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FFmpeg/libavformat/rtmpproto.c

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  1. /*

  2.  * RTMP network protocol

  3.  * Copyright (c) 2009 Kostya Shishkov

  4.  *

  5.  * This file is part of Libav.

  6.  *

  7.  * Libav 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.  * Libav 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 Libav; if not, write to the Free Software

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

  20.  */

  21. 

  22. /**

  23.  * @file

  24.  * RTMP protocol

  25.  */

  26. 

  27. #include "libavcodec/bytestream.h"

  28. #include "libavutil/avstring.h"

  29. #include "libavutil/intfloat.h"

  30. #include "libavutil/lfg.h"

  31. #include "libavutil/opt.h"

  32. #include "libavutil/sha.h"

  33. #include "avformat.h"

  34. #include "internal.h"

  35. 

  36. #include "network.h"

  37. 

  38. #include "flv.h"

  39. #include "rtmp.h"

  40. #include "rtmpcrypt.h"

  41. #include "rtmppkt.h"

  42. #include "url.h"

  43. 

  44. //#define DEBUG

  45. 

  46. #define APP_MAX_LENGTH 128

  47. #define PLAYPATH_MAX_LENGTH 256

  48. #define TCURL_MAX_LENGTH 512

  49. #define FLASHVER_MAX_LENGTH 64

  50. 

  51. /** RTMP protocol handler state */

  52. typedef enum {

  53.     STATE_START,      ///< client has not done anything yet

  54.     STATE_HANDSHAKED, ///< client has performed handshake

  55.     STATE_RELEASING,  ///< client releasing stream before publish it (for output)

  56.     STATE_FCPUBLISH,  ///< client FCPublishing stream (for output)

  57.     STATE_CONNECTING, ///< client connected to server successfully

  58.     STATE_READY,      ///< client has sent all needed commands and waits for server reply

  59.     STATE_PLAYING,    ///< client has started receiving multimedia data from server

  60.     STATE_PUBLISHING, ///< client has started sending multimedia data to server (for output)

  61.     STATE_STOPPED,    ///< the broadcast has been stopped

  62. } ClientState;

  63. 

  64. /** protocol handler context */

  65. typedef struct RTMPContext {

  66.     const AVClass *class;

  67.     URLContext*   stream;                     ///< TCP stream used in interactions with RTMP server

  68.     RTMPPacket    prev_pkt[2][RTMP_CHANNELS]; ///< packet history used when reading and sending packets

  69.     int           chunk_size;                 ///< size of the chunks RTMP packets are divided into

  70.     int           is_input;                   ///< input/output flag

  71.     char          *playpath;                  ///< stream identifier to play (with possible "mp4:" prefix)

  72.     int           live;                       ///< 0: recorded, -1: live, -2: both

  73.     char          *app;                       ///< name of application

  74.     char          *conn;                      ///< append arbitrary AMF data to the Connect message

  75.     ClientState   state;                      ///< current state

  76.     int           main_channel_id;            ///< an additional channel ID which is used for some invocations

  77.     uint8_t*      flv_data;                   ///< buffer with data for demuxer

  78.     int           flv_size;                   ///< current buffer size

  79.     int           flv_off;                    ///< number of bytes read from current buffer

  80.     int           flv_nb_packets;             ///< number of flv packets published

  81.     RTMPPacket    out_pkt;                    ///< rtmp packet, created from flv a/v or metadata (for output)

  82.     uint32_t      client_report_size;         ///< number of bytes after which client should report to server

  83.     uint32_t      bytes_read;                 ///< number of bytes read from server

  84.     uint32_t      last_bytes_read;            ///< number of bytes read last reported to server

  85.     int           skip_bytes;                 ///< number of bytes to skip from the input FLV stream in the next write call

  86.     uint8_t       flv_header[11];             ///< partial incoming flv packet header

  87.     int           flv_header_bytes;           ///< number of initialized bytes in flv_header

  88.     int           nb_invokes;                 ///< keeps track of invoke messages

  89.     int           create_stream_invoke;       ///< invoke id for the create stream command

  90.     char*         tcurl;                      ///< url of the target stream

  91.     char*         flashver;                   ///< version of the flash plugin

  92.     char*         swfurl;                     ///< url of the swf player

  93.     char*         pageurl;                    ///< url of the web page

  94.     int           server_bw;                  ///< server bandwidth

  95.     int           client_buffer_time;         ///< client buffer time in ms

  96.     int           flush_interval;             ///< number of packets flushed in the same request (RTMPT only)

  97.     int           encrypted;                  ///< use an encrypted connection (RTMPE only)

  98. } RTMPContext;

  99. 

  100. #define PLAYER_KEY_OPEN_PART_LEN 30   ///< length of partial key used for first client digest signing

  101. /** Client key used for digest signing */

  102. static const uint8_t rtmp_player_key[] = {

  103.     'G', 'e', 'n', 'u', 'i', 'n', 'e', ' ', 'A', 'd', 'o', 'b', 'e', ' ',

  104.     'F', 'l', 'a', 's', 'h', ' ', 'P', 'l', 'a', 'y', 'e', 'r', ' ', '0', '0', '1',

  105. 

  106.     0xF0, 0xEE, 0xC2, 0x4A, 0x80, 0x68, 0xBE, 0xE8, 0x2E, 0x00, 0xD0, 0xD1, 0x02,

  107.     0x9E, 0x7E, 0x57, 0x6E, 0xEC, 0x5D, 0x2D, 0x29, 0x80, 0x6F, 0xAB, 0x93, 0xB8,

  108.     0xE6, 0x36, 0xCF, 0xEB, 0x31, 0xAE

  109. };

  110. 

  111. #define SERVER_KEY_OPEN_PART_LEN 36   ///< length of partial key used for first server digest signing

  112. /** Key used for RTMP server digest signing */

  113. static const uint8_t rtmp_server_key[] = {

  114.     'G', 'e', 'n', 'u', 'i', 'n', 'e', ' ', 'A', 'd', 'o', 'b', 'e', ' ',

  115.     'F', 'l', 'a', 's', 'h', ' ', 'M', 'e', 'd', 'i', 'a', ' ',

  116.     'S', 'e', 'r', 'v', 'e', 'r', ' ', '0', '0', '1',

  117. 

  118.     0xF0, 0xEE, 0xC2, 0x4A, 0x80, 0x68, 0xBE, 0xE8, 0x2E, 0x00, 0xD0, 0xD1, 0x02,

  119.     0x9E, 0x7E, 0x57, 0x6E, 0xEC, 0x5D, 0x2D, 0x29, 0x80, 0x6F, 0xAB, 0x93, 0xB8,

  120.     0xE6, 0x36, 0xCF, 0xEB, 0x31, 0xAE

  121. };

  122. 

  123. static int rtmp_write_amf_data(URLContext *s, char *param, uint8_t **p)

  124. {

  125.     char *field, *value;

  126.     char type;

  127. 

  128.     /* The type must be B for Boolean, N for number, S for string, O for

  129.      * object, or Z for null. For Booleans the data must be either 0 or 1 for

  130.      * FALSE or TRUE, respectively. Likewise for Objects the data must be

  131.      * 0 or 1 to end or begin an object, respectively. Data items in subobjects

  132.      * may be named, by prefixing the type with 'N' and specifying the name

  133.      * before the value (ie. NB:myFlag:1). This option may be used multiple times

  134.      * to construct arbitrary AMF sequences. */

  135.     if (param[0] && param[1] == ':') {

  136.         type = param[0];

  137.         value = param + 2;

  138.     } else if (param[0] == 'N' && param[1] && param[2] == ':') {

  139.         type = param[1];

  140.         field = param + 3;

  141.         value = strchr(field, ':');

  142.         if (!value)

  143.             goto fail;

  144.         *value = '\0';

  145.         value++;

  146. 

  147.         if (!field || !value)

  148.             goto fail;

  149. 

  150.         ff_amf_write_field_name(p, field);

  151.     } else {

  152.         goto fail;

  153.     }

  154. 

  155.     switch (type) {

  156.     case 'B':

  157.         ff_amf_write_bool(p, value[0] != '0');

  158.         break;

  159.     case 'S':

  160.         ff_amf_write_string(p, value);

  161.         break;

  162.     case 'N':

  163.         ff_amf_write_number(p, strtod(value, NULL));

  164.         break;

  165.     case 'Z':

  166.         ff_amf_write_null(p);

  167.         break;

  168.     case 'O':

  169.         if (value[0] != '0')

  170.             ff_amf_write_object_start(p);

  171.         else

  172.             ff_amf_write_object_end(p);

  173.         break;

  174.     default:

  175.         goto fail;

  176.         break;

  177.     }

  178. 

  179.     return 0;

  180. 

  181. fail:

  182.     av_log(s, AV_LOG_ERROR, "Invalid AMF parameter: %s\n", param);

  183.     return AVERROR(EINVAL);

  184. }

  185. 

  186. /**

  187.  * Generate 'connect' call and send it to the server.

  188.  */

  189. static int gen_connect(URLContext *s, RTMPContext *rt)

  190. {

  191.     RTMPPacket pkt;

  192.     uint8_t *p;

  193.     int ret;

  194. 

  195.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SYSTEM_CHANNEL, RTMP_PT_INVOKE,

  196.                                      0, 4096)) < 0)

  197.         return ret;

  198. 

  199.     p = pkt.data;

  200. 

  201.     ff_amf_write_string(&p, "connect");

  202.     ff_amf_write_number(&p, ++rt->nb_invokes);

  203.     ff_amf_write_object_start(&p);

  204.     ff_amf_write_field_name(&p, "app");

  205.     ff_amf_write_string(&p, rt->app);

  206. 

