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FFmpeg/libavformat/rtpdec.c

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  1. /*

  2.  * RTP input format

  3.  * Copyright (c) 2002 Fabrice Bellard

  4.  *

  5.  * This file is part of FFmpeg.

  6.  *

  7.  * FFmpeg is free software; you can redistribute it and/or

  8.  * modify it under the terms of the GNU Lesser General Public

  9.  * License as published by the Free Software Foundation; either

  10.  * version 2.1 of the License, or (at your option) any later version.

  11.  *

  12.  * FFmpeg is distributed in the hope that it will be useful,

  13.  * but WITHOUT ANY WARRANTY; without even the implied warranty of

  14.  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU

  15.  * Lesser General Public License for more details.

  16.  *

  17.  * You should have received a copy of the GNU Lesser General Public

  18.  * License along with FFmpeg; if not, write to the Free Software

  19.  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA

  20.  */

  21. 

  22. #include "libavutil/mathematics.h"

  23. #include "libavutil/avstring.h"

  24. #include "libavutil/time.h"

  25. #include "libavcodec/get_bits.h"

  26. #include "avformat.h"

  27. #include "network.h"

  28. #include "srtp.h"

  29. #include "url.h"

  30. #include "rtpdec.h"

  31. #include "rtpdec_formats.h"

  32. 

  33. #define MIN_FEEDBACK_INTERVAL 200000 /* 200 ms in us */

  34. 

  35. static RTPDynamicProtocolHandler gsm_dynamic_handler = {

  36.     .enc_name   = "GSM",

  37.     .codec_type = AVMEDIA_TYPE_AUDIO,

  38.     .codec_id   = AV_CODEC_ID_GSM,

  39. };

  40. 

  41. static RTPDynamicProtocolHandler realmedia_mp3_dynamic_handler = {

  42.     .enc_name   = "X-MP3-draft-00",

  43.     .codec_type = AVMEDIA_TYPE_AUDIO,

  44.     .codec_id   = AV_CODEC_ID_MP3ADU,

  45. };

  46. 

  47. static RTPDynamicProtocolHandler speex_dynamic_handler = {

  48.     .enc_name   = "speex",

  49.     .codec_type = AVMEDIA_TYPE_AUDIO,

  50.     .codec_id   = AV_CODEC_ID_SPEEX,

  51. };

  52. 

  53. static RTPDynamicProtocolHandler opus_dynamic_handler = {

  54.     .enc_name   = "opus",

  55.     .codec_type = AVMEDIA_TYPE_AUDIO,

  56.     .codec_id   = AV_CODEC_ID_OPUS,

  57. };

  58. 

  59. static RTPDynamicProtocolHandler *rtp_first_dynamic_payload_handler = NULL;

  60. 

  61. void ff_register_dynamic_payload_handler(RTPDynamicProtocolHandler *handler)

  62. {

  63.     handler->next = rtp_first_dynamic_payload_handler;

  64.     rtp_first_dynamic_payload_handler = handler;

  65. }

  66. 

  67. void ff_register_rtp_dynamic_payload_handlers(void)

  68. {

  69.     ff_register_dynamic_payload_handler(&ff_amr_nb_dynamic_handler);

  70.     ff_register_dynamic_payload_handler(&ff_amr_wb_dynamic_handler);

  71.     ff_register_dynamic_payload_handler(&ff_g726_16_dynamic_handler);

  72.     ff_register_dynamic_payload_handler(&ff_g726_24_dynamic_handler);

  73.     ff_register_dynamic_payload_handler(&ff_g726_32_dynamic_handler);

  74.     ff_register_dynamic_payload_handler(&ff_g726_40_dynamic_handler);

  75.     ff_register_dynamic_payload_handler(&ff_h261_dynamic_handler);

  76.     ff_register_dynamic_payload_handler(&ff_h263_1998_dynamic_handler);

  77.     ff_register_dynamic_payload_handler(&ff_h263_2000_dynamic_handler);

  78.     ff_register_dynamic_payload_handler(&ff_h263_rfc2190_dynamic_handler);

  79.     ff_register_dynamic_payload_handler(&ff_h264_dynamic_handler);

  80.     ff_register_dynamic_payload_handler(&ff_hevc_dynamic_handler);

  81.     ff_register_dynamic_payload_handler(&ff_ilbc_dynamic_handler);

  82.     ff_register_dynamic_payload_handler(&ff_jpeg_dynamic_handler);

  83.     ff_register_dynamic_payload_handler(&ff_mp4a_latm_dynamic_handler);

  84.     ff_register_dynamic_payload_handler(&ff_mp4v_es_dynamic_handler);

  85.     ff_register_dynamic_payload_handler(&ff_mpeg_audio_dynamic_handler);

  86.     ff_register_dynamic_payload_handler(&ff_mpeg_video_dynamic_handler);

  87.     ff_register_dynamic_payload_handler(&ff_mpeg4_generic_dynamic_handler);

  88.     ff_register_dynamic_payload_handler(&ff_mpegts_dynamic_handler);

