/** * OpenAL cross platform audio library * Copyright (C) 2011 by authors. * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * Or go to http://www.gnu.org/copyleft/lgpl.html */ #include "config.h" #include "backends/wasapi.h" #include #include #include #include #include #include #include #include #include #include #include #include #ifndef _WAVEFORMATEXTENSIBLE_ #include #include #endif #include #include #include #include #include #include #include #include #include #include #include "alMain.h" #include "alu.h" #include "ringbuffer.h" #include "compat.h" #include "converter.h" /* Some headers seem to define these as macros for __uuidof, which is annoying * since some headers don't declare them at all. Hopefully the ifdef is enough * to tell if they need to be declared. */ #ifndef KSDATAFORMAT_SUBTYPE_PCM DEFINE_GUID(KSDATAFORMAT_SUBTYPE_PCM, 0x00000001, 0x0000, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); #endif #ifndef KSDATAFORMAT_SUBTYPE_IEEE_FLOAT DEFINE_GUID(KSDATAFORMAT_SUBTYPE_IEEE_FLOAT, 0x00000003, 0x0000, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); #endif DEFINE_DEVPROPKEY(DEVPKEY_Device_FriendlyName, 0xa45c254e, 0xdf1c, 0x4efd, 0x80,0x20, 0x67,0xd1,0x46,0xa8,0x50,0xe0, 14); DEFINE_PROPERTYKEY(PKEY_AudioEndpoint_FormFactor, 0x1da5d803, 0xd492, 0x4edd, 0x8c,0x23, 0xe0,0xc0,0xff,0xee,0x7f,0x0e, 0); DEFINE_PROPERTYKEY(PKEY_AudioEndpoint_GUID, 0x1da5d803, 0xd492, 0x4edd, 0x8c, 0x23,0xe0, 0xc0,0xff,0xee,0x7f,0x0e, 4 ); namespace { #define MONO SPEAKER_FRONT_CENTER #define STEREO (SPEAKER_FRONT_LEFT|SPEAKER_FRONT_RIGHT) #define QUAD (SPEAKER_FRONT_LEFT|SPEAKER_FRONT_RIGHT|SPEAKER_BACK_LEFT|SPEAKER_BACK_RIGHT) #define X5DOT1 (SPEAKER_FRONT_LEFT|SPEAKER_FRONT_RIGHT|SPEAKER_FRONT_CENTER|SPEAKER_LOW_FREQUENCY|SPEAKER_SIDE_LEFT|SPEAKER_SIDE_RIGHT) #define X5DOT1REAR (SPEAKER_FRONT_LEFT|SPEAKER_FRONT_RIGHT|SPEAKER_FRONT_CENTER|SPEAKER_LOW_FREQUENCY|SPEAKER_BACK_LEFT|SPEAKER_BACK_RIGHT) #define X6DOT1 (SPEAKER_FRONT_LEFT|SPEAKER_FRONT_RIGHT|SPEAKER_FRONT_CENTER|SPEAKER_LOW_FREQUENCY|SPEAKER_BACK_CENTER|SPEAKER_SIDE_LEFT|SPEAKER_SIDE_RIGHT) #define X7DOT1 (SPEAKER_FRONT_LEFT|SPEAKER_FRONT_RIGHT|SPEAKER_FRONT_CENTER|SPEAKER_LOW_FREQUENCY|SPEAKER_BACK_LEFT|SPEAKER_BACK_RIGHT|SPEAKER_SIDE_LEFT|SPEAKER_SIDE_RIGHT) #define X7DOT1_WIDE (SPEAKER_FRONT_LEFT|SPEAKER_FRONT_RIGHT|SPEAKER_FRONT_CENTER|SPEAKER_LOW_FREQUENCY|SPEAKER_BACK_LEFT|SPEAKER_BACK_RIGHT|SPEAKER_FRONT_LEFT_OF_CENTER|SPEAKER_FRONT_RIGHT_OF_CENTER) #define REFTIME_PER_SEC ((REFERENCE_TIME)10000000) #define DEVNAME_HEAD "OpenAL Soft on " /* Scales the given value using 64-bit integer math, ceiling the result. */ inline int64_t ScaleCeil(int64_t val, int64_t new_scale, int64_t old_scale) { return (val*new_scale + old_scale-1) / old_scale; } struct PropVariant { PROPVARIANT mProp; public: PropVariant() { PropVariantInit(&mProp); } ~PropVariant() { clear(); } void clear() { PropVariantClear(&mProp); } PROPVARIANT* get() noexcept { return &mProp; } PROPVARIANT& operator*() noexcept { return mProp; } const PROPVARIANT& operator*() const noexcept { return mProp; } PROPVARIANT* operator->() noexcept { return &mProp; } const PROPVARIANT* operator->() const noexcept { return &mProp; } }; struct DevMap { std::string name; std::string endpoint_guid; // obtained from PKEY_AudioEndpoint_GUID , set to "Unknown device GUID" if absent. std::wstring devid; template DevMap(T0&& name_, T1&& guid_, T2&& devid_) : name{std::forward(name_)} , endpoint_guid{std::forward(guid_)} , devid{std::forward(devid_)} { } }; bool checkName(const al::vector &list, const std::string &name) { return std::find_if(list.cbegin(), list.cend(), [&name](const DevMap &entry) -> bool { return entry.name == name; } ) != list.cend(); } al::vector PlaybackDevices; al::vector CaptureDevices; using NameGUIDPair = std::pair; NameGUIDPair get_device_name_and_guid(IMMDevice *device) { std::string name{DEVNAME_HEAD}; std::string guid; IPropertyStore *ps; HRESULT hr = device->OpenPropertyStore(STGM_READ, &ps); if(FAILED(hr)) { WARN("OpenPropertyStore failed: 0x%08lx\n", hr); return { name+"Unknown Device Name", "Unknown Device GUID" }; } PropVariant pvprop; hr = ps->GetValue(reinterpret_cast(DEVPKEY_Device_FriendlyName), pvprop.get()); if(FAILED(hr)) { WARN("GetValue Device_FriendlyName failed: 0x%08lx\n", hr); name += "Unknown Device Name"; } else if(pvprop->vt == VT_LPWSTR) name += wstr_to_utf8(pvprop->pwszVal); else { WARN("Unexpected PROPVARIANT type: 0x%04x\n", pvprop->vt); name += "Unknown Device Name"; } pvprop.clear(); hr = ps->GetValue(reinterpret_cast(PKEY_AudioEndpoint_GUID), pvprop.get()); if(FAILED(hr)) { WARN("GetValue AudioEndpoint_GUID failed: 0x%08lx\n", hr); guid = "Unknown Device GUID"; } else if(pvprop->vt == VT_LPWSTR) guid = wstr_to_utf8(pvprop->pwszVal); else { WARN("Unexpected PROPVARIANT type: 0x%04x\n", pvprop->vt); guid = "Unknown Device GUID"; } ps->Release(); return {name, guid}; } void get_device_formfactor(IMMDevice *device, EndpointFormFactor *formfactor) { IPropertyStore *ps; HRESULT