuffer(output_frames, AUDCLNT_BUFFERFLAGS_SILENT); } else { hr = stm->render_client->ReleaseBuffer(output_frames, 0); } if (FAILED(hr)) { LOG("failed to release buffer: %lx", hr); return false; } return true; } bool refill_callback_input(cubeb_stream * stm) { bool rv; size_t input_frames; XASSERT(has_input(stm) && !has_output(stm)); rv = get_input_buffer(stm); if (!rv) { return rv; } input_frames = stm->linear_input_buffer->length() / stm->input_stream_params.channels; if (!input_frames) { return true; } ALOGV("Input callback: input frames: %Iu", input_frames); long read = refill(stm, stm->linear_input_buffer->data(), input_frames, nullptr, 0); XASSERT(read >= 0); stm->linear_input_buffer->clear(); return !stm->draining; } bool refill_callback_output(cubeb_stream * stm) { bool rv; HRESULT hr; void * output_buffer = nullptr; size_t output_frames = 0; XASSERT(!has_input(stm) && has_output(stm)); rv = get_output_buffer(stm, output_buffer, output_frames); if (!rv) { return rv; } if (stm->draining || output_frames == 0) { return true; } long got = refill(stm, nullptr, 0, output_buffer, output_frames); ALOGV("Output callback: output frames requested: %Iu, got %ld", output_frames, got); XASSERT(got >= 0); XASSERT(size_t(got) == output_frames || stm->draining); hr = stm->render_client->ReleaseBuffer(got, 0); if (FAILED(hr)) { LOG("failed to release buffer: %lx", hr); return false; } return size_t(got) == output_frames || stm->draining; } static unsigned int __stdcall wasapi_stream_render_loop(LPVOID stream) { cubeb_stream * stm = static_cast(stream); std::atomic * emergency_bailout = stm->emergency_bailout; // Signal wasapi_stream_start that we've copied emergency_bailout. BOOL ok = SetEvent(stm->thread_ready_event); if (!ok) { LOG("thread_ready SetEvent failed: %lx", GetLastError()); return 0; } bool is_playing = true; HANDLE wait_array[4] = { stm->shutdown_event, stm->reconfigure_event, stm->refill_event, stm->input_available_event }; HANDLE mmcss_handle = NULL; HRESULT hr = 0; DWORD mmcss_task_index = 0; struct auto_com { auto_com() { HRESULT hr = CoInitializeEx(nullptr, COINIT_MULTITHREADED); XASSERT(SUCCEEDED(hr)); } ~auto_com() { CoUninitialize(); } } com; /* We could consider using "Pro Audio" here for WebAudio and maybe WebRTC. */ mmcss_handle = AvSetMmThreadCharacteristicsA("Audio", &mmcss_task_index); if (!mmcss_handle) { /* This is not fatal, but we might glitch under heavy load. */ LOG("Unable to use mmcss to bump the render thread priority: %lx", GetLastError()); } /* WaitForMultipleObjects timeout can trigger in cases where we don't want to treat it as a timeout, such as across a system sleep/wake cycle. Trigger the timeout error handling only when the timeout_limit is reached, which is reset on each successful loop. */ unsigned timeout_count = 0; const unsigned timeout_limit = 3; while (is_playing) { // We want to check the emergency bailout variable before a // and after the WaitForMultipleObject, because the handles WaitForMultipleObjects // is going to wait on might have been closed already. if (*emergency_bailout) { delete emergency_bailout; return 0; } DWORD waitResult = WaitForMultipleObjects(ARRAY_LENGTH(wait_array), wait_array, FALSE, 1000); if (*emergency_bailout) { delete emergency_bailout; return 0; } if (waitResult != WAIT_TIMEOUT) { timeout_count = 0; } switch (waitResult) { case WAIT_OBJECT_0: { /* shutdown */ is_playing = false; /* We don't check if the drain is actually finished here, we just want to shutdown. */ if (stm->draining) { stm->state_callback(stm, stm->user_ptr, CUBEB_STATE_DRAINED); } continue; } case WAIT_OBJECT_0 + 1: { /* reconfigure */ XASSERT(stm->output_client || stm->input_client); LOG("Reconfiguring the stream"); /* Close the stream */ if (stm->output_client) { stm->output_client->Stop(); LOG("Output stopped."); } if (stm->input_client) { stm->input_client->Stop(); LOG("Input stopped."); } { auto_lock lock(stm->stream_reset_lock); close_wasapi_stream(stm); LOG("Stream closed."); /* Reopen a stream and start it immediately. This will automatically pick the new default device for this role. */ int r = setup_wasapi_stream(stm); if (r != CUBEB_OK) { LOG("Error setting up the stream during reconfigure."); /* Don't destroy the stream here, since we expect the caller to do so after the error has propagated via the state callback. */ is_playing = false; hr = E_FAIL; continue; } LOG("Stream setup successfuly."); } XASSERT(stm->output_client || stm->input_client); if (stm->output_client) { hr = stm->output_client->Start(); if (FAILED(hr)) { LOG("Error starting output after reconfigure, error: %lx", hr); is_playing = false; continue; } LOG("Output started after reconfigure."); } if (stm->input_client) { hr = stm->input_client->Start(); if (FAILED(hr)) { LOG("Error starting input after reconfiguring, error: %lx", hr); is_playing = false; continue; } LOG("Input started after reconfigure."); } break; } case WAIT_OBJECT_0 + 2: /* refill */ XASSERT((has_input(stm) && has_output(stm)) || (!has_input(stm) && has_output(stm))); is_playing = stm->refill_callback(stm); break; case WAIT_OBJECT_0 + 3: /* input available */ if (has_input(stm) && has_output(stm)) { continue; } is_playing = stm->refill_callback(stm); break; case WAIT_TIMEOUT: XASSERT(stm->shutdown_event == wait_array[0]); if (++timeout_count >= timeout_limit) { LOG("Render loop reached the timeout limit."); is_playing = false; hr = E_FAIL; } break; default: LOG("case %lu not handled in render loop.", waitResult); abort(); } } if (FAILED(hr)) { stm->state_callback(stm, stm->user_ptr, CUBEB_STATE_ERROR); } if (mmcss_handle) { AvRevertMmThreadCharacteristics(mmcss_handle); } return 0; } void wasapi_destroy(cubeb * context); HRESULT register_notification_client(cubeb_stream * stm) { HRESULT hr = CoCreateInstance(__uuidof(MMDeviceEnumerator), NULL, CLSCTX_INPROC_SERVER, IID_PPV_ARGS(stm->device_enumerator.receive())); if (FAILED(hr)) { LOG("Could not get device enumerator: %lx", hr); return hr; } stm->notification_client.reset(new wasapi_endpoint_notification_client(stm->reconfigure_event, stm->role)); hr = stm->device_enumerator->RegisterEndpointNotificationCallback(stm->notification_client.get()); if (FAILED(hr)) { LOG("Could not register endpoint notification callback: %lx", hr); stm->notification_client = nullptr; stm->device_enumerator = nullptr; } return hr; } HRESULT unregister_notification_client(cubeb_stream * stm) { XASSERT(stm); HRESULT hr; if (!stm->device_enumerator) { return S_OK; } hr = stm->device_enumerator->UnregisterEndpointNotificationCallback(stm->notification_client.get()); if (FAILED(hr)) { // We can't really do anything here, we'll probably