  89.     ff_register_dynamic_payload_handler(&ff_ms_rtp_asf_pfa_handler);

  90.     ff_register_dynamic_payload_handler(&ff_ms_rtp_asf_pfv_handler);

  91.     ff_register_dynamic_payload_handler(&ff_qcelp_dynamic_handler);

  92.     ff_register_dynamic_payload_handler(&ff_qdm2_dynamic_handler);

  93.     ff_register_dynamic_payload_handler(&ff_qt_rtp_aud_handler);

  94.     ff_register_dynamic_payload_handler(&ff_qt_rtp_vid_handler);

  95.     ff_register_dynamic_payload_handler(&ff_quicktime_rtp_aud_handler);

  96.     ff_register_dynamic_payload_handler(&ff_quicktime_rtp_vid_handler);

  97.     ff_register_dynamic_payload_handler(&ff_svq3_dynamic_handler);

  98.     ff_register_dynamic_payload_handler(&ff_theora_dynamic_handler);

  99.     ff_register_dynamic_payload_handler(&ff_vorbis_dynamic_handler);

  100.     ff_register_dynamic_payload_handler(&ff_vp8_dynamic_handler);

  101.     ff_register_dynamic_payload_handler(&gsm_dynamic_handler);

  102.     ff_register_dynamic_payload_handler(&opus_dynamic_handler);

  103.     ff_register_dynamic_payload_handler(&realmedia_mp3_dynamic_handler);

  104.     ff_register_dynamic_payload_handler(&speex_dynamic_handler);

  105. }

  106. 

  107. RTPDynamicProtocolHandler *ff_rtp_handler_find_by_name(const char *name,

  108.                                                        enum AVMediaType codec_type)

  109. {

  110.     RTPDynamicProtocolHandler *handler;

  111.     for (handler = rtp_first_dynamic_payload_handler;

  112.          handler; handler = handler->next)

  113.         if (!av_strcasecmp(name, handler->enc_name) &&

  114.             codec_type == handler->codec_type)

  115.             return handler;

  116.     return NULL;

  117. }

  118. 

  119. RTPDynamicProtocolHandler *ff_rtp_handler_find_by_id(int id,

  120.                                                      enum AVMediaType codec_type)

  121. {

  122.     RTPDynamicProtocolHandler *handler;

  123.     for (handler = rtp_first_dynamic_payload_handler;

  124.          handler; handler = handler->next)

  125.         if (handler->static_payload_id && handler->static_payload_id == id &&

  126.             codec_type == handler->codec_type)

  127.             return handler;

  128.     return NULL;

  129. }

  130. 

  131. static int rtcp_parse_packet(RTPDemuxContext *s, const unsigned char *buf,

  132.                              int len)

  133. {

  134.     int payload_len;

  135.     while (len >= 4) {

  136.         payload_len = FFMIN(len, (AV_RB16(buf + 2) + 1) * 4);

  137. 

  138.         switch (buf[1]) {

  139.         case RTCP_SR:

  140.             if (payload_len < 20) {

  141.                 av_log(NULL, AV_LOG_ERROR,

  142.                        "Invalid length for RTCP SR packet\n");

  143.                 return AVERROR_INVALIDDATA;

  144.             }

  145. 

  146.             s->last_rtcp_reception_time = av_gettime();

  147.             s->last_rtcp_ntp_time  = AV_RB64(buf + 8);

  148.             s->last_rtcp_timestamp = AV_RB32(buf + 16);

  149.             if (s->first_rtcp_ntp_time == AV_NOPTS_VALUE) {

  150.                 s->first_rtcp_ntp_time = s->last_rtcp_ntp_time;

  151.                 if (!s->base_timestamp)

  152.                     s->base_timestamp = s->last_rtcp_timestamp;

  153.                 s->rtcp_ts_offset = s->last_rtcp_timestamp - s->base_timestamp;

  154.             }

  155. 

  156.             break;

  157.         case RTCP_BYE:

  158.             return -RTCP_BYE;

  159.         }

  160. 

  161.         buf += payload_len;

  162.         len -= payload_len;

  163.     }

  164.     return -1;

  165. }

  166. 

  167. #define RTP_SEQ_MOD (1 << 16)

  168. 

  169. static void rtp_init_statistics(RTPStatistics *s, uint16_t base_sequence)

  170. {

  171.     memset(s, 0, sizeof(RTPStatistics));

  172.     s->max_seq   = base_sequence;

  173.     s->probation = 1;

  174. }

  175. 

  176. /*

  177.  * Called whenever there is a large jump in sequence numbers,

  178.  * or when they get out of probation...

  179.  */

  180. static void rtp_init_sequence(RTPStatistics *s, uint16_t seq)

  181. {

  182.     s->max_seq        = seq;

  183.     s->cycles         = 0;

  184.     s->base_seq       = seq - 1;

  185.     s->bad_seq        = RTP_SEQ_MOD + 1;

  186.     s->received       = 0;

  187.     s->expected_prior = 0;

  188.     s->received_prior = 0;

  189.     s->jitter         = 0;

  190.     s->transit        = 0;

  191. }

  192. 

