rtp.c 24 KB

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  1. /*
  2. * HairTunes - RAOP packet handler and slave-clocked replay engine
  3. * Copyright (c) James Laird 2011
  4. * All rights reserved.
  5. *
  6. * Modularisation: philippe_44@outlook.com, 2019
  7. *
  8. * Permission is hereby granted, free of charge, to any person
  9. * obtaining a copy of this software and associated documentation
  10. * files (the "Software"), to deal in the Software without
  11. * restriction, including without limitation the rights to use,
  12. * copy, modify, merge, publish, distribute, sublicense, and/or
  13. * sell copies of the Software, and to permit persons to whom the
  14. * Software is furnished to do so, subject to the following conditions:
  15. *
  16. * The above copyright notice and this permission notice shall be
  17. * included in all copies or substantial portions of the Software.
  18. *
  19. * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
  20. * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES
  21. * OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
  22. * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
  23. * HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY,
  24. * WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
  25. * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
  26. * OTHER DEALINGS IN THE SOFTWARE.
  27. */
  28. #include <stdio.h>
  29. #include <stdlib.h>
  30. #include <string.h>
  31. #include <stdarg.h>
  32. #include <sys/types.h>
  33. #include <pthread.h>
  34. #include <math.h>
  35. #include <errno.h>
  36. #include <sys/stat.h>
  37. #include <stdint.h>
  38. #include <fcntl.h>
  39. #include <assert.h>
  40. #include "platform.h"
  41. #include "rtp.h"
  42. #include "raop_sink.h"
  43. #include "log_util.h"
  44. #include "util.h"
  45. #ifdef WIN32
  46. #include <openssl/aes.h>
  47. #include "alac_wrapper.h"
  48. #define MSG_DONTWAIT 0
  49. #else
  50. #include "esp_pthread.h"
  51. #include "esp_system.h"
  52. #include <mbedtls/version.h>
  53. #include <mbedtls/aes.h>
  54. #include "alac_wrapper.h"
  55. #endif
  56. #define NTP2MS(ntp) ((((ntp) >> 10) * 1000L) >> 22)
  57. #define MS2NTP(ms) (((((u64_t) (ms)) << 22) / 1000) << 10)
  58. #define NTP2TS(ntp, rate) ((((ntp) >> 16) * (rate)) >> 16)
  59. #define TS2NTP(ts, rate) (((((u64_t) (ts)) << 16) / (rate)) << 16)
  60. #define MS2TS(ms, rate) ((((u64_t) (ms)) * (rate)) / 1000)
  61. #define TS2MS(ts, rate) NTP2MS(TS2NTP(ts,rate))
  62. extern log_level raop_loglevel;
  63. static log_level *loglevel = &raop_loglevel;
  64. //#define __RTP_STORE
  65. // default buffer size
  66. #define BUFFER_FRAMES ( (150 * RAOP_SAMPLE_RATE * 2) / (352 * 100) )
  67. #define MAX_PACKET 1408
  68. #define MIN_LATENCY 11025
  69. #define MAX_LATENCY ( (120 * RAOP_SAMPLE_RATE * 2) / 100 )
  70. #define RTP_STACK_SIZE (4*1024)
  71. #define RTP_SYNC (0x01)
  72. #define NTP_SYNC (0x02)
  73. #define RESEND_TO 200
  74. enum { DATA = 0, CONTROL, TIMING };
  75. static const u8_t silence_frame[MAX_PACKET] = { 0 };
  76. typedef u16_t seq_t;
  77. typedef struct audio_buffer_entry { // decoded audio packets
  78. int ready;
  79. u32_t rtptime, last_resend;
  80. s16_t *data;
  81. int len;
  82. } abuf_t;
  83. typedef struct rtp_s {
  84. #ifdef __RTP_STORE
  85. FILE *rtpIN, *rtpOUT;
  86. #endif
  87. bool running;
  88. unsigned char aesiv[16];
  89. #ifdef WIN32
  90. AES_KEY aes;
  91. #else
  92. mbedtls_aes_context aes;
  93. #endif
  94. bool decrypt;
  95. u8_t *decrypt_buf;