leak the // notification client, but we can at least release the enumerator. stm->device_enumerator = nullptr; return S_OK; } stm->notification_client = nullptr; stm->device_enumerator = nullptr; return S_OK; } HRESULT get_endpoint(com_ptr & device, LPCWSTR devid) { com_ptr enumerator; HRESULT hr = CoCreateInstance(__uuidof(MMDeviceEnumerator), NULL, CLSCTX_INPROC_SERVER, IID_PPV_ARGS(enumerator.receive())); if (FAILED(hr)) { LOG("Could not get device enumerator: %lx", hr); return hr; } hr = enumerator->GetDevice(devid, device.receive()); if (FAILED(hr)) { LOG("Could not get device: %lx", hr); return hr; } return S_OK; } HRESULT register_collection_notification_client(cubeb * context) { HRESULT hr = CoCreateInstance(__uuidof(MMDeviceEnumerator), NULL, CLSCTX_INPROC_SERVER, IID_PPV_ARGS(context->device_collection_enumerator.receive())); if (FAILED(hr)) { LOG("Could not get device enumerator: %lx", hr); return hr; } context->collection_notification_client.reset(new wasapi_collection_notification_client(context)); hr = context->device_collection_enumerator->RegisterEndpointNotificationCallback( context->collection_notification_client.get()); if (FAILED(hr)) { LOG("Could not register endpoint notification callback: %lx", hr); context->collection_notification_client.reset(); context->device_collection_enumerator.reset(); } return hr; } HRESULT unregister_collection_notification_client(cubeb * context) { HRESULT hr = context->device_collection_enumerator-> UnregisterEndpointNotificationCallback(context->collection_notification_client.get()); if (FAILED(hr)) { return hr; } context->collection_notification_client = nullptr; context->device_collection_enumerator = nullptr; return hr; } HRESULT get_default_endpoint(com_ptr & device, EDataFlow direction, ERole role) { com_ptr enumerator; HRESULT hr = CoCreateInstance(__uuidof(MMDeviceEnumerator), NULL, CLSCTX_INPROC_SERVER, IID_PPV_ARGS(enumerator.receive())); if (FAILED(hr)) { LOG("Could not get device enumerator: %lx", hr); return hr; } hr = enumerator->GetDefaultAudioEndpoint(direction, role, device.receive()); if (FAILED(hr)) { LOG("Could not get default audio endpoint: %lx", hr); return hr; } return ERROR_SUCCESS; } double current_stream_delay(cubeb_stream * stm) { stm->stream_reset_lock.assert_current_thread_owns(); /* If the default audio endpoint went away during playback and we weren't able to configure a new one, it's possible the caller may call this before the error callback has propogated back. */ if (!stm->audio_clock) { return 0; } UINT64 freq; HRESULT hr = stm->audio_clock->GetFrequency(&freq); if (FAILED(hr)) { LOG("GetFrequency failed: %lx", hr); return 0; } UINT64 pos; hr = stm->audio_clock->GetPosition(&pos, NULL); if (FAILED(hr)) { LOG("GetPosition failed: %lx", hr); return 0; } double cur_pos = static_cast(pos) / freq; double max_pos = static_cast(stm->frames_written) / stm->output_mix_params.rate; double delay = max_pos - cur_pos; XASSERT(delay >= 0); return delay; } int stream_set_volume(cubeb_stream * stm, float volume) { stm->stream_reset_lock.assert_current_thread_owns(); if (!stm->audio_stream_volume) { return CUBEB_ERROR; } uint32_t channels; HRESULT hr = stm->audio_stream_volume->GetChannelCount(&channels); if (FAILED(hr)) { LOG("could not get the channel count: %lx", hr); return CUBEB_ERROR; } /* up to 9.1 for now */ if (channels > 10) { return CUBEB_ERROR_NOT_SUPPORTED; } float volumes[10]; for (uint32_t i = 0; i < channels; i++) { volumes[i] = volume; } hr = stm->audio_stream_volume->SetAllVolumes(channels, volumes); if (FAILED(hr)) { LOG("could not set the channels volume: %lx", hr); return CUBEB_ERROR; } return CUBEB_OK; } } // namespace anonymous extern "C" { int wasapi_init(cubeb ** context, char const * context_name) { /* We don't use the device yet, but need to make sure we can initialize one so that this backend is not incorrectly enabled on platforms that don't support WASAPI. */ com_ptr device; HRESULT hr = get_default_endpoint(device, eRender, eConsole); if (FAILED(hr)) { XASSERT(hr != CO_E_NOTINITIALIZED); LOG("It wasn't able to find a default rendering device: %lx", hr); hr = get_default_endpoint(device, eCapture, eConsole); if (FAILED(hr)) { LOG("It wasn't able to find a default capture device: %lx", hr); return CUBEB_ERROR; } } cubeb * ctx = new cubeb(); ctx->ops = &wasapi_ops; if (cubeb_strings_init(&ctx->device_ids) != CUBEB_OK) { delete ctx; return CUBEB_ERROR; } *context = ctx; return CUBEB_OK; } } namespace { bool stop_and_join_render_thread(cubeb_stream * stm) { bool rv = true; LOG("Stop and join render thread."); if (!stm->thread) { LOG("No thread present."); return true; } // If we've already leaked the thread, just return, // there is not much we can do. if (!stm->emergency_bailout.load()) { return false; } BOOL ok = SetEvent(stm->shutdown_event); if (!ok) { LOG("Destroy SetEvent failed: %lx", GetLastError()); } /* Wait five seconds for the rendering thread to return. It's supposed to * check its event loop very often, five seconds is rather conservative. */ DWORD r = WaitForSingleObject(stm->thread, 5000); if (r != WAIT_OBJECT_0) { /* Something weird happened, leak the thread and continue the shutdown * process. */ *(stm->emergency_bailout) = true; // We give the ownership to the rendering thread. stm->emergency_bailout = nullptr; LOG("Destroy WaitForSingleObject on thread failed: %lx, %lx", r, GetLastError()); rv = false; } // Only attempts to close and null out the thread and event if the // WaitForSingleObject above succeeded, so that calling this function again // attemps to clean up the thread and event each time. if (rv) { LOG("Closing thread."); CloseHandle(stm->thread); stm->thread = NULL; CloseHandle(stm->shutdown_event); stm->shutdown_event = 0; } return rv; } void wasapi_destroy(cubeb * context) { if (context->device_ids) { cubeb_strings_destroy(context->device_ids); } delete context; } char const * wasapi_get_backend_id(cubeb * context) { return "wasapi"; } int wasapi_get_max_channel_count(cubeb * ctx, uint32_t * max_channels) { XASSERT(ctx && max_channels); com_ptr device; HRESULT hr = get_default_endpoint(device, eRender, eConsole); if (FAILED(hr)) { return CUBEB_ERROR; } com_ptr client; hr = device->Activate(__uuidof(IAudioClient), CLSCTX_INPROC_SERVER, NULL, client.receive_vpp()); if (FAILED(hr)) { return CUBEB_ERROR; } WAVEFORMATEX * tmp = nullptr; hr = client->GetMixFormat(&tmp); if (FAILED(hr)) { return CUBEB_ERROR; } com_heap_ptr mix_format(tmp); *max_channels = mix_format->nChannels; return CUBEB_OK; } int wasapi_get_min_latency(cubeb * ctx, cubeb_stream_params params, uint32_t * latency_frames) { if (params.format != CUBEB_SAMPLE_FLOAT32NE && params.format != CUBEB_SAMPLE_S16NE) { return CUBEB_ERROR_INVALID_FORMAT; } ERole role = pref_to_role(params.prefs); com_ptr device; HRESULT hr = get_default_endpoint(device, eRender, role); if (FAILED(hr)) { LOG("Could not get default endpoint: %lx", hr); return CUBEB_ERROR; } com_ptr client; hr = device->Activate(__uuidof(IAudioClient), CLSCTX_INPROC_SERVER, NULL, client.receive_vpp()); if (FAILED(hr)) { LOG("Could not activate device for latency: %lx", hr); return CUBEB_ERROR; } REFERENCE_TIME minimum_period; REFERENCE_TIME default_period; hr = client->GetDevicePeriod(&default_period, &minimum_period); if (FAILED(hr)) { LOG("Could not get device period: %lx", hr); return CUBEB_ERROR; } LOG("default device period: %I64d, minimum device period: %I64d", default_period, minimum_period); /* If we're on Windows 10, we can use IAudioClient3 to get minimal latency. Otherwise, according to the docs, the best latency we can achieve is by synchronizing the stream and the engine. http://msdn.microsoft.com/en-us/library/windows/desktop/dd370871%28v=vs.85%29.aspx */ #ifdef _WIN32_WINNT_WIN10 *latency_frames = hns_to_frames(params.rate, minimum_period); #else *latency_frames = hns_to_frames(params.rate, default_period); #endif LOG("Minimum latency in frames: %u", *latency_frames); return CUBEB_OK; } int wasapi_get_preferred_sample_rate(cubeb * ctx, uint32_t * rate) { com_ptr device; HRESULT hr = get_default_endpoint(device, eRender, eConsole); if (FAILED(hr)) { return CUBEB_ERROR; } com_ptr client; hr = device->Activate(__uuidof(IAudioClient), CLSCTX_INPROC_SERVER, NULL, client.receive_vpp()); if (FAILED(hr)) { return CUBEB_ERROR; } WAVEFORMATEX * tmp = nullptr; hr = client->GetMixFormat(&tmp); if (FAILED(hr)) { return CUBEB_ERROR; } com_heap_ptr mix_format(tmp); *rate = mix_format->nSamplesPerSec; LOG("Preferred sample rate for output: %u", *rate); return CUBEB_OK; } void wasapi_stream_destroy(cubeb_stream * stm); static void waveformatex_update_derived_properties(WAVEFORMATEX * format) { format->nBlockAlign = format->wBitsPerSample * format->nChannels / 8; format->nAvgBytesPerSec = format->nSamplesPerSec * format->nBlockAlign; if (format->wFormatTag == WAVE_FORMAT_EXTENSIBLE) { WAVEFORMATEXTENSIBLE * format_pcm = reinterpret_cast(format); format_pcm->Samples.wValidBitsPerSample = format->wBitsPerSample; } } /* Based on the mix format and the stream format, try to find a way to play what the user requested. */ static void handle_channel_layout(cubeb_stream * stm, EDataFlow direction, com_heap_ptr & mix_format, const cubeb_stream_params * stream_params) { com_ptr & audio_client = (direction == eRender) ? stm->output_client : stm->input_client; XASSERT(audio_client); /* The docs say that GetMixFormat is always of type WAVEFORMATEXTENSIBLE [1], so the reinterpret_cast below should be safe. In practice, this is not true, and we just want to bail out and let the rest of the code find a good conversion path instead of trying to make WASAPI do it by itself. [1]: http://msdn.microsoft.com/en-us/library/windows/desktop/dd370811%28v=vs.85%29.aspx*/ if (mix_format->wFormatTag != WAVE_FORMAT_EXTENSIBLE) { return; } WAVEFORMATEXTENSIBLE * format_pcm = reinterpret_cast(mix_format.get()); /* Stash a copy of the original mix format in case we need to restore it later. */ WAVEFORMATEXTENSIBLE hw_mix_format = *format_pcm; /* Get the channel mask by the channel layout. If the layout is not supported, we will get a closest settings below. */ format_pcm->dwChannelMask = stream_params->layout; mix_format->nChannels = stream_params->channels; waveformatex_update_derived_properties(mix_format.get()); /* Check if wasapi will accept our channel layout request. */ WAVEFORMATEX * closest; HRESULT hr = audio_client->IsFormatSupported(AUDCLNT_SHAREMODE_SHARED, mix_format.get(), &closest); if (hr == S_FALSE) { /* Channel layout not supported, but WASAPI gives us a suggestion. Use it, and handle the eventual upmix/downmix ourselves. Ignore the subformat of the suggestion, since it seems to always be IEEE_FLOAT. */ LOG("Using WASAPI suggested format: channels: %d", closest->nChannels); XASSERT(closest->wFormatTag == WAVE_FORMAT_EXTENSIBLE); WAVEFORMATEXTENSIBLE * closest_pcm = reinterpret_cast(closest); format_pcm->dwChannelMask = closest_pcm->dwChannelMask; mix_format->nChannels = closest->nChannels; waveformatex_update_derived_properties(mix_format.get()); } else if (hr == AUDCLNT_E_UNSUPPORTED_FORMAT) { /* Not supported, no suggestion. This should not happen, but it does in the field with some sound cards. We restore the mix format, and let the rest of the code figure out the right conversion path. */ XASSERT(mix_format->wFormatTag == WAVE_FORMAT_EXTENSIBLE); *reinterpret_cast(mix_format.get()) = hw_mix_format; } else if (hr == S_OK) { LOG("Requested format accepted by WASAPI."); } else { LOG("IsFormatSupported unhandled error: %lx", hr); } } static bool initialize_iaudioclient3(com_ptr & audio_client, cubeb_stream * stm, const com_heap_ptr & mix_format, DWORD flags, EDataFlow direction) { com_ptr audio_client3; audio_client->QueryInterface(audio_client3.receive()); if (!audio_client3) { LOG("Could not get IAudioClient3 interface"); return false; } if (flags & AUDCLNT_STREAMFLAGS_LOOPBACK) { // IAudioClient3 doesn't work with loopback streams, and will return error // 88890021: AUDCLNT_E_INVALID_STREAM_FLAG LOG("Audio stream is loopback, not using IAudioClient3"); return false; } // IAudioClient3 doesn't support AUDCLNT_STREAMFLAGS_NOPERSIST, and will return // AUDCLNT_E_INVALID_STREAM_FLAG. This is undocumented. flags = flags ^ AUDCLNT_STREAMFLAGS_NOPERSIST; // Some people have reported glitches with capture streams: // http://blog.nirbheek.in/2018/03/low-latency-audio-on-windows-with.html if (direction == eCapture) { LOG("Audio stream is capture, not using IAudioClient3"); return false; } // Possibly initialize a shared-mode stream using IAudioClient3. Initializing // a stream this way lets you request lower latencies, but also locks the global // WASAPI engine at that latency. // - If we request a shared-mode stream, streams created with IAudioClient will // have their latency adjusted to match. When the shared-mode stream is // closed, they'll go back to normal. // - If there's already a shared-mode stream running, then we cannot request // the engine change to a different latency - we have to match it. // - It's antisocial to lock the WASAPI engine at its default latency. If we // would do this, then stop and use IAudioClient instead. HRESULT hr; uint32_t default_period = 0, fundamental_period = 0, min_period = 0, max_period = 0; hr = audio_client3->GetSharedModeEnginePeriod(mix_format.get(), &default_period, &fundamental_period, &min_period, &max_period); if (FAILED(hr)) { LOG("Could not get shared mode engine period: error: %lx", hr); return false; } uint32_t requested_latency = stm->latency; if (requested_latency >= default_period) { LOG("Requested latency %i greater than default latency %i, not using IAudioClient3", requested_latency, default_period); return false; } LOG("Got shared mode engine period: default=%i fundamental=%i min=%i max=%i", default_period, fundamental_period, min_period, max_period); // Snap requested latency to a valid value uint32_t old_requested_latency = requested_latency; if (requested_latency < min_period) { requested_latency = min_period; } requested_latency -= (requested_latency - min_period) % fundamental_period; if (requested_latency != old_requested_latency) { LOG("Requested latency %i was adjusted to %i", old_requested_latency, requested_latency); } hr = audio_client3->InitializeSharedAudioStream(flags, requested_latency, mix_format.get(), NULL); if (SUCCEEDED(hr)) { return true; } else if (hr == AUDCLNT_E_ENGINE_PERIODICITY_LOCKED) { LOG("Got AUDCLNT_E_ENGINE_PERIODICITY_LOCKED, adjusting latency request"); } else { LOG("Could not initialize shared stream with IAudioClient3: error: %lx", hr); return false; } uint32_t current_period = 0; WAVEFORMATEX* current_format = nullptr; // We have to pass a valid WAVEFORMATEX** and not nullptr, otherwise // GetCurrentSharedModeEnginePeriod will return E_POINTER hr = audio_client3->GetCurrentSharedModeEnginePeriod(¤t_format, ¤t_period); CoTaskMemFree(current_format); if (FAILED(hr)) { LOG("Could not get current shared mode engine period: error: %lx", hr); return false; } if (current_period >= default_period) { LOG("Current shared mode engine period %i too high, not using IAudioClient", current_period); return false; } hr = audio_client3->InitializeSharedAudioStream(flags, current_period, mix_format.get(), NULL); if (SUCCEEDED(hr)) { LOG("Current shared mode engine period is %i instead of requested %i", current_period, requested_latency); return true; } LOG("Could not initialize shared stream with IAudioClient3: error: %lx", hr); return false; } #define DIRECTION_NAME (direction == eCapture ? "capture" : "render") template int setup_wasapi_stream_one_side(cubeb_stream * stm, cubeb_stream_params * stream_params, wchar_t const * devid, EDataFlow direction, REFIID riid, com_ptr & audio_client, uint32_t * buffer_frame_count, HANDLE & event, T & render_or_capture_client, cubeb_stream_params * mix_params) { com_ptr device; HRESULT hr; bool is_loopback = stream_params->prefs & CUBEB_STREAM_PREF_LOOPBACK; if (is_loopback && direction != eCapture) { LOG("Loopback pref can only be used with capture streams!\n"); return CUBEB_ERROR; } stm->stream_reset_lock.assert_current_thread_owns(); bool try_again = false; // This loops until we find a device that works, or we've exhausted all // possibilities. do { if (devid) { hr = get_endpoint(device, devid); if (FAILED(hr)) { LOG("Could not get %s endpoint, error: %lx\n", DIRECTION_NAME, hr); return CUBEB_ERROR; } } else { // If caller has requested loopback but not specified a device, look for // the default render device. Otherwise look for the default device // appropriate to the direction. hr = get_default_endpoint(device, is_loopback ? eRender : direction, pref_to_role(stream_params->prefs)); if (FAILED(hr)) { if (is_loopback) { LOG("Could not get default render endpoint for loopback, error: %lx\n", hr); } else { LOG("Could not get default %s endpoint, error: %lx\n", DIRECTION_NAME, hr); } return CUBEB_ERROR; } } /* Get a client. We will get all other interfaces we need from * this pointer. */ // hr = device->Activate(__uuidof(IAudioClient3), // CLSCTX_INPROC_SERVER, // NULL, audio_client.receive_vpp()); // if (hr == E_NOINTERFACE) { hr = device->Activate(__uuidof(IAudioClient), CLSCTX_INPROC_SERVER, NULL, audio_client.receive_vpp()); //} if (FAILED(hr)) { LOG("Could not activate the device to get an audio" " client for %s: error: %lx\n", DIRECTION_NAME, hr); // A particular device can't be activated because it has been // unplugged, try fall back to the default audio device. if (devid && hr == AUDCLNT_E_DEVICE_INVALIDATED) { LOG("Trying again with the default %s audio device.", DIRECTION_NAME); devid = nullptr; device = nullptr; try_again = true; } else { return CUBEB_ERROR; } } else { try_again = false; } } while (try_again); /* We have to distinguish between the format the mixer uses, * and the format the stream we want to play uses. */ WAVEFORMATEX * tmp = nullptr; hr = audio_client->GetMixFormat(&tmp); if (FAILED(hr)) { LOG("Could not fetch current mix format from the audio" " client for %s: error: %lx", DIRECTION_NAME, hr); return CUBEB_ERROR; } com_heap_ptr mix_format(tmp); mix_format->wBitsPerSample = stm->bytes_per_sample * 8; if (mix_format->wFormatTag == WAVE_FORMAT_EXTENSIBLE) { WAVEFORMATEXTENSIBLE * format_pcm = reinterpret_cast(mix_format.get()); format_pcm->SubFormat = stm->waveformatextensible_sub_format; } waveformatex_update_derived_properties(mix_format.get()); /* Set channel layout only when there're more than two channels. Otherwise, * use the default setting retrieved from the stream format of the audio * engine's internal processing by GetMixFormat. */ if (mix_format->nChannels > 2) { handle_channel_layout(stm, direction, mix_format, stream_params); } mix_params->format = stream_params->format; mix_params->rate = mix_format->nSamplesPerSec; mix_params->channels = mix_format->nChannels; mix_params->layout = mask_to_channel_layout(mix_format.get()); LOG("Setup requested=[f=%d r=%u c=%u l=%u] mix=[f=%d r=%u c=%u l=%u]", stream_params->format, stream_params->rate, stream_params->channels, stream_params->layout, mix_params->format, mix_params->rate, mix_params->channels, mix_params->layout); DWORD flags = AUDCLNT_STREAMFLAGS_NOPERSIST; // Check if a loopback device should be requested. Note that event callbacks // do not work with loopback devices, so only request these if not looping. if (is_loopback) { flags |= AUDCLNT_STREAMFLAGS_LOOPBACK; } else { flags |= AUDCLNT_STREAMFLAGS_EVENTCALLBACK; } // if (initialize_iaudioclient3(audio_client, stm, mix_format, flags, direction)) { // LOG("Initialized with IAudioClient3"); // } else { hr = audio_client->Initialize(AUDCLNT_SHAREMODE_SHARED, flags, frames_to_hns(stm, stm->latency), 0, mix_format.get(), NULL); // } if (FAILED(hr)) { LOG("Unable to initialize audio client for %s: %lx.", DIRECTION_NAME, hr); return CUBEB_ERROR; } hr = audio_client->GetBufferSize(buffer_frame_count); if (FAILED(hr)) { LOG("Could not get the