mac-audio.c 29 KB

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  1. #include <AudioUnit/AudioUnit.h>
  2. #include <CoreFoundation/CFString.h>
  3. #include <CoreAudio/CoreAudio.h>
  4. #include <unistd.h>
  5. #include <errno.h>
  6. #include <obs-module.h>
  7. #include <mach/mach_time.h>
  8. #include <util/threading.h>
  9. #include <util/c99defs.h>
  10. #include <util/apple/cfstring-utils.h>
  11. #include "audio-device-enum.h"
  12. #define PROPERTY_DEFAULT_DEVICE kAudioHardwarePropertyDefaultInputDevice
  13. #define PROPERTY_FORMATS kAudioStreamPropertyAvailablePhysicalFormats
  14. #define SCOPE_OUTPUT kAudioUnitScope_Output
  15. #define SCOPE_INPUT kAudioUnitScope_Input
  16. #define SCOPE_GLOBAL kAudioUnitScope_Global
  17. #define BUS_OUTPUT 0
  18. #define BUS_INPUT 1
  19. #define set_property AudioUnitSetProperty
  20. #define get_property AudioUnitGetProperty
  21. #define TEXT_AUDIO_INPUT obs_module_text("CoreAudio.InputCapture");
  22. #define TEXT_AUDIO_OUTPUT obs_module_text("CoreAudio.OutputCapture");
  23. #define TEXT_DEVICE obs_module_text("CoreAudio.Device")
  24. #define TEXT_DEVICE_DEFAULT obs_module_text("CoreAudio.Device.Default")
  25. struct coreaudio_data {
  26. char *device_name;
  27. char *device_uid;
  28. AudioUnit unit;
  29. AudioDeviceID device_id;
  30. AudioBufferList *buf_list;
  31. bool au_initialized;
  32. bool active;
  33. bool default_device;
  34. bool input;
  35. bool no_devices;
  36. uint32_t available_channels;
  37. char **channel_names;
  38. int32_t *channel_map;
  39. uint32_t sample_rate;
  40. enum audio_format format;
  41. enum speaker_layout speakers;
  42. bool enable_downmix;
  43. pthread_t reconnect_thread;
  44. os_event_t *exit_event;
  45. volatile bool reconnecting;
  46. unsigned long retry_time;
  47. obs_source_t *source;
  48. };
  49. static bool get_default_output_device(struct coreaudio_data *ca)
  50. {
  51. struct device_list list;
  52. memset(&list, 0, sizeof(struct device_list));
  53. coreaudio_enum_devices(&list, false);
  54. if (!list.items.num)
  55. return false;
  56. bfree(ca->device_uid);
  57. ca->device_uid = bstrdup(list.items.array[0].value.array);
  58. device_list_free(&list);
  59. return true;
  60. }
  61. static bool find_device_id_by_uid(struct coreaudio_data *ca)
  62. {
  63. UInt32 size = sizeof(AudioDeviceID);
  64. CFStringRef cf_uid = NULL;
  65. CFStringRef qual = NULL;
  66. UInt32 qual_size = 0;
  67. OSStatus stat;
  68. bool success;
  69. AudioObjectPropertyAddress addr = {
  70. .mScope = kAudioObjectPropertyScopeGlobal,
  71. .mElement = kAudioObjectPropertyElementMain};
  72. if (!ca->device_uid)
  73. ca->device_uid = bstrdup("default");
  74. ca->default_device = false;
  75. ca->no_devices = false;
  76. /* have to do this because mac output devices don't actually exist */
  77. if (astrcmpi(ca->device_uid, "default") == 0) {
  78. if (ca->input) {
  79. ca->default_device = true;
  80. } else {
  81. if (!get_default_output_device(ca)) {
  82. ca->no_devices = true;
  83. return false;
  84. }
  85. }
  86. }
  87. cf_uid = CFStringCreateWithCString(NULL, ca->device_uid,
  88. kCFStringEncodingUTF8);
  89. if (ca->default_device) {
  90. addr.mSelector = kAudioHardwarePropertyDefaultInputDevice;
  91. stat = AudioObjectGetPropertyData(kAudioObjectSystemObject,
  92. &addr, qual_size, &qual,
  93. &size, &ca->device_id);
  94. success = (stat == noErr);
  95. } else {
  96. success = coreaudio_get_device_id(cf_uid, &ca->device_id);
  97. }
  98. if (cf_uid)
  99. CFRelease(cf_uid);
  100. return success;
  101. }
  102. static inline void ca_warn(struct coreaudio_data *ca, const char *func,
  103. const char *format, ...)