  96. u32_t frame_size, frame_duration;
  97. u32_t in_frames, out_frames;
  98. struct in_addr host;
  99. struct sockaddr_in rtp_host;
  100. struct {
  101. unsigned short rport, lport;
  102. int sock;
  103. } rtp_sockets[3]; // data, control, timing
  104. struct timing_s {
  105. u64_t local, remote;
  106. } timing;
  107. struct {
  108. u32_t rtp, time;
  109. u8_t status;
  110. } synchro;
  111. struct {
  112. u32_t time;
  113. seq_t seqno;
  114. u32_t rtptime;
  115. } record;
  116. int latency; // rtp hold depth in samples
  117. u32_t resent_req, resent_rec; // total resent + recovered frames
  118. u32_t silent_frames; // total silence frames
  119. u32_t discarded;
  120. abuf_t audio_buffer[BUFFER_FRAMES];
  121. seq_t ab_read, ab_write;
  122. pthread_mutex_t ab_mutex;
  123. #ifdef WIN32
  124. pthread_t thread;
  125. #else
  126. TaskHandle_t thread, joiner;
  127. StaticTask_t *xTaskBuffer;
  128. StackType_t xStack[RTP_STACK_SIZE] __attribute__ ((aligned (4)));
  129. #endif
  130. struct alac_codec_s *alac_codec;
  131. int flush_seqno;
  132. bool playing;
  133. raop_data_cb_t data_cb;
  134. raop_cmd_cb_t cmd_cb;
  135. } rtp_t;
  136. #define BUFIDX(seqno) ((seq_t)(seqno) % BUFFER_FRAMES)
  137. static void buffer_alloc(abuf_t *audio_buffer, int size);
  138. static void buffer_release(abuf_t *audio_buffer);
  139. static void buffer_reset(abuf_t *audio_buffer);
  140. static void buffer_push_packet(rtp_t *ctx);
  141. static bool rtp_request_resend(rtp_t *ctx, seq_t first, seq_t last);
  142. static bool rtp_request_timing(rtp_t *ctx);
  143. static int seq_order(seq_t a, seq_t b);
  144. #ifdef WIN32
  145. static void *rtp_thread_func(void *arg);
  146. #else
  147. static void rtp_thread_func(void *arg);
  148. #endif
  149. /*---------------------------------------------------------------------------*/
  150. static struct alac_codec_s* alac_init(int fmtp[32]) {
  151. struct alac_codec_s *alac;
  152. unsigned sample_rate, block_size;
  153. unsigned char sample_size, channels;
  154. struct {
  155. uint32_t frameLength;
  156. uint8_t compatibleVersion;
  157. uint8_t bitDepth;
  158. uint8_t pb;
  159. uint8_t mb;
  160. uint8_t kb;
  161. uint8_t numChannels;
  162. uint16_t maxRun;
  163. uint32_t maxFrameBytes;
  164. uint32_t avgBitRate;
  165. uint32_t sampleRate;
  166. } config;
  167. config.frameLength = htonl(fmtp[1]);
  168. config.compatibleVersion = fmtp[2];
  169. config.bitDepth = fmtp[3];
  170. config.pb = fmtp[4];
  171. config.mb = fmtp[5];
  172. config.kb = fmtp[6];
  173. config.numChannels = fmtp[7];
  174. config.maxRun = htons(fmtp[8]);
  175. config.maxFrameBytes = htonl(fmtp[9]);
  176. config.avgBitRate = htonl(fmtp[10]);
  177. config.sampleRate = htonl(fmtp[11]);
  178. alac = alac_create_decoder(sizeof(config), (unsigned char*) &config, &sample_size, &sample_rate, &channels, &block_size);
  179. if (!alac) {
  180. LOG_ERROR("cannot create alac codec", NULL);
  181. return NULL;
  182. }
  183. return alac;
  184. }
  185. /*---------------------------------------------------------------------------*/
  186. rtp_resp_t rtp_init(struct in_addr host, int latency, char *aeskey, char *aesiv, char *fmtpstr,
  187. short unsigned pCtrlPort, short unsigned pTimingPort,
  188. raop_cmd_cb_t cmd_cb, raop_data_cb_t data_cb)
  189. {
  190. int i = 0;
  191. char *arg;
  192. int fmtp[12];
  193. bool rc = true;
  194. rtp_t *ctx = calloc(1, sizeof(rtp_t));
  195. rtp_resp_t resp = { 0, 0, 0, NULL };
  196. if (!ctx) return resp;
  197. ctx->host = host;
