RTMPdump(libRTMP) 源代码分析 10: 处理各种消息(Message)
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RTMPdump(libRTMP) 源代码分析系列文章:
RTMPdump 源代码分析 1: main()函数
RTMPDump (libRTMP) 源代码分析2:解析RTMP地址——RTMP_ParseURL()
RTMPdump (libRTMP) 源代码分析3: AMF编码
RTMPdump (libRTMP) 源代码分析4: 连接第一步——握手 (HandShake)
RTMPdump (libRTMP) 源代码分析5: 建立一个流媒体连接 (NetConnection部分)
RTMPdump (libRTMP) 源代码分析6: 建立一个流媒体连接 (NetStream部分 1)
RTMPdump (libRTMP) 源代码分析7: 建立一个流媒体连接 (NetStream部分 2)
RTMPdump (libRTMP) 源代码分析8: 发送消息 (Message)
RTMPdump (libRTMP) 源代码分析9: 接收消息 (Message) (接收视音频数据)
RTMPdump (libRTMP) 源代码分析10: 处理各种消息 (Message)
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函数调用结构图
RTMPDump (libRTMP)的整体的函数调用结构图如下图所示。
单击查看大图
详细分析
已经连续写了一系列的博客了,其实大部分内容都是去年搞RTMP研究的时候积累的经验,回顾一下过去的知识,其实RTMPdump(libRTMP)主要的功能也都分析的差不多了,现在感觉还需要一些查漏补缺。主要就是它是如何处理各种消息(Message)的这方面还没有研究的特明白,在此需要详细研究一下。
再来看一下RTMPdump(libRTMP)的“灵魂”函数RTMP_ClientPacket(),主要完成了各种消息的处理。
//处理接收到的数据
int
RTMP_ClientPacket(RTMP *r, RTMPPacket *packet)
{
int bHasMediaPacket = 0;
switch (packet->m_packetType)
{
//RTMP消息类型ID=1,设置块大小
case 0x01:
/* chunk size */
//----------------
r->dlg->AppendCInfo("处理收到的数据。消息 Set Chunk Size (typeID=1)。");
//-----------------------------
RTMP_LogPrintf("处理消息 Set Chunk Size (typeID=1)\n");
HandleChangeChunkSize(r, packet);
break;
//RTMP消息类型ID=3,致谢
case 0x03:
/* bytes read report */
RTMP_Log(RTMP_LOGDEBUG, "%s, received: bytes read report", __FUNCTION__);
break;
//RTMP消息类型ID=4,用户控制
case 0x04:
/* ctrl */
//----------------
r->dlg->AppendCInfo("处理收到的数据。消息 User Control (typeID=4)。");
//-----------------------------
RTMP_LogPrintf("处理消息 User Control (typeID=4)\n");
HandleCtrl(r, packet);
break;
//RTMP消息类型ID=5
case 0x05:
/* server bw */
//----------------
r->dlg->AppendCInfo("处理收到的数据。消息 Window Acknowledgement Size (typeID=5)。");
//-----------------------------
RTMP_LogPrintf("处理消息 Window Acknowledgement Size (typeID=5)\n");
HandleServerBW(r, packet);
break;
//RTMP消息类型ID=6
case 0x06:
/* client bw */
//----------------
r->dlg->AppendCInfo("处理收到的数据。消息 Set Peer Bandwidth (typeID=6)。");
//-----------------------------
RTMP_LogPrintf("处理消息 Set Peer Bandwidth (typeID=6)\n");
HandleClientBW(r, packet);
break;
//RTMP消息类型ID=8,音频数据
case 0x08:
/* audio data */
/*RTMP_Log(RTMP_LOGDEBUG, "%s, received: audio %lu bytes", __FUNCTION__, packet.m_nBodySize); */
HandleAudio(r, packet);
bHasMediaPacket = 1;
if (!r->m_mediaChannel)
r->m_mediaChannel = packet->m_nChannel;
if (!r->m_pausing)
r->m_mediaStamp = packet->m_nTimeStamp;
break;
//RTMP消息类型ID=9,视频数据
case 0x09:
/* video data */
/*RTMP_Log(RTMP_LOGDEBUG, "%s, received: video %lu bytes", __FUNCTION__, packet.m_nBodySize); */