  104. {
  105. va_list args;
  106. struct dstr str = {0};
  107. va_start(args, format);
  108. dstr_printf(&str, "[%s]:[device '%s'] ", func, ca->device_name);
  109. dstr_vcatf(&str, format, args);
  110. blog(LOG_WARNING, "%s", str.array);
  111. dstr_free(&str);
  112. va_end(args);
  113. }
  114. static inline bool ca_success(OSStatus stat, struct coreaudio_data *ca,
  115. const char *func, const char *action)
  116. {
  117. if (stat != noErr) {
  118. blog(LOG_WARNING, "[%s]:[device '%s'] %s failed: %d", func,
  119. ca->device_name, action, (int)stat);
  120. return false;
  121. }
  122. return true;
  123. }
  124. enum coreaudio_io_type {
  125. IO_TYPE_INPUT,
  126. IO_TYPE_OUTPUT,
  127. };
  128. static inline bool enable_io(struct coreaudio_data *ca,
  129. enum coreaudio_io_type type, bool enable)
  130. {
  131. UInt32 enable_int = enable;
  132. return set_property(ca->unit, kAudioOutputUnitProperty_EnableIO,
  133. (type == IO_TYPE_INPUT) ? SCOPE_INPUT
  134. : SCOPE_OUTPUT,
  135. (type == IO_TYPE_INPUT) ? BUS_INPUT : BUS_OUTPUT,
  136. &enable_int, sizeof(enable_int));
  137. }
  138. static inline enum speaker_layout convert_ca_speaker_layout(UInt32 channels)
  139. {
  140. switch (channels) {
  141. case 1:
  142. return SPEAKERS_MONO;
  143. case 2:
  144. return SPEAKERS_STEREO;
  145. case 3:
  146. return SPEAKERS_2POINT1;
  147. case 4:
  148. return SPEAKERS_4POINT0;
  149. case 5:
  150. return SPEAKERS_4POINT1;
  151. case 6:
  152. return SPEAKERS_5POINT1;
  153. case 8:
  154. return SPEAKERS_7POINT1;
  155. }
  156. return SPEAKERS_UNKNOWN;
  157. }
  158. static inline enum audio_format convert_ca_format(UInt32 format_flags,
  159. UInt32 bits)
  160. {
  161. bool planar = (format_flags & kAudioFormatFlagIsNonInterleaved) != 0;
  162. if (format_flags & kAudioFormatFlagIsFloat)
  163. return planar ? AUDIO_FORMAT_FLOAT_PLANAR : AUDIO_FORMAT_FLOAT;
  164. if (!(format_flags & kAudioFormatFlagIsSignedInteger) && bits == 8)
  165. return planar ? AUDIO_FORMAT_U8BIT_PLANAR : AUDIO_FORMAT_U8BIT;
  166. /* not float? not signed int? no clue, fail */
  167. if ((format_flags & kAudioFormatFlagIsSignedInteger) == 0)
  168. return AUDIO_FORMAT_UNKNOWN;
  169. if (bits == 16)
  170. return planar ? AUDIO_FORMAT_16BIT_PLANAR : AUDIO_FORMAT_16BIT;
  171. else if (bits == 32)
  172. return planar ? AUDIO_FORMAT_32BIT_PLANAR : AUDIO_FORMAT_32BIT;
  173. return AUDIO_FORMAT_UNKNOWN;
  174. }
  175. static char *sanitize_device_name(char *name)
  176. {
  177. const size_t max_len = 64;
  178. size_t len = strlen(name);
  179. char buf[64];
  180. size_t out_idx = 0;
  181. for (size_t i = len > max_len ? len - max_len : 0; i < len; i++) {
  182. char c = name[i];
  183. if (isalnum(c)) {
  184. buf[out_idx++] = name[i];
  185. }
  186. if (c == '-' || c == ' ' || c == '_' || c == ':') {
  187. buf[out_idx++] = '_';
  188. }
  189. }
  190. return bstrdup_n(buf, out_idx);
  191. }
  192. static char **coreaudio_get_channel_names(struct coreaudio_data *ca)
  193. {
  194. char **channel_names = bzalloc(sizeof(char *) * ca->available_channels);
  195. for (uint32_t i = 0; i < ca->available_channels; i++) {
  196. CFStringRef cf_chan_name = NULL;
  197. UInt32 dataSize = sizeof(cf_chan_name);
  198. AudioObjectPropertyAddress pa;
  199. pa.mSelector = kAudioObjectPropertyElementName;
  200. pa.mScope = kAudioDevicePropertyScopeInput;
  201. pa.mElement = i + 1;
  202. OSStatus stat = AudioObjectGetPropertyData(
  203. ca->device_id, &pa, 0, NULL, &dataSize, &cf_chan_name);
  204. struct dstr name;
  205. dstr_init(&name);
  206. if (ca_success(stat, ca, "coreaudio_init_format",
  207. "get channel names") &&
  208. CFStringGetLength(cf_chan_name)) {
  209. char *channelName = cfstr_copy_cstr(
  210. cf_chan_name, kCFStringEncodingUTF8);
  211. dstr_printf(&name, "%s", channelName);
  212. if (channelName) {
  213. bfree(channelName);
  214. }
  215. } else {
  216. dstr_printf(&name, "%s %d",
  217. obs_module_text("CoreAudio.Channel.Device"),
  218. i + 1);
  219. }
  220. channel_names[i] = bstrdup_n(name.array, name.len);
  221. dstr_free(&name);
  222. if (cf_chan_name) {
  223. CFRelease(cf_chan_name);
  224. }
  225. }
  226. return channel_names;
  227. }
  228. static bool coreaudio_init_format(struct coreaudio_data *ca)
  229. {
  230. AudioStreamBasicDescription desc;