  198. ctx->decrypt = false;
  199. ctx->cmd_cb = cmd_cb;
  200. ctx->data_cb = data_cb;
  201. ctx->rtp_host.sin_family = AF_INET;
  202. ctx->rtp_host.sin_addr.s_addr = INADDR_ANY;
  203. pthread_mutex_init(&ctx->ab_mutex, 0);
  204. ctx->flush_seqno = -1;
  205. ctx->latency = latency;
  206. ctx->ab_read = ctx->ab_write;
  207. #ifdef __RTP_STORE
  208. ctx->rtpIN = fopen("airplay.rtpin", "wb");
  209. ctx->rtpOUT = fopen("airplay.rtpout", "wb");
  210. #endif
  211. ctx->rtp_sockets[CONTROL].rport = pCtrlPort;
  212. ctx->rtp_sockets[TIMING].rport = pTimingPort;
  213. if (aesiv && aeskey) {
  214. memcpy(ctx->aesiv, aesiv, 16);
  215. #ifdef WIN32
  216. AES_set_decrypt_key((unsigned char*) aeskey, 128, &ctx->aes);
  217. #else
  218. memset(&ctx->aes, 0, sizeof(mbedtls_aes_context));
  219. mbedtls_aes_setkey_dec(&ctx->aes, (unsigned char*) aeskey, 128);
  220. #endif
  221. ctx->decrypt = true;
  222. ctx->decrypt_buf = malloc(MAX_PACKET);
  223. }
  224. memset(fmtp, 0, sizeof(fmtp));
  225. while ((arg = strsep(&fmtpstr, " \t")) != NULL) fmtp[i++] = atoi(arg);
  226. ctx->frame_size = fmtp[1];
  227. ctx->frame_duration = (ctx->frame_size * 1000) / RAOP_SAMPLE_RATE;
  228. // alac decoder
  229. ctx->alac_codec = alac_init(fmtp);
  230. rc &= ctx->alac_codec != NULL;
  231. buffer_alloc(ctx->audio_buffer, ctx->frame_size*4);
  232. // create rtp ports
  233. for (i = 0; i < 3; i++) {
  234. ctx->rtp_sockets[i].sock = bind_socket(&ctx->rtp_sockets[i].lport, SOCK_DGRAM);
  235. rc &= ctx->rtp_sockets[i].sock > 0;
  236. }
  237. // create http port and start listening
  238. resp.cport = ctx->rtp_sockets[CONTROL].lport;
  239. resp.tport = ctx->rtp_sockets[TIMING].lport;
  240. resp.aport = ctx->rtp_sockets[DATA].lport;
  241. ctx->running = true;
  242. #ifdef WIN32
  243. pthread_create(&ctx->thread, NULL, rtp_thread_func, (void *) ctx);
  244. #else
  245. ctx->xTaskBuffer = (StaticTask_t*) heap_caps_malloc(sizeof(StaticTask_t), MALLOC_CAP_INTERNAL | MALLOC_CAP_8BIT);
  246. ctx->thread = xTaskCreateStatic( (TaskFunction_t) rtp_thread_func, "RTP_thread", RTP_STACK_SIZE, ctx,
  247. CONFIG_ESP32_PTHREAD_TASK_PRIO_DEFAULT + 1, ctx->xStack, ctx->xTaskBuffer );
  248. #endif
  249. // cleanup everything if we failed
  250. if (!rc) {
  251. LOG_ERROR("[%p]: cannot start RTP", ctx);
  252. rtp_end(ctx);
  253. ctx = NULL;
  254. }
  255. resp.ctx = ctx;
  256. return resp;
  257. }
  258. /*---------------------------------------------------------------------------*/
  259. void rtp_end(rtp_t *ctx)
  260. {
  261. int i;
  262. if (!ctx) return;
  263. if (ctx->running) {
  264. #if !defined WIN32
  265. ctx->joiner = xTaskGetCurrentTaskHandle();
  266. #endif
  267. ctx->running = false;
  268. #ifdef WIN32
  269. pthread_join(ctx->thread, NULL);
  270. #else
  271. ulTaskNotifyTake(pdFALSE, portMAX_DELAY);
  272. vTaskDelete(ctx->thread);
  273. heap_caps_free(ctx->xTaskBuffer);
  274. #endif
  275. }
  276. for (i = 0; i < 3; i++) closesocket(ctx->rtp_sockets[i].sock);
  277. if (ctx->alac_codec) alac_delete_decoder(ctx->alac_codec);
  278. if (ctx->decrypt_buf) free(ctx->decrypt_buf);
  279. pthread_mutex_destroy(&ctx->ab_mutex);
  280. buffer_release(ctx->audio_buffer);
  281. free(ctx);
  282. #ifdef __RTP_STORE
  283. fclose(ctx->rtpIN);
  284. fclose(ctx->rtpOUT);
  285. #endif
  286. }
  287. /*---------------------------------------------------------------------------*/
  288. bool rtp_flush(rtp_t *ctx, unsigned short seqno, unsigned int rtptime, bool exit_locked)
  289. {
  290. bool rc = true;
