/* * CoreAudio audio output driver for macOS * * original copyright (C) Timothy J. Wood - Aug 2000 * ported to MPlayer libao2 by Dan Christiansen * * Chris Roccati * Stefano Pigozzi * * The S/PDIF part of the code is based on the auhal audio output * module from VideoLAN: * Copyright (c) 2006 Derk-Jan Hartman * * This file is part of mpv. * * 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 . */ /* * The macOS CoreAudio framework doesn't mesh as simply as some * simpler frameworks do. This is due to the fact that CoreAudio pulls * audio samples rather than having them pushed at it (which is nice * when you are wanting to do good buffering of audio). */ #include #include #include #include #include "ao.h" #include "internal.h" #include "audio/format.h" #include "osdep/timer.h" #include "options/m_option.h" #include "common/msg.h" #include "audio/out/ao_coreaudio_chmap.h" #include "audio/out/ao_coreaudio_properties.h" #include "audio/out/ao_coreaudio_utils.h" struct priv { // This must be put in the front struct coreaudio_cb_sem sem; AudioDeviceID device; // selected device bool paused; // audio render callback AudioDeviceIOProcID render_cb; // pid set for hog mode, (-1) means that hog mode on the device was // released. hog mode is exclusive access to a device pid_t hog_pid; AudioStreamID stream; // stream index in an AudioBufferList int stream_idx; // format we changed the stream to, and the original format to restore AudioStreamBasicDescription stream_asbd; AudioStreamBasicDescription original_asbd; // Output s16 physical format, float32 virtual format, ac3/dts mpv format bool spdif_hack; bool changed_mixing; atomic_bool reload_requested; uint64_t hw_latency_ns; }; static OSStatus property_listener_cb( AudioObjectID object, uint32_t n_addresses, const AudioObjectPropertyAddress addresses[], void *data) { struct ao *ao = data; struct priv *p = ao->priv; // Check whether we need to reset the compressed output stream. AudioStreamBasicDescription f; OSErr err = CA_GET(p->stream, kAudioStreamPropertyVirtualFormat, &f); CHECK_CA_WARN("could not get stream format"); if (err != noErr || !ca_asbd_equals(&p->stream_asbd, &f)) { if (atomic_compare_exchange_strong(&p->reload_requested, &(bool){false}, true)) { ao_request_reload(ao); MP_INFO(ao, "Stream format changed! Reloading.\n"); } } return noErr; } static OSStatus enable_property_listener(struct ao *ao, bool enabled) { struct priv *p = ao->priv; uint32_t selectors[] = {kAudioDevicePropertyDeviceHasChanged, kAudioHardwarePropertyDevices}; AudioDeviceID devs[] = {p->device, kAudioObjectSystemObject}; static_assert(MP_ARRAY_SIZE(selectors) == MP_ARRAY_SIZE(devs), ""); OSStatus status = noErr; for (int n = 0; n < MP_ARRAY_SIZE(devs); n++) { AudioObjectPropertyAddress addr = { .mScope = kAudioObjectPropertyScopeGlobal, .mElement = kAudioObjectPropertyElementMaster, .mSelector = selectors[n], }; AudioDeviceID device = devs[n]; OSStatus status2; if (enabled) { status2 = AudioObjectAddPropertyListener( device, &addr, property_listener_cb, ao); } else { status2 = AudioObjectRemovePropertyListener( device, &addr, property_listener_cb, ao); } if (status == noErr) status = status2; } return status; } // This is a hack for passing through AC3/DTS on drivers which don't support it. // The goal is to have the driver output the AC3 data bitexact, so basically we // feed it float data by converting the AC3 data to float in the reverse way we // assume the driver outputs it. // Input: data_as_int16[0..samples] // Output: data_as_float[0..samples] // The conversion is done in-place. static void bad_hack_mygodwhy(char *data, int samples) { // In reverse, so we can do it in-place. for (int n = samples - 1; n >= 0; n--) { int16_t val = AV_RN16(data + n * 2); float fval = val / (float)(1 << 15); uint32_t ival = av_float2int(fval); AV_WN32(data + n * 4, ival); } } static OSStatus render_cb_compressed( AudioDeviceID device, const AudioTimeStamp *ts, const void *in_data, const AudioTimeStamp *in_ts, AudioBufferList *out_data, const AudioTimeStamp *out_ts, void *ctx) { struct ao *ao = ctx; struct priv *p = ao->priv; AudioBuffer buf = out_data->mBuffers[p->stream_idx]; int requested = buf.mDataByteSize; int sstride = p->spdif_hack ? 