  193. /* Returns 1 if we should handle this packet. */

  194. static int rtp_valid_packet_in_sequence(RTPStatistics *s, uint16_t seq)

  195. {

  196.     uint16_t udelta = seq - s->max_seq;

  197.     const int MAX_DROPOUT    = 3000;

  198.     const int MAX_MISORDER   = 100;

  199.     const int MIN_SEQUENTIAL = 2;

  200. 

  201.     /* source not valid until MIN_SEQUENTIAL packets with sequence

  202.      * seq. numbers have been received */

  203.     if (s->probation) {

  204.         if (seq == s->max_seq + 1) {

  205.             s->probation--;

  206.             s->max_seq = seq;

  207.             if (s->probation == 0) {

  208.                 rtp_init_sequence(s, seq);

  209.                 s->received++;

  210.                 return 1;

  211.             }

  212.         } else {

  213.             s->probation = MIN_SEQUENTIAL - 1;

  214.             s->max_seq   = seq;

  215.         }

  216.     } else if (udelta < MAX_DROPOUT) {

  217.         // in order, with permissible gap

  218.         if (seq < s->max_seq) {

  219.             // sequence number wrapped; count another 64k cycles

  220.             s->cycles += RTP_SEQ_MOD;

  221.         }

  222.         s->max_seq = seq;

  223.     } else if (udelta <= RTP_SEQ_MOD - MAX_MISORDER) {

  224.         // sequence made a large jump...

  225.         if (seq == s->bad_seq) {

  226.             /* two sequential packets -- assume that the other side

  227.              * restarted without telling us; just resync. */

  228.             rtp_init_sequence(s, seq);

  229.         } else {

  230.             s->bad_seq = (seq + 1) & (RTP_SEQ_MOD - 1);

  231.             return 0;

  232.         }

  233.     } else {

  234.         // duplicate or reordered packet...

  235.     }

  236.     s->received++;

  237.     return 1;

  238. }

  239. 

  240. static void rtcp_update_jitter(RTPStatistics *s, uint32_t sent_timestamp,

  241.                                uint32_t arrival_timestamp)

  242. {

  243.     // Most of this is pretty straight from RFC 3550 appendix A.8

  244.     uint32_t transit = arrival_timestamp - sent_timestamp;

  245.     uint32_t prev_transit = s->transit;

  246.     int32_t d = transit - prev_transit;

  247.     // Doing the FFABS() call directly on the "transit - prev_transit"

  248.     // expression doesn't work, since it's an unsigned expression. Doing the

  249.     // transit calculation in unsigned is desired though, since it most

  250.     // probably will need to wrap around.

  251.     d = FFABS(d);

  252.     s->transit = transit;

  253.     if (!prev_transit)

  254.         return;

  255.     s->jitter += d - (int32_t) ((s->jitter + 8) >> 4);

  256. }

  257. 

  258. int ff_rtp_check_and_send_back_rr(RTPDemuxContext *s, URLContext *fd,

  259.                                   AVIOContext *avio, int count)

  260. {

  261.     AVIOContext *pb;

  262.     uint8_t *buf;

  263.     int len;

  264.     int rtcp_bytes;

  265.     RTPStatistics *stats = &s->statistics;

  266.     uint32_t lost;

  267.     uint32_t extended_max;

  268.     uint32_t expected_interval;

  269.     uint32_t received_interval;

  270.     int32_t  lost_interval;

  271.     uint32_t expected;

  272.     uint32_t fraction;

  273. 

  274.     if ((!fd && !avio) || (count < 1))

  275.         return -1;

  276. 

  277.     /* TODO: I think this is way too often; RFC 1889 has algorithm for this */

  278.     /* XXX: MPEG pts hardcoded. RTCP send every 0.5 seconds */

  279.     s->octet_count += count;

  280.     rtcp_bytes = ((s->octet_count - s->last_octet_count) * RTCP_TX_RATIO_NUM) /

  281.         RTCP_TX_RATIO_DEN;

  282.     rtcp_bytes /= 50; // mmu_man: that's enough for me... VLC sends much less btw !?

  283.     if (rtcp_bytes < 28)

  284.         return -1;

  285.     s->last_octet_count = s->octet_count;

  286. 

  287.     if (!fd)

  288.         pb = avio;

  289.     else if (avio_open_dyn_buf(&pb) < 0)

  290.         return -1;

  291. 

  292.     // Receiver Report

  293.     avio_w8(pb, (RTP_VERSION << 6) + 1); /* 1 report block */

  294.     avio_w8(pb, RTCP_RR);

  295.     avio_wb16(pb, 7); /* length in words - 1 */

  296.     // our own SSRC: we use the server's SSRC + 1 to avoid conflicts

  297.     avio_wb32(pb, s->ssrc + 1);

  298.     avio_wb32(pb, s->ssrc); // server SSRC

  299.     // some placeholders we should really fill...