hr = device->OpenPropertyStore(STGM_READ, &ps); if(FAILED(hr)) { WARN("OpenPropertyStore failed: 0x%08lx\n", hr); return; } PropVariant pvform; hr = ps->GetValue(reinterpret_cast(PKEY_AudioEndpoint_FormFactor), pvform.get()); if(FAILED(hr)) WARN("GetValue AudioEndpoint_FormFactor failed: 0x%08lx\n", hr); else if(pvform->vt == VT_UI4) *formfactor = static_cast(pvform->ulVal); else if(pvform->vt == VT_EMPTY) *formfactor = UnknownFormFactor; else WARN("Unexpected PROPVARIANT type: 0x%04x\n", pvform->vt); ps->Release(); } void add_device(IMMDevice *device, const WCHAR *devid, al::vector &list) { std::string basename, guidstr; std::tie(basename, guidstr) = get_device_name_and_guid(device); int count{1}; std::string newname{basename}; while(checkName(list, newname)) { newname = basename; newname += " #"; newname += std::to_string(++count); } list.emplace_back(std::move(newname), std::move(guidstr), devid); const DevMap &newentry = list.back(); TRACE("Got device \"%s\", \"%s\", \"%ls\"\n", newentry.name.c_str(), newentry.endpoint_guid.c_str(), newentry.devid.c_str()); } WCHAR *get_device_id(IMMDevice *device) { WCHAR *devid; HRESULT hr = device->GetId(&devid); if(FAILED(hr)) { ERR("Failed to get device id: %lx\n", hr); return nullptr; } return devid; } HRESULT probe_devices(IMMDeviceEnumerator *devenum, EDataFlow flowdir, al::vector &list) { IMMDeviceCollection *coll; HRESULT hr{devenum->EnumAudioEndpoints(flowdir, DEVICE_STATE_ACTIVE, &coll)}; if(FAILED(hr)) { ERR("Failed to enumerate audio endpoints: 0x%08lx\n", hr); return hr; } IMMDevice *defdev{nullptr}; WCHAR *defdevid{nullptr}; UINT count{0}; hr = coll->GetCount(&count); if(SUCCEEDED(hr) && count > 0) { list.clear(); list.reserve(count); hr = devenum->GetDefaultAudioEndpoint(flowdir, eMultimedia, &defdev); } if(SUCCEEDED(hr) && defdev != nullptr) { defdevid = get_device_id(defdev); if(defdevid) add_device(defdev, defdevid, list); } for(UINT i{0};i < count;++i) { IMMDevice *device; hr = coll->Item(i, &device); if(FAILED(hr)) continue; WCHAR *devid{get_device_id(device)}; if(devid) { if(!defdevid || wcscmp(devid, defdevid) != 0) add_device(device, devid, list); CoTaskMemFree(devid); } device->Release(); } if(defdev) defdev->Release(); if(defdevid) CoTaskMemFree(defdevid); coll->Release(); return S_OK; } enum class MsgType : unsigned int { OpenDevice, ResetDevice, StartDevice, StopDevice, CloseDevice, EnumeratePlayback, EnumerateCapture, QuitThread, Count }; constexpr char MessageStr[static_cast(MsgType::Count)][20]{ "Open Device", "Reset Device", "Start Device", "Stop Device", "Close Device", "Enumerate Playback", "Enumerate Capture", "Quit" }; /* Proxy interface used by the message handler. */ struct WasapiProxy { virtual HRESULT openProxy() = 0; virtual void closeProxy() = 0; virtual HRESULT resetProxy() = 0; virtual HRESULT startProxy() = 0; virtual void stopProxy() = 0; struct Msg { MsgType mType; WasapiProxy *mProxy; std::promise mPromise; }; static std::deque mMsgQueue; static std::mutex mMsgQueueLock; static std::condition_variable mMsgQueueCond; std::future pushMessage(MsgType type) { std::promise promise; std::future future{promise.get_future()}; { std::lock_guard _{mMsgQueueLock}; mMsgQueue.emplace_back(Msg{type, this, std::move(promise)}); } mMsgQueueCond.notify_one(); return future; } static std::future pushMessageStatic(MsgType type) { std::promise promise; std::future future{promise.get_future()}; { std::lock_guard _{mMsgQueueLock}; mMsgQueue.emplace_back(Msg{type, nullptr, std::move(promise)}); } mMsgQueueCond.notify_one(); return future; } static bool popMessage(Msg &msg) { std::unique_lock lock{mMsgQueueLock}; while(mMsgQueue.empty()) mMsgQueueCond.wait(lock); msg = std::move(mMsgQueue.front()); mMsgQueue.pop_front(); return msg.mType != MsgType::QuitThread; } static int messageHandler(std::promise *promise); }; std::deque WasapiProxy::mMsgQueue; std::mutex WasapiProxy::mMsgQueueLock; std::condition_variable WasapiProxy::mMsgQueueCond; int WasapiProxy::messageHandler(std::promise *promise) { TRACE("Starting message thread\n"); HRESULT cohr = CoInitializeEx(nullptr, COINIT_MULTITHREADED); if(FAILED(cohr)) { WARN("Failed to initialize COM: 0x%08lx\n", cohr); promise->set_value(cohr); return 0; } void *ptr{}; HRESULT hr{CoCreateInstance(CLSID_MMDeviceEnumerator, nullptr, CLSCTX_INPROC_SERVER, IID_IMMDeviceEnumerator, &ptr)}; if(FAILED(hr)) { WARN("Failed to create IMMDeviceEnumerator instance: 0x%08lx\n", hr); promise->set_value(hr); CoUninitialize(); return 0; } auto Enumerator = static_cast(ptr); Enumerator->Release(); Enumerator = nullptr; CoUninitialize(); TRACE("Message thread initialization complete\n"); promise->set_value(S_OK); promise = nullptr; TRACE("Starting message loop\n"); ALuint deviceCount{0}; Msg msg; while(popMessage(msg)) { TRACE("Got message \"%s\" (0x%04x, this=%p)\n", MessageStr[static_cast(msg.mType)], static_cast(msg.mType), msg.mProxy); switch(msg.mType) { case MsgType::OpenDevice: hr = cohr = S_OK; if(++deviceCount == 1) hr = cohr = CoInitializeEx(nullptr, COINIT_MULTITHREADED); if(SUCCEEDED(hr)) hr = msg.mProxy->openProxy(); msg.mPromise.set_value(hr); if(FAILED(hr)) { if(--deviceCount == 0 && SUCCEEDED(cohr)) CoUninitialize(); } continue; case MsgType::ResetDevice: hr = msg.mProxy->resetProxy(); msg.mPromise.set_value(hr); continue; case MsgType::StartDevice: hr = msg.mProxy->startProxy(); msg.mPromise.set_value(hr); continue; case MsgType::StopDevice: msg.mProxy->stopProxy(); msg.mPromise.set_value(S_OK); continue; case MsgType::CloseDevice: msg.mProxy->closeProxy(); msg.mPromise.set_value(S_OK); if(--deviceCount == 0) CoUninitialize(); continue; case MsgType::EnumeratePlayback: case MsgType::EnumerateCapture: hr = cohr = S_OK; if(++deviceCount == 1) hr = cohr = CoInitializeEx(nullptr, COINIT_MULTITHREADED); if(SUCCEEDED(hr)) hr = CoCreateInstance(CLSID_MMDeviceEnumerator, nullptr, CLSCTX_INPROC_SERVER, IID_IMMDeviceEnumerator, &ptr); if(FAILED(hr)) msg.mPromise.set_value(hr); else { Enumerator = static_cast(ptr); if(msg.mType == MsgType::EnumeratePlayback) hr = probe_devices(Enumerator, eRender, PlaybackDevices); else if(msg.mType == MsgType::EnumerateCapture) hr = probe_devices(Enumerator, eCapture, CaptureDevices); msg.mPromise.set_value(hr); Enumerator->Release(); Enumerator = nullptr; } if(--deviceCount == 0 && SUCCEEDED(cohr)) CoUninitialize(); continue; default: ERR("Unexpected message: %u\n", static_cast(msg.mType)); msg.mPromise.set_value(E_FAIL); continue; } } TRACE("Message loop finished\n"); return 0; } struct WasapiPlayback final : public BackendBase, WasapiProxy { WasapiPlayback(ALCdevice *device) noexcept : BackendBase{device} { } ~WasapiPlayback() override; int mixerProc(); ALCenum open(const ALCchar *name) override; HRESULT openProxy() override; void closeProxy() override; ALCboolean reset() override; HRESULT resetProxy() override; ALCboolean start() override; HRESULT startProxy() override; void stop() override; void stopProxy() override; ClockLatency getClockLatency() override; std::wstring mDevId; IMMDevice *mMMDev{nullptr}; IAudioClient *mClient{nullptr}; IAudioRenderClient *mRender{nullptr}; HANDLE mNotifyEvent{nullptr}; std::atomic mPadding{0u}; std::atomic mKillNow{true}; std::thread mThread; DEF_NEWDEL(WasapiPlayback) }; WasapiPlayback::~WasapiPlayback() { pushMessage(MsgType::CloseDevice).wait(); if(mNotifyEvent != nullptr) CloseHandle(mNotifyEvent); mNotifyEvent = nullptr; } FORCE_ALIGN int WasapiPlayback::mixerProc() { HRESULT hr = CoInitializeEx(nullptr, COINIT_MULTITHREADED); if(FAILED(hr)) { ERR("CoInitializeEx(nullptr, COINIT_MULTITHREADED) failed: 0x%08lx\n", hr); aluHandleDisconnect(mDevice, "COM init failed: 0x%08lx", hr); return 1; } SetRTPriority(); althrd_setname(MIXER_THREAD_NAME); const ALuint update_size{mDevice->UpdateSize}; const UINT32 buffer_len{mDevice->BufferSize}; while(!mKillNow.load(std::memory_order_relaxed)) { UINT32 written; hr = mClient->GetCurrentPadding(&written); if(FAILED(hr)) { ERR("Failed to get padding: 0x%08lx\n", hr); aluHandleDisconnect(mDevice, "Failed to retrieve buffer padding: 0x%08lx", hr); break; } mPadding.store(written, std::memory_order_relaxed); ALuint len{buffer_len - written}; if(len < update_size) { DWORD res{WaitForSingleObjectEx(mNotifyEvent, 2000, FALSE)}; if(res != WAIT_OBJECT_0) ERR("WaitForSingleObjectEx error: 0x%lx\n", res); continue; } BYTE *buffer; hr = mRender->GetBuffer(len, &buffer); if(SUCCEEDED(hr)) { lock(); aluMixData(mDevice, buffer, len); mPadding.store(written + len, std::memory_order_relaxed); unlock(); hr = mRender->ReleaseBuffer(len, 0); } if(FAILED(hr)) { ERR("Failed to buffer data: 0x%08lx\n", hr); aluHandleDisconnect(mDevice, "Failed to send playback samples: 0x%08lx", hr); break; } } mPadding.store(0u, std::memory_order_release); CoUninitialize(); return 0; } bool MakeExtensible(WAVEFORMATEXTENSIBLE *out, const WAVEFORMATEX *in) { *out = WAVEFORMATEXTENSIBLE{}; if(in->wFormatTag == WAVE_FORMAT_EXTENSIBLE) { *out = reinterpret_cast(*in); out->Format.cbSize = sizeof(*out) - sizeof(out->Format); } else if(in->wFormatTag == WAVE_FORMAT_PCM) { out->Format = *in; if(out->Format.nChannels == 1) out->dwChannelMask = MONO; else if(out->Format.nChannels == 2) out->dwChannelMask = STEREO; else ERR("Unhandled PCM channel count: %d\n", out->Format.nChannels); out->SubFormat = KSDATAFORMAT_SUBTYPE_PCM; } else if(in->wFormatTag == WAVE_FORMAT_IEEE_FLOAT) { out->Format = *in; if(out->Format.nChannels == 1) out->dwChannelMask = MONO; else if(out->Format.nChannels == 2) out->dwChannelMask = STEREO; else ERR("Unhandled IEEE float channel count: %d\n", out->Format.nChannels); out->SubFormat = KSDATAFORMAT_SUBTYPE_IEEE_FLOAT; } else { ERR("Unhandled format tag: 0x%04x\n", in->wFormatTag); return false; } return true; } ALCenum WasapiPlayback::open(const ALCchar *name) { HRESULT hr{S_OK}; mNotifyEvent = CreateEventW(nullptr, FALSE, FALSE, nullptr); if(mNotifyEvent == nullptr) { ERR("Failed to create notify events: %lu\n", GetLastError()); hr = E_FAIL; } if(SUCCEEDED(hr)) { if(name) { if(PlaybackDevices.empty()) pushMessage(MsgType::EnumeratePlayback).wait(); hr = E_FAIL; auto iter = std::find_if(PlaybackDevices.cbegin(), PlaybackDevices.cend(), [name](const DevMap &entry) -> bool { return entry.name == name || entry.endpoint_guid == name; } ); if(iter == PlaybackDevices.cend()) { std::wstring wname{utf8_to_wstr(name)}; iter = std::find_if(PlaybackDevices.cbegin(), PlaybackDevices.cend(), [&wname](const DevMap &entry) -> bool { return entry.devid == wname; } ); } if(iter == PlaybackDevices.cend()) WARN("Failed to find device name matching \"%s\"\n", name); else { mDevId = iter->devid; mDevice->DeviceName = iter->name; hr = S_OK; } } } if(SUCCEEDED(hr)) hr = pushMessage(MsgType::OpenDevice).get(); if(FAILED(hr)) { if(mNotifyEvent != nullptr) CloseHandle(mNotifyEvent); mNotifyEvent = nullptr; mDevId.clear(); ERR("Device init failed: 0x%08lx\n", hr); return ALC_INVALID_VALUE; } return ALC_NO_ERROR; } HRESULT WasapiPlayback::openProxy() { void *ptr; HRESULT hr{CoCreateInstance(CLSID_MMDeviceEnumerator, nullptr, CLSCTX_INPROC_SERVER, IID_IMMDeviceEnumerator, &ptr)}; if(SUCCEEDED(hr)) { auto Enumerator = static_cast(ptr); if(mDevId.empty()) hr = Enumerator->GetDefaultAudioEndpoint(eRender, eMultimedia, &mMMDev); else hr = Enumerator->GetDevice(mDevId.c_str(), &mMMDev); Enumerator->Release(); } if(SUCCEEDED(hr)) hr = mMMDev->Activate(IID_IAudioClient, CLSCTX_INPROC_SERVER, nullptr, &ptr); if(SUCCEEDED(hr)) { mClient = static_cast(ptr); if(mDevice->DeviceName.empty()) mDevice->DeviceName = get_device_name_and_guid(mMMDev).first; } if(FAILED(hr)) { if(mMMDev) mMMDev->Release(); mMMDev = nullptr; } return hr; } void WasapiPlayback::closeProxy() { if(mClient) mClient->Release(); mClient = nullptr; if(mMMDev) mMMDev->Release(); mMMDev = nullptr; } ALCboolean WasapiPlayback::reset() { HRESULT hr{pushMessage(MsgType::ResetDevice).get()}; return SUCCEEDED(hr) ? ALC_TRUE : ALC_FALSE; } HRESULT WasapiPlayback::resetProxy() { if(mClient) mClient->Release(); mClient = nullptr; void *ptr; HRESULT hr = mMMDev->Activate(IID_IAudioClient, CLSCTX_INPROC_SERVER, nullptr, &ptr); if(FAILED(hr)) { ERR("Failed to reactivate audio client: 0x%08lx\n", hr); return hr; } mClient = static_cast(ptr); WAVEFORMATEX *wfx; hr = mClient->GetMixFormat(&wfx); if(FAILED(hr)) { ERR("Failed to get mix format: 0x%08lx\n", hr); return hr; } WAVEFORMATEXTENSIBLE OutputType; if(!MakeExtensible(&OutputType, wfx)) { CoTaskMemFree(wfx); return E_FAIL; } CoTaskMemFree(wfx); wfx = nullptr; const REFERENCE_TIME per_time{mDevice->UpdateSize * REFTIME_PER_SEC / mDevice->Frequency}; const REFERENCE_TIME buf_time{mDevice->BufferSize * REFTIME_PER_SEC / mDevice->Frequency}; if(!(mDevice->Flags&DEVICE_FREQUENCY_REQUEST)) mDevice->Frequency = OutputType.Format.nSamplesPerSec; if(!(mDevice->Flags&DEVICE_CHANNELS_REQUEST)) { if(OutputType.Format.nChannels == 1 && OutputType.dwChannelMask == MONO) mDevice->FmtChans = DevFmtMono; else if(OutputType.Format.nChannels == 2 && OutputType.dwChannelMask == STEREO) mDevice->FmtChans = DevFmtStereo; else if(OutputType.Format.nChannels == 4 && OutputType.dwChannelMask == QUAD) mDevice->FmtChans = DevFmtQuad; else if(OutputType.Format.nChannels == 6 && OutputType.dwChannelMask == X5DOT1) mDevice->FmtChans = DevFmtX51; else if(OutputType.Format.nChannels == 6 && OutputType.dwChannelMask == X5DOT1REAR) mDevice->FmtChans = DevFmtX51Rear; else if(OutputType.Format.nChannels == 7 && OutputType.dwChannelMask == X6DOT1) mDevice->FmtChans = DevFmtX61; else if(OutputType.Format.nChannels == 8 && (OutputType.dwChannelMask == X7DOT1 || OutputType.dwChannelMask == X7DOT1_WIDE)) mDevice->FmtChans = DevFmtX71; else ERR("Unhandled channel config: %d -- 0x%08lx\n", OutputType.Format.nChannels, OutputType.dwChannelMask); } OutputType.Format.wFormatTag = WAVE_FORMAT_EXTENSIBLE; switch(mDevice->FmtChans) { case DevFmtMono: OutputType.Format.nChannels = 1; OutputType.dwChannelMask = MONO; break; case DevFmtAmbi3D: mDevice->FmtChans = DevFmtStereo; /*fall-through*/ case DevFmtStereo: OutputType.Format.nChannels = 2; OutputType.dwChannelMask = STEREO; break; case DevFmtQuad: OutputType.Format.nChannels = 4; OutputType.dwChannelMask = QUAD; break; case DevFmtX51: OutputType.Format.nChannels = 6; OutputType.dwChannelMask = X5DOT1; break; case DevFmtX51Rear: OutputType.Format.nChannels = 6; OutputType.dwChannelMask = X5DOT1REAR; break; case DevFmtX61: OutputType.Format.nChannels = 7; OutputType.dwChannelMask = X6DOT1; break; case DevFmtX71: OutputType.Format.nChannels = 8; OutputType.dwChannelMask = X7DOT1; break; } switch(mDevice->FmtType) { case DevFmtByte: mDevice->FmtType = DevFmtUByte; /* fall-through */ case DevFmtUByte: OutputType.Format.wBitsPerSample = 8; OutputType.Samples.wValidBitsPerSample = 8; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_PCM; break; case DevFmtUShort: mDevice->FmtType = DevFmtShort; /* fall-through */ case DevFmtShort: OutputType.Format.wBitsPerSample = 16; OutputType.Samples.wValidBitsPerSample = 16; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_PCM; break; case