tsdecrypt reads and decrypts CSA encrypted incoming mpeg transport stream over UDP/RTP using code words obtained from OSCAM or similar CAM server. tsdecrypt communicates with CAM server using cs378x (camd35 over tcp) protocol or newcamd protocol. https://georgi.unixsol.org/programs/tsdecrypt/
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process.c 12KB

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  1. /*
  2. * Process packets
  3. * Copyright (C) 2011 Unix Solutions Ltd.
  4. *
  5. * This program is free software; you can redistribute it and/or modify
  6. * it under the terms of the GNU General Public License version 2
  7. * as published by the Free Software Foundation.
  8. *
  9. * This program is distributed in the hope that it will be useful,
  10. * but WITHOUT ANY WARRANTY; without even the implied warranty of
  11. * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
  12. * GNU General Public License for more details.
  13. *
  14. * You should have received a copy of the GNU General Public License
  15. * along with this program; if not, write to the Free Software
  16. * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston MA 02110-1301, USA.
  17. */
  18. #include <unistd.h>
  19. #include <string.h>
  20. #include <sys/uio.h>
  21. #include "data.h"
  22. #include "csa.h"
  23. #include "tables.h"
  24. #include "util.h"
  25. static unsigned long ts_pack;
  26. static int ts_pack_shown;
  27. char *get_pid_desc(struct ts *ts, uint16_t pid) {
  28. int i;
  29. uint16_t nitpid = 0x0010, pmtpid = 0xffff, pcrpid = 0xffff;
  30. if (ts->pat->initialized) {
  31. for (i=0;i<ts->pat->programs_num;i++) {
  32. struct ts_pat_program *prg = ts->pat->programs[i];
  33. if (prg->pid) {
  34. if (prg->program == 0)
  35. nitpid = prg->pid;
  36. }
  37. }
  38. }
  39. if (ts->pmt->initialized) {
  40. pmtpid = ts->pmt->ts_header.pid;
  41. pcrpid = ts->pmt->PCR_pid;
  42. for (i=0;i<ts->pmt->streams_num;i++) {
  43. struct ts_pmt_stream *stream = ts->pmt->streams[i];
  44. if (pid == stream->pid)
  45. return h222_stream_type_desc(stream->stream_type);
  46. }
  47. }
  48. switch (pid) {
  49. case 0x0000: return "PAT"; break;
  50. case 0x0001: return "CAT"; break;
  51. case 0x0011: return "SDT"; break;
  52. case 0x0012: return "EPG"; break;
  53. case 0x0014: return "TDT/TOT"; break;
  54. }
  55. if (pid == nitpid) return "NIT";
  56. else if (pid == pmtpid) return "PMT";
  57. else if (pid == pcrpid) return "PCR";
  58. else if (pid == ts->emm_pid) return "EMM";
  59. else if (pid == ts->ecm_pid) return "ECM";
  60. return "Unknown";
  61. }
  62. void show_ts_pack(struct ts *ts, uint16_t pid, char *wtf, char *extra, uint8_t *ts_packet) {
  63. char pdump[188 * 6];
  64. char cw1_dump[8 * 6];
  65. char cw2_dump[8 * 6];
  66. if (ts->debug_level >= 4) {
  67. if (ts_pack_shown)
  68. return;
  69. if (ts->debug_level >= 5)
  70. ts_hex_dump_buf(pdump, 188 * 6, ts_packet, 188, 0);
  71. int stype = ts_packet_get_scrambled(ts_packet);
  72. ts_hex_dump_buf(cw1_dump, 8 * 6, ts->key.cw , 8, 0);
  73. ts_hex_dump_buf(cw2_dump, 8 * 6, ts->key.cw + 8, 8, 0);
  74. fprintf(stderr, "@ %s %s %03x %5ld %7ld | %s %s | %s %s\n",
  75. stype == 0 ? "------" :
  76. stype == 2 ? "even 0" :
  77. stype == 3 ? "odd 1" : "??????",
  78. wtf,
  79. pid,
  80. ts_pack, ts_pack * 188,
  81. cw1_dump, cw2_dump, extra ? extra : wtf,
  82. ts->debug_level >= 5 ? pdump : "");
  83. }
  84. }
  85. static void dump_ts_pack(struct ts *ts, uint16_t pid, uint8_t *ts_packet) {