HandleVideo(r, packet);
bHasMediaPacket = 1;
if (!r->m_mediaChannel)
r->m_mediaChannel = packet->m_nChannel;
if (!r->m_pausing)
r->m_mediaStamp = packet->m_nTimeStamp;
break;
//RTMP消息类型ID=15,AMF3编码,忽略
case 0x0F: /* flex stream send */
RTMP_Log(RTMP_LOGDEBUG,
"%s, flex stream send, size %lu bytes, not supported, ignoring",
__FUNCTION__, packet->m_nBodySize);
break;
//RTMP消息类型ID=16,AMF3编码,忽略
case 0x10: /* flex shared object */
RTMP_Log(RTMP_LOGDEBUG,
"%s, flex shared object, size %lu bytes, not supported, ignoring",
__FUNCTION__, packet->m_nBodySize);
break;
//RTMP消息类型ID=17,AMF3编码,忽略
case 0x11: /* flex message */
{
RTMP_Log(RTMP_LOGDEBUG,
"%s, flex message, size %lu bytes, not fully supported",
__FUNCTION__, packet->m_nBodySize);
/*RTMP_LogHex(packet.m_body, packet.m_nBodySize); */
/* some DEBUG code */
#if 0
RTMP_LIB_AMFObject obj;
int nRes = obj.Decode(packet.m_body+1, packet.m_nBodySize-1);
if(nRes < 0) {
RTMP_Log(RTMP_LOGERROR, "%s, error decoding AMF3 packet", __FUNCTION__);
/*return; */
}
obj.Dump();
#endif
if (HandleInvoke(r, packet->m_body + 1, packet->m_nBodySize - 1) == 1)
bHasMediaPacket = 2;
break;
}
//RTMP消息类型ID=18,AMF0编码,数据消息
case 0x12:
/* metadata (notify) */
RTMP_Log(RTMP_LOGDEBUG, "%s, received: notify %lu bytes", __FUNCTION__,
packet->m_nBodySize);
//处理元数据,暂时注释
/*
if (HandleMetadata(r, packet->m_body, packet->m_nBodySize))
bHasMediaPacket = 1;
break;
*/
//RTMP消息类型ID=19,AMF0编码,忽略
case 0x13:
RTMP_Log(RTMP_LOGDEBUG, "%s, shared object, not supported, ignoring",
__FUNCTION__);
break;
//RTMP消息类型ID=20,AMF0编码,命令消息
//处理命令消息!
case 0x14:
//----------------
r->dlg->AppendCInfo("处理收到的数据。消息 命令 (AMF0编码) (typeID=20)。");
//-----------------------------
/* invoke */
RTMP_Log(RTMP_LOGDEBUG, "%s, received: invoke %lu bytes", __FUNCTION__,
packet->m_nBodySize);
RTMP_LogPrintf("处理命令消息 (typeID=20,AMF0编码)\n");
/*RTMP_LogHex(packet.m_body, packet.m_nBodySize); */
if (HandleInvoke(r, packet->m_body, packet->m_nBodySize) == 1)
bHasMediaPacket = 2;
break;
//RTMP消息类型ID=22
case 0x16:
{
/* go through FLV packets and handle metadata packets */
unsigned int pos = 0;
uint32_t nTimeStamp = packet->m_nTimeStamp;
while (pos + 11 < packet->m_nBodySize)
{
uint32_t dataSize = AMF_DecodeInt24(packet->m_body + pos + 1); /* size without header (11) and prevTagSize (4) */
if (pos + 11 + dataSize + 4 > packet->m_nBodySize)
{
RTMP_Log(RTMP_LOGWARNING, "Stream corrupt?!");
break;
}
if (packet->m_body[pos] == 0x12)
{
HandleMetadata(r, packet->m_body + pos + 11, dataSize);
}
else if (packet->m_body[pos] == 8 || packet->m_body[pos] == 9)
{
nTimeStamp = AMF_DecodeInt24(packet->m_body + pos + 4);