  300.     // RFC 1889/p64

  301.     extended_max          = stats->cycles + stats->max_seq;

  302.     expected              = extended_max - stats->base_seq;

  303.     lost                  = expected - stats->received;

  304.     lost                  = FFMIN(lost, 0xffffff); // clamp it since it's only 24 bits...

  305.     expected_interval     = expected - stats->expected_prior;

  306.     stats->expected_prior = expected;

  307.     received_interval     = stats->received - stats->received_prior;

  308.     stats->received_prior = stats->received;

  309.     lost_interval         = expected_interval - received_interval;

  310.     if (expected_interval == 0 || lost_interval <= 0)

  311.         fraction = 0;

  312.     else

  313.         fraction = (lost_interval << 8) / expected_interval;

  314. 

  315.     fraction = (fraction << 24) | lost;

  316. 

  317.     avio_wb32(pb, fraction); /* 8 bits of fraction, 24 bits of total packets lost */

  318.     avio_wb32(pb, extended_max); /* max sequence received */

  319.     avio_wb32(pb, stats->jitter >> 4); /* jitter */

  320. 

  321.     if (s->last_rtcp_ntp_time == AV_NOPTS_VALUE) {

  322.         avio_wb32(pb, 0); /* last SR timestamp */

  323.         avio_wb32(pb, 0); /* delay since last SR */

  324.     } else {

  325.         uint32_t middle_32_bits   = s->last_rtcp_ntp_time >> 16; // this is valid, right? do we need to handle 64 bit values special?

  326.         uint32_t delay_since_last = av_rescale(av_gettime() - s->last_rtcp_reception_time,

  327.                                                65536, AV_TIME_BASE);

  328. 

  329.         avio_wb32(pb, middle_32_bits); /* last SR timestamp */

  330.         avio_wb32(pb, delay_since_last); /* delay since last SR */

  331.     }

  332. 

  333.     // CNAME

  334.     avio_w8(pb, (RTP_VERSION << 6) + 1); /* 1 report block */

  335.     avio_w8(pb, RTCP_SDES);

  336.     len = strlen(s->hostname);

  337.     avio_wb16(pb, (7 + len + 3) / 4); /* length in words - 1 */

  338.     avio_wb32(pb, s->ssrc + 1);

  339.     avio_w8(pb, 0x01);

  340.     avio_w8(pb, len);

  341.     avio_write(pb, s->hostname, len);

  342.     avio_w8(pb, 0); /* END */

  343.     // padding

  344.     for (len = (7 + len) % 4; len % 4; len++)

  345.         avio_w8(pb, 0);

  346. 

  347.     avio_flush(pb);

  348.     if (!fd)

  349.         return 0;

  350.     len = avio_close_dyn_buf(pb, &buf);

  351.     if ((len > 0) && buf) {

  352.         int av_unused result;

  353.         av_dlog(s->ic, "sending %d bytes of RR\n", len);

  354.         result = ffurl_write(fd, buf, len);

  355.         av_dlog(s->ic, "result from ffurl_write: %d\n", result);

  356.         av_free(buf);

  357.     }

  358.     return 0;

  359. }

  360. 

  361. void ff_rtp_send_punch_packets(URLContext *rtp_handle)

  362. {

  363.     AVIOContext *pb;

  364.     uint8_t *buf;

  365.     int len;

  366. 

  367.     /* Send a small RTP packet */

  368.     if (avio_open_dyn_buf(&pb) < 0)

  369.         return;

  370. 

  371.     avio_w8(pb, (RTP_VERSION << 6));

  372.     avio_w8(pb, 0); /* Payload type */

  373.     avio_wb16(pb, 0); /* Seq */

  374.     avio_wb32(pb, 0); /* Timestamp */

  375.     avio_wb32(pb, 0); /* SSRC */

  376. 

  377.     avio_flush(pb);

  378.     len = avio_close_dyn_buf(pb, &buf);

  379.     if ((len > 0) && buf)

  380.         ffurl_write(rtp_handle, buf, len);

  381.     av_free(buf);

  382. 

  383.     /* Send a minimal RTCP RR */

  384.     if (avio_open_dyn_buf(&pb) < 0)

  385.         return;

  386. 

  387.     avio_w8(pb, (RTP_VERSION << 6));

  388.     avio_w8(pb, RTCP_RR); /* receiver report */

  389.     avio_wb16(pb, 1); /* length in words - 1 */

  390.     avio_wb32(pb, 0); /* our own SSRC */

  391. 

  392.     avio_flush(pb);

  393.     len = avio_close_dyn_buf(pb, &buf);

  394.     if ((len > 0) && buf)

  395.         ffurl_write(rtp_handle, buf, len);

  396.     av_free(buf);

  397. }

  398. 

  399. static int find_missing_packets(RTPDemuxContext *s, uint16_t *first_missing,

  400.                                 uint16_t *missing_mask)

  401. {

  402.     int i;

  403.     uint16_t next_seq = s->seq + 1;

  404.     RTPPacket *pkt = s->queue;

  405. 

  406.     if (!pkt || pkt->seq == next_seq)

  407.         return 0;

  408. 