buffer size from the client" " for %s %lx.", DIRECTION_NAME, hr); return CUBEB_ERROR; } // Events are used if not looping back if (!is_loopback) { hr = audio_client->SetEventHandle(event); if (FAILED(hr)) { LOG("Could set the event handle for the %s client %lx.", DIRECTION_NAME, hr); return CUBEB_ERROR; } } hr = audio_client->GetService(riid, render_or_capture_client.receive_vpp()); if (FAILED(hr)) { LOG("Could not get the %s client %lx.", DIRECTION_NAME, hr); return CUBEB_ERROR; } return CUBEB_OK; } #undef DIRECTION_NAME int setup_wasapi_stream(cubeb_stream * stm) { int rv; stm->stream_reset_lock.assert_current_thread_owns(); XASSERT((!stm->output_client || !stm->input_client) && "WASAPI stream already setup, close it first."); if (has_input(stm)) { LOG("(%p) Setup capture: device=%p", stm, stm->input_device.get()); rv = setup_wasapi_stream_one_side(stm, &stm->input_stream_params, stm->input_device.get(), eCapture, __uuidof(IAudioCaptureClient), stm->input_client, &stm->input_buffer_frame_count, stm->input_available_event, stm->capture_client, &stm->input_mix_params); if (rv != CUBEB_OK) { LOG("Failure to open the input side."); return rv; } // We initializing an input stream, buffer ahead two buffers worth of silence. // This delays the input side slightly, but allow to not glitch when no input // is available when calling into the resampler to call the callback: the input // refill event will be set shortly after to compensate for this lack of data. // In debug, four buffers are used, to avoid tripping up assertions down the line. #if !defined(DEBUG) const int silent_buffer_count = 2; #else const int silent_buffer_count = 6; #endif stm->linear_input_buffer->push_silence(stm->input_buffer_frame_count * stm->input_stream_params.channels * silent_buffer_count); } // If we don't have an output device but are requesting a loopback device, // we attempt to open that same device in output mode in order to drive the // loopback via the output events. stm->has_dummy_output = false; if (!has_output(stm) && stm->input_stream_params.prefs & CUBEB_STREAM_PREF_LOOPBACK) { stm->output_stream_params.rate = stm->input_stream_params.rate; stm->output_stream_params.channels = stm->input_stream_params.channels; stm->output_stream_params.layout = stm->input_stream_params.layout; if (stm->input_device) { size_t len = wcslen(stm->input_device.get()); std::unique_ptr tmp(new wchar_t[len + 1]); if (wcsncpy_s(tmp.get(), len + 1, stm->input_device.get(), len) != 0) { LOG("Failed to copy device identifier while copying input stream" " configuration to output stream configuration to drive loopback."); return CUBEB_ERROR; } stm->output_device = move(tmp); } stm->has_dummy_output = true; } if (has_output(stm)) { LOG("(%p) Setup render: device=%p", stm, stm->output_device.get()); rv = setup_wasapi_stream_one_side(stm, &stm->output_stream_params, stm->output_device.get(), eRender, __uuidof(IAudioRenderClient), stm->output_client, &stm->output_buffer_frame_count, stm->refill_event, stm->render_client, &stm->output_mix_params); if (rv != CUBEB_OK) { LOG("Failure to open the output side."); return rv; } HRESULT hr = stm->output_client->GetService(__uuidof(IAudioStreamVolume), stm->audio_stream_volume.receive_vpp()); if (FAILED(hr)) { LOG("Could not get the IAudioStreamVolume: %lx", hr); return CUBEB_ERROR; } XASSERT(stm->frames_written == 0); hr = stm->output_client->GetService(__uuidof(IAudioClock), stm->audio_clock.receive_vpp()); if (FAILED(hr)) { LOG("Could not get the IAudioClock: %lx", hr); return CUBEB_ERROR; } /* Restore the stream volume over a device change. */ if (stream_set_volume(stm, stm->volume) != CUBEB_OK) { LOG("Could not set the volume."); return CUBEB_ERROR; } } /* If we have both input and output, we resample to * the highest sample rate available. */ int32_t target_sample_rate; if (has_input(stm) && has_output(stm)) { XASSERT(stm->input_stream_params.rate == stm->output_stream_params.rate); target_sample_rate = stm->input_stream_params.rate; } else if (has_input(stm)) { target_sample_rate = stm->input_stream_params.rate; } else { XASSERT(has_output(stm)); target_sample_rate = stm->output_stream_params.rate; } LOG("Target sample rate: %d", target_sample_rate); /* If we are playing/capturing a mono stream, we only resample one channel, and copy it over, so we are always resampling the number of channels of the stream, not the number of channels that WASAPI wants. */ cubeb_stream_params input_params = stm->input_mix_params; input_params.channels = stm->input_stream_params.channels; cubeb_stream_params output_params = stm->output_mix_params; output_params.channels = stm->output_stream_params.channels; stm->resampler.reset( cubeb_resampler_create(stm, has_input(stm) ? &input_params : nullptr, has_output(stm) ? &output_params : nullptr, target_sample_rate, stm->data_callback, stm->user_ptr, CUBEB_RESAMPLER_QUALITY_DESKTOP)); if (!stm->resampler) { LOG("Could not get a resampler"); return CUBEB_ERROR; } XASSERT(has_input(stm) || has_output(stm)); if (has_input(stm) && has_output(stm)) { stm->refill_callback = refill_callback_duplex; } else if (has_input(stm)) { stm->refill_callback = refill_callback_input; } else if (has_output(stm)) { stm->refill_callback = refill_callback_output; } // Create input mixer. if (has_input(stm) && ((stm->input_mix_params.layout != CUBEB_LAYOUT_UNDEFINED && stm->input_mix_params.layout != stm->input_stream_params.layout) || (stm->input_mix_params.channels != stm->input_stream_params.channels))) { if (stm->input_mix_params.layout == CUBEB_LAYOUT_UNDEFINED) { LOG("Input stream using undefined layout! Any mixing may be " "unpredictable!\n"); } stm->input_mixer.reset(cubeb_mixer_create(stm->input_stream_params.format, stm->input_mix_params.channels, stm->input_mix_params.layout, stm->input_stream_params.channels, stm->input_stream_params.layout)); assert(stm->input_mixer); } // Create output mixer. if (has_output(stm) && stm->output_mix_params.layout != stm->output_stream_params.layout) { if (stm->output_mix_params.layout == CUBEB_LAYOUT_UNDEFINED) { LOG("Output stream using undefined layout! Any mixing may be unpredictable!