  207.     if (!rt->is_input) {

  208.         ff_amf_write_field_name(&p, "type");

  209.         ff_amf_write_string(&p, "nonprivate");

  210.     }

  211.     ff_amf_write_field_name(&p, "flashVer");

  212.     ff_amf_write_string(&p, rt->flashver);

  213. 

  214.     if (rt->swfurl) {

  215.         ff_amf_write_field_name(&p, "swfUrl");

  216.         ff_amf_write_string(&p, rt->swfurl);

  217.     }

  218. 

  219.     ff_amf_write_field_name(&p, "tcUrl");

  220.     ff_amf_write_string(&p, rt->tcurl);

  221.     if (rt->is_input) {

  222.         ff_amf_write_field_name(&p, "fpad");

  223.         ff_amf_write_bool(&p, 0);

  224.         ff_amf_write_field_name(&p, "capabilities");

  225.         ff_amf_write_number(&p, 15.0);

  226. 

  227.         /* Tell the server we support all the audio codecs except

  228.          * SUPPORT_SND_INTEL (0x0008) and SUPPORT_SND_UNUSED (0x0010)

  229.          * which are unused in the RTMP protocol implementation. */

  230.         ff_amf_write_field_name(&p, "audioCodecs");

  231.         ff_amf_write_number(&p, 4071.0);

  232.         ff_amf_write_field_name(&p, "videoCodecs");

  233.         ff_amf_write_number(&p, 252.0);

  234.         ff_amf_write_field_name(&p, "videoFunction");

  235.         ff_amf_write_number(&p, 1.0);

  236. 

  237.         if (rt->pageurl) {

  238.             ff_amf_write_field_name(&p, "pageUrl");

  239.             ff_amf_write_string(&p, rt->pageurl);

  240.         }

  241.     }

  242.     ff_amf_write_object_end(&p);

  243. 

  244.     if (rt->conn) {

  245.         char *param = rt->conn;

  246. 

  247.         // Write arbitrary AMF data to the Connect message.

  248.         while (param != NULL) {

  249.             char *sep;

  250.             param += strspn(param, " ");

  251.             if (!*param)

  252.                 break;

  253.             sep = strchr(param, ' ');

  254.             if (sep)

  255.                 *sep = '\0';

  256.             if ((ret = rtmp_write_amf_data(s, param, &p)) < 0) {

  257.                 // Invalid AMF parameter.

  258.                 ff_rtmp_packet_destroy(&pkt);

  259.                 return ret;

  260.             }

  261. 

  262.             if (sep)

  263.                 param = sep + 1;

  264.             else

  265.                 break;

  266.         }

  267.     }

  268. 

  269.     pkt.data_size = p - pkt.data;

  270. 

  271.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  272.                                rt->prev_pkt[1]);

  273.     ff_rtmp_packet_destroy(&pkt);

  274. 

  275.     return ret;

  276. }

  277. 

  278. /**

  279.  * Generate 'releaseStream' call and send it to the server. It should make

  280.  * the server release some channel for media streams.

  281.  */

  282. static int gen_release_stream(URLContext *s, RTMPContext *rt)

  283. {

  284.     RTMPPacket pkt;

  285.     uint8_t *p;

  286.     int ret;

  287. 

  288.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SYSTEM_CHANNEL, RTMP_PT_INVOKE,

  289.                                      0, 29 + strlen(rt->playpath))) < 0)

  290.         return ret;

  291. 

  292.     av_log(s, AV_LOG_DEBUG, "Releasing stream...\n");

  293.     p = pkt.data;

  294.     ff_amf_write_string(&p, "releaseStream");

  295.     ff_amf_write_number(&p, ++rt->nb_invokes);

  296.     ff_amf_write_null(&p);

  297.     ff_amf_write_string(&p, rt->playpath);

  298. 

  299.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  300.                                rt->prev_pkt[1]);

  301.     ff_rtmp_packet_destroy(&pkt);

  302. 

  303.     return ret;

  304. }

  305. 

  306. /**

  307.  * Generate 'FCPublish' call and send it to the server. It should make

  308.  * the server preapare for receiving media streams.

  309.  */

  310. static int gen_fcpublish_stream(URLContext *s, RTMPContext *rt)

  311. {

  312.     RTMPPacket pkt;

  313.     uint8_t *p;

  314.     int ret;

  315. 

  316.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SYSTEM_CHANNEL, RTMP_PT_INVOKE,

  317.                                      0, 25 + strlen(rt->playpath))) < 0)

  318.         return ret;

  319. 

  320.     av_log(s, AV_LOG_DEBUG, "FCPublish stream...\n");

  321.     p = pkt.data;

  322.     ff_amf_write_string(&p, "FCPublish");

  323.     ff_amf_write_number(&p, ++rt->nb_invokes);

  324.     ff_amf_write_null(&p);

  325.     ff_amf_write_string(&p, rt->playpath);

  326. 

  327.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  328.                                rt->prev_pkt[1]);

  329.     ff_rtmp_packet_destroy(&pkt);

  330. 

  331.     return ret;

  332. }

  333. 

  334. /**

  335.  * Generate 'FCUnpublish' call and send it to the server. It should make

  336.  * the server destroy stream.

  337.  */

  338. static int gen_fcunpublish_stream(URLContext *s, RTMPContext *rt)

  339. {

  340.     RTMPPacket pkt;

  341.     uint8_t *p;

  342.     int ret;

  343. 

  344.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SYSTEM_CHANNEL, RTMP_PT_INVOKE,

  345.                                      0, 27 + strlen(rt->playpath))) < 0)

  346.         return ret;

  347. 

  348.     av_log(s, AV_LOG_DEBUG, "UnPublishing stream...\n");

  349.     p = pkt.data;

  350.     ff_amf_write_string(&p, "FCUnpublish");

  351.     ff_amf_write_number(&p, ++rt->nb_invokes);

  352.     ff_amf_write_null(&p);

  353.     ff_amf_write_string(&p, rt->playpath);

  354. 

  355.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  356.                                rt->prev_pkt[1]);

  357.     ff_rtmp_packet_destroy(&pkt);

  358. 

  359.     return ret;

  360. }

  361. 

  362. /**

  363.  * Generate 'createStream' call and send it to the server. It should make

  364.  * the server allocate some channel for media streams.

  365.  */

  366. static int gen_create_stream(URLContext *s, RTMPContext *rt)

  367. {

  368.     RTMPPacket pkt;

  369.     uint8_t *p;

  370.     int ret;

  371. 

  372.     av_log(s, AV_LOG_DEBUG, "Creating stream...\n");

  373. 

  374.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SYSTEM_CHANNEL, RTMP_PT_INVOKE,

  375.                                      0, 25)) < 0)

  376.         return ret;

  377. 

  378.     p = pkt.data;

  379.     ff_amf_write_string(&p, "createStream");

  380.     ff_amf_write_number(&p, ++rt->nb_invokes);

  381.     ff_amf_write_null(&p);

  382.     rt->create_stream_invoke = rt->nb_invokes;

  383. 

  384.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  385.                                rt->prev_pkt[1]);

  386.     ff_rtmp_packet_destroy(&pkt);

  387. 

  388.     return ret;

  389. }

  390. 

  391. 

  392. /**

  393.  * Generate 'deleteStream' call and send it to the server. It should make

  394.  * the server remove some channel for media streams.

  395.  */

  396. static int gen_delete_stream(URLContext *s, RTMPContext *rt)

  397. {

  398.     RTMPPacket pkt;

  399.     uint8_t *p;

  400.     int ret;

  401. 

  402.     av_log(s, AV_LOG_DEBUG, "Deleting stream...\n");

  403. 

  404.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SYSTEM_CHANNEL, RTMP_PT_INVOKE,

  405.                                      0, 34)) < 0)

  406.         return ret;

  407. 

  408.     p = pkt.data;

  409.     ff_amf_write_string(&p, "deleteStream");

  410.     ff_amf_write_number(&p, ++rt->nb_invokes);

  411.     ff_amf_write_null(&p);

  412.     ff_amf_write_number(&p, rt->main_channel_id);

  413. 

  414.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  415.                                rt->prev_pkt[1]);

  416.     ff_rtmp_packet_destroy(&pkt);

  417. 

  418.     return ret;

  419. }

  420. 

  421. /**

  422.  * Generate client buffer time and send it to the server.

  423.  */

  424. static int gen_buffer_time(URLContext *s, RTMPContext *rt)

  425. {

  426.     RTMPPacket pkt;

  427.     uint8_t *p;

  428.     int ret;

  429. 

  430.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_NETWORK_CHANNEL, RTMP_PT_PING,

  431.                                      1, 10)) < 0)

  432.         return ret;

  433. 

  434.     p = pkt.data;

  435.     bytestream_put_be16(&p, 3);

  436.     bytestream_put_be32(&p, rt->main_channel_id);

  437.     bytestream_put_be32(&p, rt->client_buffer_time);

  438. 

  439.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  440.                                rt->prev_pkt[1]);

  441.     ff_rtmp_packet_destroy(&pkt);

  442. 

  443.     return ret;

  444. }

  445. 

  446. /**

  447.  * Generate 'play' call and send it to the server, then ping the server

  448.  * to start actual playing.

  449.  */

  450. static int gen_play(URLContext *s, RTMPContext *rt)

  451. {

  452.     RTMPPacket pkt;

  453.     uint8_t *p;

  454.     int ret;

  455. 

  456.     av_log(s, AV_LOG_DEBUG, "Sending play command for '%s'\n", rt->playpath);

  457. 

  458.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_VIDEO_CHANNEL, RTMP_PT_INVOKE,

  459.                                      0, 29 + strlen(rt->playpath))) < 0)

  460.         return ret;

  461. 