  409.     *missing_mask = 0;

  410.     for (i = 1; i <= 16; i++) {

  411.         uint16_t missing_seq = next_seq + i;

  412.         while (pkt) {

  413.             int16_t diff = pkt->seq - missing_seq;

  414.             if (diff >= 0)

  415.                 break;

  416.             pkt = pkt->next;

  417.         }

  418.         if (!pkt)

  419.             break;

  420.         if (pkt->seq == missing_seq)

  421.             continue;

  422.         *missing_mask |= 1 << (i - 1);

  423.     }

  424. 

  425.     *first_missing = next_seq;

  426.     return 1;

  427. }

  428. 

  429. int ff_rtp_send_rtcp_feedback(RTPDemuxContext *s, URLContext *fd,

  430.                               AVIOContext *avio)

  431. {

  432.     int len, need_keyframe, missing_packets;

  433.     AVIOContext *pb;

  434.     uint8_t *buf;

  435.     int64_t now;

  436.     uint16_t first_missing = 0, missing_mask = 0;

  437. 

  438.     if (!fd && !avio)

  439.         return -1;

  440. 

  441.     need_keyframe = s->handler && s->handler->need_keyframe &&

  442.                     s->handler->need_keyframe(s->dynamic_protocol_context);

  443.     missing_packets = find_missing_packets(s, &first_missing, &missing_mask);

  444. 

  445.     if (!need_keyframe && !missing_packets)

  446.         return 0;

  447. 

  448.     /* Send new feedback if enough time has elapsed since the last

  449.      * feedback packet. */

  450. 

  451.     now = av_gettime();

  452.     if (s->last_feedback_time &&

  453.         (now - s->last_feedback_time) < MIN_FEEDBACK_INTERVAL)

  454.         return 0;

  455.     s->last_feedback_time = now;

  456. 

  457.     if (!fd)

  458.         pb = avio;

  459.     else if (avio_open_dyn_buf(&pb) < 0)

  460.         return -1;

  461. 

  462.     if (need_keyframe) {

  463.         avio_w8(pb, (RTP_VERSION << 6) | 1); /* PLI */

  464.         avio_w8(pb, RTCP_PSFB);

  465.         avio_wb16(pb, 2); /* length in words - 1 */

  466.         // our own SSRC: we use the server's SSRC + 1 to avoid conflicts

  467.         avio_wb32(pb, s->ssrc + 1);

  468.         avio_wb32(pb, s->ssrc); // server SSRC

  469.     }

  470. 

  471.     if (missing_packets) {

  472.         avio_w8(pb, (RTP_VERSION << 6) | 1); /* NACK */

  473.         avio_w8(pb, RTCP_RTPFB);

  474.         avio_wb16(pb, 3); /* length in words - 1 */

  475.         avio_wb32(pb, s->ssrc + 1);

  476.         avio_wb32(pb, s->ssrc); // server SSRC

  477. 

  478.         avio_wb16(pb, first_missing);

  479.         avio_wb16(pb, missing_mask);

  480.     }

  481. 

  482.     avio_flush(pb);

  483.     if (!fd)

  484.         return 0;

  485.     len = avio_close_dyn_buf(pb, &buf);

  486.     if (len > 0 && buf) {

  487.         ffurl_write(fd, buf, len);

  488.         av_free(buf);

  489.     }

  490.     return 0;

  491. }

  492. 

  493. /**

  494.  * open a new RTP parse context for stream 'st'. 'st' can be NULL for

  495.  * MPEG2-TS streams.

  496.  */

  497. RTPDemuxContext *ff_rtp_parse_open(AVFormatContext *s1, AVStream *st,

  498.                                    int payload_type, int queue_size)

  499. {

  500.     RTPDemuxContext *s;

  501. 

  502.     s = av_mallocz(sizeof(RTPDemuxContext));

  503.     if (!s)

  504.         return NULL;

  505.     s->payload_type        = payload_type;

  506.     s->last_rtcp_ntp_time  = AV_NOPTS_VALUE;

  507.     s->first_rtcp_ntp_time = AV_NOPTS_VALUE;

  508.     s->ic                  = s1;

  509.     s->st                  = st;

  510.     s->queue_size          = queue_size;

  511.     rtp_init_statistics(&s->statistics, 0);

  512.     if (st) {

  513.         switch (st->codec->codec_id) {

  514.         case AV_CODEC_ID_ADPCM_G722:

  515.             /* According to RFC 3551, the stream clock rate is 8000

  516.              * even if the sample rate is 16000. */

  517.             if (st->codec->sample_rate == 8000)

  518.                 st->codec->sample_rate = 16000;

  519.             break;

  520.         default:

  521.             break;

  522.         }

  523.     }

  524.     // needed to send back RTCP RR in RTSP sessions

  525.     gethostname(s->hostname, sizeof(s->hostname));

  526.     return s;

  527. }

  528. 

  529. void ff_rtp_parse_set_dynamic_protocol(RTPDemuxContext *s, PayloadContext *ctx,

  530.                                        RTPDynamicProtocolHandler *handler)

  531. {

  532.     s->dynamic_protocol_context = ctx;

  533.     s->handler                  = handler;

  534. }

  535. 

