/* * This file is part of mpv. * * Original author: Jonathan Yong <10walls@gmail.com> * * mpv is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * mpv 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 Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with mpv. If not, see . */ #include #include #include #include #include #include #include #include "audio/format.h" #include "osdep/timer.h" #include "osdep/io.h" #include "osdep/strnlen.h" #include "ao_wasapi.h" #define MIXER_DEFAULT_LABEL L"mpv - video player" DEFINE_PROPERTYKEY(mp_PKEY_Device_FriendlyName, 0xa45c254e, 0xdf1c, 0x4efd, 0x80, 0x20, 0x67, 0xd1, 0x46, 0xa8, 0x50, 0xe0, 14); DEFINE_PROPERTYKEY(mp_PKEY_Device_DeviceDesc, 0xa45c254e, 0xdf1c, 0x4efd, 0x80, 0x20, 0x67, 0xd1, 0x46, 0xa8, 0x50, 0xe0, 2); // CEA 861 subformats // should work on vista DEFINE_GUID(mp_KSDATAFORMAT_SUBTYPE_IEC61937_DTS, 0x00000008, 0x0000, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); DEFINE_GUID(mp_KSDATAFORMAT_SUBTYPE_IEC61937_DOLBY_DIGITAL, 0x00000092, 0x0000, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); // might require 7+ DEFINE_GUID(mp_KSDATAFORMAT_SUBTYPE_IEC61937_AAC, 0x00000006, 0x0cea, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); DEFINE_GUID(mp_KSDATAFORMAT_SUBTYPE_IEC61937_MPEG3, 0x00000004, 0x0cea, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); DEFINE_GUID(mp_KSDATAFORMAT_SUBTYPE_IEC61937_DOLBY_DIGITAL_PLUS, 0x0000000a, 0x0cea, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); DEFINE_GUID(mp_KSDATAFORMAT_SUBTYPE_IEC61937_DTS_HD, 0x0000000b, 0x0cea, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); DEFINE_GUID(mp_KSDATAFORMAT_SUBTYPE_IEC61937_DOLBY_MLP, 0x0000000c, 0x0cea, 0x0010, 0x80, 0x00, 0x00, 0xaa, 0x00, 0x38, 0x9b, 0x71); struct wasapi_sample_fmt { int mp_format; // AF_FORMAT_* int bits; // aka wBitsPerSample int used_msb; // aka wValidBitsPerSample const GUID *subtype; }; // some common bit depths / container sizes (requests welcome) // Entries that have the same mp_format must be: // 1. consecutive // 2. sorted by preferred format (worst comes last) static const struct wasapi_sample_fmt wasapi_formats[] = { {AF_FORMAT_U8, 8, 8, &KSDATAFORMAT_SUBTYPE_PCM}, {AF_FORMAT_S16, 16, 16, &KSDATAFORMAT_SUBTYPE_PCM}, {AF_FORMAT_S32, 32, 32, &KSDATAFORMAT_SUBTYPE_PCM}, // compatible, assume LSBs are ignored {AF_FORMAT_S32, 32, 24, &KSDATAFORMAT_SUBTYPE_PCM}, // aka S24 (with conversion) - untested, thus commented. //{AF_FORMAT_S32, 24, 24, &KSDATAFORMAT_SUBTYPE_PCM}, {AF_FORMAT_FLOAT, 32, 32, &KSDATAFORMAT_SUBTYPE_IEEE_FLOAT}, {AF_FORMAT_S_AC3, 16, 16, &mp_KSDATAFORMAT_SUBTYPE_IEC61937_DOLBY_DIGITAL}, {AF_FORMAT_S_DTS, 16, 16, &mp_KSDATAFORMAT_SUBTYPE_IEC61937_DTS}, {AF_FORMAT_S_AAC, 16, 16, &mp_KSDATAFORMAT_SUBTYPE_IEC61937_AAC}, {AF_FORMAT_S_MP3, 16, 16, &mp_KSDATAFORMAT_SUBTYPE_IEC61937_MPEG3}, {AF_FORMAT_S_TRUEHD, 16, 16, &mp_KSDATAFORMAT_SUBTYPE_IEC61937_DOLBY_MLP}, {AF_FORMAT_S_EAC3, 16, 16, &mp_KSDATAFORMAT_SUBTYPE_IEC61937_DOLBY_DIGITAL_PLUS}, {AF_FORMAT_S_DTSHD, 16, 16, &mp_KSDATAFORMAT_SUBTYPE_IEC61937_DTS_HD}, {0}, }; static const GUID *format_to_subtype(int format) { for (int i = 0; wasapi_formats[i].mp_format; i++) { if (format == wasapi_formats[i].mp_format) return wasapi_formats[i].subtype; } return &KSDATAFORMAT_SPECIFIER_NONE; } // "solve" the under-determined inverse of format_to_subtype by assuming the // input subtype is "special" (i.e. IEC61937) static int special_subtype_to_format(const GUID *subtype) { for (int i = 0; wasapi_formats[i].mp_format; i++) { if (IsEqualGUID(subtype, wasapi_formats[i].subtype) && af_fmt_is_spdif(wasapi_formats[i].mp_format)) return wasapi_formats[i].mp_format; } return 0; } char *mp_PKEY_to_str_buf(char *buf, size_t buf_size, const PROPERTYKEY *pkey) { buf = mp_GUID_to_str_buf(buf, buf_size, &pkey->fmtid); size_t guid_len = strnlen(buf, buf_size); snprintf(buf + guid_len, buf_size - guid_len, ",%"PRIu32, (uint32_t) pkey->pid); return buf; } static void update_waveformat_datarate(WAVEFORMATEXTENSIBLE *wformat) { WAVEFORMATEX *wf = &wformat->Format; wf->nBlockAlign = wf->nChannels * wf->wBitsPerSample / 8; wf->nAvgBytesPerSec = wf->nSamplesPerSec * wf->nBlockAlign; } static void set_waveformat(WAVEFORMATEXTENSIBLE *wformat, struct wasapi_sample_fmt format, DWORD samplerate, struct mp_chmap *channels) { wformat->Format.wFormatTag = WAVE_FORMAT_EXTENSIBLE; wformat->Format.nChannels = channels->num; wformat->Format.nSamplesPerSec = samplerate; wformat->Format.wBitsPerSample = format.bits; wformat->Format.cbSize = sizeof(WAVEFORMATEXTENSIBLE) - sizeof(WAVEFORMATEX); wformat->SubFormat = *format_to_subtype(format.mp_format); wformat->Samples.wValidBitsPerSample = format.used_msb; wformat->dwChannelMask = mp_chmap_to_waveext(channels); update_waveformat_datarate(wformat); } // This implicitly transforms all pcm formats to: interleaved / signed (except // 8-bit is unsigned) / waveext channel order. "Special" formats should be // exempt as they should already satisfy these properties. static void set_waveformat_with_ao(WAVEFORMATEXTENSIBLE *wformat, struct ao *ao) { struct mp_chmap channels = ao->channels; if (mp_chmap_is_unknown(&channels)) mp_chmap_from_channels(&channels, channels.num); mp_chmap_reorder_to_waveext(&channels); if (!mp_chmap_is_valid(&channels)) mp_chmap_from_channels(&channels, 2); // First find a format that is actually representable. // (Notably excludes AF_FORMAT_DOUBLE.) struct wasapi_sample_fmt format = {AF_FORMAT_S16, 16, 16, &KSDATAFORMAT_SUBTYPE_PCM}; int alt_formats[AF_FORMAT_COUNT]; af_get_best_sample_formats(ao->format, alt_formats); for (int n = 0; alt_formats[n]; n++) { for (int i = 0; wasapi_formats[i].mp_format; i++) { if (wasapi_formats[i].mp_format == alt_formats[n]) format = wasapi_formats[i]; } } set_waveformat(wformat, format, ao->samplerate, &channels); } // other wformat parameters must already be set with set_waveformat static void change_waveformat_samplerate(WAVEFORMATEXTENSIBLE *wformat, DWORD samplerate) { wformat->Format.nSamplesPerSec = samplerate; update_waveformat_datarate(wformat); } // other wformat parameters must already be set with set_waveformat static void change_waveformat_channels(WAVEFORMATEXTENSIBLE *wformat, struct mp_chmap *channels) { wformat->Format.nChannels = channels->num; wformat->dwChannelMask = mp_chmap_to_waveext(channels); update_waveformat_datarate(wformat); } static struct wasapi_sample_fmt format_from_waveformat(WAVEFORMATEX *wf) { struct wasapi_sample_fmt res = {0}; for (int n = 0; wasapi_formats[n].mp_format; n++) { const struct wasapi_sample_fmt *fmt = &wasapi_formats[n]; int valid_bits = 0; if (wf->wBitsPerSample != fmt->bits) continue; const GUID *wf_guid = NULL; switch (wf->wFormatTag) { case WAVE_FORMAT_EXTENSIBLE: { WAVEFORMATEXTENSIBLE *wformat = (WAVEFORMATEXTENSIBLE *)wf; wf_guid = &wformat->SubFormat; if (IsEqualGUID(wf_guid, &KSDATAFORMAT_SUBTYPE_PCM)) valid_bits = wformat->Samples.wValidBitsPerSample; break; } case WAVE_FORMAT_PCM: wf_guid = &KSDATAFORMAT_SUBTYPE_PCM; break; case WAVE_FORMAT_IEEE_FLOAT: wf_guid = &KSDATAFORMAT_SUBTYPE_IEEE_FLOAT; break; } if (!wf_guid || !IsEqualGUID(wf_guid, fmt->subtype)) continue; res = *fmt; if (valid_bits > 0 && valid_bits < fmt->bits) res.used_msb = valid_bits; break; } return res; } static bool chmap_from_waveformat(struct mp_chmap *channels, const WAVEFORMATEX *wf) { if (wf->wFormatTag == WAVE_FORMAT_EXTENSIBLE) { WAVEFORMATEXTENSIBLE *wformat = (WAVEFORMATEXTENSIBLE *)wf; mp_chmap_from_waveext(channels, wformat->dwChannelMask); } else { mp_chmap_from_channels(channels, wf->nChannels); } if (channels->num != wf->nChannels) { mp_chmap_from_str(channels, bstr0("empty")); return false; } return true; } static char *waveformat_to_str_buf(char *buf, size_t buf_size, WAVEFORMATEX *wf) { struct mp_chmap channels; chmap_from_waveformat(&channels, wf); struct wasapi_sample_fmt format = format_from_waveformat(wf); snprintf(buf, buf_size, "%s %s (%d/%d bits) @ %uhz", mp_chmap_to_str(&channels), af_fmt_to_str(format.mp_format), format.bits, format.used_msb, (unsigned) wf->nSamplesPerSec); return buf; } #define waveformat_to_str(wf) waveformat_to_str_buf((char[64]){0}, 64, (wf)) static void waveformat_copy(WAVEFORMATEXTENSIBLE* dst, WAVEFORMATEX* src) { if (src->wFormatTag == WAVE_FORMAT_EXTENSIBLE) { *dst = *(WAVEFORMATEXTENSIBLE *)src; } else { dst->Format = *src; } } static bool set_ao_format(struct ao *ao, WAVEFORMATEX *wf, AUDCLNT_SHAREMODE share_mode) { struct wasapi_state *state = ao->priv; struct wasapi_sample_fmt format = format_from_waveformat(wf); if (!format.mp_format) { MP_ERR(ao, "Unable to construct sample format from WAVEFORMAT %s\n", waveformat_to_str(wf)); return false; } // Do not touch the ao for passthrough, just assume that we set WAVEFORMATEX // correctly. if (af_fmt_is_pcm(format.mp_format)) { struct mp_chmap channels; if (!chmap_from_waveformat(&channels, wf)) { MP_ERR(ao, "Unable to construct channel map from WAVEFORMAT %s\n", waveformat_to_str(wf)); return false; } struct ao_convert_fmt conv = { .src_fmt = format.mp_format, .channels = channels.num, .dst_bits = format.bits, .pad_lsb = format.bits - format.used_msb, }; if (!ao_can_convert_inplace(&conv)) { MP_ERR(ao, "Unable to convert to %s\n", waveformat_to_str(wf)); return false; } state->convert_format = conv; ao->samplerate = wf->nSamplesPerSec; ao->format = format.mp_format; ao->channels = channels; } waveformat_copy(&state->format, wf); state->share_mode = share_mode; return true; } static bool try_format_exclusive(struct ao *ao, WAVEFORMATEXTENSIBLE *wformat) { struct wasapi_state *state = ao->priv; HRESULT hr = IAudioClient_IsFormatSupported(state->pAudioClient, AUDCLNT_SHAREMODE_EXCLUSIVE, &wformat->Format, NULL); MP_VERBOSE(ao, "Trying %s (exclusive) -> %s\n", waveformat_to_str(&wformat->Format), mp_format_res_str(hr)); return SUCCEEDED(hr); } // This works like try_format_exclusive(), but will try to fallback to the AC3 // format if the format is a non-AC3 passthrough format. *wformat will be // adjusted accordingly. static bool try_format_exclusive_with_spdif_fallback(struct ao *ao, WAVEFORMATEXTENSIBLE *wformat) { if (try_format_exclusive(ao, wformat)) return true; int special_format = special_subtype_to_format(&wformat->SubFormat); if (special_format && special_format != AF_FORMAT_S_AC3) { MP_VERBOSE(ao, "Retrying as AC3.\n"); wformat->SubFormat = *format_to_subtype(AF_FORMAT_S_AC3); return try_format_exclusive(ao, wformat); } return false; } static bool search_sample_formats(struct ao *ao, WAVEFORMATEXTENSIBLE *wformat, int samplerate, struct mp_chmap *channels) { int alt_formats[AF_FORMAT_COUNT]; af_get_best_sample_formats(ao->format, alt_formats); for (int n = 0; alt_formats[n]; n++) { for (int i = 0; wasapi_formats[i].mp_format; i++) { if (wasapi_formats[i].mp_format == alt_formats[n]) { set_waveformat(wformat, wasapi_formats[i], samplerate, channels); if (try_format_exclusive(ao, wformat)) return true; } } } wformat->Format.wBitsPerSample = 0; return false; } static bool search_samplerates(struct ao *ao, WAVEFORMATEXTENSIBLE *wformat, struct