DevFmtUInt: mDevice->FmtType = DevFmtInt; /* fall-through */ case DevFmtInt: OutputType.Format.wBitsPerSample = 32; OutputType.Samples.wValidBitsPerSample = 32; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_PCM; break; case DevFmtFloat: OutputType.Format.wBitsPerSample = 32; OutputType.Samples.wValidBitsPerSample = 32; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_IEEE_FLOAT; break; } OutputType.Format.nSamplesPerSec = mDevice->Frequency; OutputType.Format.nBlockAlign = OutputType.Format.nChannels * OutputType.Format.wBitsPerSample / 8; OutputType.Format.nAvgBytesPerSec = OutputType.Format.nSamplesPerSec * OutputType.Format.nBlockAlign; hr = mClient->IsFormatSupported(AUDCLNT_SHAREMODE_SHARED, &OutputType.Format, &wfx); if(FAILED(hr)) { ERR("Failed to check format support: 0x%08lx\n", hr); hr = mClient->GetMixFormat(&wfx); } if(FAILED(hr)) { ERR("Failed to find a supported format: 0x%08lx\n", hr); return hr; } if(wfx != nullptr) { if(!MakeExtensible(&OutputType, wfx)) { CoTaskMemFree(wfx); return E_FAIL; } CoTaskMemFree(wfx); wfx = nullptr; mDevice->Frequency = OutputType.Format.nSamplesPerSec; if(OutputType.Format.nChannels == 1 && OutputType.dwChannelMask == MONO) mDevice->FmtChans = DevFmtMono; else if(OutputType.Format.nChannels == 2 && OutputType.dwChannelMask == STEREO) mDevice->FmtChans = DevFmtStereo; else if(OutputType.Format.nChannels == 4 && OutputType.dwChannelMask == QUAD) mDevice->FmtChans = DevFmtQuad; else if(OutputType.Format.nChannels == 6 && OutputType.dwChannelMask == X5DOT1) mDevice->FmtChans = DevFmtX51; else if(OutputType.Format.nChannels == 6 && OutputType.dwChannelMask == X5DOT1REAR) mDevice->FmtChans = DevFmtX51Rear; else if(OutputType.Format.nChannels == 7 && OutputType.dwChannelMask == X6DOT1) mDevice->FmtChans = DevFmtX61; else if(OutputType.Format.nChannels == 8 && (OutputType.dwChannelMask == X7DOT1 || OutputType.dwChannelMask == X7DOT1_WIDE)) mDevice->FmtChans = DevFmtX71; else { ERR("Unhandled extensible channels: %d -- 0x%08lx\n", OutputType.Format.nChannels, OutputType.dwChannelMask); mDevice->FmtChans = DevFmtStereo; OutputType.Format.nChannels = 2; OutputType.dwChannelMask = STEREO; } if(IsEqualGUID(OutputType.SubFormat, KSDATAFORMAT_SUBTYPE_PCM)) { if(OutputType.Format.wBitsPerSample == 8) mDevice->FmtType = DevFmtUByte; else if(OutputType.Format.wBitsPerSample == 16) mDevice->FmtType = DevFmtShort; else if(OutputType.Format.wBitsPerSample == 32) mDevice->FmtType = DevFmtInt; else { mDevice->FmtType = DevFmtShort; OutputType.Format.wBitsPerSample = 16; } } else if(IsEqualGUID(OutputType.SubFormat, KSDATAFORMAT_SUBTYPE_IEEE_FLOAT)) { mDevice->FmtType = DevFmtFloat; OutputType.Format.wBitsPerSample = 32; } else { ERR("Unhandled format sub-type\n"); mDevice->FmtType = DevFmtShort; if(OutputType.Format.wFormatTag != WAVE_FORMAT_EXTENSIBLE) OutputType.Format.wFormatTag = WAVE_FORMAT_PCM; OutputType.Format.wBitsPerSample = 16; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_PCM; } OutputType.Samples.wValidBitsPerSample = OutputType.Format.wBitsPerSample; } EndpointFormFactor formfactor = UnknownFormFactor; get_device_formfactor(mMMDev, &formfactor); mDevice->IsHeadphones = (mDevice->FmtChans == DevFmtStereo && (formfactor == Headphones || formfactor == Headset)); SetDefaultWFXChannelOrder(mDevice); hr = mClient->Initialize(AUDCLNT_SHAREMODE_SHARED, AUDCLNT_STREAMFLAGS_EVENTCALLBACK, buf_time, 0, &OutputType.Format, nullptr); if(FAILED(hr)) { ERR("Failed to initialize audio client: 0x%08lx\n", hr); return hr; } UINT32 buffer_len, min_len; REFERENCE_TIME min_per; hr = mClient->GetDevicePeriod(&min_per, nullptr); if(SUCCEEDED(hr)) hr = mClient->GetBufferSize(&buffer_len); if(FAILED(hr)) { ERR("Failed to get audio buffer info: 0x%08lx\n", hr); return hr; } /* Find the nearest multiple of the period size to the update size */ if(min_per < per_time) min_per *= maxi64((per_time + min_per/2) / min_per, 1); min_len = (UINT32)ScaleCeil(min_per, mDevice->Frequency, REFTIME_PER_SEC); min_len = minu(min_len, buffer_len/2); mDevice->UpdateSize = min_len; mDevice->BufferSize = buffer_len; hr = mClient->SetEventHandle(mNotifyEvent); if(FAILED(hr)) { ERR("Failed to set event handle: 0x%08lx\n", hr); return hr; } return hr; } ALCboolean WasapiPlayback::start() { HRESULT hr{pushMessage(MsgType::StartDevice).get()}; return SUCCEEDED(hr) ? ALC_TRUE : ALC_FALSE; } HRESULT WasapiPlayback::startProxy() { ResetEvent(mNotifyEvent); HRESULT hr = mClient->Start(); if(FAILED(hr)) { ERR("Failed to start audio client: 0x%08lx\n", hr); return hr; } void *ptr; hr = mClient->GetService(IID_IAudioRenderClient, &ptr); if(SUCCEEDED(hr)) { mRender = static_cast(ptr); try { mKillNow.store(false, std::memory_order_release); mThread = std::thread{std::mem_fn(&WasapiPlayback::mixerProc), this}; } catch(...) { mRender->Release(); mRender = nullptr; ERR("Failed to start thread\n"); hr = E_FAIL; } } if(FAILED(hr)) mClient->Stop(); return hr; } void WasapiPlayback::stop() { pushMessage(MsgType::StopDevice).wait(); } void