  536. void ff_rtp_parse_set_crypto(RTPDemuxContext *s, const char *suite,

  537.                              const char *params)

  538. {

  539.     if (!ff_srtp_set_crypto(&s->srtp, suite, params))

  540.         s->srtp_enabled = 1;

  541. }

  542. 

  543. /**

  544.  * This was the second switch in rtp_parse packet.

  545.  * Normalizes time, if required, sets stream_index, etc.

  546.  */

  547. static void finalize_packet(RTPDemuxContext *s, AVPacket *pkt, uint32_t timestamp)

  548. {

  549.     if (pkt->pts != AV_NOPTS_VALUE || pkt->dts != AV_NOPTS_VALUE)

  550.         return; /* Timestamp already set by depacketizer */

  551.     if (timestamp == RTP_NOTS_VALUE)

  552.         return;

  553. 

  554.     if (s->last_rtcp_ntp_time != AV_NOPTS_VALUE && s->ic->nb_streams > 1) {

  555.         int64_t addend;

  556.         int delta_timestamp;

  557. 

  558.         /* compute pts from timestamp with received ntp_time */

  559.         delta_timestamp = timestamp - s->last_rtcp_timestamp;

  560.         /* convert to the PTS timebase */

  561.         addend = av_rescale(s->last_rtcp_ntp_time - s->first_rtcp_ntp_time,

  562.                             s->st->time_base.den,

  563.                             (uint64_t) s->st->time_base.num << 32);

  564.         pkt->pts = s->range_start_offset + s->rtcp_ts_offset + addend +

  565.                    delta_timestamp;

  566.         return;

  567.     }

  568. 

  569.     if (!s->base_timestamp)

  570.         s->base_timestamp = timestamp;

  571.     /* assume that the difference is INT32_MIN < x < INT32_MAX,

  572.      * but allow the first timestamp to exceed INT32_MAX */

  573.     if (!s->timestamp)

  574.         s->unwrapped_timestamp += timestamp;

  575.     else

  576.         s->unwrapped_timestamp += (int32_t)(timestamp - s->timestamp);

  577.     s->timestamp = timestamp;

  578.     pkt->pts     = s->unwrapped_timestamp + s->range_start_offset -

  579.                    s->base_timestamp;

  580. }

  581. 

  582. static int rtp_parse_packet_internal(RTPDemuxContext *s, AVPacket *pkt,

  583.                                      const uint8_t *buf, int len)

  584. {

  585.     unsigned int ssrc;

  586.     int payload_type, seq, flags = 0;

  587.     int ext, csrc;

  588.     AVStream *st;

  589.     uint32_t timestamp;

  590.     int rv = 0;

  591. 

  592.     csrc         = buf[0] & 0x0f;

  593.     ext          = buf[0] & 0x10;

  594.     payload_type = buf[1] & 0x7f;

  595.     if (buf[1] & 0x80)

  596.         flags |= RTP_FLAG_MARKER;

  597.     seq       = AV_RB16(buf + 2);

  598.     timestamp = AV_RB32(buf + 4);

  599.     ssrc      = AV_RB32(buf + 8);

  600.     /* store the ssrc in the RTPDemuxContext */

  601.     s->ssrc = ssrc;

  602. 

  603.     /* NOTE: we can handle only one payload type */

  604.     if (s->payload_type != payload_type)

  605.         return -1;

  606. 

  607.     st = s->st;

  608.     // only do something with this if all the rtp checks pass...

  609.     if (!rtp_valid_packet_in_sequence(&s->statistics, seq)) {

  610.         av_log(st ? st->codec : NULL, AV_LOG_ERROR,

  611.                "RTP: PT=%02x: bad cseq %04x expected=%04x\n",

  612.                payload_type, seq, ((s->seq + 1) & 0xffff));

  613.         return -1;

  614.     }

  615. 

  616.     if (buf[0] & 0x20) {

  617.         int padding = buf[len - 1];

  618.         if (len >= 12 + padding)

  619.             len -= padding;

  620.     }

  621. 

  622.     s->seq = seq;

  623.     len   -= 12;

  624.     buf   += 12;

  625. 

  626.     len   -= 4 * csrc;

  627.     buf   += 4 * csrc;

  628.     if (len < 0)

  629.         return AVERROR_INVALIDDATA;

  630. 

  631.     /* RFC 3550 Section 5.3.1 RTP Header Extension handling */

  632.     if (ext) {

  633.         if (len < 4)

  634.             return -1;

  635.         /* calculate the header extension length (stored as number

  636.          * of 32-bit words) */

  637.         ext = (AV_RB16(buf + 2) + 1) << 2;

  638. 

  639.         if (len < ext)

  640.             return -1;

  641.         // skip past RTP header extension

  642.         len -= ext;

  643.         buf += ext;

  644.     }

  645. 

