/* * 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 . */ /* * This file contains functions interacting with the CoreAudio framework * that are not specific to the AUHAL. These are split in a separate file for * the sake of readability. In the future the could be used by other AOs based * on CoreAudio but not the AUHAL (such as using AudioQueue services). */ #include "audio/out/ao_coreaudio_utils.h" #include "osdep/timer.h" #include "osdep/endian.h" #include "audio/format.h" #if HAVE_COREAUDIO || HAVE_AVFOUNDATION #include "audio/out/ao_coreaudio_properties.h" #include #else #include #endif #if HAVE_COREAUDIO || HAVE_AVFOUNDATION static bool ca_is_output_device(struct ao *ao, AudioDeviceID dev) { size_t n_buffers; AudioBufferList *buffers; const ca_scope scope = kAudioDevicePropertyStreamConfiguration; OSStatus err = CA_GET_ARY_O(dev, scope, &buffers, &n_buffers); if (err != noErr) return false; talloc_free(buffers); return n_buffers > 0; } void ca_get_device_list(struct ao *ao, struct ao_device_list *list) { AudioDeviceID *devs; size_t n_devs; OSStatus err = CA_GET_ARY(kAudioObjectSystemObject, kAudioHardwarePropertyDevices, &devs, &n_devs); CHECK_CA_ERROR("Failed to get list of output devices."); for (int i = 0; i < n_devs; i++) { if (!ca_is_output_device(ao, devs[i])) continue; void *ta_ctx = talloc_new(NULL); char *name; char *desc; err = CA_GET_STR(devs[i], kAudioDevicePropertyDeviceUID, &name); if (err != noErr) { MP_VERBOSE(ao, "skipping device %d, which has no UID\n", i); talloc_free(ta_ctx); continue; } talloc_steal(ta_ctx, name); err = CA_GET_STR(devs[i], kAudioObjectPropertyName, &desc); if (err != noErr) desc = talloc_strdup(NULL, "Unknown"); talloc_steal(ta_ctx, desc); ao_device_list_add(list, ao, &(struct ao_device_desc){name, desc}); talloc_free(ta_ctx); } talloc_free(devs); coreaudio_error: return; } OSStatus ca_select_device(struct ao *ao, char* name, AudioDeviceID *device) { OSStatus err = noErr; *device = kAudioObjectUnknown; if (name && name[0]) { CFStringRef uid = cfstr_from_cstr(name); AudioValueTranslation v = (AudioValueTranslation) { .mInputData = &uid, .mInputDataSize = sizeof(CFStringRef), .mOutputData = device, .mOutputDataSize = sizeof(*device), }; uint32_t size = sizeof(AudioValueTranslation); AudioObjectPropertyAddress p_addr = (AudioObjectPropertyAddress) { .mSelector = kAudioHardwarePropertyDeviceForUID, .mScope = kAudioObjectPropertyScopeGlobal, .mElement = kAudioObjectPropertyElementMaster, }; err = AudioObjectGetPropertyData( kAudioObjectSystemObject, &p_addr, 0, 0, &size, &v); CFRelease(uid); CHECK_CA_ERROR("unable to query for device UID"); uint32_t is_alive = 1; err = CA_GET(*device, kAudioDevicePropertyDeviceIsAlive, &is_alive); CHECK_CA_ERROR("could not check whether device is alive (invalid device?)"); if (!is_alive) MP_WARN(ao, "device is not alive!\n"); } else { // device not set by user, get the default one err = CA_GET(kAudioObjectSystemObject, kAudioHardwarePropertyDefaultOutputDevice, device); CHECK_CA_ERROR("could not get default audio device"); } if (mp_msg_test(ao->log, MSGL_V)) { char *desc; OSStatus err2 = CA_GET_STR(*device, kAudioObjectPropertyName, &desc); if (err2 == noErr) { MP_VERBOSE(ao, "selected audio output device: %s (%" PRIu32 ")\n", desc, *device); talloc_free(desc); } } coreaudio_error: return err; } #endif bool check_ca_st(struct ao *ao, int level, OSStatus code, const char *message) { if (code == noErr) return true; if (ao) mp_msg(ao->log, level, "%s (%s/%d)\n", message, mp_tag_str(code), (int)code); return false; } static void ca_fill_asbd_raw(AudioStreamBasicDescription *asbd, int mp_format, int samplerate, int num_channels) { asbd->mSampleRate = samplerate; // Set "AC3" for other spdif formats too - unknown if that works. asbd->mFormatID = af_fmt_is_spdif(mp_format) ? kAudioFormat60958AC3 : kAudioFormatLinearPCM; asbd->mChannelsPerFrame = num_channels; asbd->mBitsPerChannel = af_fmt_to_bytes(mp_format) * 8; asbd->mFormatFlags = kAudioFormatFlagIsPacked; int channels_per_buffer = num_channels; if (af_fmt_is_planar(mp_format)) { asbd->mFormatFlags |= kAudioFormatFlagIsNonInterleaved; channels_per_buffer = 1; } if (af_fmt_is_float(mp_format)) { asbd->mFormatFlags |= kAudioFormatFlagIsFloat; } else if (!af_fmt_is_unsigned(mp_format)) { asbd->mFormatFlags |= kAudioFormatFlagIsSignedInteger; } if (BYTE_ORDER == BIG_ENDIAN) asbd->mFormatFlags |= kAudioFormatFlagIsBigEndian; asbd->mFramesPerPacket = 1; asbd->mBytesPerPacket = asbd->mBytesPerFrame = asbd->mFramesPerPacket * channels_per_buffer * (asbd->mBitsPerChannel / 8); } void ca_fill_asbd(struct ao *ao, AudioStreamBasicDescription *asbd) { ca_fill_asbd_raw(asbd, ao->format, ao->samplerate, ao->channels.num); } bool ca_formatid_is_compressed(uint32_t formatid) { switch (formatid) case 'IAC3': case 'iac3': case kAudioFormat60958AC3: case kAudioFormatAC3: return true; return false; } // This might be wrong, but for now it's sufficient for us. static uint32_t ca_normalize_formatid(uint32_t formatID) { return ca_formatid_is_compressed(formatID) ? kAudioFormat60958AC3 : formatID; } bool ca_asbd_equals(const AudioStreamBasicDescription *a, const AudioStreamBasicDescription *b) { int flags = kAudioFormatFlagIsPacked | kAudioFormatFlagIsFloat | kAudioFormatFlagIsSignedInteger | kAudioFormatFlagIsBigEndian; bool spdif = ca_formatid_is_compressed(a->mFormatID) && ca_formatid_is_compressed(b->mFormatID); return (a->mFormatFlags & flags) == (b->mFormatFlags & flags) && a->mBitsPerChannel == b->mBitsPerChannel && ca_normalize_formatid(a->mFormatID) == ca_normalize_formatid(b->mFormatID) && (spdif || a->mBytesPerPacket == b->mBytesPerPacket) && (spdif || a->mChannelsPerFrame == b->mChannelsPerFrame) && a->mSampleRate == b->mSampleRate; } // Return the AF_FORMAT_* (AF_FORMAT_S16 etc.) corresponding to the asbd. int ca_asbd_to_mp_format(const AudioStreamBasicDescription *asbd) { for (int fmt = 1; fmt < AF_FORMAT_COUNT; fmt++) { AudioStreamBasicDescription mp_asbd = {0}; ca_fill_asbd_raw(&mp_asbd, fmt, asbd->mSampleRate, asbd->mChannelsPerFrame); if (ca_asbd_equals(&mp_asbd, asbd)) return af_fmt_is_spdif(fmt) ? AF_FORMAT_S_AC3 : fmt; } return 0; } void ca_print_asbd(struct ao *ao, const char *description, const AudioStreamBasicDescription *asbd) { uint32_t flags = asbd->mFormatFlags; char *format = mp_tag_str(asbd->mFormatID); int mpfmt = ca_asbd_to_mp_format(asbd); MP_VERBOSE(ao, "%s %7.1fHz %" PRIu32 "bit %s " "[%" PRIu32 "][%" PRIu32 "bpp][%" PRIu32 "fbp]" "[%" PRIu32 "bpf][%" PRIu32 "ch] " "%s %s %s%s%s%s (%s)\n", description, asbd->mSampleRate, asbd->mBitsPerChannel, format, asbd->mFormatFlags, asbd->mBytesPerPacket, asbd->mFramesPerPacket, asbd->mBytesPerFrame, asbd->mChannelsPerFrame, (flags & kAudioFormatFlagIsFloat) ? "float" : "int", (flags & kAudioFormatFlagIsBigEndian) ? "BE" : "LE", (flags & kAudioFormatFlagIsSignedInteger) ? "S" : "U", (flags & kAudioFormatFlagIsPacked) ? " packed" : "", (flags & kAudioFormatFlagIsAlignedHigh) ? " aligned" : "", (flags & kAudioFormatFlagIsNonInterleaved) ? " P" : "", mpfmt ? af_fmt_to_str(mpfmt) : "-"); } // Return whether new is an improvement over old. Assume a higher value means // better quality, and