  291. u32_t now = gettime_ms();
  292. if (now < ctx->record.time + 250 || (ctx->record.seqno == seqno && ctx->record.rtptime == rtptime)) {
  293. rc = false;
  294. LOG_ERROR("[%p]: FLUSH ignored as same as RECORD (%hu - %u)", ctx, seqno, rtptime);
  295. } else {
  296. pthread_mutex_lock(&ctx->ab_mutex);
  297. buffer_reset(ctx->audio_buffer);
  298. ctx->playing = false;
  299. ctx->flush_seqno = seqno;
  300. if (!exit_locked) pthread_mutex_unlock(&ctx->ab_mutex);
  301. }
  302. LOG_INFO("[%p]: flush %hu %u", ctx, seqno, rtptime);
  303. return rc;
  304. }
  305. /*---------------------------------------------------------------------------*/
  306. void rtp_flush_release(rtp_t *ctx) {
  307. pthread_mutex_unlock(&ctx->ab_mutex);
  308. }
  309. /*---------------------------------------------------------------------------*/
  310. void rtp_record(rtp_t *ctx, unsigned short seqno, unsigned rtptime) {
  311. ctx->record.seqno = seqno;
  312. ctx->record.rtptime = rtptime;
  313. ctx->record.time = gettime_ms();
  314. LOG_INFO("[%p]: record %hu %u", ctx, seqno, rtptime);
  315. }
  316. /*---------------------------------------------------------------------------*/
  317. static void buffer_alloc(abuf_t *audio_buffer, int size) {
  318. int i;
  319. for (i = 0; i < BUFFER_FRAMES; i++) {
  320. audio_buffer[i].data = malloc(size);
  321. audio_buffer[i].ready = 0;
  322. }
  323. }
  324. /*---------------------------------------------------------------------------*/
  325. static void buffer_release(abuf_t *audio_buffer) {
  326. int i;
  327. for (i = 0; i < BUFFER_FRAMES; i++) {
  328. free(audio_buffer[i].data);
  329. }
  330. }
  331. /*---------------------------------------------------------------------------*/
  332. static void buffer_reset(abuf_t *audio_buffer) {
  333. int i;
  334. for (i = 0; i < BUFFER_FRAMES; i++) audio_buffer[i].ready = 0;
  335. }
  336. /*---------------------------------------------------------------------------*/
  337. // the sequence numbers will wrap pretty often.
  338. // this returns true if the second arg is after the first
  339. static int seq_order(seq_t a, seq_t b) {
  340. s16_t d = b - a;
  341. return d > 0;
  342. }
  343. /*---------------------------------------------------------------------------*/
  344. static void alac_decode(rtp_t *ctx, s16_t *dest, char *buf, int len, int *outsize) {
  345. unsigned char iv[16];
  346. int aeslen;
  347. assert(len<=MAX_PACKET);
  348. if (ctx->decrypt) {
  349. aeslen = len & ~0xf;
  350. memcpy(iv, ctx->aesiv, sizeof(iv));
  351. #ifdef WIN32
  352. AES_cbc_encrypt((unsigned char*)buf, ctx->decrypt_buf, aeslen, &ctx->aes, iv, AES_DECRYPT);
  353. #else
  354. mbedtls_aes_crypt_cbc(&ctx->aes, MBEDTLS_AES_DECRYPT, aeslen, iv, (unsigned char*) buf, ctx->decrypt_buf);
  355. #endif
  356. memcpy(ctx->decrypt_buf+aeslen, buf+aeslen, len-aeslen);
  357. alac_to_pcm(ctx->alac_codec, (unsigned char*) ctx->decrypt_buf, (unsigned char*) dest, 2, (unsigned int*) outsize);
  358. } else {
  359. alac_to_pcm(ctx->alac_codec, (unsigned char*) buf, (unsigned char*) dest, 2, (unsigned int*) outsize);
  360. }
  361. *outsize *= 4;
  362. }
  363. /*---------------------------------------------------------------------------*/
  364. static void buffer_put_packet(rtp_t *ctx, seq_t seqno, unsigned rtptime, bool first, char *data, int len) {
  365. abuf_t *abuf = NULL;
  366. u32_t playtime;
  367. pthread_mutex_lock(&ctx->ab_mutex);
  368. if (!ctx->playing) {
  369. if ((ctx->flush_seqno == -1 || seq_order(ctx->flush_seqno, seqno)) &&