nTimeStamp |= (packet->m_body[pos + 7] << 24);
}
pos += (11 + dataSize + 4);
}
if (!r->m_pausing)
r->m_mediaStamp = nTimeStamp;
/* FLV tag(s) */
/*RTMP_Log(RTMP_LOGDEBUG, "%s, received: FLV tag(s) %lu bytes", __FUNCTION__, packet.m_nBodySize); */
bHasMediaPacket = 1;
break;
}
default:
RTMP_Log(RTMP_LOGDEBUG, "%s, unknown packet type received: 0x%02x", __FUNCTION__,
packet->m_packetType);
#ifdef _DEBUG
RTMP_LogHex(RTMP_LOGDEBUG, (const uint8_t *)packet->m_body, packet->m_nBodySize);
#endif
}
return bHasMediaPacket;
}
前文已经分析过当消息类型ID为0x14(20)的时候,即AMF0编码的命令消息的时候,会调用HandleInvoke()进行处理。
参考:RTMPdump(libRTMP) 源代码分析 7: 建立一个流媒体连接 (NetStream部分 2)
这里就不再对这种类型ID的消息进行分析了,分析一下其他类型的消息,毕竟从发起一个RTMP连接到接收视音频数据这个过程中是要处理很多消息的。
参考:RTMP流媒体播放过程
下面我们按照消息ID从小到大的顺序,看看接收到的各种消息都是如何处理的。
消息类型ID是0x01的消息功能是“设置块(Chunk)大小”,处理函数是HandleChangeChunkSize(),可见函数内容很简单。
static void
HandleChangeChunkSize(RTMP *r, const RTMPPacket *packet)
{
if (packet->m_nBodySize >= 4)
{
r->m_inChunkSize = AMF_DecodeInt32(packet->m_body);
RTMP_Log(RTMP_LOGDEBUG, "%s, received: chunk size change to %d", __FUNCTION__,
r->m_inChunkSize);
}
}
消息类型ID是0x03的消息功能是“致谢”,没有处理函数。
消息类型ID是0x04的消息功能是“用户控制(UserControl)”,处理函数是HandleCtrl(),这类的消息出现的频率非常高,函数体如下所示。具体用户控制消息的作用这里就不多说了,有相应的文档可以参考。
注:该函数中间有一段很长的英文注释,英语好的大神可以看一看
//处理用户控制(UserControl)消息。用户控制消息是服务器端发出的。
static void
HandleCtrl(RTMP *r, const RTMPPacket *packet)
{
short nType = -1;
unsigned int tmp;
if (packet->m_body && packet->m_nBodySize >= 2)
//事件类型(2B)
nType = AMF_DecodeInt16(packet->m_body);
RTMP_Log(RTMP_LOGDEBUG, "%s, received ctrl. type: %d, len: %d", __FUNCTION__, nType,
packet->m_nBodySize);
/*RTMP_LogHex(packet.m_body, packet.m_nBodySize); */
if (packet->m_nBodySize >= 6)
{
//不同事件类型做不同处理
switch (nType)
{
//流开始
case 0:
//流ID
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Stream Begin %d", __FUNCTION__, tmp);
break;
//流结束
case 1:
//流ID
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Stream EOF %d", __FUNCTION__, tmp);
if (r->m_pausing == 1)
r->m_pausing = 2;
break;
//流枯竭
case 2:
//流ID
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Stream Dry %d", __FUNCTION__, tmp);
break;
//是录制流
case 4:
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Stream IsRecorded %d", __FUNCTION__, tmp);
break;
//Ping客户端
case 6: /* server ping. reply with pong. */
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Ping %d", __FUNCTION__, tmp);
RTMP_SendCtrl(r, 0x07, tmp, 0);
break;
/* FMS 3.5 servers send the following two controls to let the client
* know when the server has sent a complete buffer. I.e., when the
* server has sent an amount of data equal to m_nBufferMS in duration.