  86. if (pid == 0x010) show_ts_pack(ts, pid, "nit", NULL, ts_packet);
  87. else if (pid == 0x11) show_ts_pack(ts, pid, "sdt", NULL, ts_packet);
  88. else if (pid == 0x12) show_ts_pack(ts, pid, "epg", NULL, ts_packet);
  89. else show_ts_pack(ts, pid, "---", NULL, ts_packet);
  90. }
  91. static void decode_packet(struct ts *ts, uint8_t *ts_packet) {
  92. int scramble_idx = ts_packet_get_scrambled(ts_packet);
  93. if (scramble_idx > 1) {
  94. if (ts->key.is_valid_cw) {
  95. csa_decrypt_single_packet(ts->key.csakey, ts_packet);
  96. } else {
  97. // Can't decrypt the packet just make it NULL packet
  98. if (ts->pid_filter)
  99. ts_packet_set_pid(ts_packet, 0x1fff);
  100. }
  101. }
  102. }
  103. static void decode_buffer(struct ts *ts, uint8_t *data, int data_len) {
  104. int i;
  105. int batch_sz = csa_get_batch_size(); // Tested with 32 for libdvbcsa, 70 for FFdecsa (must be multiplied by 2)
  106. int even_packets = 0;
  107. int odd_packets = 0;
  108. struct csa_batch even_pcks[batch_sz + 1];
  109. struct csa_batch odd_pcks [batch_sz + 1];
  110. uint8_t *ff_even_pcks[batch_sz * 2 + 1];
  111. uint8_t *ff_odd_pcks [batch_sz * 2 + 1];
  112. int scramble_idx_old = 0;
  113. // Prepare batch structure
  114. for (i = 0; i < batch_sz; i++) {
  115. uint8_t *ts_packet = data + (i * 188);
  116. uint16_t pid = ts_packet_get_pid(ts_packet);
  117. if (pidmap_get(&ts->pidmap, pid) && ts_packet_is_scrambled(ts_packet)) {
  118. if (ts->key.is_valid_cw) {
  119. int scramble_idx = ts_packet_get_scrambled(ts_packet);
  120. if (!scramble_idx_old)
  121. scramble_idx_old = scramble_idx;
  122. if (use_dvbcsa) {
  123. uint8_t payload_ofs = ts_packet_get_payload_offset(ts_packet);
  124. if (scramble_idx == 2) { // scramble_idx 2 == even key
  125. even_pcks[even_packets].data = ts_packet + payload_ofs;
  126. even_pcks[even_packets].len = 188 - payload_ofs;
  127. even_packets++;
  128. }
  129. if (scramble_idx == 3) { // scramble_idx 3 == odd key
  130. odd_pcks[odd_packets].data = ts_packet + payload_ofs;
  131. odd_pcks[odd_packets].len = 188 - payload_ofs;
  132. odd_packets++;
  133. }
  134. ts_packet_set_not_scrambled(ts_packet);
  135. }
  136. if (use_ffdecsa) {
  137. if (scramble_idx == 2) { // scramble_idx 2 == even key
  138. ff_even_pcks[even_packets * 2 ] = ts_packet;
  139. ff_even_pcks[even_packets * 2 + 1] = ts_packet + 188;
  140. even_packets++;
  141. }
  142. if (scramble_idx == 3) { // scramble_idx 3 == odd key
  143. ff_odd_pcks[odd_packets * 2 ] = ts_packet;
  144. ff_odd_pcks[odd_packets * 2 + 1] = ts_packet + 188;
  145. odd_packets++;
  146. }
  147. }
  148. if (scramble_idx_old != scramble_idx && !ts->camd.constant_codeword) {
  149. struct timeval tv;
  150. gettimeofday(&tv, NULL);
  151. ts_LOGf("CWC | SID 0x%04x ------------ EcmTime: %5llu ms CW_time: %5llu ms\n",
  152. ts->service_id,
  153. timeval_diff_msec(&ts->ecm_change_time, &tv),
  154. timeval_diff_msec(&ts->key.ts_keyset, &tv));
  155. }
  156. scramble_idx_old = scramble_idx;
  157. } else {
  158. if (ts->pid_filter)
  159. ts_packet_set_pid(ts_packet, 0x1fff);
  160. }
  161. }
  162. }
  163. // Decode packets
  164. if (even_packets) {
  165. if (use_dvbcsa) {
  166. even_pcks[even_packets].data = NULL; // Last one...
  167. csa_decrypt_multiple_even(ts->key.csakey, even_pcks);
  168. }
  169. if (use_ffdecsa) {
  170. ff_even_pcks[even_packets * 2] = NULL;
  171. csa_decrypt_multiple_ff(ts->key.csakey, ff_even_pcks);
  172. }
  173. }
  174. if (odd_packets) {
  175. if (use_dvbcsa) {
  176. odd_pcks[odd_packets].data = NULL; // Last one...