  370. (ctx->synchro.status & RTP_SYNC) && (ctx->synchro.status & NTP_SYNC)) {
  371. ctx->ab_write = seqno-1;
  372. ctx->ab_read = seqno;
  373. ctx->flush_seqno = -1;
  374. ctx->playing = true;
  375. ctx->resent_req = ctx->resent_rec = ctx->silent_frames = ctx->discarded = 0;
  376. playtime = ctx->synchro.time + ((rtptime - ctx->synchro.rtp) * 10) / (RAOP_SAMPLE_RATE / 100);
  377. ctx->cmd_cb(RAOP_PLAY, playtime);
  378. } else {
  379. pthread_mutex_unlock(&ctx->ab_mutex);
  380. return;
  381. }
  382. }
  383. if (seqno == (u16_t) (ctx->ab_write+1)) {
  384. // expected packet
  385. abuf = ctx->audio_buffer + BUFIDX(seqno);
  386. ctx->ab_write = seqno;
  387. LOG_SDEBUG("packet expected seqno:%hu rtptime:%u (W:%hu R:%hu)", seqno, rtptime, ctx->ab_write, ctx->ab_read);
  388. } else if (seq_order(ctx->ab_write, seqno)) {
  389. seq_t i;
  390. u32_t now;
  391. // newer than expected
  392. if (ctx->latency && seq_order(ctx->latency / ctx->frame_size, seqno - ctx->ab_write - 1)) {
  393. // only get rtp latency-1 frames back (last one is seqno)
  394. LOG_WARN("[%p] too many missing frames %hu seq: %hu, (W:%hu R:%hu)", ctx, seqno - ctx->ab_write - 1, seqno, ctx->ab_write, ctx->ab_read);
  395. ctx->ab_write = seqno - ctx->latency / ctx->frame_size;
  396. }
  397. // need to request re-send and adjust timing of gaps
  398. rtp_request_resend(ctx, ctx->ab_write + 1, seqno-1);
  399. for (now = gettime_ms(), i = ctx->ab_write + 1; seq_order(i, seqno); i++) {
  400. ctx->audio_buffer[BUFIDX(i)].rtptime = rtptime - (seqno-i)*ctx->frame_size;
  401. ctx->audio_buffer[BUFIDX(i)].last_resend = now;
  402. }
  403. LOG_DEBUG("[%p]: packet newer seqno:%hu rtptime:%u (W:%hu R:%hu)", ctx, seqno, rtptime, ctx->ab_write, ctx->ab_read);
  404. abuf = ctx->audio_buffer + BUFIDX(seqno);
  405. ctx->ab_write = seqno;
  406. } else if (seq_order(ctx->ab_read, seqno + 1)) {
  407. // recovered packet, not yet sent
  408. abuf = ctx->audio_buffer + BUFIDX(seqno);
  409. ctx->resent_rec++;
  410. LOG_DEBUG("[%p]: packet recovered seqno:%hu rtptime:%u (W:%hu R:%hu)", ctx, seqno, rtptime, ctx->ab_write, ctx->ab_read);
  411. } else {
  412. // too late
  413. LOG_DEBUG("[%p]: packet too late seqno:%hu rtptime:%u (W:%hu R:%hu)", ctx, seqno, rtptime, ctx->ab_write, ctx->ab_read);
  414. }
  415. if (ctx->in_frames++ > 1000) {
  416. LOG_INFO("[%p]: fill [level:%hu rec:%u] [W:%hu R:%hu]", ctx, ctx->ab_write - ctx->ab_read, ctx->resent_rec, ctx->ab_write, ctx->ab_read);
  417. ctx->in_frames = 0;
  418. }
  419. if (abuf) {
  420. alac_decode(ctx, abuf->data, data, len, &abuf->len);
  421. abuf->ready = 1;
  422. // this is the local rtptime when this frame is expected to play
  423. abuf->rtptime = rtptime;
  424. buffer_push_packet(ctx);
  425. #ifdef __RTP_STORE
  426. fwrite(data, len, 1, ctx->rtpIN);
  427. fwrite(abuf->data, abuf->len, 1, ctx->rtpOUT);
  428. #endif
  429. }
  430. pthread_mutex_unlock(&ctx->ab_mutex);
  431. }
  432. /*---------------------------------------------------------------------------*/
  433. // push as many frames as possible through callback
  434. static void buffer_push_packet(rtp_t *ctx) {
  435. abuf_t *curframe = NULL;
  436. u32_t now, playtime, hold = max((ctx->latency * 1000) / (8 * RAOP_SAMPLE_RATE), 100);
  437. int i;
  438. // not ready to play yet
  439. if (!ctx->playing || ctx->synchro.status != (RTP_SYNC | NTP_SYNC)) return;
  440. // there is always at least one frame in the buffer
  441. do {
  442. // re-evaluate time in loop in case data callback blocks ...