  462.     pkt.extra = rt->main_channel_id;

  463. 

  464.     p = pkt.data;

  465.     ff_amf_write_string(&p, "play");

  466.     ff_amf_write_number(&p, ++rt->nb_invokes);

  467.     ff_amf_write_null(&p);

  468.     ff_amf_write_string(&p, rt->playpath);

  469.     ff_amf_write_number(&p, rt->live);

  470. 

  471.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  472.                                rt->prev_pkt[1]);

  473.     ff_rtmp_packet_destroy(&pkt);

  474. 

  475.     return ret;

  476. }

  477. 

  478. /**

  479.  * Generate 'publish' call and send it to the server.

  480.  */

  481. static int gen_publish(URLContext *s, RTMPContext *rt)

  482. {

  483.     RTMPPacket pkt;

  484.     uint8_t *p;

  485.     int ret;

  486. 

  487.     av_log(s, AV_LOG_DEBUG, "Sending publish command for '%s'\n", rt->playpath);

  488. 

  489.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SOURCE_CHANNEL, RTMP_PT_INVOKE,

  490.                                      0, 30 + strlen(rt->playpath))) < 0)

  491.         return ret;

  492. 

  493.     pkt.extra = rt->main_channel_id;

  494. 

  495.     p = pkt.data;

  496.     ff_amf_write_string(&p, "publish");

  497.     ff_amf_write_number(&p, ++rt->nb_invokes);

  498.     ff_amf_write_null(&p);

  499.     ff_amf_write_string(&p, rt->playpath);

  500.     ff_amf_write_string(&p, "live");

  501. 

  502.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  503.                                rt->prev_pkt[1]);

  504.     ff_rtmp_packet_destroy(&pkt);

  505. 

  506.     return ret;

  507. }

  508. 

  509. /**

  510.  * Generate ping reply and send it to the server.

  511.  */

  512. static int gen_pong(URLContext *s, RTMPContext *rt, RTMPPacket *ppkt)

  513. {

  514.     RTMPPacket pkt;

  515.     uint8_t *p;

  516.     int ret;

  517. 

  518.     if (ppkt->data_size < 6) {

  519.         av_log(s, AV_LOG_ERROR, "Too short ping packet (%d)\n",

  520.                ppkt->data_size);

  521.         return AVERROR_INVALIDDATA;

  522.     }

  523. 

  524.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_NETWORK_CHANNEL, RTMP_PT_PING,

  525.                                      ppkt->timestamp + 1, 6)) < 0)

  526.         return ret;

  527. 

  528.     p = pkt.data;

  529.     bytestream_put_be16(&p, 7);

  530.     bytestream_put_be32(&p, AV_RB32(ppkt->data+2));

  531.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  532.                                rt->prev_pkt[1]);

  533.     ff_rtmp_packet_destroy(&pkt);

  534. 

  535.     return ret;

  536. }

  537. 

  538. /**

  539.  * Generate server bandwidth message and send it to the server.

  540.  */

  541. static int gen_server_bw(URLContext *s, RTMPContext *rt)

  542. {

  543.     RTMPPacket pkt;

  544.     uint8_t *p;

  545.     int ret;

  546. 

  547.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_NETWORK_CHANNEL, RTMP_PT_SERVER_BW,

  548.                                      0, 4)) < 0)

  549.         return ret;

  550. 

  551.     p = pkt.data;

  552.     bytestream_put_be32(&p, rt->server_bw);

  553.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  554.                                rt->prev_pkt[1]);

  555.     ff_rtmp_packet_destroy(&pkt);

  556. 

  557.     return ret;

  558. }

  559. 

  560. /**

  561.  * Generate check bandwidth message and send it to the server.

  562.  */

  563. static int gen_check_bw(URLContext *s, RTMPContext *rt)

  564. {

  565.     RTMPPacket pkt;

  566.     uint8_t *p;

  567.     int ret;

  568. 

  569.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_SYSTEM_CHANNEL, RTMP_PT_INVOKE,

  570.                                      0, 21)) < 0)

  571.         return ret;

  572. 

  573.     p = pkt.data;

  574.     ff_amf_write_string(&p, "_checkbw");

  575.     ff_amf_write_number(&p, ++rt->nb_invokes);

  576.     ff_amf_write_null(&p);

  577. 

  578.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  579.                                rt->prev_pkt[1]);

  580.     ff_rtmp_packet_destroy(&pkt);

  581. 

  582.     return ret;

  583. }

  584. 

  585. /**

  586.  * Generate report on bytes read so far and send it to the server.

  587.  */

  588. static int gen_bytes_read(URLContext *s, RTMPContext *rt, uint32_t ts)

  589. {

  590.     RTMPPacket pkt;

  591.     uint8_t *p;

  592.     int ret;

  593. 

  594.     if ((ret = ff_rtmp_packet_create(&pkt, RTMP_NETWORK_CHANNEL, RTMP_PT_BYTES_READ,

  595.                                      ts, 4)) < 0)

  596.         return ret;

  597. 

  598.     p = pkt.data;

  599.     bytestream_put_be32(&p, rt->bytes_read);

  600.     ret = ff_rtmp_packet_write(rt->stream, &pkt, rt->chunk_size,

  601.                                rt->prev_pkt[1]);

  602.     ff_rtmp_packet_destroy(&pkt);

  603. 

  604.     return ret;

  605. }

  606. 

  607. int ff_rtmp_calc_digest(const uint8_t *src, int len, int gap,

  608.                         const uint8_t *key, int keylen, uint8_t *dst)

  609. {

  610.     struct AVSHA *sha;

  611.     uint8_t hmac_buf[64+32] = {0};

  612.     int i;

  613. 

  614.     sha = av_mallocz(av_sha_size);

  615.     if (!sha)

  616.         return AVERROR(ENOMEM);

  617. 

  618.     if (keylen < 64) {

  619.         memcpy(hmac_buf, key, keylen);

  620.     } else {

  621.         av_sha_init(sha, 256);

  622.         av_sha_update(sha,key, keylen);

  623.         av_sha_final(sha, hmac_buf);

  624.     }

  625.     for (i = 0; i < 64; i++)

  626.         hmac_buf[i] ^= HMAC_IPAD_VAL;

  627. 

  628.     av_sha_init(sha, 256);

  629.     av_sha_update(sha, hmac_buf, 64);

  630.     if (gap <= 0) {

  631.         av_sha_update(sha, src, len);

  632.     } else { //skip 32 bytes used for storing digest

  633.         av_sha_update(sha, src, gap);

  634.         av_sha_update(sha, src + gap + 32, len - gap - 32);

  635.     }

  636.     av_sha_final(sha, hmac_buf + 64);

  637. 

  638.     for (i = 0; i < 64; i++)

  639.         hmac_buf[i] ^= HMAC_IPAD_VAL ^ HMAC_OPAD_VAL; //reuse XORed key for opad

  640.     av_sha_init(sha, 256);

  641.     av_sha_update(sha, hmac_buf, 64+32);

  642.     av_sha_final(sha, dst);

  643. 

  644.     av_free(sha);

  645. 

  646.     return 0;

  647. }

  648. 

  649. int ff_rtmp_calc_digest_pos(const uint8_t *buf, int off, int mod_val,

  650.                             int add_val)

  651. {

  652.     int i, digest_pos = 0;

  653. 

  654.     for (i = 0; i < 4; i++)

  655.         digest_pos += buf[i + off];

  656.     digest_pos = digest_pos % mod_val + add_val;

  657. 

  658.     return digest_pos;

  659. }

  660. 

  661. /**

  662.  * Put HMAC-SHA2 digest of packet data (except for the bytes where this digest

  663.  * will be stored) into that packet.

  664.  *

  665.  * @param buf handshake data (1536 bytes)

  666.  * @param encrypted use an encrypted connection (RTMPE)

  667.  * @return offset to the digest inside input data

  668.  */

  669. static int rtmp_handshake_imprint_with_digest(uint8_t *buf, int encrypted)

  670. {

  671.     int ret, digest_pos;

  672. 

  673.     if (encrypted)

  674.         digest_pos = ff_rtmp_calc_digest_pos(buf, 772, 728, 776);

  675.     else

  676.         digest_pos = ff_rtmp_calc_digest_pos(buf, 8, 728, 12);

  677. 

  678.     ret = ff_rtmp_calc_digest(buf, RTMP_HANDSHAKE_PACKET_SIZE, digest_pos,

  679.                               rtmp_player_key, PLAYER_KEY_OPEN_PART_LEN,

  680.                               buf + digest_pos);

  681.     if (ret < 0)

  682.         return ret;

  683. 

  684.     return digest_pos;

  685. }

  686. 

  687. /**

  688.  * Verify that the received server response has the expected digest value.

  689.  *

  690.  * @param buf handshake data received from the server (1536 bytes)

  691.  * @param off position to search digest offset from

  692.  * @return 0 if digest is valid, digest position otherwise

  693.  */

  694. static int rtmp_validate_digest(uint8_t *buf, int off)

  695. {

  696.     uint8_t digest[32];

  697.     int ret, digest_pos;

  698. 

  699.     digest_pos = ff_rtmp_calc_digest_pos(buf, off, 728, off + 4);

  700. 

  701.     ret = ff_rtmp_calc_digest(buf, RTMP_HANDSHAKE_PACKET_SIZE, digest_pos,

  702.                               rtmp_server_key, SERVER_KEY_OPEN_PART_LEN,

  703.                               digest);

  704.     if (ret < 0)

  705.         return ret;

  706. 

  707.     if (!memcmp(digest, buf + digest_pos, 32))

  708.         return digest_pos;

  709.     return 0;

  710. }

  711. 