  177. csa_decrypt_multiple_odd(ts->key.csakey, odd_pcks);
  178. }
  179. if (use_ffdecsa) {
  180. ff_odd_pcks[odd_packets * 2] = NULL;
  181. csa_decrypt_multiple_ff(ts->key.csakey, ff_odd_pcks);
  182. }
  183. }
  184. // Fill write buffer
  185. for (i=0; i<data_len; i += 188) {
  186. uint8_t *ts_packet = data + i;
  187. if (!ts->pid_filter) {
  188. cbuf_fill(ts->write_buf, ts_packet, 188);
  189. } else {
  190. uint16_t pid = ts_packet_get_pid(ts_packet);
  191. if (pidmap_get(&ts->pidmap, pid)) // PAT or allowed PIDs
  192. cbuf_fill(ts->write_buf, ts_packet, 188);
  193. }
  194. }
  195. }
  196. void *decode_thread(void *_ts) {
  197. struct ts *ts = _ts;
  198. uint8_t *data;
  199. int data_size;
  200. int req_size = 188 * csa_get_batch_size();
  201. set_thread_name("tsdec-decode");
  202. while (!ts->decode_stop) {
  203. data = cbuf_peek(ts->decode_buf, req_size, &data_size);
  204. if (data_size < req_size) {
  205. usleep(1000);
  206. continue;
  207. }
  208. data = cbuf_get(ts->decode_buf, req_size, &data_size);
  209. if (data)
  210. decode_buffer(ts, data, data_size);
  211. }
  212. do { // Flush data
  213. data = cbuf_get(ts->decode_buf, req_size, &data_size);
  214. if (data)
  215. decode_buffer(ts, data, data_size);
  216. } while(data);
  217. return NULL;
  218. }
  219. static inline void output_write(struct ts *ts, uint8_t *data, unsigned int data_size) {
  220. if (!data)
  221. return;
  222. if (!ts->rtp_output) {
  223. write(ts->output.fd, data, data_size);
  224. } else {
  225. struct iovec iov[2];
  226. uint8_t rtp_header[12];
  227. uint32_t rtime = get_time() * 9 / 100;
  228. ts->rtp_seqnum++;
  229. rtp_header[ 0] = 0x80;
  230. rtp_header[ 1] = 33; // MPEG TS rtp payload type
  231. rtp_header[ 2] = ts->rtp_seqnum >> 8;
  232. rtp_header[ 3] = ts->rtp_seqnum & 0xff;
  233. rtp_header[ 4] = (rtime >> 24) & 0xff;
  234. rtp_header[ 5] = (rtime >> 16) & 0xff;
  235. rtp_header[ 6] = (rtime >> 8) & 0xff;
  236. rtp_header[ 7] = rtime & 0xff;
  237. rtp_header[ 8] = (ts->rtp_ssrc >> 24) & 0xff;
  238. rtp_header[ 9] = (ts->rtp_ssrc >> 16) & 0xff;
  239. rtp_header[10] = (ts->rtp_ssrc >> 8) & 0xff;
  240. rtp_header[11] = ts->rtp_ssrc & 0xff;
  241. iov[0].iov_base = rtp_header;
  242. iov[0].iov_len = sizeof(rtp_header);
  243. iov[1].iov_base = data;
  244. iov[1].iov_len = data_size;
  245. writev(ts->output.fd, iov, 2);
  246. }
  247. }
  248. void *write_thread(void *_ts) {
  249. struct ts *ts = _ts;
  250. uint8_t *data;
  251. int data_size;
  252. set_thread_name("tsdec-write");
  253. while (!ts->write_stop) {
  254. data_size = 0;
  255. data = cbuf_peek(ts->write_buf, FRAME_SIZE, &data_size);
  256. if (data_size < FRAME_SIZE) {
  257. usleep(5000);
  258. continue;
  259. }
  260. data = cbuf_get (ts->write_buf, FRAME_SIZE, &data_size);
  261. output_write(ts, data, data_size);
  262. }
  263. do { // Flush data
  264. data = cbuf_get(ts->write_buf, FRAME_SIZE, &data_size);
  265. output_write(ts, data, data_size);
  266. } while(data);
  267. return NULL;
  268. }
  269. static void detect_discontinuity(struct ts *ts, uint8_t *ts_packet) {
  270. uint16_t pid;
  271. uint8_t cur_cc, last_cc;
  272. if (!ts->ts_discont)
  273. return;
  274. pid = ts_packet_get_pid(ts_packet);
  275. cur_cc = ts_packet_get_cont(ts_packet);
  276. if (!pidmap_get(&ts->pid_seen, pid)) {
  277. if (strcmp(get_pid_desc(ts, pid), "Unknown") == 0)
  278. return;
  279. pidmap_set(&ts->pid_seen, pid);