  443. now = gettime_ms();
  444. // try to manage playtime so that we overflow as late as possible if we miss NTP (2^31 / 10 / 44100)
  445. curframe = ctx->audio_buffer + BUFIDX(ctx->ab_read);
  446. playtime = ctx->synchro.time + ((curframe->rtptime - ctx->synchro.rtp) * 10) / (RAOP_SAMPLE_RATE / 100);
  447. if (now > playtime) {
  448. LOG_DEBUG("[%p]: discarded frame now:%u missed by:%d (W:%hu R:%hu)", ctx, now, now - playtime, ctx->ab_write, ctx->ab_read);
  449. ctx->discarded++;
  450. curframe->ready = 0;
  451. } else if (playtime - now <= hold) {
  452. if (curframe->ready) {
  453. ctx->data_cb((const u8_t*) curframe->data, curframe->len, playtime);
  454. curframe->ready = 0;
  455. } else {
  456. LOG_DEBUG("[%p]: created zero frame (W:%hu R:%hu)", ctx, ctx->ab_write, ctx->ab_read);
  457. ctx->data_cb(silence_frame, ctx->frame_size * 4, playtime);
  458. ctx->silent_frames++;
  459. }
  460. } else if (curframe->ready) {
  461. ctx->data_cb((const u8_t*) curframe->data, curframe->len, playtime);
  462. curframe->ready = 0;
  463. } else {
  464. break;
  465. }
  466. ctx->ab_read++;
  467. ctx->out_frames++;
  468. } while (seq_order(ctx->ab_read, ctx->ab_write));
  469. if (ctx->out_frames > 1000) {
  470. LOG_INFO("[%p]: drain [level:%hd head:%d ms] [W:%hu R:%hu] [req:%u sil:%u dis:%u]",
  471. ctx, ctx->ab_write - ctx->ab_read, playtime - now, ctx->ab_write, ctx->ab_read,
  472. ctx->resent_req, ctx->silent_frames, ctx->discarded);
  473. ctx->out_frames = 0;
  474. }
  475. LOG_SDEBUG("playtime %u %d [W:%hu R:%hu] %d", playtime, playtime - now, ctx->ab_write, ctx->ab_read, curframe->ready);
  476. // each missing packet will be requested up to (latency_frames / 16) times
  477. for (i = 0; seq_order(ctx->ab_read + i, ctx->ab_write); i += 16) {
  478. abuf_t *frame = ctx->audio_buffer + BUFIDX(ctx->ab_read + i);
  479. if (!frame->ready && now - frame->last_resend > RESEND_TO) {
  480. rtp_request_resend(ctx, ctx->ab_read + i, ctx->ab_read + i);
  481. frame->last_resend = now;
  482. }
  483. }
  484. }
  485. /*---------------------------------------------------------------------------*/
  486. #ifdef WIN32
  487. static void *rtp_thread_func(void *arg) {
  488. #else
  489. static void rtp_thread_func(void *arg) {
  490. #endif
  491. fd_set fds;
  492. int i, sock = -1;
  493. int count = 0;
  494. bool ntp_sent;
  495. char *packet = malloc(MAX_PACKET);
  496. rtp_t *ctx = (rtp_t*) arg;
  497. for (i = 0; i < 3; i++) {
  498. if (ctx->rtp_sockets[i].sock > sock) sock = ctx->rtp_sockets[i].sock;
  499. // send synchro request 3 times
  500. ntp_sent = rtp_request_timing(ctx);
  501. }
  502. while (ctx->running) {
  503. ssize_t plen;
  504. char type;
  505. socklen_t rtp_client_len = sizeof(struct sockaddr_in);
  506. int idx = 0;
  507. char *pktp = packet;
  508. struct timeval timeout = {0, 100*1000};
  509. FD_ZERO(&fds);
  510. for (i = 0; i < 3; i++) { FD_SET(ctx->rtp_sockets[i].sock, &fds); }
  511. if (select(sock + 1, &fds, NULL, NULL, &timeout) <= 0) continue;
  512. for (i = 0; i < 3; i++)
  513. if (FD_ISSET(ctx->rtp_sockets[i].sock, &fds)) idx = i;
  514. plen = recvfrom(ctx->rtp_sockets[idx].sock, packet, MAX_PACKET, MSG_DONTWAIT, (struct sockaddr*) &ctx->rtp_host, &rtp_client_len);
  515. if (!ntp_sent) {
  516. LOG_WARN("[%p]: NTP request not send yet", ctx);
  517. ntp_sent = rtp_request_timing(ctx);
  518. }