  712. /**

  713.  * Perform handshake with the server by means of exchanging pseudorandom data

  714.  * signed with HMAC-SHA2 digest.

  715.  *

  716.  * @return 0 if handshake succeeds, negative value otherwise

  717.  */

  718. static int rtmp_handshake(URLContext *s, RTMPContext *rt)

  719. {

  720.     AVLFG rnd;

  721.     uint8_t tosend    [RTMP_HANDSHAKE_PACKET_SIZE+1] = {

  722.         3,                // unencrypted data

  723.         0, 0, 0, 0,       // client uptime

  724.         RTMP_CLIENT_VER1,

  725.         RTMP_CLIENT_VER2,

  726.         RTMP_CLIENT_VER3,

  727.         RTMP_CLIENT_VER4,

  728.     };

  729.     uint8_t clientdata[RTMP_HANDSHAKE_PACKET_SIZE];

  730.     uint8_t serverdata[RTMP_HANDSHAKE_PACKET_SIZE+1];

  731.     int i;

  732.     int server_pos, client_pos;

  733.     uint8_t digest[32], signature[32];

  734.     int ret, type = 0;

  735. 

  736.     av_log(s, AV_LOG_DEBUG, "Handshaking...\n");

  737. 

  738.     av_lfg_init(&rnd, 0xDEADC0DE);

  739.     // generate handshake packet - 1536 bytes of pseudorandom data

  740.     for (i = 9; i <= RTMP_HANDSHAKE_PACKET_SIZE; i++)

  741.         tosend[i] = av_lfg_get(&rnd) >> 24;

  742. 

  743.     if (rt->encrypted && CONFIG_FFRTMPCRYPT_PROTOCOL) {

  744.         /* When the client wants to use RTMPE, we have to change the command

  745.          * byte to 0x06 which means to use encrypted data and we have to set

  746.          * the flash version to at least 9.0.115.0. */

  747.         tosend[0] = 6;

  748.         tosend[5] = 128;

  749.         tosend[6] = 0;

  750.         tosend[7] = 3;

  751.         tosend[8] = 2;

  752. 

  753.         /* Initialize the Diffie-Hellmann context and generate the public key

  754.          * to send to the server. */

  755.         if ((ret = ff_rtmpe_gen_pub_key(rt->stream, tosend + 1)) < 0)

  756.             return ret;

  757.     }

  758. 

  759.     client_pos = rtmp_handshake_imprint_with_digest(tosend + 1, rt->encrypted);

  760.     if (client_pos < 0)

  761.         return client_pos;

  762. 

  763.     if ((ret = ffurl_write(rt->stream, tosend,

  764.                            RTMP_HANDSHAKE_PACKET_SIZE + 1)) < 0) {

  765.         av_log(s, AV_LOG_ERROR, "Cannot write RTMP handshake request\n");

  766.         return ret;

  767.     }

  768. 

  769.     if ((ret = ffurl_read_complete(rt->stream, serverdata,

  770.                                    RTMP_HANDSHAKE_PACKET_SIZE + 1)) < 0) {

  771.         av_log(s, AV_LOG_ERROR, "Cannot read RTMP handshake response\n");

  772.         return ret;

  773.     }

  774. 

  775.     if ((ret = ffurl_read_complete(rt->stream, clientdata,

  776.                                    RTMP_HANDSHAKE_PACKET_SIZE)) < 0) {

  777.         av_log(s, AV_LOG_ERROR, "Cannot read RTMP handshake response\n");

  778.         return ret;

  779.     }

  780. 

  781.     av_log(s, AV_LOG_DEBUG, "Type answer %d\n", serverdata[0]);

  782.     av_log(s, AV_LOG_DEBUG, "Server version %d.%d.%d.%d\n",

  783.            serverdata[5], serverdata[6], serverdata[7], serverdata[8]);

  784. 

  785.     if (rt->is_input && serverdata[5] >= 3) {

  786.         server_pos = rtmp_validate_digest(serverdata + 1, 772);

  787.         if (server_pos < 0)

  788.             return server_pos;

  789. 

  790.         if (!server_pos) {

  791.             type = 1;

  792.             server_pos = rtmp_validate_digest(serverdata + 1, 8);

  793.             if (server_pos < 0)

  794.                 return server_pos;

  795. 

  796.             if (!server_pos) {

  797.                 av_log(s, AV_LOG_ERROR, "Server response validating failed\n");

  798.                 return AVERROR(EIO);

  799.             }

  800.         }

  801. 

  802.         ret = ff_rtmp_calc_digest(tosend + 1 + client_pos, 32, 0,

  803.                                   rtmp_server_key, sizeof(rtmp_server_key),

  804.                                   digest);

  805.         if (ret < 0)

  806.             return ret;

  807. 

  808.         ret = ff_rtmp_calc_digest(clientdata, RTMP_HANDSHAKE_PACKET_SIZE - 32,

  809.                                   0, digest, 32, signature);

  810.         if (ret < 0)

  811.             return ret;

  812. 

  813.         if (rt->encrypted && CONFIG_FFRTMPCRYPT_PROTOCOL) {

  814.             /* Compute the shared secret key sent by the server and initialize

  815.              * the RC4 encryption. */

  816.             if ((ret = ff_rtmpe_compute_secret_key(rt->stream, serverdata + 1,

  817.                                                    tosend + 1, type)) < 0)

  818.                 return ret;

  819. 

  820.             /* Encrypt the signature received by the server. */

  821.             ff_rtmpe_encrypt_sig(rt->stream, signature, digest, serverdata[0]);

  822.         }

  823. 

  824.         if (memcmp(signature, clientdata + RTMP_HANDSHAKE_PACKET_SIZE - 32, 32)) {

  825.             av_log(s, AV_LOG_ERROR, "Signature mismatch\n");

  826.             return AVERROR(EIO);

  827.         }

  828. 

  829.         for (i = 0; i < RTMP_HANDSHAKE_PACKET_SIZE; i++)

  830.             tosend[i] = av_lfg_get(&rnd) >> 24;

  831.         ret = ff_rtmp_calc_digest(serverdata + 1 + server_pos, 32, 0,

  832.                                   rtmp_player_key, sizeof(rtmp_player_key),

  833.                                   digest);

  834.         if (ret < 0)

  835.             return ret;

  836. 

  837.         ret = ff_rtmp_calc_digest(tosend, RTMP_HANDSHAKE_PACKET_SIZE - 32, 0,

  838.                                   digest, 32,

  839.                                   tosend + RTMP_HANDSHAKE_PACKET_SIZE - 32);

  840.         if (ret < 0)

  841.             return ret;

  842. 

  843.         if (rt->encrypted && CONFIG_FFRTMPCRYPT_PROTOCOL) {

  844.             /* Encrypt the signature to be send to the server. */

  845.             ff_rtmpe_encrypt_sig(rt->stream, tosend +

  846.                                  RTMP_HANDSHAKE_PACKET_SIZE - 32, digest,

  847.                                  serverdata[0]);

  848.         }

  849. 

  850.         // write reply back to the server

  851.         if ((ret = ffurl_write(rt->stream, tosend,

  852.                                RTMP_HANDSHAKE_PACKET_SIZE)) < 0)

  853.             return ret;

  854. 

  855.         if (rt->encrypted && CONFIG_FFRTMPCRYPT_PROTOCOL) {

  856.             /* Set RC4 keys for encryption and update the keystreams. */

  857.             if ((ret = ff_rtmpe_update_keystream(rt->stream)) < 0)

  858.                 return ret;

  859.         }

  860.     } else {

  861.         if (rt->encrypted && CONFIG_FFRTMPCRYPT_PROTOCOL) {

  862.             /* Compute the shared secret key sent by the server and initialize

  863.              * the RC4 encryption. */

  864.             if ((ret = ff_rtmpe_compute_secret_key(rt->stream, serverdata + 1,

  865.                             tosend + 1, 1)) < 0)

  866.                 return ret;

  867. 

  868.             if (serverdata[0] == 9) {

  869.                 /* Encrypt the signature received by the server. */

  870.                 ff_rtmpe_encrypt_sig(rt->stream, signature, digest,

  871.                                      serverdata[0]);

  872.             }

  873.         }

  874. 

  875.         if ((ret = ffurl_write(rt->stream, serverdata + 1,

  876.                                RTMP_HANDSHAKE_PACKET_SIZE)) < 0)

  877.             return ret;

  878. 

  879.         if (rt->encrypted && CONFIG_FFRTMPCRYPT_PROTOCOL) {

  880.             /* Set RC4 keys for encryption and update the keystreams. */

  881.             if ((ret = ff_rtmpe_update_keystream(rt->stream)) < 0)

  882.                 return ret;

  883.         }

  884.     }

  885. 

  886.     return 0;

  887. }

  888. 

  889. static int handle_chunk_size(URLContext *s, RTMPPacket *pkt)

  890. {

  891.     RTMPContext *rt = s->priv_data;

  892.     int ret;

  893. 

  894.     if (pkt->data_size < 4) {

  895.         av_log(s, AV_LOG_ERROR,

  896.                "Too short chunk size change packet (%d)\n",

  897.                pkt->data_size);

  898.         return AVERROR_INVALIDDATA;

  899.     }

  900. 

  901.     if (!rt->is_input) {

  902.         if ((ret = ff_rtmp_packet_write(rt->stream, pkt, rt->chunk_size,

  903.                                         rt->prev_pkt[1])) < 0)

  904.             return ret;

  905.     }

  906. 

  907.     rt->chunk_size = AV_RB32(pkt->data);

  908.     if (rt->chunk_size <= 0) {

  909.         av_log(s, AV_LOG_ERROR, "Incorrect chunk size %d\n", rt->chunk_size);

  910.         return AVERROR_INVALIDDATA;

  911.     }

  912.     av_log(s, AV_LOG_DEBUG, "New chunk size = %d\n", rt->chunk_size);

  913. 