4 * ao->channels.num : ao->sstride; int pseudo_frames = requested / sstride; // we expect the callback to read full frames, which are aligned accordingly if (pseudo_frames * sstride != requested) { MP_ERR(ao, "Unsupported unaligned read of %d bytes.\n", requested); return kAudioHardwareUnspecifiedError; } int64_t end = mp_time_ns(); end += p->hw_latency_ns + ca_get_latency(ts) + ca_frames_to_ns(ao, pseudo_frames); ao_read_data(ao, &buf.mData, pseudo_frames, end, NULL, true, true); if (p->spdif_hack) bad_hack_mygodwhy(buf.mData, pseudo_frames * ao->channels.num); return noErr; } // Apparently, audio devices can have multiple sub-streams. It's not clear to // me what devices with multiple streams actually do. So only select the first // one that fulfills some minimum requirements. // If this is not sufficient, we could duplicate the device list entries for // each sub-stream, and make it explicit. static int select_stream(struct ao *ao) { struct priv *p = ao->priv; AudioStreamID *streams; size_t n_streams; OSStatus err; /* Get a list of all the streams on this device. */ err = CA_GET_ARY_O(p->device, kAudioDevicePropertyStreams, &streams, &n_streams); CHECK_CA_ERROR("could not get number of streams"); for (int i = 0; i < n_streams; i++) { uint32_t direction; err = CA_GET(streams[i], kAudioStreamPropertyDirection, &direction); CHECK_CA_WARN("could not get stream direction"); if (err == noErr && direction != 0) { MP_VERBOSE(ao, "Substream %d is not an output stream.\n", i); continue; } if (af_fmt_is_pcm(ao->format) || p->spdif_hack || ca_stream_supports_compressed(ao, streams[i])) { MP_VERBOSE(ao, "Using substream %d/%zd.\n", i, n_streams); p->stream = streams[i]; p->stream_idx = i; break; } } talloc_free(streams); if (p->stream_idx < 0) { MP_ERR(ao, "No useable substream found.\n"); goto coreaudio_error; } return 0; coreaudio_error: return -1; } static int find_best_format(struct ao *ao, AudioStreamBasicDescription *out_fmt) { struct priv *p = ao->priv; // Build ASBD for the input format AudioStreamBasicDescription asbd; ca_fill_asbd(ao, &asbd); ca_print_asbd(ao, "our format:", &asbd); *out_fmt = (AudioStreamBasicDescription){0}; AudioStreamRangedDescription *formats; size_t n_formats; OSStatus err; err = CA_GET_ARY(p->stream, kAudioStreamPropertyAvailablePhysicalFormats, &formats, &n_formats); CHECK_CA_ERROR("could not get number of stream formats"); for (int j = 0; j < n_formats; j++) { AudioStreamBasicDescription *stream_asbd = &formats[j].mFormat; ca_print_asbd(ao, "- ", stream_asbd); if (!out_fmt->mFormatID || ca_asbd_is_better(&asbd, out_fmt, stream_asbd)) *out_fmt = *stream_asbd; } talloc_free(formats); if (!out_fmt->mFormatID) { MP_ERR(ao, "no format found\n"); return -1; } return 0; coreaudio_error: return -1; } static int init(struct ao *ao) { struct priv *p = ao->priv; int original_format = ao->format; OSStatus err = ca_select_device(ao, ao->device, &p->device); CHECK_CA_ERROR_L(coreaudio_error_nounlock, "failed to select device"); ao->format = af_fmt_from_planar(ao->format); if (!af_fmt_is_pcm(ao->format) && !af_fmt_is_spdif(ao->format)) { MP_ERR(ao, "Unsupported format.\n"); goto coreaudio_error_nounlock; } if (af_fmt_is_pcm(ao->format)) p->spdif_hack = false; if (p->spdif_hack) { if (af_fmt_to_bytes(ao->format) != 2) { MP_ERR(ao, "HD formats not supported with spdif hack.\n"); goto coreaudio_error_nounlock; } // Let the pure evil begin! ao->format = AF_FORMAT_S16; } uint32_t is_alive = 1; err = CA_GET(p->device, kAudioDevicePropertyDeviceIsAlive, &is_alive); CHECK_CA_WARN("could not check whether device is alive"); if (!is_alive) MP_WARN(ao, "device is not alive\n"); err = ca_lock_device(p->device, &p->hog_pid); CHECK_CA_WARN("failed to set hogmode"); err = ca_disable_mixing(ao, p->device, &p->changed_mixing); CHECK_CA_WARN("failed to disable mixing"); if (select_stream(ao) < 0) goto coreaudio_error; AudioStreamBasicDescription hwfmt; if (find_best_format(ao, &hwfmt) < 0) goto coreaudio_error; err = CA_GET(p->stream, kAudioStreamPropertyPhysicalFormat, &p->original_asbd); CHECK_CA_ERROR("could not get stream's original physical format"); // Even if changing the physical format fails, we can try using the current // virtual format. ca_change_physical_format_sync(ao, p->stream, hwfmt); if (!ca_init_chmap(ao, p->device)) goto coreaudio_error; err = CA_GET(p->stream, kAudioStreamPropertyVirtualFormat, &p->stream_asbd); CHECK_CA_ERROR("could not get stream's virtual format"); ca_print_asbd(ao, "virtual format", &p->stream_asbd); if (p->stream_asbd.mChannelsPerFrame > MP_NUM_CHANNELS) { MP_ERR(ao, "unsupported number of channels: %d > %d.