  280. pidmap_set_val(&ts->cc, pid, cur_cc);
  281. ts_LOGf("NEW | Input PID 0x%04x appeared (%s)\n",
  282. pid, get_pid_desc(ts, pid));
  283. return;
  284. }
  285. last_cc = pidmap_get(&ts->cc, pid);
  286. if (last_cc != cur_cc && ((last_cc + 1) & 0x0f) != cur_cc)
  287. ts_LOGf("--- | TS discontinuity on PID 0x%04x expected %2d got %2d /%d/ (%s)\n",
  288. pid,
  289. ((last_cc + 1) & 0x0f), cur_cc,
  290. (cur_cc - ((last_cc + 1) & 0x0f)) & 0x0f,
  291. get_pid_desc(ts, pid));
  292. pidmap_set_val(&ts->cc, pid, cur_cc);
  293. }
  294. void process_packets(struct ts *ts, uint8_t *data, ssize_t data_len) {
  295. ssize_t i;
  296. int64_t now = get_time();
  297. for (i=0; i<data_len; i += 188) {
  298. uint8_t *ts_packet = data + i;
  299. uint16_t pid = ts_packet_get_pid(ts_packet);
  300. if (ts->pid_report)
  301. ts->pid_stats[pid]++;
  302. ts_pack_shown = 0;
  303. process_pat(ts, pid, ts_packet);
  304. process_cat(ts, pid, ts_packet);
  305. process_pmt(ts, pid, ts_packet);
  306. process_sdt(ts, pid, ts_packet);
  307. process_emm(ts, pid, ts_packet);
  308. process_ecm(ts, pid, ts_packet);
  309. detect_discontinuity(ts, ts_packet);
  310. if (!ts_pack_shown)
  311. dump_ts_pack(ts, pid, ts_packet);
  312. if (ts->emm_only)
  313. continue;
  314. // Return rewritten PAT
  315. if (pid == 0x00 && ts->pid_filter && ts->genpat->initialized) {
  316. if (!ts_packet_is_pusi(ts_packet))
  317. continue;
  318. ts_packet_set_cont(ts->genpat->section_header->packet_data, ts->genpat_cc);
  319. ts->genpat->ts_header.continuity = ts->genpat_cc;
  320. ts_packet = ts->genpat->section_header->packet_data;
  321. ts->genpat_cc = (ts->genpat_cc + 1) & 0x0f;
  322. }
  323. if (ts->threaded) {
  324. // Add to decode buffer. The decoder thread will handle it
  325. if (ts->input_buffer_time == 0) {
  326. // No input buffer, move packets to decoding buffer
  327. if (cbuf_fill(ts->decode_buf, ts_packet, 188) != 0) {
  328. ts_LOGf("Decode buffer is full, waiting...\n");
  329. cbuf_dump(ts->decode_buf);
  330. usleep(10000);
  331. }
  332. } else {
  333. // Handle input buffer
  334. struct packet_buf *p = malloc(sizeof(struct packet_buf));
  335. p->time = now + (ts->input_buffer_time * 1000); //buffer time is in ms, p->time is in us
  336. memcpy(p->data, ts_packet, 188);
  337. list_add(ts->input_buffer, p);
  338. // Move packets to decrypt buffer
  339. LNODE *lc, *lctmp;
  340. list_for_each(ts->input_buffer, lc, lctmp) {
  341. p = lc->data;
  342. if (p->time <= now) {
  343. if (cbuf_fill(ts->decode_buf, p->data, 188) != 0) {
  344. ts_LOGf("Decode buffer is full, waiting...\n");
  345. cbuf_dump(ts->decode_buf);
  346. usleep(10000);
  347. }
  348. list_del(ts->input_buffer, &lc);
  349. free(p);
  350. } else {
  351. break;
  352. }
  353. }
  354. }
  355. } else {
  356. int allowed_pid = pidmap_get(&ts->pidmap, pid);
  357. if (allowed_pid) // PAT or allowed PIDs
  358. decode_packet(ts, ts_packet);
  359. if (ts->pid_filter) {
  360. if (allowed_pid) // PAT or allowed PIDs
  361. output_write(ts, ts_packet, 188);
  362. } else {
  363. output_write(ts, ts_packet, 188);
  364. }
  365. }
  366. ts_pack++;
  367. }
  368. }
  369. void show_pid_report(struct ts *ts) {
  370. int i;
  371. if (!ts->pid_report)
  372. return;
  373. for (i = 0; i < MAX_PIDS; i++) {
  374. if (ts->pid_stats[i]) {
  375. ts_LOGf("PID | %8u packets with PID 0x%04x (%4u) %s\n",
  376. ts->pid_stats[i], i, i, get_pid_desc(ts, i));
  377. }
  378. }
  379. }