  231. AudioStreamBasicDescription inputDescription;
  232. OSStatus stat;
  233. UInt32 size;
  234. struct obs_audio_info aoi;
  235. if (!obs_get_audio_info(&aoi)) {
  236. blog(LOG_WARNING, "No active audio");
  237. return false;
  238. }
  239. ca->speakers = aoi.speakers;
  240. uint32_t channels = get_audio_channels(ca->speakers);
  241. size = sizeof(inputDescription);
  242. stat = get_property(ca->unit, kAudioUnitProperty_StreamFormat,
  243. kAudioUnitScope_Input, 1, &inputDescription, &size);
  244. if (!ca_success(stat, ca, "coreaudio_init_format",
  245. "get input device format"))
  246. return false;
  247. stat = get_property(ca->unit, kAudioUnitProperty_StreamFormat,
  248. SCOPE_OUTPUT, BUS_INPUT, &desc, &size);
  249. if (!ca_success(stat, ca, "coreaudio_init_format", "get input format"))
  250. return false;
  251. ca->available_channels = inputDescription.mChannelsPerFrame;
  252. if (ca->available_channels > MAX_DEVICE_INPUT_CHANNELS) {
  253. ca->available_channels = MAX_DEVICE_INPUT_CHANNELS;
  254. }
  255. ca->channel_names = coreaudio_get_channel_names(ca);
  256. if (ca->enable_downmix) {
  257. blog(LOG_INFO, "Downmix enabled: %d to %d channels.",
  258. ca->available_channels, channels);
  259. desc.mChannelsPerFrame = ca->available_channels;
  260. } else {
  261. // Mute any channels mapped in config that we don't really have
  262. char *sep = "";
  263. struct dstr cm_str;
  264. dstr_init(&cm_str);
  265. for (size_t i = 0; i < channels; i++) {
  266. dstr_cat(&cm_str, sep);
  267. if (ca->channel_map[i] >=
  268. (int32_t)ca->available_channels) {
  269. ca->channel_map[i] = -1;
  270. }
  271. dstr_catf(&cm_str, "%d", ca->channel_map[i]);
  272. sep = ",";
  273. }
  274. blog(LOG_INFO,
  275. "Channel map enabled: [%s] (%d channels available)",
  276. cm_str.array, ca->available_channels);
  277. dstr_free(&cm_str);
  278. stat = set_property(ca->unit,
  279. kAudioOutputUnitProperty_ChannelMap,
  280. SCOPE_OUTPUT, BUS_INPUT, ca->channel_map,
  281. sizeof(SInt32) * channels);
  282. if (!ca_success(stat, ca, "coreaudio_init_format",
  283. "set channel map")) {
  284. return false;
  285. }
  286. desc.mChannelsPerFrame = channels;
  287. }
  288. desc.mSampleRate = inputDescription.mSampleRate;
  289. stat = set_property(ca->unit, kAudioUnitProperty_StreamFormat,
  290. SCOPE_OUTPUT, BUS_INPUT, &desc, size);
  291. if (!ca_success(stat, ca, "coreaudio_init_format", "set output format"))
  292. return false;
  293. if (desc.mFormatID != kAudioFormatLinearPCM) {
  294. ca_warn(ca, "coreaudio_init_format", "format is not PCM");
  295. return false;
  296. }
  297. ca->format = convert_ca_format(desc.mFormatFlags, desc.mBitsPerChannel);
  298. if (ca->format == AUDIO_FORMAT_UNKNOWN) {
  299. ca_warn(ca, "coreaudio_init_format",
  300. "unknown format flags: "
  301. "%u, bits: %u",
  302. (unsigned int)desc.mFormatFlags,
  303. (unsigned int)desc.mBitsPerChannel);
  304. return false;
  305. }
  306. ca->sample_rate = (uint32_t)desc.mSampleRate;
  307. return true;
  308. }
  309. static bool coreaudio_init_buffer(struct coreaudio_data *ca)
  310. {
  311. UInt32 bufferSizeFrames;
  312. UInt32 bufferSizeBytes;
  313. UInt32 propertySize;
  314. OSStatus err = noErr;
  315. propertySize = sizeof(bufferSizeFrames);
  316. err = AudioUnitGetProperty(ca->unit,
  317. kAudioDevicePropertyBufferFrameSize,
  318. kAudioUnitScope_Global, 0, &bufferSizeFrames,
  319. &propertySize);
  320. if (!ca_success(err, ca, "coreaudio_init_buffer",
  321. "get buffer frame size")) {
  322. return false;
  323. }
  324. bufferSizeBytes = bufferSizeFrames * sizeof(Float32);
  325. AudioStreamBasicDescription streamDescription;
  326. propertySize = sizeof(streamDescription);
  327. err = AudioUnitGetProperty(ca->unit, kAudioUnitProperty_StreamFormat,
  328. kAudioUnitScope_Output, 1,
  329. &streamDescription, &propertySize);
  330. if (!ca_success(err, ca, "coreaudio_init_buffer",
  331. "get stream format")) {
  332. return false;
  333. }
  334. if (!ca->enable_downmix) {
  335. streamDescription.mChannelsPerFrame =
  336. get_audio_channels(ca->speakers);
  337. }
  338. Float64 rate = 0.0;
  339. propertySize = sizeof(Float64);
  340. AudioObjectPropertyAddress propertyAddress = {
  341. kAudioDevicePropertyNominalSampleRate,
  342. kAudioObjectPropertyScopeGlobal,