we always prefer the value closest to the requested one, // which is still larger than the requested one. // Equal values prefer the new one (so ca_asbd_is_better() checks other params). static bool value_is_better(double req, double old, double new) { if (new >= req) { return old < req || new <= old; } else { return old < req && new >= old; } } // Return whether new is an improvement over old (req is the requested format). bool ca_asbd_is_better(AudioStreamBasicDescription *req, AudioStreamBasicDescription *old, AudioStreamBasicDescription *new) { if (new->mChannelsPerFrame > MP_NUM_CHANNELS) return false; if (old->mChannelsPerFrame > MP_NUM_CHANNELS) return true; if (req->mFormatID != new->mFormatID) return false; if (req->mFormatID != old->mFormatID) return true; if (!value_is_better(req->mBitsPerChannel, old->mBitsPerChannel, new->mBitsPerChannel)) return false; if (!value_is_better(req->mSampleRate, old->mSampleRate, new->mSampleRate)) return false; if (!value_is_better(req->mChannelsPerFrame, old->mChannelsPerFrame, new->mChannelsPerFrame)) return false; return true; } int64_t ca_frames_to_ns(struct ao *ao, uint32_t frames) { return MP_TIME_S_TO_NS(frames / (double)ao->samplerate); } int64_t ca_get_latency(const AudioTimeStamp *ts) { #if HAVE_COREAUDIO || HAVE_AVFOUNDATION uint64_t out = AudioConvertHostTimeToNanos(ts->mHostTime); uint64_t now = AudioConvertHostTimeToNanos(AudioGetCurrentHostTime()); if (now > out) return 0; return out - now; #else static mach_timebase_info_data_t timebase; if (timebase.denom == 0) mach_timebase_info(&timebase); uint64_t out = ts->mHostTime; uint64_t now = mach_absolute_time(); if (now > out) return 0; return (out - now) * timebase.numer / timebase.denom; #endif } #if HAVE_COREAUDIO || HAVE_AVFOUNDATION bool ca_stream_supports_compressed(struct ao *ao, AudioStreamID stream) { AudioStreamRangedDescription *formats = NULL; size_t n_formats; OSStatus err = CA_GET_ARY(stream, kAudioStreamPropertyAvailablePhysicalFormats, &formats, &n_formats); CHECK_CA_ERROR("Could not get number of stream formats."); for (int i = 0; i < n_formats; i++) { AudioStreamBasicDescription asbd = formats[i].mFormat; ca_print_asbd(ao, "- ", &asbd); if (ca_formatid_is_compressed(asbd.mFormatID)) { talloc_free(formats); return true; } } talloc_free(formats); coreaudio_error: return false; } OSStatus ca_lock_device(AudioDeviceID device, pid_t *pid) { *pid = getpid(); OSStatus err = CA_SET(device, kAudioDevicePropertyHogMode, pid); if (err != noErr) *pid = -1; return err; } OSStatus ca_unlock_device(AudioDeviceID device, pid_t *pid) { if (*pid == getpid()) { *pid = -1; return CA_SET(device, kAudioDevicePropertyHogMode, &pid); } return noErr; } static OSStatus ca_change_mixing(struct ao *ao, AudioDeviceID device, uint32_t val, bool *changed) { *changed = false; AudioObjectPropertyAddress p_addr = (AudioObjectPropertyAddress) { .mSelector = kAudioDevicePropertySupportsMixing, .mScope = kAudioObjectPropertyScopeGlobal, .mElement = kAudioObjectPropertyElementMaster, }; if (AudioObjectHasProperty(device, &p_addr)) { OSStatus err; Boolean writeable = 0; err = CA_SETTABLE(device, kAudioDevicePropertySupportsMixing, &writeable); if (!CHECK_CA_WARN("can't tell if mixing property is settable")) { return err; } if (!writeable) return noErr; err = CA_SET(device, kAudioDevicePropertySupportsMixing, &val); if (err != noErr) return err; if (!CHECK_CA_WARN("can't set mix mode")) { return err; } *changed = true; } return noErr; } OSStatus ca_disable_mixing(struct ao *ao, AudioDeviceID device, bool *changed) { return ca_change_mixing(ao, device, 