mp_chmap *channels) { // try list of typical sample rates (requests welcome) int try[] = {8000, 11025, 16000, 22050, 32000, 44100, 48000, 88200, 96000, 176400, 192000, 352800, 384000, 0}; // get a list of supported rates int n = 0; int supported[MP_ARRAY_SIZE(try)] = {0}; wformat->Format.wBitsPerSample = 0; for (int i = 0; try[i]; i++) { if (!wformat->Format.wBitsPerSample) { if (search_sample_formats(ao, wformat, try[i], channels)) supported[n++] = try[i]; } else { change_waveformat_samplerate(wformat, try[i]); if (try_format_exclusive(ao, wformat)) supported[n++] = try[i]; } } int samplerate = af_select_best_samplerate(ao->samplerate, supported); if (samplerate > 0) { change_waveformat_samplerate(wformat, samplerate); return true; } // otherwise, this is probably an unsupported channel map wformat->Format.nSamplesPerSec = 0; return false; } static bool search_channels(struct ao *ao, WAVEFORMATEXTENSIBLE *wformat) { struct wasapi_state *state = ao->priv; struct mp_chmap_sel chmap_sel = {.tmp = state}; struct mp_chmap entry; // put common layouts first so that we find sample rate/format early char *channel_layouts[] = {"mono", "stereo", "2.1", "4.0", "5.0", "5.1", "6.1", "7.1", "3.0", "3.0(back)", "quad", "quad(side)", "3.1", "5.0(side)", "4.1", "5.1(side)", "6.0", "6.0(front)", "hexagonal" "6.1(back)", "6.1(front)", "7.0", "7.0(front)", "7.1(wide)", "7.1(wide-side)", "7.1(rear)", "octagonal", NULL}; wformat->Format.nSamplesPerSec = 0; for (int j = 0; channel_layouts[j]; j++) { mp_chmap_from_str(&entry, bstr0(channel_layouts[j])); if (!wformat->Format.nSamplesPerSec) { if (search_samplerates(ao, wformat, &entry)) mp_chmap_sel_add_map(&chmap_sel, &entry); } else { change_waveformat_channels(wformat, &entry); if (try_format_exclusive(ao, wformat)) mp_chmap_sel_add_map(&chmap_sel, &entry); } } entry = ao->channels; if (ao_chmap_sel_adjust2(ao, &chmap_sel, &entry, !state->opt_exclusive)){ change_waveformat_channels(wformat, &entry); return true; } MP_ERR(ao, "No suitable audio format found\n"); return false; } static bool find_formats_exclusive(struct ao *ao, bool do_search) { WAVEFORMATEXTENSIBLE wformat; set_waveformat_with_ao(&wformat, ao); // Try the requested format as is. If that doesn't work, and the do_search // argument is set, do the pcm format search. if (!try_format_exclusive_with_spdif_fallback(ao, &wformat) && (!do_search || !search_channels(ao, &wformat))) return false; if (!set_ao_format(ao, &wformat.Format, AUDCLNT_SHAREMODE_EXCLUSIVE)) return false; MP_VERBOSE(ao, "Accepted as %s %s @ %dhz (exclusive) -> %s\n", mp_chmap_to_str(&ao->channels), af_fmt_to_str(ao->format), ao->samplerate, waveformat_to_str(&wformat.Format)); return true; } static bool find_formats_shared(struct ao *ao) { struct wasapi_state *state = ao->priv; WAVEFORMATEXTENSIBLE wformat; set_waveformat_with_ao(&wformat, ao); WAVEFORMATEX *closestMatch; HRESULT hr = IAudioClient_IsFormatSupported(state->pAudioClient, AUDCLNT_SHAREMODE_SHARED, &wformat.Format, &closestMatch); MP_VERBOSE(ao, "Trying %s (shared) -> %s\n", waveformat_to_str(&wformat.Format), mp_format_res_str(hr)); if (hr != AUDCLNT_E_UNSUPPORTED_FORMAT) EXIT_ON_ERROR(hr); switch (hr) { case S_OK: break; case S_FALSE: waveformat_copy(&wformat, closestMatch); CoTaskMemFree(closestMatch); MP_VERBOSE(ao, "Closest match is %s\n", waveformat_to_str(&wformat.Format)); break; default: hr = IAudioClient_GetMixFormat(state->pAudioClient, &closestMatch); EXIT_ON_ERROR(hr); waveformat_copy(&wformat, closestMatch); MP_VERBOSE(ao, "Fallback to mix format %s\n", waveformat_to_str(&wformat.Format)); CoTaskMemFree(closestMatch); } if (!set_ao_format(ao, &wformat.Format, AUDCLNT_SHAREMODE_SHARED)) return