  343. kAudioObjectPropertyElementMain};
  344. err = AudioObjectGetPropertyData(ca->device_id, &propertyAddress, 0,
  345. NULL, &propertySize, &rate);
  346. if (!ca_success(err, ca, "coreaudio_init_buffer",
  347. "get input sample rate")) {
  348. return false;
  349. }
  350. streamDescription.mSampleRate = rate;
  351. int bufferPropertySize =
  352. offsetof(AudioBufferList, mBuffers[0]) +
  353. (sizeof(AudioBuffer) * streamDescription.mChannelsPerFrame);
  354. AudioBufferList *inputBuffer =
  355. (AudioBufferList *)bmalloc(bufferPropertySize);
  356. inputBuffer->mNumberBuffers = streamDescription.mChannelsPerFrame;
  357. for (UInt32 i = 0; i < inputBuffer->mNumberBuffers; i++) {
  358. inputBuffer->mBuffers[i].mNumberChannels = 1;
  359. inputBuffer->mBuffers[i].mDataByteSize = bufferSizeBytes;
  360. inputBuffer->mBuffers[i].mData = bmalloc(bufferSizeBytes);
  361. }
  362. ca->buf_list = inputBuffer;
  363. return true;
  364. }
  365. static void buf_list_free(AudioBufferList *buf_list)
  366. {
  367. if (buf_list) {
  368. for (UInt32 i = 0; i < buf_list->mNumberBuffers; i++)
  369. bfree(buf_list->mBuffers[i].mData);
  370. bfree(buf_list);
  371. }
  372. }
  373. static OSStatus input_callback(void *data,
  374. AudioUnitRenderActionFlags *action_flags,
  375. const AudioTimeStamp *ts_data, UInt32 bus_num,
  376. UInt32 frames, AudioBufferList *ignored_buffers)
  377. {
  378. struct coreaudio_data *ca = data;
  379. OSStatus stat;
  380. struct obs_source_audio audio;
  381. stat = AudioUnitRender(ca->unit, action_flags, ts_data, bus_num, frames,
  382. ca->buf_list);
  383. if (!ca_success(stat, ca, "input_callback", "audio retrieval"))
  384. return noErr;
  385. for (UInt32 i = 0; i < ca->buf_list->mNumberBuffers; i++) {
  386. if (i < MAX_AUDIO_CHANNELS) {
  387. audio.data[i] = ca->buf_list->mBuffers[i].mData;
  388. }
  389. }
  390. audio.frames = frames;
  391. audio.speakers = (ca->buf_list->mNumberBuffers > MAX_AUDIO_CHANNELS)
  392. ? MAX_AUDIO_CHANNELS
  393. : ca->buf_list->mNumberBuffers;
  394. audio.format = ca->format;
  395. audio.samples_per_sec = ca->sample_rate;
  396. static double factor = 0.;
  397. static mach_timebase_info_data_t info = {0, 0};
  398. if (info.numer == 0 && info.denom == 0) {
  399. mach_timebase_info(&info);
  400. factor = ((double)info.numer) / info.denom;
  401. }
  402. if (info.numer != info.denom)
  403. audio.timestamp = (uint64_t)(factor * ts_data->mHostTime);
  404. else
  405. audio.timestamp = ts_data->mHostTime;
  406. obs_source_output_audio(ca->source, &audio);
  407. UNUSED_PARAMETER(ignored_buffers);
  408. return noErr;
  409. }
  410. static void coreaudio_stop(struct coreaudio_data *ca);
  411. static bool coreaudio_init(struct coreaudio_data *ca);
  412. static void coreaudio_uninit(struct coreaudio_data *ca);
  413. static void *reconnect_thread(void *param)
  414. {
  415. struct coreaudio_data *ca = param;
  416. ca->reconnecting = true;
  417. while (os_event_timedwait(ca->exit_event, ca->retry_time) ==
  418. ETIMEDOUT) {
  419. if (coreaudio_init(ca))
  420. break;
  421. }
  422. blog(LOG_DEBUG, "coreaudio: exit the reconnect thread");
  423. ca->reconnecting = false;
  424. return NULL;
  425. }
  426. static void coreaudio_begin_reconnect(struct coreaudio_data *ca)
  427. {
  428. int ret;
  429. if (ca->reconnecting)
  430. return;
  431. ret = pthread_create(&ca->reconnect_thread, NULL, reconnect_thread, ca);
  432. if (ret != 0)
  433. blog(LOG_WARNING,
  434. "[coreaudio_begin_reconnect] failed to "
  435. "create thread, error code: %d",
  436. ret);
  437. }
  438. static OSStatus
  439. notification_callback(AudioObjectID id, UInt32 num_addresses,
  440. const AudioObjectPropertyAddress addresses[], void *data)
  441. {
  442. struct coreaudio_data *ca = data;
  443. coreaudio_stop(ca);
  444. coreaudio_uninit(ca);
  445. if (addresses[0].mSelector == PROPERTY_DEFAULT_DEVICE)
  446. ca->retry_time = 300;
  447. else
  448. ca->retry_time = 2000;
  449. blog(LOG_INFO,
  450. "coreaudio: device '%s' disconnected or changed. "
  451. "attempting to reconnect",
  452. ca->device_name);
  453. coreaudio_begin_reconnect(ca);
  454. UNUSED_PARAMETER(id);
  455. UNUSED_PARAMETER(num_addresses);
  456. return noErr;
  457. }
  458. static OSStatus add_listener(struct coreaudio_data *ca, UInt32 property)
  459. {