  646.     if (s->handler && s->handler->parse_packet) {

  647.         rv = s->handler->parse_packet(s->ic, s->dynamic_protocol_context,

  648.                                       s->st, pkt, &timestamp, buf, len, seq,

  649.                                       flags);

  650.     } else if (st) {

  651.         if ((rv = av_new_packet(pkt, len)) < 0)

  652.             return rv;

  653.         memcpy(pkt->data, buf, len);

  654.         pkt->stream_index = st->index;

  655.     } else {

  656.         return AVERROR(EINVAL);

  657.     }

  658. 

  659.     // now perform timestamp things....

  660.     finalize_packet(s, pkt, timestamp);

  661. 

  662.     return rv;

  663. }

  664. 

  665. void ff_rtp_reset_packet_queue(RTPDemuxContext *s)

  666. {

  667.     while (s->queue) {

  668.         RTPPacket *next = s->queue->next;

  669.         av_free(s->queue->buf);

  670.         av_free(s->queue);

  671.         s->queue = next;

  672.     }

  673.     s->seq       = 0;

  674.     s->queue_len = 0;

  675.     s->prev_ret  = 0;

  676. }

  677. 

  678. static void enqueue_packet(RTPDemuxContext *s, uint8_t *buf, int len)

  679. {

  680.     uint16_t seq   = AV_RB16(buf + 2);

  681.     RTPPacket **cur = &s->queue, *packet;

  682. 

  683.     /* Find the correct place in the queue to insert the packet */

  684.     while (*cur) {

  685.         int16_t diff = seq - (*cur)->seq;

  686.         if (diff < 0)

  687.             break;

  688.         cur = &(*cur)->next;

  689.     }

  690. 

  691.     packet = av_mallocz(sizeof(*packet));

  692.     if (!packet)

  693.         return;

  694.     packet->recvtime = av_gettime();

  695.     packet->seq      = seq;

  696.     packet->len      = len;

  697.     packet->buf      = buf;

  698.     packet->next     = *cur;

  699.     *cur = packet;

  700.     s->queue_len++;

  701. }

  702. 

  703. static int has_next_packet(RTPDemuxContext *s)

  704. {

  705.     return s->queue && s->queue->seq == (uint16_t) (s->seq + 1);

  706. }

  707. 

  708. int64_t ff_rtp_queued_packet_time(RTPDemuxContext *s)

  709. {

  710.     return s->queue ? s->queue->recvtime : 0;

  711. }

  712. 

  713. static int rtp_parse_queued_packet(RTPDemuxContext *s, AVPacket *pkt)

  714. {

  715.     int rv;

  716.     RTPPacket *next;

  717. 

  718.     if (s->queue_len <= 0)

  719.         return -1;

  720. 

  721.     if (!has_next_packet(s))

  722.         av_log(s->st ? s->st->codec : NULL, AV_LOG_WARNING,

  723.                "RTP: missed %d packets\n", s->queue->seq - s->seq - 1);

  724. 

  725.     /* Parse the first packet in the queue, and dequeue it */

  726.     rv   = rtp_parse_packet_internal(s, pkt, s->queue->buf, s->queue->len);

  727.     next = s->queue->next;

  728.     av_free(s->queue->buf);

  729.     av_free(s->queue);

  730.     s->queue = next;

  731.     s->queue_len--;

  732.     return rv;

  733. }

  734. 

  735. static int rtp_parse_one_packet(RTPDemuxContext *s, AVPacket *pkt,

  736.                                 uint8_t **bufptr, int len)

  737. {

  738.     uint8_t *buf = bufptr ? *bufptr : NULL;

  739.     int flags = 0;

  740.     uint32_t timestamp;

  741.     int rv = 0;

  742. 

  743.     if (!buf) {

  744.         /* If parsing of the previous packet actually returned 0 or an error,

  745.          * there's nothing more to be parsed from that packet, but we may have

  746.          * indicated that we can return the next enqueued packet. */

  747.         if (s->prev_ret <= 0)

  748.             return rtp_parse_queued_packet(s, pkt);

  749.         /* return the next packets, if any */

  750.         if (s->handler && s->handler->parse_packet) {

  751.             /* timestamp should be overwritten by parse_packet, if not,

  752.              * the packet is left with pts == AV_NOPTS_VALUE */

  753.             timestamp = RTP_NOTS_VALUE;

  754.             rv        = s->handler->parse_packet(s->ic, s->dynamic_protocol_context,

  755.                                                  s->st, pkt, &timestamp, NULL, 0, 0,

  756.                                                  flags);

  757.             finalize_packet(s, pkt, timestamp);

  758.             return rv;

  759.         }

  760.     }

  761. 

  762.     if (len < 12)

  763.         return -1;

  764. 

  765.     if ((buf[0] & 0xc0) != (RTP_VERSION << 6))

  766.         return -1;

  767.     if (RTP_PT_IS_RTCP(buf[1])) {

  768.         return rtcp_parse_packet(s, buf, len);

  769.     }

  770. 

  771.     if (s->st) {

  772.         int64_t received = av_gettime();

  773.         uint32_t arrival_ts = av_rescale_q(received, AV_TIME_BASE_Q,

  774.                                            s->st->time_base);

  775.         timestamp = AV_RB32(buf + 4);

  776.         // Calculate the jitter immediately, before queueing the packet

  777.         // into the reordering queue.