0, changed); } OSStatus ca_enable_mixing(struct ao *ao, AudioDeviceID device, bool changed) { if (changed) { bool dont_care = false; return ca_change_mixing(ao, device, 1, &dont_care); } return noErr; } int64_t ca_get_device_latency_ns(struct ao *ao, AudioDeviceID device) { uint32_t latency_frames = 0; uint32_t latency_properties[] = { kAudioDevicePropertyLatency, kAudioDevicePropertyBufferFrameSize, kAudioDevicePropertySafetyOffset, }; for (int n = 0; n < MP_ARRAY_SIZE(latency_properties); n++) { uint32_t temp; OSStatus err = CA_GET_O(device, latency_properties[n], &temp); CHECK_CA_WARN("cannot get device latency"); if (err == noErr) { latency_frames += temp; MP_VERBOSE(ao, "Latency property %s: %d frames\n", mp_tag_str(latency_properties[n]), (int)temp); } } double sample_rate; OSStatus err = CA_GET_O(device, kAudioDevicePropertyNominalSampleRate, &sample_rate); CHECK_CA_WARN("cannot get device sample rate, falling back to AO sample rate!"); if (err == noErr) { MP_VERBOSE(ao, "Device sample rate: %f\n", sample_rate); } else { sample_rate = ao->samplerate; } return MP_TIME_S_TO_NS(latency_frames / sample_rate); } static OSStatus ca_change_format_listener( AudioObjectID object, uint32_t n_addresses, const AudioObjectPropertyAddress addresses[], void *data) { struct coreaudio_cb_sem *sem = data; mp_mutex_lock(&sem->mutex); mp_cond_broadcast(&sem->cond); mp_mutex_unlock(&sem->mutex); return noErr; } bool ca_change_physical_format_sync(struct ao *ao, AudioStreamID stream, AudioStreamBasicDescription change_format) { struct coreaudio_cb_sem *sem = ao->priv; OSStatus err = noErr; bool format_set = false; ca_print_asbd(ao, "setting stream physical format:", &change_format); AudioStreamBasicDescription prev_format; err = CA_GET(stream, kAudioStreamPropertyPhysicalFormat, &prev_format); CHECK_CA_ERROR("can't get current physical format"); ca_print_asbd(ao, "format in use before switching:", &prev_format); /* Install the callback. */ AudioObjectPropertyAddress p_addr = { .mSelector = kAudioStreamPropertyPhysicalFormat, .mScope = kAudioObjectPropertyScopeGlobal, .mElement = kAudioObjectPropertyElementMaster, }; err = AudioObjectAddPropertyListener(stream, &p_addr, ca_change_format_listener, sem); CHECK_CA_ERROR("can't add property listener during format change"); mp_mutex_lock(&sem->mutex); /* Change the format. */ err = CA_SET(stream, kAudioStreamPropertyPhysicalFormat, &change_format); CHECK_CA_WARN("error changing physical format"); /* The AudioStreamSetProperty is not only asynchronous, * it is also not Atomic, in its behaviour. */ int64_t wait_until = mp_time_ns() + MP_TIME_S_TO_NS(2); AudioStreamBasicDescription actual_format = {0}; while (1) { err = CA_GET(stream, kAudioStreamPropertyPhysicalFormat, &actual_format); if (!CHECK_CA_WARN("could not retrieve physical format")) break; format_set = ca_asbd_equals(&change_format, &actual_format); if (format_set) break; if (mp_cond_timedwait_until(&sem->cond, &sem->mutex, wait_until)) { MP_VERBOSE(ao, "reached timeout\n"); break; } } mp_mutex_unlock(&sem->mutex); ca_print_asbd(ao, "actual format in use:", &actual_format); if (!format_set) { MP_WARN(ao, "changing physical format failed\n"); // Some drivers just fuck up and get into a broken state. Restore the // old format in this case. err = CA_SET(stream, kAudioStreamPropertyPhysicalFormat, &prev_format); CHECK_CA_WARN("error restoring physical format"); } err = AudioObjectRemovePropertyListener(stream, &p_addr, ca_change_format_listener, sem); CHECK_CA_ERROR("can't remove property listener"); coreaudio_error: return format_set; } #endif