WasapiPlayback::stopProxy() { if(!mRender || !mThread.joinable()) return; mKillNow.store(true, std::memory_order_release); mThread.join(); mRender->Release(); mRender = nullptr; mClient->Stop(); } ClockLatency WasapiPlayback::getClockLatency() { ClockLatency ret; lock(); ret.ClockTime = GetDeviceClockTime(mDevice); ret.Latency = std::chrono::seconds{mPadding.load(std::memory_order_relaxed)}; ret.Latency /= mDevice->Frequency; unlock(); return ret; } struct WasapiCapture final : public BackendBase, WasapiProxy { WasapiCapture(ALCdevice *device) noexcept : BackendBase{device} { } ~WasapiCapture() override; int recordProc(); ALCenum open(const ALCchar *name) override; HRESULT openProxy() override; void closeProxy() override; HRESULT resetProxy() override; ALCboolean start() override; HRESULT startProxy() override; void stop() override; void stopProxy() override; ALCenum captureSamples(void *buffer, ALCuint samples) override; ALCuint availableSamples() override; std::wstring mDevId; IMMDevice *mMMDev{nullptr}; IAudioClient *mClient{nullptr}; IAudioCaptureClient *mCapture{nullptr}; HANDLE mNotifyEvent{nullptr}; ChannelConverterPtr mChannelConv; SampleConverterPtr mSampleConv; RingBufferPtr mRing; std::atomic mKillNow{true}; std::thread mThread; DEF_NEWDEL(WasapiCapture) }; WasapiCapture::~WasapiCapture() { pushMessage(MsgType::CloseDevice).wait(); if(mNotifyEvent != nullptr) CloseHandle(mNotifyEvent); mNotifyEvent = nullptr; } FORCE_ALIGN int WasapiCapture::recordProc() { HRESULT hr = CoInitializeEx(nullptr, COINIT_MULTITHREADED); if(FAILED(hr)) { ERR("CoInitializeEx(nullptr, COINIT_MULTITHREADED) failed: 0x%08lx\n", hr); aluHandleDisconnect(mDevice, "COM init failed: 0x%08lx", hr); return 1; } althrd_setname(RECORD_THREAD_NAME); al::vector samples; while(!mKillNow.load(std::memory_order_relaxed)) { UINT32 avail; hr = mCapture->GetNextPacketSize(&avail); if(FAILED(hr)) ERR("Failed to get next packet size: 0x%08lx\n", hr); else if(avail > 0) { UINT32 numsamples; DWORD flags; BYTE *rdata; hr = mCapture->GetBuffer(&rdata, &numsamples, &flags, nullptr, nullptr); if(FAILED(hr)) ERR("Failed to get capture buffer: 0x%08lx\n", hr); else { if(mChannelConv) { samples.resize(numsamples*2); mChannelConv->convert(rdata, samples.data(), numsamples); rdata = reinterpret_cast(samples.data()); } auto data = mRing->getWriteVector(); size_t dstframes; if(mSampleConv) { const ALvoid *srcdata{rdata}; auto srcframes = static_cast(numsamples); dstframes = mSampleConv->convert(&srcdata, &srcframes, data.first.buf, static_cast(minz(data.first.len, INT_MAX))); if(srcframes > 0 && dstframes == data.first.len && data.second.len > 0) { /* If some source samples remain, all of the first dest * block was filled, and there's space in the second * dest block, do another run for the second block. */ dstframes += mSampleConv->convert(&srcdata, &srcframes, data.second.buf, static_cast(minz(data.second.len, INT_MAX))); } } else { const auto framesize = static_cast(mDevice->frameSizeFromFmt()); size_t len1 = minz(data.first.len, numsamples); size_t len2 = minz(data.second.len, numsamples-len1); memcpy(data.first.buf, rdata, len1*framesize); if(len2 > 0) memcpy(data.second.buf, rdata+len1*framesize, len2*framesize); dstframes = len1 + len2; } mRing->writeAdvance(dstframes); hr = mCapture->ReleaseBuffer(numsamples); if(FAILED(hr)) ERR("Failed to release capture buffer: 0x%08lx\n", hr); } } if(FAILED(hr)) { aluHandleDisconnect(mDevice, "Failed to capture samples: 0x%08lx", hr); break; } DWORD res{WaitForSingleObjectEx(mNotifyEvent, 2000, FALSE)}; if(res != WAIT_OBJECT_0) ERR("WaitForSingleObjectEx error: 0x%lx\n", res); } CoUninitialize(); return 0; } ALCenum WasapiCapture::open(const ALCchar *name) { HRESULT hr{S_OK}; mNotifyEvent = CreateEventW(nullptr, FALSE, FALSE, nullptr); if(mNotifyEvent == nullptr) { ERR("Failed to create notify event: %lu\n", GetLastError()); hr = E_FAIL; } if(SUCCEEDED(hr)) { if(name) { if(CaptureDevices.empty()) pushMessage(MsgType::EnumerateCapture).wait(); hr = E_FAIL; auto iter = std::find_if(CaptureDevices.cbegin(), CaptureDevices.cend(), [name](const DevMap &entry) -> bool { return entry.name == name || entry.endpoint_guid == name; } ); if(iter == CaptureDevices.cend()) { std::wstring wname{utf8_to_wstr(name)}; iter = std::find_if(CaptureDevices.cbegin(), CaptureDevices.cend(), [&wname](const DevMap &entry) -> bool { return entry.devid == wname; } ); } if(iter == CaptureDevices.cend()) WARN("Failed to find device name matching \"%s\"\n", name); else { mDevId = iter->devid; mDevice->DeviceName = iter->name; hr = S_OK; } } } if(SUCCEEDED(hr)) hr = pushMessage(MsgType::OpenDevice).get(); if(FAILED(hr)) { if(mNotifyEvent != nullptr) CloseHandle(mNotifyEvent); mNotifyEvent = nullptr; mDevId.clear(); ERR("Device init failed: 0x%08lx\n", hr); return ALC_INVALID_VALUE; } hr = pushMessage(MsgType::ResetDevice).get(); if(FAILED(hr)) { if(hr == E_OUTOFMEMORY) return ALC_OUT_OF_MEMORY; return ALC_INVALID_VALUE; } return ALC_NO_ERROR; } HRESULT