false; MP_VERBOSE(ao, "Accepted as %s %s @ %dhz (shared) -> %s\n", mp_chmap_to_str(&ao->channels), af_fmt_to_str(ao->format), ao->samplerate, waveformat_to_str(&wformat.Format)); return true; exit_label: MP_ERR(state, "Error finding shared mode format: %s\n", mp_HRESULT_to_str(hr)); return false; } static bool find_formats(struct ao *ao) { struct wasapi_state *state = ao->priv; if (state->opt_exclusive) { // If exclusive is requested, try the requested format (which // might be passthrough). If that fails, do a pcm format // search. return find_formats_exclusive(ao, true); } else if (af_fmt_is_spdif(ao->format)) { // If a passthrough format is requested, but exclusive mode // was not explicitly set, try only the requested passthrough // format in exclusive mode. Fall back on shared mode if that // fails without doing the exclusive pcm format search. if (find_formats_exclusive(ao, false)) return true; } // Default is to use shared mode return find_formats_shared(ao); } static HRESULT init_clock(struct wasapi_state *state) { HRESULT hr = IAudioClient_GetService(state->pAudioClient, &IID_IAudioClock, (void **)&state->pAudioClock); EXIT_ON_ERROR(hr); hr = IAudioClock_GetFrequency(state->pAudioClock, &state->clock_frequency); EXIT_ON_ERROR(hr); QueryPerformanceFrequency(&state->qpc_frequency); atomic_store(&state->sample_count, 0); MP_VERBOSE(state, "IAudioClock::GetFrequency gave a frequency of %"PRIu64".\n", (uint64_t) state->clock_frequency); return S_OK; exit_label: MP_ERR(state, "Error obtaining the audio device's timing: %s\n", mp_HRESULT_to_str(hr)); return hr; } static void init_session_display(struct wasapi_state *state) { HRESULT hr = IAudioClient_GetService(state->pAudioClient, &IID_IAudioSessionControl, (void **)&state->pSessionControl); EXIT_ON_ERROR(hr); wchar_t path[MAX_PATH+12] = {0}; GetModuleFileNameW(NULL, path, MAX_PATH); wcscat(path, L",-IDI_ICON1"); hr = IAudioSessionControl_SetIconPath(state->pSessionControl, path, NULL); if (FAILED(hr)) { // don't goto exit_label here since SetDisplayName might still work MP_WARN(state, "Error setting audio session icon: %s\n", mp_HRESULT_to_str(hr)); } hr = IAudioSessionControl_SetDisplayName(state->pSessionControl, MIXER_DEFAULT_LABEL, NULL); EXIT_ON_ERROR(hr); return; exit_label: // if we got here then the session control is useless - release it SAFE_RELEASE(state->pSessionControl); MP_WARN(state, "Error setting audio session display name: %s\n", mp_HRESULT_to_str(hr)); return; } static void init_volume_control(struct wasapi_state *state) { HRESULT hr; if (state->share_mode == AUDCLNT_SHAREMODE_EXCLUSIVE) { MP_DBG(state, "Activating pEndpointVolume interface\n"); hr = IMMDeviceActivator_Activate(state->pDevice, &IID_IAudioEndpointVolume, CLSCTX_ALL, NULL, (void **)&state->pEndpointVolume); EXIT_ON_ERROR(hr); MP_DBG(state, "IAudioEndpointVolume::QueryHardwareSupport\n"); hr = IAudioEndpointVolume_QueryHardwareSupport(state->pEndpointVolume, &state->vol_hw_support); EXIT_ON_ERROR(hr); } else { MP_DBG(state, "IAudioClient::Initialize pAudioVolume\n"); hr = IAudioClient_GetService(state->pAudioClient, &IID_ISimpleAudioVolume, (void **)&state->pAudioVolume); EXIT_ON_ERROR(hr); } return; exit_label: state->vol_hw_support = 0; SAFE_RELEASE(state->pEndpointVolume); SAFE_RELEASE(state->pAudioVolume); MP_WARN(state, "Error setting up volume control: %s\n", mp_HRESULT_to_str(hr)); } static HRESULT fix_format(struct ao *ao, bool align_hack) { struct wasapi_state *state = ao->priv; MP_DBG(state, "IAudioClient::GetDevicePeriod\n"); REFERENCE_TIME devicePeriod; HRESULT hr = IAudioClient_GetDevicePeriod(state->pAudioClient,&devicePeriod, NULL); MP_VERBOSE(state, "Device period: %.2g ms\n", (double) devicePeriod / 10000.0 ); REFERENCE_TIME bufferDuration = devicePeriod; if (state->share_mode == AUDCLNT_SHAREMODE_SHARED) { // for shared mode, use integer multiple of device period close to 50ms bufferDuration = devicePeriod * ceil(50.0 * 10000.0 / devicePeriod); } // handle unsupported buffer size if AUDCLNT_E_BUFFER_SIZE_NOT_ALIGNED was // returned in a previous attempt. hopefully this shouldn't happen because // of the above integer device period // http://msdn.microsoft.com/en-us/library/windows/desktop/dd370875%28v=vs.85%29.aspx if (align_hack) { bufferDuration = (REFERENCE_TIME) (0.5 + (10000.0 * 1000 / state->format.Format.nSamplesPerSec * state->bufferFrameCount)); } // in exclusive mode, these should all be the same REFERENCE_TIME bufferPeriod = state->share_mode == AUDCLNT_SHAREMODE_EXCLUSIVE ? bufferDuration : 0; MP_DBG(state, "IAudioClient::Initialize\n"); hr = IAudioClient_Initialize(state->pAudioClient, state->share_mode, AUDCLNT_STREAMFLAGS_EVENTCALLBACK, bufferDuration, bufferPeriod, &(state->format.Format), NULL); EXIT_ON_ERROR(hr); MP_DBG(state, "IAudioClient::Initialize pRenderClient\n"); hr = IAudioClient_GetService(state->pAudioClient, &IID_IAudioRenderClient, (void **)&state->pRenderClient); EXIT_ON_ERROR(hr); MP_DBG(state, "IAudioClient::Initialize IAudioClient_SetEventHandle\n"); hr = IAudioClient_SetEventHandle(state->pAudioClient, state->hWake); EXIT_ON_ERROR(hr); MP_DBG(state, "IAudioClient::Initialize IAudioClient_GetBufferSize\n"); hr = IAudioClient_GetBufferSize(state->pAudioClient, &state->bufferFrameCount); EXIT_ON_ERROR(hr); ao->device_buffer = state->bufferFrameCount; bufferDuration = (REFERENCE_TIME) (0.5 + (10000.0 * 1000 / state->format.Format.nSamplesPerSec * state->bufferFrameCount)); MP_VERBOSE(state, "Buffer frame count: %"PRIu32" (%.2g ms)\n", state->bufferFrameCount, (double) bufferDuration / 10000.0 ); hr = init_clock(state); EXIT_ON_ERROR(hr); init_session_display(state); init_volume_control(state); #if !HAVE_UWP state->hTask = AvSetMmThreadCharacteristics(L"Pro Audio", &(DWORD){0}); if (!state->hTask) { MP_WARN(state, "Failed to set AV thread to Pro Audio: %s\n", mp_LastError_to_str()); } #endif return S_OK; exit_label: MP_ERR(state, "Error initializing device: %s\n", mp_HRESULT_to_str(hr)); return hr; } struct device_desc { LPWSTR deviceID; char *id; char *name; }; static char* get_device_name(struct mp_log *l, void *talloc_ctx, IMMDevice *pDevice) { char *namestr = NULL; IPropertyStore *pProps = NULL; PROPVARIANT devname; PropVariantInit(&devname); HRESULT hr = IMMDevice_OpenPropertyStore(pDevice, STGM_READ, &pProps); EXIT_ON_ERROR(hr); hr = IPropertyStore_GetValue(pProps, &mp_PKEY_Device_FriendlyName, &devname); EXIT_ON_ERROR(hr); namestr = mp_to_utf8(talloc_ctx, devname.pwszVal); exit_label: if (FAILED(hr)) mp_warn(l, "Failed getting device name: %s\n", mp_HRESULT_to_str(hr)); PropVariantClear(&devname); SAFE_RELEASE(pProps); return namestr ? namestr : talloc_strdup(talloc_ctx, ""); } static struct device_desc *get_device_desc(struct mp_log *l, IMMDevice *pDevice) { LPWSTR deviceID; HRESULT hr = IMMDevice_GetId(pDevice, &deviceID); if (FAILED(hr)) { mp_err(l, "Failed getting device id: %s\n", mp_HRESULT_to_str(hr)); return NULL; } struct device_desc *d = talloc_zero(NULL, struct device_desc); d->deviceID = talloc_memdup(d, deviceID, (wcslen(deviceID) + 1) * sizeof(wchar_t)); SAFE_DESTROY(deviceID, CoTaskMemFree(deviceID)); char *full_id = mp_to_utf8(NULL, d->deviceID); bstr id = bstr0(full_id); bstr_eatstart0(&id, "{0.0.0.00000000}."); d->id = bstrdup0(d, id); talloc_free(full_id); d->name = get_device_name(l, d, pDevice); return d; } struct enumerator { struct mp_log *log; IMMDeviceEnumerator *pEnumerator; IMMDeviceCollection *pDevices; UINT count; }; static void destroy_enumerator(struct enumerator *e) { if (!e) return; SAFE_RELEASE(e->pDevices); SAFE_RELEASE(e->pEnumerator); talloc_free(e); } static struct enumerator *create_enumerator(struct mp_log *log) { struct enumerator *e = talloc_zero(NULL, struct enumerator); e->log = log; HRESULT hr = CoCreateInstance( &CLSID_MMDeviceEnumerator, NULL, CLSCTX_ALL, &IID_IMMDeviceEnumerator, (void **)&e->pEnumerator); EXIT_ON_ERROR(hr); hr = IMMDeviceEnumerator_EnumAudioEndpoints( e->pEnumerator, eRender, DEVICE_STATE_ACTIVE, &e->pDevices); EXIT_ON_ERROR(hr); hr = IMMDeviceCollection_GetCount(e->pDevices, &e->count); EXIT_ON_ERROR(hr); return e; exit_label: mp_err(log, "Error getting device enumerator: %s\n", mp_HRESULT_to_str(hr)); destroy_enumerator(e); return NULL; } static struct device_desc *device_desc_for_num(struct enumerator *e, UINT i) { IMMDevice *pDevice = NULL; HRESULT hr = IMMDeviceCollection_Item(e->pDevices, i, &pDevice); if (FAILED(hr)) { MP_ERR(e, "Failed getting device #%d: %s\n", i, mp_HRESULT_to_str(hr)); return NULL; } struct device_desc *d = get_device_desc(e->log, pDevice); SAFE_RELEASE(pDevice); return d; } static struct device_desc *default_device_desc(struct enumerator *e) { IMMDevice *pDevice = NULL; HRESULT hr = IMMDeviceEnumerator_GetDefaultAudioEndpoint( e->pEnumerator, eRender, eMultimedia, &pDevice); if (FAILED(hr)) { MP_ERR(e, "Error from GetDefaultAudioEndpoint: %s\n", mp_HRESULT_to_str(hr)); return NULL; } struct device_desc *d = get_device_desc(e->log, pDevice); SAFE_RELEASE(pDevice); return d; } void wasapi_list_devs(struct ao *ao, struct ao_device_list *list) { struct enumerator *enumerator = create_enumerator(ao->log); if (!enumerator) return; for (UINT i = 0; i < enumerator->count; i++) { struct device_desc *d = device_desc_for_num(enumerator, i); if (!d) goto exit_label; ao_device_list_add(list, ao, &(struct ao_device_desc){d->id, d->name}); talloc_free(d); } exit_label: destroy_enumerator(enumerator); } static HRESULT load_device(struct mp_log *l, IMMDevice **ppDevice, LPWSTR deviceID) { IMMDeviceEnumerator *pEnumerator = NULL; HRESULT hr = CoCreateInstance(&CLSID_MMDeviceEnumerator, NULL, CLSCTX_ALL, &IID_IMMDeviceEnumerator, (void **)&pEnumerator); EXIT_ON_ERROR(hr); hr = IMMDeviceEnumerator_GetDevice(pEnumerator, deviceID, ppDevice); EXIT_ON_ERROR(hr); exit_label: if (FAILED(hr)) mp_err(l, "Error loading selected device: %s\n", mp_HRESULT_to_str(hr)); SAFE_RELEASE(pEnumerator); return hr; } static LPWSTR select_device(struct mp_log *l, struct device_desc *d) { if (!d) return NULL; mp_verbose(l, "Selecting device \'%s\' (%s)\n", d->id, d->name); return talloc_memdup(NULL, d->deviceID, (wcslen(d->deviceID) + 1) * sizeof(wchar_t)); } bstr wasapi_get_specified_device_string(struct ao *ao) { return bstr_strip(bstr0(ao->device)); } LPWSTR wasapi_find_deviceID(struct ao *ao) { LPWSTR deviceID = NULL; bstr device = wasapi_get_specified_device_string(ao); MP_DBG(ao, "Find device \'%.*s\'\n", BSTR_P(device)); struct device_desc *d = NULL; struct enumerator *enumerator = create_enumerator(ao->log); if (!enumerator) goto exit_label; if (!enumerator->count) { MP_ERR(ao, "There are no playback devices available\n"); goto exit_label; } if (!device.len) { MP_VERBOSE(ao, "No device specified. Selecting default.