  914.     return 0;

  915. }

  916. 

  917. static int handle_ping(URLContext *s, RTMPPacket *pkt)

  918. {

  919.     RTMPContext *rt = s->priv_data;

  920.     int t, ret;

  921. 

  922.     if (pkt->data_size < 2) {

  923.         av_log(s, AV_LOG_ERROR, "Too short ping packet (%d)\n",

  924.                pkt->data_size);

  925.         return AVERROR_INVALIDDATA;

  926.     }

  927. 

  928.     t = AV_RB16(pkt->data);

  929.     if (t == 6) {

  930.         if ((ret = gen_pong(s, rt, pkt)) < 0)

  931.             return ret;

  932.     }

  933. 

  934.     return 0;

  935. }

  936. 

  937. static int handle_client_bw(URLContext *s, RTMPPacket *pkt)

  938. {

  939.     RTMPContext *rt = s->priv_data;

  940. 

  941.     if (pkt->data_size < 4) {

  942.         av_log(s, AV_LOG_ERROR,

  943.                "Client bandwidth report packet is less than 4 bytes long (%d)\n",

  944.                pkt->data_size);

  945.         return AVERROR_INVALIDDATA;

  946.     }

  947. 

  948.     rt->client_report_size = AV_RB32(pkt->data);

  949.     if (rt->client_report_size <= 0) {

  950.         av_log(s, AV_LOG_ERROR, "Incorrect client bandwidth %d\n",

  951.                 rt->client_report_size);

  952.         return AVERROR_INVALIDDATA;

  953. 

  954.     }

  955.     av_log(s, AV_LOG_DEBUG, "Client bandwidth = %d\n", rt->client_report_size);

  956.     rt->client_report_size >>= 1;

  957. 

  958.     return 0;

  959. }

  960. 

  961. static int handle_server_bw(URLContext *s, RTMPPacket *pkt)

  962. {

  963.     RTMPContext *rt = s->priv_data;

  964. 

  965.     if (pkt->data_size < 4) {

  966.         av_log(s, AV_LOG_ERROR,

  967.                "Too short server bandwidth report packet (%d)\n",

  968.                pkt->data_size);

  969.         return AVERROR_INVALIDDATA;

  970.     }

  971. 

  972.     rt->server_bw = AV_RB32(pkt->data);

  973.     if (rt->server_bw <= 0) {

  974.         av_log(s, AV_LOG_ERROR, "Incorrect server bandwidth %d\n",

  975.                rt->server_bw);

  976.         return AVERROR_INVALIDDATA;

  977.     }

  978.     av_log(s, AV_LOG_DEBUG, "Server bandwidth = %d\n", rt->server_bw);

  979. 

  980.     return 0;

  981. }

  982. 

  983. static int handle_invoke(URLContext *s, RTMPPacket *pkt)

  984. {

  985.     RTMPContext *rt = s->priv_data;

  986.     int i, t;

  987.     const uint8_t *data_end = pkt->data + pkt->data_size;

  988.     int ret;

  989. 

  990.     //TODO: check for the messages sent for wrong state?

  991.     if (!memcmp(pkt->data, "\002\000\006_error", 9)) {

  992.         uint8_t tmpstr[256];

  993. 

  994.         if (!ff_amf_get_field_value(pkt->data + 9, data_end,

  995.                                     "description", tmpstr, sizeof(tmpstr)))

  996.             av_log(s, AV_LOG_ERROR, "Server error: %s\n",tmpstr);

  997.         return -1;

  998.     } else if (!memcmp(pkt->data, "\002\000\007_result", 10)) {

  999.         switch (rt->state) {

  1000.             case STATE_HANDSHAKED:

  1001.                 if (!rt->is_input) {

  1002.                     if ((ret = gen_release_stream(s, rt)) < 0)

  1003.                         return ret;

  1004.                     if ((ret = gen_fcpublish_stream(s, rt)) < 0)

  1005.                         return ret;

  1006.                     rt->state = STATE_RELEASING;

  1007.                 } else {

  1008.                     if ((ret = gen_server_bw(s, rt)) < 0)

  1009.                         return ret;

  1010.                     rt->state = STATE_CONNECTING;

  1011.                 }

  1012.                 if ((ret = gen_create_stream(s, rt)) < 0)

  1013.                     return ret;

  1014.                 break;

  1015.             case STATE_FCPUBLISH:

  1016.                 rt->state = STATE_CONNECTING;

  1017.                 break;

  1018.             case STATE_RELEASING:

  1019.                 rt->state = STATE_FCPUBLISH;

  1020.                 /* hack for Wowza Media Server, it does not send result for

  1021.                  * releaseStream and FCPublish calls */

  1022.                 if (!pkt->data[10]) {

  1023.                     int pkt_id = av_int2double(AV_RB64(pkt->data + 11));

  1024.                     if (pkt_id == rt->create_stream_invoke)

  1025.                         rt->state = STATE_CONNECTING;

  1026.                 }

  1027.                 if (rt->state != STATE_CONNECTING)

  1028.                     break;

  1029.             case STATE_CONNECTING:

  1030.                 //extract a number from the result

  1031.                 if (pkt->data[10] || pkt->data[19] != 5 || pkt->data[20]) {

  1032.                     av_log(s, AV_LOG_WARNING, "Unexpected reply on connect()\n");

  1033.                 } else {

  1034.                     rt->main_channel_id = av_int2double(AV_RB64(pkt->data + 21));

  1035.                 }

  1036.                 if (rt->is_input) {

  1037.                     if ((ret = gen_play(s, rt)) < 0)

  1038.                         return ret;

  1039.                     if ((ret = gen_buffer_time(s, rt)) < 0)

  1040.                         return ret;

  1041.                 } else {

  1042.                     if ((ret = gen_publish(s, rt)) < 0)

  1043.                         return ret;

  1044.                 }

  1045.                 rt->state = STATE_READY;

  1046.                 break;

  1047.         }

  1048.     } else if (!memcmp(pkt->data, "\002\000\010onStatus", 11)) {

  1049.         const uint8_t* ptr = pkt->data + 11;

  1050.         uint8_t tmpstr[256];

  1051. 

  1052.         for (i = 0; i < 2; i++) {

  1053.             t = ff_amf_tag_size(ptr, data_end);

  1054.             if (t < 0)

  1055.                 return 1;

  1056.             ptr += t;

  1057.         }

  1058.         t = ff_amf_get_field_value(ptr, data_end,

  1059.                                    "level", tmpstr, sizeof(tmpstr));

  1060.         if (!t && !strcmp(tmpstr, "error")) {

  1061.             if (!ff_amf_get_field_value(ptr, data_end,

  1062.                                         "description", tmpstr, sizeof(tmpstr)))

  1063.                 av_log(s, AV_LOG_ERROR, "Server error: %s\n",tmpstr);

  1064.             return -1;

  1065.         }

  1066.         t = ff_amf_get_field_value(ptr, data_end,

  1067.                 "code", tmpstr, sizeof(tmpstr));

  1068.         if (!t && !strcmp(tmpstr, "NetStream.Play.Start")) rt->state = STATE_PLAYING;

  1069.         if (!t && !strcmp(tmpstr, "NetStream.Play.Stop")) rt->state = STATE_STOPPED;

  1070.         if (!t && !strcmp(tmpstr, "NetStream.Play.UnpublishNotify")) rt->state = STATE_STOPPED;

  1071.         if (!t && !strcmp(tmpstr, "NetStream.Publish.Start")) rt->state = STATE_PUBLISHING;

  1072.     } else if (!memcmp(pkt->data, "\002\000\010onBWDone", 11)) {

  1073.         if ((ret = gen_check_bw(s, rt)) < 0)

  1074.             return ret;

  1075.     }

  1076. 

  1077.     return 0;

  1078. }

  1079. 

  1080. /**

  1081.  * Parse received packet and possibly perform some action depending on

  1082.  * the packet contents.

  1083.  * @return 0 for no errors, negative values for serious errors which prevent

  1084.  *         further communications, positive values for uncritical errors

  1085.  */

  1086. static int rtmp_parse_result(URLContext *s, RTMPContext *rt, RTMPPacket *pkt)

  1087. {

  1088.     int ret;

  1089. 

  1090. #ifdef DEBUG

  1091.     ff_rtmp_packet_dump(s, pkt);

  1092. #endif

  1093. 

  1094.     switch (pkt->type) {

  1095.     case RTMP_PT_CHUNK_SIZE:

  1096.         if ((ret = handle_chunk_size(s, pkt)) < 0)

  1097.             return ret;

  1098.         break;

  1099.     case RTMP_PT_PING:

  1100.         if ((ret = handle_ping(s, pkt)) < 0)

  1101.             return ret;

  1102.         break;

  1103.     case RTMP_PT_CLIENT_BW:

  1104.         if ((ret = handle_client_bw(s, pkt)) < 0)

  1105.             return ret;

  1106.         break;

  1107.     case RTMP_PT_SERVER_BW:

  1108.         if ((ret = handle_server_bw(s, pkt)) < 0)

  1109.             return ret;

  1110.         break;

  1111.     case RTMP_PT_INVOKE:

  1112.         if ((ret = handle_invoke(s, pkt)) < 0)

  1113.             return ret;

  1114.         break;

  1115.     case RTMP_PT_VIDEO:

  1116.     case RTMP_PT_AUDIO:

  1117.         /* Audio and Video packets are parsed in get_packet() */

  1118.         break;

  1119.     default:

  1120.         av_log(s, AV_LOG_VERBOSE, "Unknown packet type received 0x%02X\n", pkt->type);

  1121.         break;

  1122.     }

  1123.     return 0;

  1124. }

  1125. 