WasapiCapture::openProxy() { void *ptr; HRESULT hr{CoCreateInstance(CLSID_MMDeviceEnumerator, nullptr, CLSCTX_INPROC_SERVER, IID_IMMDeviceEnumerator, &ptr)}; if(SUCCEEDED(hr)) { auto Enumerator = static_cast(ptr); if(mDevId.empty()) hr = Enumerator->GetDefaultAudioEndpoint(eCapture, eMultimedia, &mMMDev); else hr = Enumerator->GetDevice(mDevId.c_str(), &mMMDev); Enumerator->Release(); } if(SUCCEEDED(hr)) hr = mMMDev->Activate(IID_IAudioClient, CLSCTX_INPROC_SERVER, nullptr, &ptr); if(SUCCEEDED(hr)) { mClient = static_cast(ptr); if(mDevice->DeviceName.empty()) mDevice->DeviceName = get_device_name_and_guid(mMMDev).first; } if(FAILED(hr)) { if(mMMDev) mMMDev->Release(); mMMDev = nullptr; } return hr; } void WasapiCapture::closeProxy() { if(mClient) mClient->Release(); mClient = nullptr; if(mMMDev) mMMDev->Release(); mMMDev = nullptr; } HRESULT WasapiCapture::resetProxy() { if(mClient) mClient->Release(); mClient = nullptr; void *ptr; HRESULT hr{mMMDev->Activate(IID_IAudioClient, CLSCTX_INPROC_SERVER, nullptr, &ptr)}; if(FAILED(hr)) { ERR("Failed to reactivate audio client: 0x%08lx\n", hr); return hr; } mClient = static_cast(ptr); // Make sure buffer is at least 100ms in size REFERENCE_TIME buf_time{mDevice->BufferSize * REFTIME_PER_SEC / mDevice->Frequency}; buf_time = maxu64(buf_time, REFTIME_PER_SEC/10); WAVEFORMATEXTENSIBLE OutputType; OutputType.Format.wFormatTag = WAVE_FORMAT_EXTENSIBLE; switch(mDevice->FmtChans) { case DevFmtMono: OutputType.Format.nChannels = 1; OutputType.dwChannelMask = MONO; break; case DevFmtStereo: OutputType.Format.nChannels = 2; OutputType.dwChannelMask = STEREO; break; case DevFmtQuad: OutputType.Format.nChannels = 4; OutputType.dwChannelMask = QUAD; break; case DevFmtX51: OutputType.Format.nChannels = 6; OutputType.dwChannelMask = X5DOT1; break; case DevFmtX51Rear: OutputType.Format.nChannels = 6; OutputType.dwChannelMask = X5DOT1REAR; break; case DevFmtX61: OutputType.Format.nChannels = 7; OutputType.dwChannelMask = X6DOT1; break; case DevFmtX71: OutputType.Format.nChannels = 8; OutputType.dwChannelMask = X7DOT1; break; case DevFmtAmbi3D: return E_FAIL; } switch(mDevice->FmtType) { /* NOTE: Signedness doesn't matter, the converter will handle it. */ case DevFmtByte: case DevFmtUByte: OutputType.Format.wBitsPerSample = 8; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_PCM; break; case DevFmtShort: case DevFmtUShort: OutputType.Format.wBitsPerSample = 16; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_PCM; break; case DevFmtInt: case DevFmtUInt: OutputType.Format.wBitsPerSample = 32; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_PCM; break; case DevFmtFloat: OutputType.Format.wBitsPerSample = 32; OutputType.SubFormat = KSDATAFORMAT_SUBTYPE_IEEE_FLOAT; break; } OutputType.Samples.wValidBitsPerSample = OutputType.Format.wBitsPerSample; OutputType.Format.nSamplesPerSec = mDevice->Frequency; OutputType.Format.nBlockAlign = OutputType.Format.nChannels * OutputType.Format.wBitsPerSample / 8; OutputType.Format.nAvgBytesPerSec = OutputType.Format.nSamplesPerSec * OutputType.Format.nBlockAlign; OutputType.Format.cbSize = sizeof(OutputType) - sizeof(OutputType.Format); WAVEFORMATEX *wfx; hr = mClient->IsFormatSupported(AUDCLNT_SHAREMODE_SHARED, &OutputType.Format, &wfx); if(FAILED(hr)) { ERR("Failed to check format support: 0x%08lx\n", hr); return hr; } mSampleConv = nullptr; mChannelConv = nullptr; if(wfx != nullptr) { if(!(wfx->nChannels == OutputType.Format.nChannels || (wfx->nChannels == 1 && OutputType.Format.nChannels == 2) || (wfx->nChannels == 2 && OutputType.Format.nChannels == 1))) { ERR("Failed to get matching format, wanted: %s %s %uhz, got: %d channel%s %d-bit %luhz\n", DevFmtChannelsString(mDevice->FmtChans), DevFmtTypeString(mDevice->FmtType), mDevice->Frequency, wfx->nChannels, (wfx->nChannels==1)?"":"s", wfx->wBitsPerSample, wfx->nSamplesPerSec); CoTaskMemFree(wfx); return E_FAIL; } if(!MakeExtensible(&OutputType, wfx)) { CoTaskMemFree(wfx); return E_FAIL; } CoTaskMemFree(wfx); wfx = nullptr; } DevFmtType srcType; if(IsEqualGUID(OutputType.SubFormat, KSDATAFORMAT_SUBTYPE_PCM)) { if(OutputType.Format.wBitsPerSample == 8) srcType = DevFmtUByte; else if(OutputType.Format.wBitsPerSample == 16) srcType = DevFmtShort; else if(OutputType.Format.wBitsPerSample == 32) srcType = DevFmtInt; else { ERR("Unhandled integer bit depth: %d\n", OutputType.Format.wBitsPerSample); return E_FAIL; } } else if(IsEqualGUID(OutputType.SubFormat, KSDATAFORMAT_SUBTYPE_IEEE_FLOAT)) { if(OutputType.Format.wBitsPerSample == 32) srcType = DevFmtFloat; else { ERR("Unhandled float bit depth: %d\n", OutputType.Format.wBitsPerSample); return E_FAIL; } } else { ERR("Unhandled format sub-type\n"); return E_FAIL; } if(mDevice->FmtChans == DevFmtMono && OutputType.Format.nChannels == 2) { mChannelConv = CreateChannelConverter(srcType, DevFmtStereo, mDevice->FmtChans); if(!mChannelConv) { ERR("Failed to create %s stereo-to-mono converter\n", DevFmtTypeString(srcType)); return E_FAIL; } TRACE("Created %s stereo-to-mono