  519. if (plen <= 0) {
  520. LOG_WARN("Nothing received on a readable socket %d", plen);
  521. continue;
  522. }
  523. assert(plen <= MAX_PACKET);
  524. type = packet[1] & ~0x80;
  525. pktp = packet;
  526. switch (type) {
  527. seq_t seqno;
  528. unsigned rtptime;
  529. // re-sent packet
  530. case 0x56: {
  531. pktp += 4;
  532. plen -= 4;
  533. }
  534. // fall through
  535. // data packet
  536. case 0x60: {
  537. seqno = ntohs(*(u16_t*)(pktp+2));
  538. rtptime = ntohl(*(u32_t*)(pktp+4));
  539. // adjust pointer and length
  540. pktp += 12;
  541. plen -= 12;
  542. LOG_SDEBUG("[%p]: seqno:%hu rtp:%u (type: %x, first: %u)", ctx, seqno, rtptime, type, packet[1] & 0x80);
  543. // check if packet contains enough content to be reasonable
  544. if (plen < 16) break;
  545. if ((packet[1] & 0x80) && (type != 0x56)) {
  546. LOG_INFO("[%p]: 1st audio packet received", ctx);
  547. }
  548. buffer_put_packet(ctx, seqno, rtptime, packet[1] & 0x80, pktp, plen);
  549. break;
  550. }
  551. // sync packet
  552. case 0x54: {
  553. u32_t rtp_now_latency = ntohl(*(u32_t*)(pktp+4));
  554. u64_t remote = (((u64_t) ntohl(*(u32_t*)(pktp+8))) << 32) + ntohl(*(u32_t*)(pktp+12));
  555. u32_t rtp_now = ntohl(*(u32_t*)(pktp+16));
  556. u16_t flags = ntohs(*(u16_t*)(pktp+2));
  557. u32_t remote_gap = NTP2MS(remote - ctx->timing.remote);
  558. // try to get NTP every 3 sec or every time if we are not synced
  559. if (!count-- || !(ctx->synchro.status & NTP_SYNC)) {
  560. rtp_request_timing(ctx);
  561. count = 3;
  562. }
  563. // something is wrong, we should not have such gap
  564. if (remote_gap > 10000) {
  565. LOG_WARN("discarding remote timing information %u", remote_gap);
  566. break;
  567. }
  568. pthread_mutex_lock(&ctx->ab_mutex);
  569. // re-align timestamp and expected local playback time (and magic 11025 latency)
  570. ctx->latency = rtp_now - rtp_now_latency;
  571. if (flags == 7 || flags == 4) ctx->latency += 11025;
  572. if (ctx->latency < MIN_LATENCY) ctx->latency = MIN_LATENCY;
  573. else if (ctx->latency > MAX_LATENCY) ctx->latency = MAX_LATENCY;
  574. ctx->synchro.rtp = rtp_now - ctx->latency;
  575. ctx->synchro.time = ctx->timing.local + remote_gap;
  576. // now we are synced on RTP frames
  577. ctx->synchro.status |= RTP_SYNC;
  578. // 1st sync packet received (signals a restart of playback)
  579. if (packet[0] & 0x10) {
  580. LOG_INFO("[%p]: 1st sync packet received", ctx);
  581. }
  582. pthread_mutex_unlock(&ctx->ab_mutex);
  583. LOG_DEBUG("[%p]: sync packet latency:%d rtp_latency:%u rtp:%u remote ntp:%llx, local time:%u local rtp:%u (now:%u)",
  584. ctx, ctx->latency, rtp_now_latency, rtp_now, remote, ctx->synchro.time, ctx->synchro.rtp, gettime_ms());
  585. if ((ctx->synchro.status & RTP_SYNC) && (ctx->synchro.status & NTP_SYNC)) ctx->cmd_cb(RAOP_TIMING);
  586. break;
  587. }
  588. // NTP timing packet
  589. case 0x53: {
  590. u32_t reference = ntohl(*(u32_t*)(pktp+12)); // only low 32 bits in our case
  591. u64_t remote =(((u64_t) ntohl(*(u32_t*)(pktp+16))) << 32) + ntohl(*(u32_t*)(pktp+20));
  592. u32_t roundtrip = gettime_ms() - reference;
  593. // better discard sync packets when roundtrip is suspicious
  594. if (roundtrip > 100) {
  595. // ask for another one only if we are not synced already
  596. if (!(ctx->synchro.status & NTP_SYNC)) rtp_request_timing(ctx);