  460. AudioObjectPropertyAddress addr = {property,
  461. kAudioObjectPropertyScopeGlobal,
  462. kAudioObjectPropertyElementMain};
  463. return AudioObjectAddPropertyListener(ca->device_id, &addr,
  464. notification_callback, ca);
  465. }
  466. static bool coreaudio_init_hooks(struct coreaudio_data *ca)
  467. {
  468. OSStatus stat;
  469. AURenderCallbackStruct callback_info = {.inputProc = input_callback,
  470. .inputProcRefCon = ca};
  471. stat = add_listener(ca, kAudioDevicePropertyDeviceIsAlive);
  472. if (!ca_success(stat, ca, "coreaudio_init_hooks",
  473. "set disconnect callback"))
  474. return false;
  475. stat = add_listener(ca, PROPERTY_FORMATS);
  476. if (!ca_success(stat, ca, "coreaudio_init_hooks",
  477. "set format change callback"))
  478. return false;
  479. if (ca->default_device) {
  480. AudioObjectPropertyAddress addr = {
  481. PROPERTY_DEFAULT_DEVICE,
  482. kAudioObjectPropertyScopeGlobal,
  483. kAudioObjectPropertyElementMain};
  484. stat = AudioObjectAddPropertyListener(kAudioObjectSystemObject,
  485. &addr,
  486. notification_callback,
  487. ca);
  488. if (!ca_success(stat, ca, "coreaudio_init_hooks",
  489. "set device change callback"))
  490. return false;
  491. }
  492. stat = set_property(ca->unit, kAudioOutputUnitProperty_SetInputCallback,
  493. SCOPE_GLOBAL, 0, &callback_info,
  494. sizeof(callback_info));
  495. if (!ca_success(stat, ca, "coreaudio_init_hooks", "set input callback"))
  496. return false;
  497. return true;
  498. }
  499. static void coreaudio_remove_hooks(struct coreaudio_data *ca)
  500. {
  501. AURenderCallbackStruct callback_info = {.inputProc = NULL,
  502. .inputProcRefCon = NULL};
  503. AudioObjectPropertyAddress addr = {kAudioDevicePropertyDeviceIsAlive,
  504. kAudioObjectPropertyScopeGlobal,
  505. kAudioObjectPropertyElementMain};
  506. AudioObjectRemovePropertyListener(ca->device_id, &addr,
  507. notification_callback, ca);
  508. addr.mSelector = PROPERTY_FORMATS;
  509. AudioObjectRemovePropertyListener(ca->device_id, &addr,
  510. notification_callback, ca);
  511. if (ca->default_device) {
  512. addr.mSelector = PROPERTY_DEFAULT_DEVICE;
  513. AudioObjectRemovePropertyListener(kAudioObjectSystemObject,
  514. &addr, notification_callback,
  515. ca);
  516. }
  517. set_property(ca->unit, kAudioOutputUnitProperty_SetInputCallback,
  518. SCOPE_GLOBAL, 0, &callback_info, sizeof(callback_info));
  519. }
  520. static bool coreaudio_get_device_name(struct coreaudio_data *ca)
  521. {
  522. CFStringRef cf_name = NULL;
  523. UInt32 size = sizeof(CFStringRef);
  524. char *name = NULL;
  525. const AudioObjectPropertyAddress addr = {
  526. kAudioDevicePropertyDeviceNameCFString,
  527. kAudioObjectPropertyScopeInput,
  528. kAudioObjectPropertyElementMain};
  529. OSStatus stat = AudioObjectGetPropertyData(ca->device_id, &addr, 0,
  530. NULL, &size, &cf_name);
  531. if (stat != noErr) {
  532. blog(LOG_WARNING,
  533. "[coreaudio_get_device_name] failed to "
  534. "get name: %d",
  535. (int)stat);
  536. return false;
  537. }
  538. name = cfstr_copy_cstr(cf_name, kCFStringEncodingUTF8);
  539. if (!name) {
  540. blog(LOG_WARNING, "[coreaudio_get_device_name] failed to "
  541. "convert name to cstr for some reason");
  542. return false;
  543. }
  544. bfree(ca->device_name);
  545. ca->device_name = name;
  546. if (cf_name)
  547. CFRelease(cf_name);
  548. return true;
  549. }
  550. static bool coreaudio_start(struct coreaudio_data *ca)
  551. {
  552. OSStatus stat;
  553. if (ca->active)
  554. return true;
  555. stat = AudioOutputUnitStart(ca->unit);
  556. return ca_success(stat, ca, "coreaudio_start", "start audio");
  557. }
  558. static void coreaudio_stop(struct coreaudio_data *ca)
  559. {
  560. OSStatus stat;
  561. if (!ca->active)
  562. return;
  563. ca->active = false;
  564. stat = AudioOutputUnitStop(ca->unit);
  565. ca_success(stat, ca, "coreaudio_stop", "stop audio");
  566. }
  567. static bool coreaudio_init_unit(struct coreaudio_data *ca)
  568. {
  569. AudioComponentDescription desc = {
  570. .componentType = kAudioUnitType_Output,
  571. .componentSubType = kAudioUnitSubType_HALOutput};
  572. AudioComponent component = AudioComponentFindNext(NULL, &desc);
  573. if (!component) {
  574. ca_warn(ca, "coreaudio_init_unit", "find component failed");
  575. return false;
  576. }