\n"); } stm->output_mixer.reset(cubeb_mixer_create(stm->output_stream_params.format, stm->output_stream_params.channels, stm->output_stream_params.layout, stm->output_mix_params.channels, stm->output_mix_params.layout)); assert(stm->output_mixer); // Input is up/down mixed when depacketized in get_input_buffer. stm->mix_buffer.resize( frames_to_bytes_before_mix(stm, stm->output_buffer_frame_count)); } return CUBEB_OK; } ERole pref_to_role(cubeb_stream_prefs prefs) { if (prefs & CUBEB_STREAM_PREF_VOICE) { return eCommunications; } return eConsole; } int wasapi_stream_init(cubeb * context, cubeb_stream ** stream, char const * stream_name, cubeb_devid input_device, cubeb_stream_params * input_stream_params, cubeb_devid output_device, cubeb_stream_params * output_stream_params, unsigned int latency_frames, cubeb_data_callback data_callback, cubeb_state_callback state_callback, void * user_ptr) { int rv; XASSERT(context && stream && (input_stream_params || output_stream_params)); if (output_stream_params && input_stream_params && output_stream_params->format != input_stream_params->format) { return CUBEB_ERROR_INVALID_FORMAT; } std::unique_ptr stm(new cubeb_stream(), wasapi_stream_destroy); stm->context = context; stm->data_callback = data_callback; stm->state_callback = state_callback; stm->user_ptr = user_ptr; if (stm->output_stream_params.prefs & CUBEB_STREAM_PREF_VOICE || stm->input_stream_params.prefs & CUBEB_STREAM_PREF_VOICE) { stm->role = eCommunications; } else { stm->role = eConsole; } if (input_stream_params) { stm->input_stream_params = *input_stream_params; stm->input_device = utf8_to_wstr(reinterpret_cast(input_device)); } if (output_stream_params) { stm->output_stream_params = *output_stream_params; stm->output_device = utf8_to_wstr(reinterpret_cast(output_device)); } switch (output_stream_params ? output_stream_params->format : input_stream_params->format) { case CUBEB_SAMPLE_S16NE: stm->bytes_per_sample = sizeof(short); stm->waveformatextensible_sub_format = KSDATAFORMAT_SUBTYPE_PCM; stm->linear_input_buffer.reset(new auto_array_wrapper_impl); break; case CUBEB_SAMPLE_FLOAT32NE: stm->bytes_per_sample = sizeof(float); stm->waveformatextensible_sub_format = KSDATAFORMAT_SUBTYPE_IEEE_FLOAT; stm->linear_input_buffer.reset(new auto_array_wrapper_impl); break; default: return CUBEB_ERROR_INVALID_FORMAT; } stm->latency = latency_frames; stm->reconfigure_event = CreateEvent(NULL, 0, 0, NULL); if (!stm->reconfigure_event) { LOG("Can't create the reconfigure event, error: %lx", GetLastError()); return CUBEB_ERROR; } /* Unconditionally create the two events so that the wait logic is simpler. */ stm->refill_event = CreateEvent(NULL, 0, 0, NULL); if (!stm->refill_event) { LOG("Can't create the refill event, error: %lx", GetLastError()); return CUBEB_ERROR; } stm->input_available_event = CreateEvent(NULL, 0, 0, NULL); if (!stm->input_available_event) { LOG("Can't create the input available event , error: %lx", GetLastError()); return CUBEB_ERROR; } { /* Locking here is not strictly necessary, because we don't have a notification client that can reset the stream yet, but it lets us assert that the lock is held in the function. */ auto_lock lock(stm->stream_reset_lock); rv = setup_wasapi_stream(stm.get()); } if (rv != CUBEB_OK) { return rv; } if (!((input_stream_params ? (input_stream_params->prefs & CUBEB_STREAM_PREF_DISABLE_DEVICE_SWITCHING) : 0) || (output_stream_params ? (output_stream_params->prefs & CUBEB_STREAM_PREF_DISABLE_DEVICE_SWITCHING) : 0))) { HRESULT hr = register_notification_client(stm.get()); if (FAILED(hr)) { /* this is not fatal, we can still play audio, but we won't be able to keep using the default audio endpoint if it changes. */ LOG("failed to register notification client, %lx", hr); } } *stream = stm.release(); LOG("Stream init succesfull (%p)", *stream); return CUBEB_OK; } void close_wasapi_stream(cubeb_stream * stm) { XASSERT(stm); stm->stream_reset_lock.assert_current_thread_owns(); stm->output_client = nullptr; stm->render_client = nullptr; stm->input_client = nullptr; stm->capture_client = nullptr; stm->audio_stream_volume = nullptr; stm->audio_clock = nullptr; stm->total_frames_written += static_cast(round(stm->frames_written * stream_to_mix_samplerate_ratio(stm->output_stream_params, stm->output_mix_params))); stm->frames_written = 0; stm->resampler.reset(); stm->output_mixer.reset(); stm->input_mixer.reset(); stm->mix_buffer.clear(); } void wasapi_stream_destroy(cubeb_stream * stm) { XASSERT(stm); LOG("Stream destroy (%p)", stm); // Only free stm->emergency_bailout if we could join the thread. // If we could not join the thread, stm->emergency_bailout is true // and is still alive until the thread wakes up and exits cleanly. if (stop_and_join_render_thread(stm)) { delete stm->emergency_bailout.load(); stm->emergency_bailout = nullptr; } if (stm->notification_client) { unregister_notification_client(stm); } CloseHandle(stm->reconfigure_event); CloseHandle(stm->refill_event); CloseHandle(stm->input_available_event); // The variables intialized in wasapi_stream_init, // must be destroyed in wasapi_stream_destroy. stm->linear_input_buffer.reset(); { auto_lock lock(stm->stream_reset_lock); close_wasapi_stream(stm); } delete stm; } enum StreamDirection { OUTPUT, INPUT }; int stream_start_one_side(cubeb_stream * stm, StreamDirection dir) { XASSERT((dir == OUTPUT && stm->output_client) || (dir == INPUT && stm->input_client)); HRESULT hr = dir == OUTPUT ? stm->output_client->Start() : stm->input_client->Start(); if (hr == AUDCLNT_E_DEVICE_INVALIDATED) { LOG("audioclient invalidated for %s device, reconfiguring", dir == OUTPUT ? "output" : "input"); BOOL ok = ResetEvent(stm->reconfigure_event); if (!ok) { LOG("resetting reconfig event failed for %s stream: %lx", dir == OUTPUT ? "output" : "input", GetLastError()); } close_wasapi_stream(stm); int r = setup_wasapi_stream(stm); if (r != CUBEB_OK) { LOG("reconfigure failed"); return r; } HRESULT hr2 = dir == OUTPUT ? stm->output_client->Start() : stm->input_client->Start(); if (FAILED(hr2)) { LOG("could not start the %s stream after reconfig: %lx", dir == OUTPUT ? "output" : "input", hr); return CUBEB_ERROR; } } else if (FAILED(hr)) { LOG("could not start the %s stream: %lx.", dir == OUTPUT ? "output" : "input", hr); return CUBEB_ERROR; } return CUBEB_OK; } int wasapi_stream_start(cubeb_stream * stm) { auto_lock lock(stm->stream_reset_lock); XASSERT(stm && !stm->thread && !stm->shutdown_event); XASSERT(stm->output_client || stm->input_client); stm->emergency_bailout = new std::atomic(false); if (stm->output_client) { int rv = stream_start_one_side(stm, OUTPUT); if (rv != CUBEB_OK) { return rv; } } if (stm->input_client) { int rv = stream_start_one_side(stm, INPUT); if (rv != CUBEB_OK) { return rv; } } stm->shutdown_event = CreateEvent(NULL, 0, 0, NULL); if (!stm->shutdown_event) { LOG("Can't create the shutdown event, error: %lx", GetLastError()); return CUBEB_ERROR; } stm->thread_ready_event = CreateEvent(NULL, 0, 0, NULL); if (!stm->thread_ready_event) { LOG("Can't create the thread_ready event, error: %lx", GetLastError()); return CUBEB_ERROR; } cubeb_async_log_reset_threads(); stm->thread = (HANDLE) _beginthreadex(NULL, 512 * 1024, wasapi_stream_render_loop, stm, STACK_SIZE_PARAM_IS_A_RESERVATION, NULL); if (stm->thread == NULL) { LOG("could not create WASAPI render thread."); return CUBEB_ERROR; } // Wait for wasapi_stream_render_loop to signal that emergency_bailout has // been read, avoiding a bailout situation where we could free `stm` // before wasapi_stream_render_loop had a chance to run. HRESULT hr = WaitForSingleObject(stm->thread_ready_event, INFINITE); XASSERT(hr == WAIT_OBJECT_0); CloseHandle(stm->thread_ready_event); stm->thread_ready_event = 0; stm->state_callback(stm, stm->user_ptr, CUBEB_STATE_STARTED); return CUBEB_OK; } int wasapi_stream_stop(cubeb_stream * stm) { XASSERT(stm); HRESULT hr; { auto_lock lock(stm->stream_reset_lock); if (stm->output_client) { hr = stm->output_client->Stop(); if (FAILED(hr)) { LOG("could not stop AudioClient (output)"); return CUBEB_ERROR; } } if (stm->input_client) { hr = stm->input_client->Stop(); if (FAILED(hr)) { LOG("could not stop AudioClient (input)"); return CUBEB_ERROR; } } stm->state_callback(stm, stm->user_ptr, CUBEB_STATE_STOPPED); } if (stop_and_join_render_thread(stm)) { delete stm->emergency_bailout.load(); stm->emergency_bailout = nullptr; } else { // If we could not join the thread, put the stream in error. stm->state_callback(stm, stm->user_ptr, CUBEB_STATE_ERROR); return CUBEB_ERROR; } return CUBEB_OK; } int wasapi_stream_reset_default_device(cubeb_stream * stm) { XASSERT(stm && stm->reconfigure_event); BOOL ok = SetEvent(stm->reconfigure_event); if (!ok) { LOG("SetEvent on reconfigure_event failed: %lx", GetLastError()); return CUBEB_ERROR; } return CUBEB_OK; } int wasapi_stream_get_position(cubeb_stream * stm, uint64_t * position) { XASSERT(stm && position); auto_lock lock(stm->stream_reset_lock); if (!has_output(stm)) { return CUBEB_ERROR; } /* Calculate how far behind the current stream head the playback cursor is. */ uint64_t stream_delay = static_cast(current_stream_delay(stm) * stm->output_stream_params.rate); /* Calculate the logical stream head in frames at the stream sample rate. */ uint64_t max_pos = stm->total_frames_written + static_cast(round(stm->frames_written * stream_to_mix_samplerate_ratio(stm->output_stream_params, stm->output_mix_params))); *position = max_pos; if (stream_delay <= *position) { *position -= stream_delay; } if (*position < stm->prev_position) { *position = stm->prev_position; } stm->prev_position = *position; return CUBEB_OK; } int wasapi_stream_get_latency(cubeb_stream * stm, uint32_t * latency) { XASSERT(stm && latency); if (!has_output(stm)) { return CUBEB_ERROR; } auto_lock lock(stm->stream_reset_lock); /* The GetStreamLatency method only works if the AudioClient has been initialized. */ if (!stm->output_client) { return CUBEB_ERROR; } REFERENCE_TIME latency_hns; HRESULT hr = stm->output_client->GetStreamLatency(&latency_hns); if (FAILED(hr)) { return CUBEB_ERROR; } *latency = hns_to_frames(stm, latency_hns); return CUBEB_OK; } int wasapi_stream_set_volume(cubeb_stream * stm, float volume) { auto_lock lock(stm->stream_reset_lock); if (!has_output(stm)) { return CUBEB_ERROR; } if (stream_set_volume(stm, volume) != CUBEB_OK) { return CUBEB_ERROR; } stm->volume = volume; return CUBEB_OK; } static char const * wstr_to_utf8(LPCWSTR str) { int size = ::WideCharToMultiByte(CP_UTF8, 0, str, -1, nullptr, 0, NULL, NULL); if (size <= 0) { return nullptr; } char * ret = static_cast(malloc(size)); ::WideCharToMultiByte(CP_UTF8, 0, str, -1, ret, size, NULL, NULL); return ret; } static std::unique_ptr utf8_to_wstr(char const * str) { int size = ::MultiByteToWideChar(CP_UTF8, 0, str, -1, nullptr, 0); if (size <= 0) { return nullptr; } std::unique_ptr ret(new wchar_t[size]); ::MultiByteToWideChar(CP_UTF8, 0, str, -1, ret.get(), size); return ret; } static com_ptr wasapi_get_device_node(IMMDeviceEnumerator * enumerator, IMMDevice * dev) { com_ptr ret; com_ptr devtopo; com_ptr connector; if (SUCCEEDED(dev->Activate(__uuidof(IDeviceTopology), CLSCTX_ALL, NULL, devtopo.receive_vpp())) && SUCCEEDED(devtopo->GetConnector(0, connector.receive()))) { wchar_t * tmp = nullptr; if (SUCCEEDED(connector->GetDeviceIdConnectedTo(&tmp))) { com_heap_ptr filterid(tmp); if (FAILED(enumerator->GetDevice(filterid.get(), ret.receive()))) ret = NULL; } } return ret; } static BOOL wasapi_is_default_device(EDataFlow flow, ERole role, LPCWSTR device_id, IMMDeviceEnumerator * enumerator) { BOOL ret = FALSE; com_ptr dev; HRESULT hr; hr = enumerator->GetDefaultAudioEndpoint(flow, role, dev.receive()); if (SUCCEEDED(hr)) { wchar_t * tmp = nullptr; if (SUCCEEDED(dev->GetId(&tmp))) { com_heap_ptr defdevid(tmp); ret = (wcscmp(defdevid.get(), device_id) == 0); } } return ret; } int wasapi_create_device(cubeb * ctx, cubeb_device_info& ret, IMMDeviceEnumerator * enumerator, IMMDevice * dev) { com_ptr endpoint; com_ptr devnode; com_ptr client; EDataFlow flow; DWORD state = DEVICE_STATE_NOTPRESENT; com_ptr propstore; REFERENCE_TIME def_period, min_period; HRESULT hr; struct prop_variant : public PROPVARIANT { prop_variant() { PropVariantInit(this); } ~prop_variant() { PropVariantClear(this); } prop_variant(prop_variant const &) = delete; prop_variant & operator=(prop_variant const &) = delete; }; hr = dev->QueryInterface(IID_PPV_ARGS(endpoint.receive())); if (FAILED(hr)) return CUBEB_ERROR; hr = endpoint->GetDataFlow(&flow); if (FAILED(hr)) return CUBEB_ERROR; wchar_t * tmp = nullptr; hr = dev->GetId(&tmp); if (FAILED(hr)) return CUBEB_ERROR; com_heap_ptr device_id(tmp); char const * device_id_intern = intern_device_id(ctx, device_id.get()); if (!device_id_intern) { return CUBEB_ERROR; } hr = dev->OpenPropertyStore(STGM_READ, propstore.receive()); if (FAILED(hr)) return CUBEB_ERROR; hr = dev->GetState(&state); if (FAILED(hr)) return CUBEB_ERROR; ret.device_id = device_id_intern; ret.devid = reinterpret_cast(ret.device_id); prop_variant namevar; hr = propstore->GetValue(PKEY_Device_FriendlyName, &namevar); if (SUCCEEDED(hr)) ret.friendly_name = wstr_to_utf8(namevar.pwszVal); devnode = wasapi_get_device_node(enumerator, dev); if (devnode) { com_ptr ps; hr = devnode->OpenPropertyStore(STGM_READ, ps.receive()); if (FAILED(hr)) return CUBEB_ERROR; prop_variant instancevar; hr = ps->GetValue(PKEY_Device_InstanceId, &instancevar); if (SUCCEEDED(hr)) { ret.group_id = wstr_to_utf8(instancevar.pwszVal); } } ret.preferred = CUBEB_DEVICE_PREF_NONE; if (wasapi_is_default_device(flow, eConsole, device_id.get(), enumerator)) ret.preferred = (cubeb_device_pref)(ret.preferred | CUBEB_DEVICE_PREF_MULTIMEDIA); if (wasapi_is_default_device(flow, eCommunications, device_id.get(), enumerator)) ret.preferred = (cubeb_device_pref)(ret.preferred | CUBEB_DEVICE_PREF_VOICE); if (wasapi_is_default_device(flow, eConsole, device_id.get(), enumerator)) ret.preferred = (cubeb_device_pref)(ret.preferred | CUBEB_DEVICE_PREF_NOTIFICATION); if (flow == eRender) ret.type = CUBEB_DEVICE_TYPE_OUTPUT; else if (flow == eCapture) ret.type = CUBEB_DEVICE_TYPE_INPUT; switch (state) { case DEVICE_STATE_ACTIVE: ret.state = CUBEB_DEVICE_STATE_ENABLED; break; case DEVICE_STATE_UNPLUGGED: ret.state = CUBEB_DEVICE_STATE_UNPLUGGED; break; default: ret.state = CUBEB_DEVICE_STATE_DISABLED; break; }; ret.format = static_cast(CUBEB_DEVICE_FMT_F32NE | CUBEB_DEVICE_FMT_S16NE); ret.default_format = CUBEB_DEVICE_FMT_F32NE; prop_variant fmtvar; hr = propstore->GetValue(PKEY_AudioEngine_DeviceFormat, &fmtvar); if (SUCCEEDED(hr) && fmtvar.vt == VT_BLOB) { if (fmtvar.blob.cbSize == sizeof(PCMWAVEFORMAT)) { const PCMWAVEFORMAT * pcm = reinterpret_cast(fmtvar.blob.pBlobData); ret.max_rate = ret.min_rate = ret.default_rate = pcm->wf.nSamplesPerSec; ret.max_channels = pcm->wf.nChannels; } else if (fmtvar.blob.cbSize >= sizeof(WAVEFORMATEX)) { WAVEFORMATEX* wfx = reinterpret_cast(fmtvar.blob.pBlobData); if (fmtvar.blob.cbSize >= sizeof(WAVEFORMATEX) + wfx->cbSize || wfx->wFormatTag == WAVE_FORMAT_PCM) { ret.max_rate = ret.min_rate = ret.default_rate = wfx->nSamplesPerSec; ret.max_channels = wfx->nChannels; } } } if (SUCCEEDED(dev->Activate(__uuidof(IAudioClient), CLSCTX_INPROC_SERVER, NULL, client.receive_vpp())) && SUCCEEDED(client->GetDevicePeriod(&def_period, &min_period))) { ret.latency_lo = hns_to_frames(ret.default_rate, min_period); ret.latency_hi = hns_to_frames(ret.default_rate, def_period); } else { ret.latency_lo = 0; ret.latency_hi = 0; } return CUBEB_OK; } static int wasapi_enumerate_devices(cubeb * context, cubeb_device_type type, cubeb_device_collection * out) { com_ptr enumerator; com_ptr collection; HRESULT hr; UINT cc, i; EDataFlow flow; hr = CoCreateInstance(__uuidof(MMDeviceEnumerator), NULL, CLSCTX_INPROC_SERVER, IID_PPV_ARGS(enumerator.receive())); if (FAILED(hr)) { LOG("Could not get device enumerator: %lx", hr); return CUBEB_ERROR; } if (type == CUBEB_DEVICE_TYPE_OUTPUT) flow = eRender; else if (type == CUBEB_DEVICE_TYPE_INPUT) flow = eCapture; else if (type & (CUBEB_DEVICE_TYPE_INPUT | CUBEB_DEVICE_TYPE_OUTPUT)) flow = eAll; else return CUBEB_ERROR; hr = enumerator->EnumAudioEndpoints(flow, DEVICE_STATEMASK_ALL, collection.receive()); if (FAILED(hr)) { LOG("Could not enumerate audio endpoints: %lx", hr); return CUBEB_ERROR; } hr = collection->GetCount(&cc); if (FAILED(hr)) { LOG("IMMDeviceCollection::GetCount() failed: %lx", hr); return CUBEB_ERROR; } cubeb_device_info * devices = new cubeb_device_info[cc]; if (!devices) return CUBEB_ERROR; PodZero(devices, cc); out->count = 0; for (i = 0; i < cc; i++) { com_ptr dev; hr = collection->Item(i, dev.receive()); if (FAILED(hr)) { LOG("IMMDeviceCollection::Item(%u) failed: %lx", i-1, hr); continue; } if (wasapi_create_device(context, devices[out->count], enumerator.get(), dev.get()) == CUBEB_OK) { out->count += 1; } } out->device = devices; return CUBEB_OK; } static int wasapi_device_collection_destroy(cubeb * /*ctx*/, cubeb_device_collection * collection) { XASSERT(collection); for (size_t n = 0; n < collection->count; n++) { cubeb_device_info& dev = collection->device[n]; delete [] dev.friendly_name; delete [] dev.group_id; } delete [] collection->device; return CUBEB_OK; } static int wasapi_register_device_collection_changed(cubeb * context, cubeb_device_type devtype, cubeb_device_collection_changed_callback collection_changed_callback, void * user_ptr) { if (devtype == CUBEB_DEVICE_TYPE_UNKNOWN) { return CUBEB_ERROR_INVALID_PARAMETER; } if (collection_changed_callback) { // Make sure it has been unregistered first. XASSERT(((devtype & CUBEB_DEVICE_TYPE_INPUT) && !context->input_collection_changed_callback) || ((devtype & CUBEB_DEVICE_TYPE_OUTPUT) && !context->output_collection_changed_callback)); // Stop the notification client. Notifications arrive on // a separate thread. We stop them here to avoid // synchronization issues during the update. if (context->device_collection_enumerator.get()) { HRESULT hr = unregister_collection_notification_client(context); if (FAILED(hr)) { return CUBEB_ERROR; } } if (devtype & CUBEB_DEVICE_TYPE_INPUT) { context->input_collection_changed_callback = collection_changed_callback; context->input_collection_changed_user_ptr = user_ptr; } if (devtype & CUBEB_DEVICE_TYPE_OUTPUT) { context->output_collection_changed_callback = collection_changed_callback; context->output_collection_changed_user_ptr = user_ptr; } HRESULT hr = register_collection_notification_client(context); if (FAILED(hr)) { return CUBEB_ERROR; } } else { if (!context->device_collection_enumerator.get()) { // Already unregistered, ignore it. return CUBEB_OK; } HRESULT hr = unregister_collection_notification_client(context); if (FAILED(hr)) { return CUBEB_ERROR; } if (devtype & CUBEB_DEVICE_TYPE_INPUT) { context->input_collection_changed_callback = nullptr; context->input_collection_changed_user_ptr = nullptr; } if (devtype & CUBEB_DEVICE_TYPE_OUTPUT) { context->output_collection_changed_callback = nullptr; context->output_collection_changed_user_ptr = nullptr; } // If after the updates we still have registered // callbacks restart the notification client. if (context->input_collection_changed_callback || context->output_collection_changed_callback) { hr = register_collection_notification_client(context); if (FAILED(hr)) { return CUBEB_ERROR; } } } return CUBEB_OK; } cubeb_ops const wasapi_ops = { /*.init =*/ wasapi_init, /*.get_backend_id =*/ wasapi_get_backend_id, /*.get_max_channel_count =*/ wasapi_get_max_channel_count, /*.get_min_latency =*/ wasapi_get_min_latency, /*.get_preferred_sample_rate =*/ wasapi_get_preferred_sample_rate, /*.enumerate_devices =*/ wasapi_enumerate_devices, /*.device_collection_destroy =*/ wasapi_device_collection_destroy, /*.destroy =*/ wasapi_destroy, /*.stream_init =*/ wasapi_stream_init, /*.stream_destroy =*/ wasapi_stream_destroy, /*.stream_start =*/ wasapi_stream_start, /*.stream_stop =*/ wasapi_stream_stop, /*.stream_reset_default_device =*/ wasapi_stream_reset_default_device, /*.stream_get_position =*/ wasapi_stream_get_position, /*.stream_get_latency =*/ wasapi_stream_get_latency, /*.stream_set_volume =*/ wasapi_stream_set_volume, /*.stream_get_current_device =*/ NULL, /*.stream_device_destroy =*/ NULL, /*.stream_register_device_changed_callback =*/ NULL, /*.register_device_collection_changed =*/ wasapi_register_device_collection_changed, }; } // namespace anonymous