\n", p->stream_asbd.mChannelsPerFrame, MP_NUM_CHANNELS); goto coreaudio_error; } int new_format = ca_asbd_to_mp_format(&p->stream_asbd); // If both old and new formats are spdif, avoid changing it due to the // imperfect mapping between mp and CA formats. if (!(af_fmt_is_spdif(ao->format) && af_fmt_is_spdif(new_format))) ao->format = new_format; if (!ao->format || af_fmt_is_planar(ao->format)) { MP_ERR(ao, "hardware format not supported\n"); goto coreaudio_error; } ao->samplerate = p->stream_asbd.mSampleRate; if (ao->channels.num != p->stream_asbd.mChannelsPerFrame) { ca_get_active_chmap(ao, p->device, p->stream_asbd.mChannelsPerFrame, &ao->channels); } if (!ao->channels.num) { MP_ERR(ao, "number of channels changed, and unknown channel layout!\n"); goto coreaudio_error; } if (p->spdif_hack) { AudioStreamBasicDescription physical_format = {0}; err = CA_GET(p->stream, kAudioStreamPropertyPhysicalFormat, &physical_format); CHECK_CA_ERROR("could not get stream's physical format"); int ph_format = ca_asbd_to_mp_format(&physical_format); if (ao->format != AF_FORMAT_FLOAT || ph_format != AF_FORMAT_S16) { MP_ERR(ao, "Wrong parameters for spdif hack (%d / %d)\n", ao->format, ph_format); } ao->format = original_format; // pretend AC3 or DTS *evil laughter* MP_WARN(ao, "Using spdif passthrough hack. This could produce noise.\n"); } p->hw_latency_ns = ca_get_device_latency_ns(ao, p->device); MP_VERBOSE(ao, "base latency: %lld nanoseconds\n", p->hw_latency_ns); err = enable_property_listener(ao, true); CHECK_CA_ERROR("cannot install format change listener during init"); err = AudioDeviceCreateIOProcID(p->device, (AudioDeviceIOProc)render_cb_compressed, (void *)ao, &p->render_cb); CHECK_CA_ERROR("failed to register audio render callback"); return CONTROL_TRUE; coreaudio_error: err = enable_property_listener(ao, false); CHECK_CA_WARN("can't remove format change listener"); err = ca_unlock_device(p->device, &p->hog_pid); CHECK_CA_WARN("can't release hog mode"); coreaudio_error_nounlock: return CONTROL_ERROR; } static void uninit(struct ao *ao) { struct priv *p = ao->priv; OSStatus err = noErr; err = enable_property_listener(ao, false); CHECK_CA_WARN("can't remove device listener, this may cause a crash"); err = AudioDeviceStop(p->device, p->render_cb); CHECK_CA_WARN("failed to stop audio device"); err = AudioDeviceDestroyIOProcID(p->device, p->render_cb); CHECK_CA_WARN("failed to remove device render callback"); if (!ca_change_physical_format_sync(ao, p->stream, p->original_asbd)) MP_WARN(ao, "can't revert to original device format\n"); err = ca_enable_mixing(ao, p->device, p->changed_mixing); CHECK_CA_WARN("can't re-enable mixing"); err = ca_unlock_device(p->device, &p->hog_pid); CHECK_CA_WARN("can't release hog mode"); } static void audio_pause(struct ao *ao) { struct priv *p = ao->priv; OSStatus err = AudioDeviceStop(p->device, p->render_cb); CHECK_CA_WARN("can't stop audio device"); } static void audio_resume(struct ao *ao) { struct priv *p = ao->priv; OSStatus err = AudioDeviceStart(p->device, p->render_cb); CHECK_CA_WARN("can't start audio device"); } #define OPT_BASE_STRUCT struct priv const struct ao_driver audio_out_coreaudio_exclusive = { .description = "CoreAudio Exclusive Mode", .name = "coreaudio_exclusive", .uninit = uninit, .init = init, .reset = audio_pause, .start = audio_resume, .list_devs = ca_get_device_list, .priv_size = sizeof(struct priv), .priv_defaults = &(const struct priv){ .sem = (struct coreaudio_cb_sem){ .mutex = MP_STATIC_MUTEX_INITIALIZER, .cond = MP_STATIC_COND_INITIALIZER, }, .hog_pid = -1, .stream = 0, .stream_idx = -1, .changed_mixing = false, }, .options = (const struct m_option[]){ {"spdif-hack", OPT_BOOL(spdif_hack)}, {0} }, .options_prefix = "coreaudio", };