  577. OSStatus stat = AudioComponentInstanceNew(component, &ca->unit);
  578. if (!ca_success(stat, ca, "coreaudio_init_unit", "instance unit"))
  579. return false;
  580. ca->au_initialized = true;
  581. return true;
  582. }
  583. static bool coreaudio_init(struct coreaudio_data *ca)
  584. {
  585. OSStatus stat;
  586. if (ca->au_initialized)
  587. return true;
  588. if (!find_device_id_by_uid(ca))
  589. return false;
  590. if (!coreaudio_get_device_name(ca))
  591. return false;
  592. if (!coreaudio_init_unit(ca))
  593. return false;
  594. stat = enable_io(ca, IO_TYPE_INPUT, true);
  595. if (!ca_success(stat, ca, "coreaudio_init", "enable input io"))
  596. goto fail;
  597. stat = enable_io(ca, IO_TYPE_OUTPUT, false);
  598. if (!ca_success(stat, ca, "coreaudio_init", "disable output io"))
  599. goto fail;
  600. stat = set_property(ca->unit, kAudioOutputUnitProperty_CurrentDevice,
  601. SCOPE_GLOBAL, 0, &ca->device_id,
  602. sizeof(ca->device_id));
  603. if (!ca_success(stat, ca, "coreaudio_init", "set current device"))
  604. goto fail;
  605. if (!coreaudio_init_format(ca))
  606. goto fail;
  607. if (!coreaudio_init_buffer(ca))
  608. goto fail;
  609. if (!coreaudio_init_hooks(ca))
  610. goto fail;
  611. stat = AudioUnitInitialize(ca->unit);
  612. if (!ca_success(stat, ca, "coreaudio_initialize", "initialize"))
  613. goto fail;
  614. if (!coreaudio_start(ca))
  615. goto fail;
  616. blog(LOG_INFO, "coreaudio: Device '%s' [%" PRIu32 " Hz] initialized",
  617. ca->device_name, ca->sample_rate);
  618. return ca->au_initialized;
  619. fail:
  620. coreaudio_uninit(ca);
  621. return false;
  622. }
  623. static void coreaudio_try_init(struct coreaudio_data *ca)
  624. {
  625. if (!coreaudio_init(ca)) {
  626. blog(LOG_INFO,
  627. "coreaudio: failed to find device "
  628. "uid: %s, waiting for connection",
  629. ca->device_uid);
  630. ca->retry_time = 2000;
  631. if (ca->no_devices)
  632. blog(LOG_INFO, "coreaudio: no device found");
  633. else
  634. coreaudio_begin_reconnect(ca);
  635. }
  636. }
  637. static void coreaudio_uninit(struct coreaudio_data *ca)
  638. {
  639. if (!ca->au_initialized)
  640. return;
  641. if (ca->unit) {
  642. coreaudio_stop(ca);
  643. OSStatus stat = AudioUnitUninitialize(ca->unit);
  644. ca_success(stat, ca, "coreaudio_uninit", "uninitialize");
  645. coreaudio_remove_hooks(ca);
  646. stat = AudioComponentInstanceDispose(ca->unit);
  647. ca_success(stat, ca, "coreaudio_uninit", "dispose");
  648. ca->unit = NULL;
  649. }
  650. ca->au_initialized = false;
  651. buf_list_free(ca->buf_list);
  652. ca->buf_list = NULL;
  653. if (ca->channel_names) {
  654. for (uint32_t i = 0; i < ca->available_channels; i++) {
  655. bfree(ca->channel_names[i]);
  656. }
  657. bfree(ca->channel_names);
  658. ca->channel_names = NULL;
  659. }
  660. }
  661. /* ------------------------------------------------------------------------- */
  662. static const char *coreaudio_input_getname(void *unused)
  663. {
  664. UNUSED_PARAMETER(unused);
  665. return TEXT_AUDIO_INPUT;
  666. }
  667. static const char *coreaudio_output_getname(void *unused)
  668. {
  669. UNUSED_PARAMETER(unused);
  670. return TEXT_AUDIO_OUTPUT;
  671. }
  672. static void coreaudio_shutdown(struct coreaudio_data *ca)
  673. {
  674. if (ca->reconnecting) {
  675. os_event_signal(ca->exit_event);
  676. pthread_join(ca->reconnect_thread, NULL);
  677. os_event_reset(ca->exit_event);
  678. }
  679. coreaudio_uninit(ca);
  680. if (ca->unit)
  681. AudioComponentInstanceDispose(ca->unit);
  682. }
  683. static void coreaudio_destroy(void *data)
  684. {
  685. struct coreaudio_data *ca = data;
  686. if (ca) {
  687. coreaudio_shutdown(ca);
  688. os_event_destroy(ca->exit_event);
  689. if (ca->channel_map) {
  690. bfree(ca->channel_map);
  691. ca->channel_map = NULL;
  692. }
  693. bfree(ca->device_name);
  694. bfree(ca->device_uid);
  695. bfree(ca);
  696. }
  697. }
  698. static void coreaudio_set_channels(struct coreaudio_data *ca,
  699. obs_data_t *settings)
  700. {
  701. ca->channel_map = bzalloc(sizeof(SInt32) * MAX_AUDIO_CHANNELS);
  702. char *device_config_name = sanitize_device_name(ca->device_uid);
  703. for (uint8_t i = 0; i < MAX_AUDIO_CHANNELS; i++) {
  704. char setting_name[128];
  705. snprintf(setting_name, 128, "output-%s-%i", device_config_name,