\n"); d = default_device_desc(enumerator); deviceID = select_device(ao->log, d); goto exit_label; } // try selecting by number bstr rest; long long devno = bstrtoll(device, &rest, 10); if (!rest.len && 0 <= devno && devno < (long long)enumerator->count) { MP_VERBOSE(ao, "Selecting device by number: #%lld\n", devno); d = device_desc_for_num(enumerator, devno); deviceID = select_device(ao->log, d); goto exit_label; } // select by id or name bstr_eatstart0(&device, "{0.0.0.00000000}."); for (UINT i = 0; i < enumerator->count; i++) { d = device_desc_for_num(enumerator, i); if (!d) goto exit_label; if (bstrcmp(device, bstr_strip(bstr0(d->id))) == 0) { MP_VERBOSE(ao, "Selecting device by id: \'%.*s\'\n", BSTR_P(device)); deviceID = select_device(ao->log, d); goto exit_label; } if (bstrcmp(device, bstr_strip(bstr0(d->name))) == 0) { if (!deviceID) { MP_VERBOSE(ao, "Selecting device by name: \'%.*s\'\n", BSTR_P(device)); deviceID = select_device(ao->log, d); } else { MP_WARN(ao, "Multiple devices matched \'%.*s\'." "Ignoring device \'%s\' (%s).\n", BSTR_P(device), d->id, d->name); } } SAFE_DESTROY(d, talloc_free(d)); } if (!deviceID) MP_ERR(ao, "Failed to find device \'%.*s\'\n", BSTR_P(device)); exit_label: talloc_free(d); destroy_enumerator(enumerator); return deviceID; } HRESULT wasapi_thread_init(struct ao *ao) { struct wasapi_state *state = ao->priv; MP_DBG(ao, "Init wasapi thread\n"); int64_t retry_wait = 1; bool align_hack = false; HRESULT hr; ao->format = af_fmt_from_planar(ao->format); retry: ; if (state->deviceID) { hr = load_device(ao->log, &state->pDevice, state->deviceID); EXIT_ON_ERROR(hr); MP_DBG(ao, "Activating pAudioClient interface\n"); hr = IMMDeviceActivator_Activate(state->pDevice, &IID_IAudioClient, CLSCTX_ALL, NULL, (void **)&state->pAudioClient); EXIT_ON_ERROR(hr); } else { MP_VERBOSE(ao, "Trying UWP wrapper.\n"); HRESULT (*wuCreateDefaultAudioRenderer)(IUnknown **res) = NULL; HANDLE lib = LoadLibraryW(L"wasapiuwp2.dll"); if (!lib) { MP_ERR(ao, "Wrapper not found: %d\n", (int)GetLastError()); hr = E_FAIL; EXIT_ON_ERROR(hr); } if (lib) { wuCreateDefaultAudioRenderer = (void*)GetProcAddress(lib, "wuCreateDefaultAudioRenderer"); } if (!wuCreateDefaultAudioRenderer) { MP_ERR(ao, "Function not found.\n"); hr = E_FAIL; EXIT_ON_ERROR(hr); } IUnknown *res = NULL; hr = wuCreateDefaultAudioRenderer(&res); MP_VERBOSE(ao, "Device: %s %p\n", mp_HRESULT_to_str(hr), res); EXIT_ON_ERROR(hr); hr = IUnknown_QueryInterface(res, &IID_IAudioClient, (void **)&state->pAudioClient); IUnknown_Release(res); EXIT_ON_ERROR(hr); } MP_DBG(ao, "Probing formats\n"); if (!find_formats(ao)) { hr = E_FAIL; EXIT_ON_ERROR(hr); } MP_DBG(ao, "Fixing format\n"); hr = fix_format(ao, align_hack); if (hr == AUDCLNT_E_BUFFER_SIZE_NOT_ALIGNED && !align_hack) { // According to MSDN, we must use this as base after the failure. IAudioClient_GetBufferSize(state->pAudioClient, &state->bufferFrameCount); SAFE_RELEASE(state->pAudioClient); align_hack = true; MP_WARN(ao, "This appears to require a weird Windows 7 hack. Retrying.\n"); goto retry; } if ((hr == AUDCLNT_E_DEVICE_IN_USE || hr == AUDCLNT_E_DEVICE_INVALIDATED) && retry_wait <= 8) { wasapi_thread_uninit(ao); MP_WARN(ao, "Retrying in %"PRId64" us\n", retry_wait); mp_sleep_us(retry_wait); retry_wait *= 2; goto retry; } EXIT_ON_ERROR(hr); MP_DBG(ao, "Init wasapi thread done\n"); return S_OK; exit_label: MP_FATAL(state, "Error setting up audio thread: %s\n", mp_HRESULT_to_str(hr)); return hr; } void wasapi_thread_uninit(struct ao *ao) { struct wasapi_state *state = ao->priv; MP_DBG(ao, "Thread shutdown\n"); if (state->pAudioClient) IAudioClient_Stop(state->pAudioClient); SAFE_RELEASE(state->pRenderClient); SAFE_RELEASE(state->pAudioClock); SAFE_RELEASE(state->pAudioVolume); SAFE_RELEASE(state->pEndpointVolume); SAFE_RELEASE(state->pSessionControl); SAFE_RELEASE(state->pAudioClient); SAFE_RELEASE(state->pDevice); #if !HAVE_UWP SAFE_DESTROY(state->hTask, AvRevertMmThreadCharacteristics(state->hTask)); #endif MP_DBG(ao, "Thread uninit done\n"); }