  1126. /**

  1127.  * Interact with the server by receiving and sending RTMP packets until

  1128.  * there is some significant data (media data or expected status notification).

  1129.  *

  1130.  * @param s          reading context

  1131.  * @param for_header non-zero value tells function to work until it

  1132.  * gets notification from the server that playing has been started,

  1133.  * otherwise function will work until some media data is received (or

  1134.  * an error happens)

  1135.  * @return 0 for successful operation, negative value in case of error

  1136.  */

  1137. static int get_packet(URLContext *s, int for_header)

  1138. {

  1139.     RTMPContext *rt = s->priv_data;

  1140.     int ret;

  1141.     uint8_t *p;

  1142.     const uint8_t *next;

  1143.     uint32_t data_size;

  1144.     uint32_t ts, cts, pts=0;

  1145. 

  1146.     if (rt->state == STATE_STOPPED)

  1147.         return AVERROR_EOF;

  1148. 

  1149.     for (;;) {

  1150.         RTMPPacket rpkt = { 0 };

  1151.         if ((ret = ff_rtmp_packet_read(rt->stream, &rpkt,

  1152.                                        rt->chunk_size, rt->prev_pkt[0])) <= 0) {

  1153.             if (ret == 0) {

  1154.                 return AVERROR(EAGAIN);

  1155.             } else {

  1156.                 return AVERROR(EIO);

  1157.             }

  1158.         }

  1159.         rt->bytes_read += ret;

  1160.         if (rt->bytes_read > rt->last_bytes_read + rt->client_report_size) {

  1161.             av_log(s, AV_LOG_DEBUG, "Sending bytes read report\n");

  1162.             if ((ret = gen_bytes_read(s, rt, rpkt.timestamp + 1)) < 0)

  1163.                 return ret;

  1164.             rt->last_bytes_read = rt->bytes_read;

  1165.         }

  1166. 

  1167.         ret = rtmp_parse_result(s, rt, &rpkt);

  1168.         if (ret < 0) {//serious error in current packet

  1169.             ff_rtmp_packet_destroy(&rpkt);

  1170.             return ret;

  1171.         }

  1172.         if (rt->state == STATE_STOPPED) {

  1173.             ff_rtmp_packet_destroy(&rpkt);

  1174.             return AVERROR_EOF;

  1175.         }

  1176.         if (for_header && (rt->state == STATE_PLAYING || rt->state == STATE_PUBLISHING)) {

  1177.             ff_rtmp_packet_destroy(&rpkt);

  1178.             return 0;

  1179.         }

  1180.         if (!rpkt.data_size || !rt->is_input) {

  1181.             ff_rtmp_packet_destroy(&rpkt);

  1182.             continue;

  1183.         }

  1184.         if (rpkt.type == RTMP_PT_VIDEO || rpkt.type == RTMP_PT_AUDIO ||

  1185.            (rpkt.type == RTMP_PT_NOTIFY && !memcmp("\002\000\012onMetaData", rpkt.data, 13))) {

  1186.             ts = rpkt.timestamp;

  1187. 

  1188.             // generate packet header and put data into buffer for FLV demuxer

  1189.             rt->flv_off  = 0;

  1190.             rt->flv_size = rpkt.data_size + 15;

  1191.             rt->flv_data = p = av_realloc(rt->flv_data, rt->flv_size);

  1192.             bytestream_put_byte(&p, rpkt.type);

  1193.             bytestream_put_be24(&p, rpkt.data_size);

  1194.             bytestream_put_be24(&p, ts);

  1195.             bytestream_put_byte(&p, ts >> 24);

  1196.             bytestream_put_be24(&p, 0);

  1197.             bytestream_put_buffer(&p, rpkt.data, rpkt.data_size);

  1198.             bytestream_put_be32(&p, 0);

  1199.             ff_rtmp_packet_destroy(&rpkt);

  1200.             return 0;

  1201.         } else if (rpkt.type == RTMP_PT_METADATA) {

  1202.             // we got raw FLV data, make it available for FLV demuxer

  1203.             rt->flv_off  = 0;

  1204.             rt->flv_size = rpkt.data_size;

  1205.             rt->flv_data = av_realloc(rt->flv_data, rt->flv_size);

  1206.             /* rewrite timestamps */

  1207.             next = rpkt.data;

  1208.             ts = rpkt.timestamp;

  1209.             while (next - rpkt.data < rpkt.data_size - 11) {

  1210.                 next++;

  1211.                 data_size = bytestream_get_be24(&next);

  1212.                 p=next;

  1213.                 cts = bytestream_get_be24(&next);

  1214.                 cts |= bytestream_get_byte(&next) << 24;

  1215.                 if (pts==0)

  1216.                     pts=cts;

  1217.                 ts += cts - pts;

  1218.                 pts = cts;

  1219.                 bytestream_put_be24(&p, ts);

  1220.                 bytestream_put_byte(&p, ts >> 24);

  1221.                 next += data_size + 3 + 4;

  1222.             }

  1223.             memcpy(rt->flv_data, rpkt.data, rpkt.data_size);

  1224.             ff_rtmp_packet_destroy(&rpkt);

  1225.             return 0;

  1226.         }

  1227.         ff_rtmp_packet_destroy(&rpkt);

  1228.     }

  1229. }

  1230. 

  1231. static int rtmp_close(URLContext *h)

  1232. {

  1233.     RTMPContext *rt = h->priv_data;

  1234.     int ret = 0;

  1235. 

  1236.     if (!rt->is_input) {

  1237.         rt->flv_data = NULL;

  1238.         if (rt->out_pkt.data_size)

  1239.             ff_rtmp_packet_destroy(&rt->out_pkt);

  1240.         if (rt->state > STATE_FCPUBLISH)

  1241.             ret = gen_fcunpublish_stream(h, rt);

  1242.     }

  1243.     if (rt->state > STATE_HANDSHAKED)

  1244.         ret = gen_delete_stream(h, rt);

  1245. 

  1246.     av_freep(&rt->flv_data);

  1247.     ffurl_close(rt->stream);

  1248.     return ret;

  1249. }

  1250. 

  1251. /**

  1252.  * Open RTMP connection and verify that the stream can be played.

  1253.  *

  1254.  * URL syntax: rtmp://server[:port][/app][/playpath]

  1255.  *             where 'app' is first one or two directories in the path

  1256.  *             (e.g. /ondemand/, /flash/live/, etc.)

  1257.  *             and 'playpath' is a file name (the rest of the path,

  1258.  *             may be prefixed with "mp4:")

  1259.  */

  1260. static int rtmp_open(URLContext *s, const char *uri, int flags)

  1261. {

  1262.     RTMPContext *rt = s->priv_data;

  1263.     char proto[8], hostname[256], path[1024], *fname;

  1264.     char *old_app;

  1265.     uint8_t buf[2048];

  1266.     int port;

  1267.     AVDictionary *opts = NULL;

  1268.     int ret;

  1269. 

  1270.     rt->is_input = !(flags & AVIO_FLAG_WRITE);

  1271. 

  1272.     av_url_split(proto, sizeof(proto), NULL, 0, hostname, sizeof(hostname), &port,

  1273.                  path, sizeof(path), s->filename);

  1274. 

  1275.     if (!strcmp(proto, "rtmpt") || !strcmp(proto, "rtmpts")) {

  1276.         if (!strcmp(proto, "rtmpts"))

  1277.             av_dict_set(&opts, "ffrtmphttp_tls", "1", 1);

  1278. 

  1279.         /* open the http tunneling connection */

  1280.         ff_url_join(buf, sizeof(buf), "ffrtmphttp", NULL, hostname, port, NULL);

  1281.     } else if (!strcmp(proto, "rtmps")) {

  1282.         /* open the tls connection */

  1283.         if (port < 0)

  1284.             port = RTMPS_DEFAULT_PORT;

  1285.         ff_url_join(buf, sizeof(buf), "tls", NULL, hostname, port, NULL);

  1286.     } else if (!strcmp(proto, "rtmpe") || (!strcmp(proto, "rtmpte"))) {

  1287.         if (!strcmp(proto, "rtmpte"))

  1288.             av_dict_set(&opts, "ffrtmpcrypt_tunneling", "1", 1);

  1289. 

  1290.         /* open the encrypted connection */

  1291.         ff_url_join(buf, sizeof(buf), "ffrtmpcrypt", NULL, hostname, port, NULL);

  1292.         rt->encrypted = 1;

  1293.     } else {

  1294.         /* open the tcp connection */

  1295.         if (port < 0)

  1296.             port = RTMP_DEFAULT_PORT;

  1297.         ff_url_join(buf, sizeof(buf), "tcp", NULL, hostname, port, NULL);

  1298.     }

  1299. 

  1300.     if ((ret = ffurl_open(&rt->stream, buf, AVIO_FLAG_READ_WRITE,

  1301.                           &s->interrupt_callback, &opts)) < 0) {

  1302.         av_log(s , AV_LOG_ERROR, "Cannot open connection %s\n", buf);

  1303.         goto fail;

  1304.     }

  1305. 

  1306.     rt->state = STATE_START;

  1307.     if ((ret = rtmp_handshake(s, rt)) < 0)

  1308.         goto fail;

  1309. 

  1310.     rt->chunk_size = 128;

  1311.     rt->state = STATE_HANDSHAKED;

  1312. 

  1313.     // Keep the application name when it has been defined by the user.

  1314.     old_app = rt->app;

  1315. 

  1316.     rt->app = av_malloc(APP_MAX_LENGTH);

  1317.     if (!rt->app) {

  1318.         ret = AVERROR(ENOMEM);

  1319.         goto fail;

  1320.     }

  1321. 