  706. i + 1);
  707. int64_t found =
  708. obs_data_has_user_value(settings, setting_name)
  709. ? obs_data_get_int(settings, setting_name)
  710. : -1L;
  711. int64_t adjusted = found > 0 ? found - 1 : -1;
  712. ca->channel_map[i] = (int32_t)adjusted;
  713. }
  714. bfree(device_config_name);
  715. }
  716. static void coreaudio_update(void *data, obs_data_t *settings)
  717. {
  718. struct coreaudio_data *ca = data;
  719. coreaudio_shutdown(ca);
  720. bfree(ca->device_uid);
  721. ca->device_uid = bstrdup(obs_data_get_string(settings, "device_id"));
  722. ca->enable_downmix = obs_data_get_bool(settings, "enable_downmix");
  723. if (!ca->enable_downmix) {
  724. coreaudio_set_channels(ca, settings);
  725. }
  726. coreaudio_try_init(ca);
  727. }
  728. static void coreaudio_defaults(obs_data_t *settings)
  729. {
  730. obs_data_set_default_string(settings, "device_id", "default");
  731. obs_data_set_default_bool(settings, "enable_downmix", true);
  732. }
  733. static void *coreaudio_create(obs_data_t *settings, obs_source_t *source,
  734. bool input)
  735. {
  736. struct coreaudio_data *ca = bzalloc(sizeof(struct coreaudio_data));
  737. if (os_event_init(&ca->exit_event, OS_EVENT_TYPE_MANUAL) != 0) {
  738. blog(LOG_ERROR,
  739. "[coreaudio_create] failed to create "
  740. "semephore: %d",
  741. errno);
  742. bfree(ca);
  743. return NULL;
  744. }
  745. ca->device_uid = bstrdup(obs_data_get_string(settings, "device_id"));
  746. ca->source = source;
  747. ca->input = input;
  748. ca->enable_downmix = obs_data_get_bool(settings, "enable_downmix");
  749. if (!ca->enable_downmix) {
  750. coreaudio_set_channels(ca, settings);
  751. }
  752. if (!ca->device_uid)
  753. ca->device_uid = bstrdup("default");
  754. coreaudio_try_init(ca);
  755. return ca;
  756. }
  757. static void *coreaudio_create_input_capture(obs_data_t *settings,
  758. obs_source_t *source)
  759. {
  760. return coreaudio_create(settings, source, true);
  761. }
  762. static void *coreaudio_create_output_capture(obs_data_t *settings,
  763. obs_source_t *source)
  764. {
  765. return coreaudio_create(settings, source, false);
  766. }
  767. static void coreaudio_fill_combo_with_inputs(const struct coreaudio_data *ca,
  768. obs_property_t *input_combo,
  769. uint32_t output_channel)
  770. {
  771. bool hasMutedChannel = false;
  772. obs_property_list_clear(input_combo);
  773. if (output_channel < ca->available_channels) {
  774. obs_property_list_add_int(input_combo,
  775. ca->channel_names[output_channel],
  776. output_channel + 1);
  777. } else {
  778. obs_property_list_add_int(
  779. input_combo, obs_module_text("CoreAudio.None"), -1);
  780. hasMutedChannel = true;
  781. }
  782. for (uint32_t input_chan = 0; input_chan < ca->available_channels;
  783. input_chan++) {
  784. if (input_chan != output_channel) {
  785. obs_property_list_add_int(input_combo,
  786. ca->channel_names[input_chan],
  787. input_chan + 1);
  788. }
  789. }
  790. if (!hasMutedChannel) {
  791. obs_property_list_add_int(
  792. input_combo, obs_module_text("CoreAudio.None"), -1);
  793. }
  794. }
  795. static void ensure_output_channel_prop(const struct coreaudio_data *ca,
  796. obs_properties_t *props,
  797. const char *device_config_name,
  798. uint32_t out_chan)
  799. {
  800. struct dstr name;
  801. dstr_init(&name);
  802. dstr_printf(&name, "output-%s-%d", device_config_name, out_chan + 1);
  803. obs_property_t *prop = obs_properties_get(props, name.array);
  804. if (prop) {
  805. obs_property_set_visible(prop, true);
  806. } else {
  807. struct dstr label;
  808. dstr_init(&label);
  809. dstr_printf(&label, "%s %i",
  810. obs_module_text("CoreAudio.Channel"), out_chan + 1);
  811. obs_property_t *input_combo = obs_properties_add_list(
  812. props, name.array, label.array, OBS_COMBO_TYPE_LIST,
  813. OBS_COMBO_FORMAT_INT);
  814. dstr_free(&label);
  815. coreaudio_fill_combo_with_inputs(ca, input_combo, out_chan);
  816. }
  817. dstr_free(&name);
  818. }
  819. static void ensure_output_channels_visible(obs_properties_t *props,
  820. const struct coreaudio_data *ca,
  821. uint32_t channels)
  822. {
  823. char *device_config_name = sanitize_device_name(ca->device_uid);
  824. for (uint32_t out_chan = 0; out_chan < channels; out_chan++) {