converter\n", DevFmtTypeString(srcType)); /* The channel converter always outputs float, so change the input type * for the resampler/type-converter. */ srcType = DevFmtFloat; } else if(mDevice->FmtChans == DevFmtStereo && OutputType.Format.nChannels == 1) { mChannelConv = CreateChannelConverter(srcType, DevFmtMono, mDevice->FmtChans); if(!mChannelConv) { ERR("Failed to create %s mono-to-stereo converter\n", DevFmtTypeString(srcType)); return E_FAIL; } TRACE("Created %s mono-to-stereo converter\n", DevFmtTypeString(srcType)); srcType = DevFmtFloat; } if(mDevice->Frequency != OutputType.Format.nSamplesPerSec || mDevice->FmtType != srcType) { mSampleConv = CreateSampleConverter(srcType, mDevice->FmtType, mDevice->channelsFromFmt(), OutputType.Format.nSamplesPerSec, mDevice->Frequency, BSinc24Resampler); if(!mSampleConv) { ERR("Failed to create converter for %s format, dst: %s %uhz, src: %s %luhz\n", DevFmtChannelsString(mDevice->FmtChans), DevFmtTypeString(mDevice->FmtType), mDevice->Frequency, DevFmtTypeString(srcType), OutputType.Format.nSamplesPerSec); return E_FAIL; } TRACE("Created converter for %s format, dst: %s %uhz, src: %s %luhz\n", DevFmtChannelsString(mDevice->FmtChans), DevFmtTypeString(mDevice->FmtType), mDevice->Frequency, DevFmtTypeString(srcType), OutputType.Format.nSamplesPerSec); } hr = mClient->Initialize(AUDCLNT_SHAREMODE_SHARED, AUDCLNT_STREAMFLAGS_EVENTCALLBACK, buf_time, 0, &OutputType.Format, nullptr); if(FAILED(hr)) { ERR("Failed to initialize audio client: 0x%08lx\n", hr); return hr; } UINT32 buffer_len; REFERENCE_TIME min_per; hr = mClient->GetDevicePeriod(&min_per, nullptr); if(SUCCEEDED(hr)) hr = mClient->GetBufferSize(&buffer_len); if(FAILED(hr)) { ERR("Failed to get buffer size: 0x%08lx\n", hr); return hr; } mDevice->UpdateSize = static_cast(ScaleCeil(min_per, mDevice->Frequency, REFTIME_PER_SEC)); mDevice->BufferSize = buffer_len; buffer_len = maxu(mDevice->BufferSize, buffer_len); mRing = CreateRingBuffer(buffer_len, mDevice->frameSizeFromFmt(), false); if(!mRing) { ERR("Failed to allocate capture ring buffer\n"); return E_OUTOFMEMORY; } hr = mClient->SetEventHandle(mNotifyEvent); if(FAILED(hr)) { ERR("Failed to set event handle: 0x%08lx\n", hr); return hr; } return hr; } ALCboolean WasapiCapture::start() { HRESULT hr{pushMessage(MsgType::StartDevice).get()}; return SUCCEEDED(hr) ? ALC_TRUE : ALC_FALSE; } HRESULT WasapiCapture::startProxy() { ResetEvent(mNotifyEvent); HRESULT hr{mClient->Start()}; if(FAILED(hr)) { ERR("Failed to start audio client: 0x%08lx\n", hr); return hr; } void *ptr; hr = mClient->GetService(IID_IAudioCaptureClient, &ptr); if(SUCCEEDED(hr)) { mCapture = static_cast(ptr); try { mKillNow.store(false, std::memory_order_release); mThread = std::thread{std::mem_fn(&WasapiCapture::recordProc), this}; } catch(...) { mCapture->Release(); mCapture = nullptr; ERR("Failed to start thread\n"); hr = E_FAIL; } } if(FAILED(hr)) { mClient->Stop(); mClient->Reset(); } return hr; } void WasapiCapture::stop() { pushMessage(MsgType::StopDevice).wait(); } void WasapiCapture::stopProxy() { if(!mCapture || !mThread.joinable()) return; mKillNow.store(true, std::memory_order_release); mThread.join(); mCapture->Release(); mCapture = nullptr; mClient->Stop(); mClient->Reset(); } ALCuint WasapiCapture::availableSamples() { return (ALCuint)mRing->readSpace(); } ALCenum WasapiCapture::captureSamples(void *buffer, ALCuint samples) { mRing->read(buffer, samples); return ALC_NO_ERROR; } } // namespace bool WasapiBackendFactory::init() { static HRESULT InitResult{E_FAIL}; if(FAILED(InitResult)) try { std::promise promise; auto future = promise.get_future(); std::thread{&WasapiProxy::messageHandler, &promise}.detach(); InitResult = future.get(); } catch(...) { } return SUCCEEDED(InitResult) ? ALC_TRUE : ALC_FALSE; } bool WasapiBackendFactory::querySupport(BackendType type) { return type == BackendType::Playback || type == BackendType::Capture; } void WasapiBackendFactory::probe(DevProbe type, std::string *outnames) { auto add_device = [outnames](const DevMap &entry) -> void { /* +1 to also append the null char (to ensure a null-separated list and * double-null terminated list). */ outnames->append(entry.name.c_str(), entry.name.length()+1); }; HRESULT hr{}; switch(type) { case DevProbe::Playback: hr = WasapiProxy::pushMessageStatic(MsgType::EnumeratePlayback).get(); if(SUCCEEDED(hr)) std::for_each(PlaybackDevices.cbegin(), PlaybackDevices.cend(), add_device); break; case DevProbe::Capture: hr = WasapiProxy::pushMessageStatic(MsgType::EnumerateCapture).get(); if(SUCCEEDED(hr)) std::for_each(CaptureDevices.cbegin(), CaptureDevices.cend(), add_device); break; } } BackendPtr WasapiBackendFactory::createBackend(ALCdevice *device, BackendType type) { if(type == BackendType::Playback) return BackendPtr{new WasapiPlayback{device}}; if(type == BackendType::Capture) return BackendPtr{new WasapiCapture{device}}; return nullptr; } BackendFactory &WasapiBackendFactory::getFactory() { static WasapiBackendFactory factory{}; return factory; }