  597. LOG_WARN("[%p]: discarding NTP roundtrip of %u ms", ctx, roundtrip);
  598. break;
  599. }
  600. /*
  601. The expected elapsed remote time should be exactly the same as
  602. elapsed local time between the two request, corrected by the
  603. drifting
  604. u64_t expected = ctx->timing.remote + MS2NTP(reference - ctx->timing.local);
  605. */
  606. ctx->timing.remote = remote;
  607. ctx->timing.local = reference;
  608. // now we are synced on NTP (mutex not needed)
  609. ctx->synchro.status |= NTP_SYNC;
  610. LOG_DEBUG("[%p]: Timing references local:%llu, remote:%llx (delta:%lld, sum:%lld, adjust:%lld, gaps:%d)",
  611. ctx, ctx->timing.local, ctx->timing.remote);
  612. break;
  613. }
  614. default: {
  615. LOG_WARN("Unknown packet received %x", (int) type);
  616. break;
  617. }
  618. }
  619. }
  620. free(packet);
  621. LOG_INFO("[%p]: terminating", ctx);
  622. #ifndef WIN32
  623. xTaskNotifyGive(ctx->joiner);
  624. vTaskSuspend(NULL);
  625. #else
  626. return NULL;
  627. #endif
  628. }
  629. /*---------------------------------------------------------------------------*/
  630. static bool rtp_request_timing(rtp_t *ctx) {
  631. unsigned char req[32];
  632. u32_t now = gettime_ms();
  633. int i;
  634. struct sockaddr_in host;
  635. LOG_DEBUG("[%p]: timing request now:%u (port: %hu)", ctx, now, ctx->rtp_sockets[TIMING].rport);
  636. req[0] = 0x80;
  637. req[1] = 0x52|0x80;
  638. *(u16_t*)(req+2) = htons(7);
  639. *(u32_t*)(req+4) = htonl(0); // dummy
  640. for (i = 0; i < 16; i++) req[i+8] = 0;
  641. *(u32_t*)(req+24) = 0;
  642. *(u32_t*)(req+28) = htonl(now); // this is not a real NTP, but a 32 ms counter in the low part of the NTP
  643. if (ctx->host.s_addr != INADDR_ANY) {
  644. host.sin_family = AF_INET;
  645. host.sin_addr = ctx->host;
  646. } else host = ctx->rtp_host;
  647. // no address from sender, need to wait for 1st packet to be received
  648. if (host.sin_addr.s_addr == INADDR_ANY) return false;
  649. host.sin_port = htons(ctx->rtp_sockets[TIMING].rport);
  650. if (sizeof(req) != sendto(ctx->rtp_sockets[TIMING].sock, req, sizeof(req), MSG_DONTWAIT, (struct sockaddr*) &host, sizeof(host))) {
  651. LOG_WARN("[%p]: SENDTO failed (%s)", ctx, strerror(errno));
  652. }
  653. return true;
  654. }
  655. /*---------------------------------------------------------------------------*/
  656. static bool rtp_request_resend(rtp_t *ctx, seq_t first, seq_t last) {
  657. unsigned char req[8]; // *not* a standard RTCP NACK
  658. // do not request silly ranges (happens in case of network large blackouts)
  659. if (seq_order(last, first) || last - first > BUFFER_FRAMES / 2) return false;
  660. ctx->resent_req += (seq_t) (last - first) + 1;
  661. LOG_DEBUG("resend request [W:%hu R:%hu first=%hu last=%hu]", ctx->ab_write, ctx->ab_read, first, last);
  662. req[0] = 0x80;
  663. req[1] = 0x55|0x80; // Apple 'resend'
  664. *(u16_t*)(req+2) = htons(1); // our seqnum
  665. *(u16_t*)(req+4) = htons(first); // missed seqnum
  666. *(u16_t*)(req+6) = htons(last-first+1); // count
  667. ctx->rtp_host.sin_port = htons(ctx->rtp_sockets[CONTROL].rport);
  668. if (sizeof(req) != sendto(ctx->rtp_sockets[CONTROL].sock, req, sizeof(req), MSG_DONTWAIT, (struct sockaddr*) &ctx->rtp_host, sizeof(ctx->rtp_host))) {
  669. LOG_WARN("[%p]: SENDTO failed (%s)", ctx, strerror(errno));
  670. }
  671. return true;
  672. }