  1322.     //extract "app" part from path

  1323.     if (!strncmp(path, "/ondemand/", 10)) {

  1324.         fname = path + 10;

  1325.         memcpy(rt->app, "ondemand", 9);

  1326.     } else {

  1327.         char *next = *path ? path + 1 : path;

  1328.         char *p = strchr(next, '/');

  1329.         if (!p) {

  1330.             fname = next;

  1331.             rt->app[0] = '\0';

  1332.         } else {

  1333.             // make sure we do not mismatch a playpath for an application instance

  1334.             char *c = strchr(p + 1, ':');

  1335.             fname = strchr(p + 1, '/');

  1336.             if (!fname || (c && c < fname)) {

  1337.                 fname = p + 1;

  1338.                 av_strlcpy(rt->app, path + 1, p - path);

  1339.             } else {

  1340.                 fname++;

  1341.                 av_strlcpy(rt->app, path + 1, fname - path - 1);

  1342.             }

  1343.         }

  1344.     }

  1345. 

  1346.     if (old_app) {

  1347.         // The name of application has been defined by the user, override it.

  1348.         av_free(rt->app);

  1349.         rt->app = old_app;

  1350.     }

  1351. 

  1352.     if (!rt->playpath) {

  1353.         int len = strlen(fname);

  1354. 

  1355.         rt->playpath = av_malloc(PLAYPATH_MAX_LENGTH);

  1356.         if (!rt->playpath) {

  1357.             ret = AVERROR(ENOMEM);

  1358.             goto fail;

  1359.         }

  1360. 

  1361.         if (!strchr(fname, ':') && len >= 4 &&

  1362.             (!strcmp(fname + len - 4, ".f4v") ||

  1363.              !strcmp(fname + len - 4, ".mp4"))) {

  1364.             memcpy(rt->playpath, "mp4:", 5);

  1365.         } else if (len >= 4 && !strcmp(fname + len - 4, ".flv")) {

  1366.             fname[len - 4] = '\0';

  1367.         } else {

  1368.             rt->playpath[0] = 0;

  1369.         }

  1370.         strncat(rt->playpath, fname, PLAYPATH_MAX_LENGTH - 5);

  1371.     }

  1372. 

  1373.     if (!rt->tcurl) {

  1374.         rt->tcurl = av_malloc(TCURL_MAX_LENGTH);

  1375.         if (!rt->tcurl) {

  1376.             ret = AVERROR(ENOMEM);

  1377.             goto fail;

  1378.         }

  1379.         ff_url_join(rt->tcurl, TCURL_MAX_LENGTH, proto, NULL, hostname,

  1380.                     port, "/%s", rt->app);

  1381.     }

  1382. 

  1383.     if (!rt->flashver) {

  1384.         rt->flashver = av_malloc(FLASHVER_MAX_LENGTH);

  1385.         if (!rt->flashver) {

  1386.             ret = AVERROR(ENOMEM);

  1387.             goto fail;

  1388.         }

  1389.         if (rt->is_input) {

  1390.             snprintf(rt->flashver, FLASHVER_MAX_LENGTH, "%s %d,%d,%d,%d",

  1391.                     RTMP_CLIENT_PLATFORM, RTMP_CLIENT_VER1, RTMP_CLIENT_VER2,

  1392.                     RTMP_CLIENT_VER3, RTMP_CLIENT_VER4);

  1393.         } else {

  1394.             snprintf(rt->flashver, FLASHVER_MAX_LENGTH,

  1395.                     "FMLE/3.0 (compatible; %s)", LIBAVFORMAT_IDENT);

  1396.         }

  1397.     }

  1398. 

  1399.     rt->client_report_size = 1048576;

  1400.     rt->bytes_read = 0;

  1401.     rt->last_bytes_read = 0;

  1402.     rt->server_bw = 2500000;

  1403. 

  1404.     av_log(s, AV_LOG_DEBUG, "Proto = %s, path = %s, app = %s, fname = %s\n",

  1405.            proto, path, rt->app, rt->playpath);

  1406.     if ((ret = gen_connect(s, rt)) < 0)

  1407.         goto fail;

  1408. 

  1409.     do {

  1410.         ret = get_packet(s, 1);

  1411.     } while (ret == EAGAIN);

  1412.     if (ret < 0)

  1413.         goto fail;

  1414. 

  1415.     if (rt->is_input) {

  1416.         // generate FLV header for demuxer

  1417.         rt->flv_size = 13;

  1418.         rt->flv_data = av_realloc(rt->flv_data, rt->flv_size);

  1419.         rt->flv_off  = 0;

  1420.         memcpy(rt->flv_data, "FLV\1\5\0\0\0\011\0\0\0\0", rt->flv_size);

  1421.     } else {

  1422.         rt->flv_size = 0;

  1423.         rt->flv_data = NULL;

  1424.         rt->flv_off  = 0;

  1425.         rt->skip_bytes = 13;

  1426.     }

  1427. 

  1428.     s->max_packet_size = rt->stream->max_packet_size;

  1429.     s->is_streamed     = 1;

  1430.     return 0;

  1431. 

  1432. fail:

  1433.     av_dict_free(&opts);

  1434.     rtmp_close(s);

  1435.     return ret;

  1436. }

  1437. 

  1438. static int rtmp_read(URLContext *s, uint8_t *buf, int size)

  1439. {

  1440.     RTMPContext *rt = s->priv_data;

  1441.     int orig_size = size;

  1442.     int ret;

  1443. 

  1444.     while (size > 0) {

  1445.         int data_left = rt->flv_size - rt->flv_off;

  1446. 

  1447.         if (data_left >= size) {

  1448.             memcpy(buf, rt->flv_data + rt->flv_off, size);

  1449.             rt->flv_off += size;

  1450.             return orig_size;

  1451.         }

  1452.         if (data_left > 0) {

  1453.             memcpy(buf, rt->flv_data + rt->flv_off, data_left);

  1454.             buf  += data_left;

  1455.             size -= data_left;

  1456.             rt->flv_off = rt->flv_size;

  1457.             return data_left;

  1458.         }

  1459.         if ((ret = get_packet(s, 0)) < 0)

  1460.            return ret;

  1461.     }

  1462.     return orig_size;

  1463. }

  1464. 

  1465. static int rtmp_write(URLContext *s, const uint8_t *buf, int size)

  1466. {

  1467.     RTMPContext *rt = s->priv_data;

  1468.     int size_temp = size;

  1469.     int pktsize, pkttype;

  1470.     uint32_t ts;

  1471.     const uint8_t *buf_temp = buf;

  1472.     uint8_t c;

  1473.     int ret;

  1474. 

  1475.     do {

  1476.         if (rt->skip_bytes) {

  1477.             int skip = FFMIN(rt->skip_bytes, size_temp);

  1478.             buf_temp       += skip;

  1479.             size_temp      -= skip;

  1480.             rt->skip_bytes -= skip;

  1481.             continue;

  1482.         }

  1483. 

  1484.         if (rt->flv_header_bytes < 11) {

  1485.             const uint8_t *header = rt->flv_header;

  1486.             int copy = FFMIN(11 - rt->flv_header_bytes, size_temp);

  1487.             bytestream_get_buffer(&buf_temp, rt->flv_header + rt->flv_header_bytes, copy);

  1488.             rt->flv_header_bytes += copy;

  1489.             size_temp            -= copy;

  1490.             if (rt->flv_header_bytes < 11)

  1491.                 break;

  1492. 

  1493.             pkttype = bytestream_get_byte(&header);

  1494.             pktsize = bytestream_get_be24(&header);

  1495.             ts = bytestream_get_be24(&header);

  1496.             ts |= bytestream_get_byte(&header) << 24;

  1497.             bytestream_get_be24(&header);

  1498.             rt->flv_size = pktsize;

  1499. 

  1500.             //force 12bytes header

  1501.             if (((pkttype == RTMP_PT_VIDEO || pkttype == RTMP_PT_AUDIO) && ts == 0) ||

  1502.                 pkttype == RTMP_PT_NOTIFY) {

  1503.                 if (pkttype == RTMP_PT_NOTIFY)

  1504.                     pktsize += 16;

  1505.                 rt->prev_pkt[1][RTMP_SOURCE_CHANNEL].channel_id = 0;

  1506.             }

  1507. 

  1508.             //this can be a big packet, it's better to send it right here

  1509.             if ((ret = ff_rtmp_packet_create(&rt->out_pkt, RTMP_SOURCE_CHANNEL,

  1510.                                              pkttype, ts, pktsize)) < 0)

  1511.                 return ret;

  1512. 

  1513.             rt->out_pkt.extra = rt->main_channel_id;

  1514.             rt->flv_data = rt->out_pkt.data;

  1515. 

  1516.             if (pkttype == RTMP_PT_NOTIFY)

  1517.                 ff_amf_write_string(&rt->flv_data, "@setDataFrame");

  1518.         }

  1519. 

  1520.         if (rt->flv_size - rt->flv_off > size_temp) {

  1521.             bytestream_get_buffer(&buf_temp, rt->flv_data + rt->flv_off, size_temp);

  1522.             rt->flv_off += size_temp;

  1523.             size_temp = 0;

  1524.         } else {

  1525.             bytestream_get_buffer(&buf_temp, rt->flv_data + rt->flv_off, rt->flv_size - rt->flv_off);

  1526.             size_temp   -= rt->flv_size - rt->flv_off;

  1527.             rt->flv_off += rt->flv_size - rt->flv_off;

  1528.         }

  1529. 

  1530.         if (rt->flv_off == rt->flv_size) {

  1531.             rt->skip_bytes = 4;

  1532. 