  778.         rtcp_update_jitter(&s->statistics, timestamp, arrival_ts);

  779.     }

  780. 

  781.     if ((s->seq == 0 && !s->queue) || s->queue_size <= 1) {

  782.         /* First packet, or no reordering */

  783.         return rtp_parse_packet_internal(s, pkt, buf, len);

  784.     } else {

  785.         uint16_t seq = AV_RB16(buf + 2);

  786.         int16_t diff = seq - s->seq;

  787.         if (diff < 0) {

  788.             /* Packet older than the previously emitted one, drop */

  789.             av_log(s->st ? s->st->codec : NULL, AV_LOG_WARNING,

  790.                    "RTP: dropping old packet received too late\n");

  791.             return -1;

  792.         } else if (diff <= 1) {

  793.             /* Correct packet */

  794.             rv = rtp_parse_packet_internal(s, pkt, buf, len);

  795.             return rv;

  796.         } else {

  797.             /* Still missing some packet, enqueue this one. */

  798.             enqueue_packet(s, buf, len);

  799.             *bufptr = NULL;

  800.             /* Return the first enqueued packet if the queue is full,

  801.              * even if we're missing something */

  802.             if (s->queue_len >= s->queue_size)

  803.                 return rtp_parse_queued_packet(s, pkt);

  804.             return -1;

  805.         }

  806.     }

  807. }

  808. 

  809. /**

  810.  * Parse an RTP or RTCP packet directly sent as a buffer.

  811.  * @param s RTP parse context.

  812.  * @param pkt returned packet

  813.  * @param bufptr pointer to the input buffer or NULL to read the next packets

  814.  * @param len buffer len

  815.  * @return 0 if a packet is returned, 1 if a packet is returned and more can follow

  816.  * (use buf as NULL to read the next). -1 if no packet (error or no more packet).

  817.  */

  818. int ff_rtp_parse_packet(RTPDemuxContext *s, AVPacket *pkt,

  819.                         uint8_t **bufptr, int len)

  820. {

  821.     int rv;

  822.     if (s->srtp_enabled && bufptr && ff_srtp_decrypt(&s->srtp, *bufptr, &len) < 0)

  823.         return -1;

  824.     rv = rtp_parse_one_packet(s, pkt, bufptr, len);

  825.     s->prev_ret = rv;

  826.     while (rv == AVERROR(EAGAIN) && has_next_packet(s))

  827.         rv = rtp_parse_queued_packet(s, pkt);

  828.     return rv ? rv : has_next_packet(s);

  829. }

  830. 

  831. void ff_rtp_parse_close(RTPDemuxContext *s)

  832. {

  833.     ff_rtp_reset_packet_queue(s);

  834.     ff_srtp_free(&s->srtp);

  835.     av_free(s);

  836. }

  837. 

  838. int ff_parse_fmtp(AVFormatContext *s,

  839.                   AVStream *stream, PayloadContext *data, const char *p,

  840.                   int (*parse_fmtp)(AVFormatContext *s,

  841.                                     AVStream *stream,

  842.                                     PayloadContext *data,

  843.                                     char *attr, char *value))

  844. {

  845.     char attr[256];

  846.     char *value;

  847.     int res;

  848.     int value_size = strlen(p) + 1;

  849. 

  850.     if (!(value = av_malloc(value_size))) {

  851.         av_log(NULL, AV_LOG_ERROR, "Failed to allocate data for FMTP.\n");

  852.         return AVERROR(ENOMEM);

  853.     }

  854. 

  855.     // remove protocol identifier

  856.     while (*p && *p == ' ')

  857.         p++;                     // strip spaces

  858.     while (*p && *p != ' ')

  859.         p++;                     // eat protocol identifier

  860.     while (*p && *p == ' ')

  861.         p++;                     // strip trailing spaces

  862. 

  863.     while (ff_rtsp_next_attr_and_value(&p,

  864.                                        attr, sizeof(attr),

  865.                                        value, value_size)) {

  866.         res = parse_fmtp(s, stream, data, attr, value);

  867.         if (res < 0 && res != AVERROR_PATCHWELCOME) {

  868.             av_free(value);

  869.             return res;

  870.         }

  871.     }

  872.     av_free(value);

  873.     return 0;

  874. }

  875. 

  876. int ff_rtp_finalize_packet(AVPacket *pkt, AVIOContext **dyn_buf, int stream_idx)

  877. {

  878.     int ret;

  879.     av_init_packet(pkt);

  880. 

  881.     pkt->size         = avio_close_dyn_buf(*dyn_buf, &pkt->data);

  882.     pkt->stream_index = stream_idx;

  883.     *dyn_buf = NULL;

  884.     if ((ret = av_packet_from_data(pkt, pkt->data, pkt->size)) < 0) {

  885.         av_freep(&pkt->data);

  886.         return ret;

  887.     }

  888.     return pkt->size;

  889. }