  825. ensure_output_channel_prop(ca, props, device_config_name,
  826. out_chan);
  827. }
  828. bfree(device_config_name);
  829. }
  830. static void hide_all_output_channels(obs_properties_t *props)
  831. {
  832. for (obs_property_t *prop = obs_properties_first(props); prop != NULL;
  833. obs_property_next(&prop)) {
  834. const char *prop_name = obs_property_name(prop);
  835. if (strncmp("output-", prop_name, 7) == 0) {
  836. obs_property_set_visible(prop, false);
  837. }
  838. }
  839. }
  840. static bool coreaudio_device_changed(void *data, obs_properties_t *props,
  841. obs_property_t *p, obs_data_t *settings)
  842. {
  843. struct coreaudio_data *ca = data;
  844. if (ca != NULL) {
  845. hide_all_output_channels(props);
  846. if (!ca->enable_downmix) {
  847. uint32_t channels = get_audio_channels(ca->speakers);
  848. ensure_output_channels_visible(props, ca, channels);
  849. }
  850. }
  851. UNUSED_PARAMETER(p);
  852. UNUSED_PARAMETER(settings);
  853. return true;
  854. }
  855. static bool coreaudio_downmix_changed(void *data, obs_properties_t *props,
  856. obs_property_t *p __unused,
  857. obs_data_t *settings)
  858. {
  859. struct coreaudio_data *ca = data;
  860. if (ca != NULL) {
  861. bool enable_downmix =
  862. obs_data_get_bool(settings, "enable_downmix");
  863. ca->enable_downmix = enable_downmix;
  864. hide_all_output_channels(props);
  865. if (!ca->enable_downmix) {
  866. uint32_t channels = get_audio_channels(ca->speakers);
  867. ensure_output_channels_visible(props, ca, channels);
  868. }
  869. }
  870. return true;
  871. }
  872. static obs_properties_t *coreaudio_properties(bool input, void *data)
  873. {
  874. struct coreaudio_data *ca = data;
  875. obs_properties_t *props = obs_properties_create();
  876. obs_property_t *property;
  877. struct device_list devices;
  878. memset(&devices, 0, sizeof(struct device_list));
  879. property = obs_properties_add_list(props, "device_id", TEXT_DEVICE,
  880. OBS_COMBO_TYPE_LIST,
  881. OBS_COMBO_FORMAT_STRING);
  882. coreaudio_enum_devices(&devices, input);
  883. if (devices.items.num)
  884. obs_property_list_add_string(property, TEXT_DEVICE_DEFAULT,
  885. "default");
  886. for (size_t i = 0; i < devices.items.num; i++) {
  887. struct device_item *item = devices.items.array + i;
  888. obs_property_list_add_string(property, item->name.array,
  889. item->value.array);
  890. }
  891. obs_property_set_modified_callback2(property, coreaudio_device_changed,
  892. ca);
  893. property = obs_properties_add_bool(
  894. props, "enable_downmix", obs_module_text("CoreAudio.Downmix"));
  895. obs_property_set_modified_callback2(property, coreaudio_downmix_changed,
  896. ca);
  897. if (ca != NULL) {
  898. uint32_t channels = get_audio_channels(ca->speakers);
  899. ensure_output_channels_visible(props, ca, channels);
  900. if (ca->enable_downmix) {
  901. hide_all_output_channels(props);
  902. }
  903. }
  904. device_list_free(&devices);
  905. return props;
  906. }
  907. static obs_properties_t *coreaudio_input_properties(void *data)
  908. {
  909. return coreaudio_properties(true, data);
  910. }
  911. static obs_properties_t *coreaudio_output_properties(void *data)
  912. {
  913. return coreaudio_properties(false, data);
  914. }
  915. struct obs_source_info coreaudio_input_capture_info = {
  916. .id = "coreaudio_input_capture",
  917. .type = OBS_SOURCE_TYPE_INPUT,
  918. .output_flags = OBS_SOURCE_AUDIO | OBS_SOURCE_DO_NOT_DUPLICATE,
  919. .get_name = coreaudio_input_getname,
  920. .create = coreaudio_create_input_capture,
  921. .destroy = coreaudio_destroy,
  922. .update = coreaudio_update,
  923. .get_defaults = coreaudio_defaults,
  924. .get_properties = coreaudio_input_properties,
  925. .icon_type = OBS_ICON_TYPE_AUDIO_INPUT,
  926. };
  927. struct obs_source_info coreaudio_output_capture_info = {
  928. .id = "coreaudio_output_capture",
  929. .type = OBS_SOURCE_TYPE_INPUT,
  930. .output_flags = OBS_SOURCE_AUDIO | OBS_SOURCE_DO_NOT_DUPLICATE |
  931. OBS_SOURCE_DO_NOT_SELF_MONITOR,
  932. .get_name = coreaudio_output_getname,
  933. .create = coreaudio_create_output_capture,
  934. .destroy = coreaudio_destroy,
  935. .update = coreaudio_update,
  936. .get_defaults = coreaudio_defaults,
  937. .get_properties = coreaudio_output_properties,
  938. .icon_type = OBS_ICON_TYPE_AUDIO_OUTPUT,
  939. };