  1533.             if ((ret = ff_rtmp_packet_write(rt->stream, &rt->out_pkt,

  1534.                                             rt->chunk_size, rt->prev_pkt[1])) < 0)

  1535.                 return ret;

  1536.             ff_rtmp_packet_destroy(&rt->out_pkt);

  1537.             rt->flv_size = 0;

  1538.             rt->flv_off = 0;

  1539.             rt->flv_header_bytes = 0;

  1540.             rt->flv_nb_packets++;

  1541.         }

  1542.     } while (buf_temp - buf < size);

  1543. 

  1544.     if (rt->flv_nb_packets < rt->flush_interval)

  1545.         return size;

  1546.     rt->flv_nb_packets = 0;

  1547. 

  1548.     /* set stream into nonblocking mode */

  1549.     rt->stream->flags |= AVIO_FLAG_NONBLOCK;

  1550. 

  1551.     /* try to read one byte from the stream */

  1552.     ret = ffurl_read(rt->stream, &c, 1);

  1553. 

  1554.     /* switch the stream back into blocking mode */

  1555.     rt->stream->flags &= ~AVIO_FLAG_NONBLOCK;

  1556. 

  1557.     if (ret == AVERROR(EAGAIN)) {

  1558.         /* no incoming data to handle */

  1559.         return size;

  1560.     } else if (ret < 0) {

  1561.         return ret;

  1562.     } else if (ret == 1) {

  1563.         RTMPPacket rpkt = { 0 };

  1564. 

  1565.         if ((ret = ff_rtmp_packet_read_internal(rt->stream, &rpkt,

  1566.                                                 rt->chunk_size,

  1567.                                                 rt->prev_pkt[0], c)) <= 0)

  1568.              return ret;

  1569. 

  1570.         if ((ret = rtmp_parse_result(s, rt, &rpkt)) < 0)

  1571.             return ret;

  1572. 

  1573.         ff_rtmp_packet_destroy(&rpkt);

  1574.     }

  1575. 

  1576.     return size;

  1577. }

  1578. 

  1579. #define OFFSET(x) offsetof(RTMPContext, x)

  1580. #define DEC AV_OPT_FLAG_DECODING_PARAM

  1581. #define ENC AV_OPT_FLAG_ENCODING_PARAM

  1582. 

  1583. static const AVOption rtmp_options[] = {

  1584.     {"rtmp_app", "Name of application to connect to on the RTMP server", OFFSET(app), AV_OPT_TYPE_STRING, {.str = NULL }, 0, 0, DEC|ENC},

  1585.     {"rtmp_buffer", "Set buffer time in milliseconds. The default is 3000.", OFFSET(client_buffer_time), AV_OPT_TYPE_INT, {3000}, 0, INT_MAX, DEC|ENC},

  1586.     {"rtmp_conn", "Append arbitrary AMF data to the Connect message", OFFSET(conn), AV_OPT_TYPE_STRING, {.str = NULL }, 0, 0, DEC|ENC},

  1587.     {"rtmp_flashver", "Version of the Flash plugin used to run the SWF player.", OFFSET(flashver), AV_OPT_TYPE_STRING, {.str = NULL }, 0, 0, DEC|ENC},

  1588.     {"rtmp_flush_interval", "Number of packets flushed in the same request (RTMPT only).", OFFSET(flush_interval), AV_OPT_TYPE_INT, {10}, 0, INT_MAX, ENC},

  1589.     {"rtmp_live", "Specify that the media is a live stream.", OFFSET(live), AV_OPT_TYPE_INT, {-2}, INT_MIN, INT_MAX, DEC, "rtmp_live"},

  1590.     {"any", "both", 0, AV_OPT_TYPE_CONST, {-2}, 0, 0, DEC, "rtmp_live"},

  1591.     {"live", "live stream", 0, AV_OPT_TYPE_CONST, {-1}, 0, 0, DEC, "rtmp_live"},

  1592.     {"recorded", "recorded stream", 0, AV_OPT_TYPE_CONST, {0}, 0, 0, DEC, "rtmp_live"},

  1593.     {"rtmp_pageurl", "URL of the web page in which the media was embedded. By default no value will be sent.", OFFSET(pageurl), AV_OPT_TYPE_STRING, {.str = NULL }, 0, 0, DEC},

  1594.     {"rtmp_playpath", "Stream identifier to play or to publish", OFFSET(playpath), AV_OPT_TYPE_STRING, {.str = NULL }, 0, 0, DEC|ENC},

  1595.     {"rtmp_swfurl", "URL of the SWF player. By default no value will be sent", OFFSET(swfurl), AV_OPT_TYPE_STRING, {.str = NULL }, 0, 0, DEC|ENC},

  1596.     {"rtmp_tcurl", "URL of the target stream. Defaults to proto://host[:port]/app.", OFFSET(tcurl), AV_OPT_TYPE_STRING, {.str = NULL }, 0, 0, DEC|ENC},

  1597.     { NULL },

  1598. };

  1599. 

  1600. static const AVClass rtmp_class = {

  1601.     .class_name = "rtmp",

  1602.     .item_name  = av_default_item_name,

  1603.     .option     = rtmp_options,

  1604.     .version    = LIBAVUTIL_VERSION_INT,

  1605. };

  1606. 

  1607. URLProtocol ff_rtmp_protocol = {

  1608.     .name           = "rtmp",

  1609.     .url_open       = rtmp_open,

  1610.     .url_read       = rtmp_read,

  1611.     .url_write      = rtmp_write,

  1612.     .url_close      = rtmp_close,

  1613.     .priv_data_size = sizeof(RTMPContext),

  1614.     .flags          = URL_PROTOCOL_FLAG_NETWORK,

  1615.     .priv_data_class= &rtmp_class,

  1616. };

  1617. 

  1618. static const AVClass rtmpe_class = {

  1619.     .class_name = "rtmpe",

  1620.     .item_name  = av_default_item_name,

  1621.     .option     = rtmp_options,

  1622.     .version    = LIBAVUTIL_VERSION_INT,

  1623. };

  1624. 

  1625. URLProtocol ff_rtmpe_protocol = {

  1626.     .name            = "rtmpe",

  1627.     .url_open        = rtmp_open,

  1628.     .url_read        = rtmp_read,

  1629.     .url_write       = rtmp_write,

  1630.     .url_close       = rtmp_close,

  1631.     .priv_data_size  = sizeof(RTMPContext),

  1632.     .flags           = URL_PROTOCOL_FLAG_NETWORK,

  1633.     .priv_data_class = &rtmpe_class,

  1634. };

  1635. 

  1636. static const AVClass rtmps_class = {

  1637.     .class_name = "rtmps",

  1638.     .item_name  = av_default_item_name,

  1639.     .option     = rtmp_options,

  1640.     .version    = LIBAVUTIL_VERSION_INT,

  1641. };

  1642. 

  1643. URLProtocol ff_rtmps_protocol = {

  1644.     .name            = "rtmps",

  1645.     .url_open        = rtmp_open,

  1646.     .url_read        = rtmp_read,

  1647.     .url_write       = rtmp_write,

  1648.     .url_close       = rtmp_close,

  1649.     .priv_data_size  = sizeof(RTMPContext),

  1650.     .flags           = URL_PROTOCOL_FLAG_NETWORK,

  1651.     .priv_data_class = &rtmps_class,

  1652. };

  1653. 

  1654. static const AVClass rtmpt_class = {

  1655.     .class_name = "rtmpt",

  1656.     .item_name  = av_default_item_name,

  1657.     .option     = rtmp_options,

  1658.     .version    = LIBAVUTIL_VERSION_INT,

  1659. };

  1660. 

  1661. URLProtocol ff_rtmpt_protocol = {

  1662.     .name            = "rtmpt",

  1663.     .url_open        = rtmp_open,

  1664.     .url_read        = rtmp_read,

  1665.     .url_write       = rtmp_write,

  1666.     .url_close       = rtmp_close,

  1667.     .priv_data_size  = sizeof(RTMPContext),

  1668.     .flags           = URL_PROTOCOL_FLAG_NETWORK,

  1669.     .priv_data_class = &rtmpt_class,

  1670. };

  1671. 

  1672. static const AVClass rtmpte_class = {

  1673.     .class_name = "rtmpte",

  1674.     .item_name  = av_default_item_name,

  1675.     .option     = rtmp_options,

  1676.     .version    = LIBAVUTIL_VERSION_INT,

  1677. };

  1678. 

  1679. URLProtocol ff_rtmpte_protocol = {

  1680.     .name            = "rtmpte",

  1681.     .url_open        = rtmp_open,

  1682.     .url_read        = rtmp_read,

  1683.     .url_write       = rtmp_write,

  1684.     .url_close       = rtmp_close,

  1685.     .priv_data_size  = sizeof(RTMPContext),

  1686.     .flags           = URL_PROTOCOL_FLAG_NETWORK,

  1687.     .priv_data_class = &rtmpte_class,

  1688. };

  1689. 

  1690. static const AVClass rtmpts_class = {

  1691.     .class_name = "rtmpts",

  1692.     .item_name  = av_default_item_name,

  1693.     .option     = rtmp_options,

  1694.     .version    = LIBAVUTIL_VERSION_INT,

  1695. };

  1696. 

  1697. URLProtocol ff_rtmpts_protocol = {

  1698.     .name            = "rtmpts",

  1699.     .url_open        = rtmp_open,

  1700.     .url_read        = rtmp_read,

  1701.     .url_write       = rtmp_write,

  1702.     .url_close       = rtmp_close,

  1703.     .priv_data_size  = sizeof(RTMPContext),

  1704.     .flags           = URL_PROTOCOL_FLAG_NETWORK,

  1705.     .priv_data_class = &rtmpts_class,

  1706. };