* The server meters its output so that data arrives at the client
* in realtime and no faster.
*
* The rtmpdump program tries to set m_nBufferMS as large as
* possible, to force the server to send data as fast as possible.
* In practice, the server appears to cap this at about 1 hour's
* worth of data. After the server has sent a complete buffer, and
* sends this BufferEmpty message, it will wait until the play
* duration of that buffer has passed before sending a new buffer.
* The BufferReady message will be sent when the new buffer starts.
* (There is no BufferReady message for the very first buffer;
* presumably the Stream Begin message is sufficient for that
* purpose.)
*
* If the network speed is much faster than the data bitrate, then
* there may be long delays between the end of one buffer and the
* start of the next.
*
* Since usually the network allows data to be sent at
* faster than realtime, and rtmpdump wants to download the data
* as fast as possible, we use this RTMP_LF_BUFX hack: when we
* get the BufferEmpty message, we send a Pause followed by an
* Unpause. This causes the server to send the next buffer immediately
* instead of waiting for the full duration to elapse. (That's
* also the purpose of the ToggleStream function, which rtmpdump
* calls if we get a read timeout.)
*
* Media player apps don't need this hack since they are just
* going to play the data in realtime anyway. It also doesn't work
* for live streams since they obviously can only be sent in
* realtime. And it's all moot if the network speed is actually
* slower than the media bitrate.
*/
case 31:
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Stream BufferEmpty %d", __FUNCTION__, tmp);
if (!(r->Link.lFlags & RTMP_LF_BUFX))
break;
if (!r->m_pausing)
{
r->m_pauseStamp = r->m_channelTimestamp[r->m_mediaChannel];
RTMP_SendPause(r, TRUE, r->m_pauseStamp);
r->m_pausing = 1;
}
else if (r->m_pausing == 2)
{
RTMP_SendPause(r, FALSE, r->m_pauseStamp);
r->m_pausing = 3;
}
break;
case 32:
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Stream BufferReady %d", __FUNCTION__, tmp);
break;
default:
tmp = AMF_DecodeInt32(packet->m_body + 2);
RTMP_Log(RTMP_LOGDEBUG, "%s, Stream xx %d", __FUNCTION__, tmp);
break;
}
}
if (nType == 0x1A)
{
RTMP_Log(RTMP_LOGDEBUG, "%s, SWFVerification ping received: ", __FUNCTION__);
if (packet->m_nBodySize > 2 && packet->m_body[2] > 0x01)
{
RTMP_Log(RTMP_LOGERROR,
"%s: SWFVerification Type %d request not supported! Patches welcome...",
__FUNCTION__, packet->m_body[2]);
}
#ifdef CRYPTO
/*RTMP_LogHex(packet.m_body, packet.m_nBodySize); */
/* respond with HMAC SHA256 of decompressed SWF, key is the 30byte player key, also the last 30 bytes of the server handshake are applied */
else if (r->Link.SWFSize)
{
RTMP_SendCtrl(r, 0x1B, 0, 0);
}
else
{
RTMP_Log(RTMP_LOGERROR,
"%s: Ignoring SWFVerification request, use --swfVfy!",
__FUNCTION__);
}
#else
RTMP_Log(RTMP_LOGERROR,
"%s: Ignoring SWFVerification request, no CRYPTO support!",
__FUNCTION__);
#endif
}
}
消息类型ID是0x05的消息功能是“窗口致谢大小(Window Acknowledgement Size,翻译的真是挺别扭)”,处理函数是HandleServerBW()。在这里注意一下,该消息在Adobe官方公开的文档中叫“Window Acknowledgement Size”,但是在Adobe公开协议规范之前,破解RTMP协议的组织一直管该协议叫“ServerBW”,只是个称呼,倒是也无所谓~处理代码很简单:
static void
HandleServerBW(RTMP *r, const RTMPPacket *packet)
{
r->m_nServerBW = AMF_DecodeInt32(packet->m_body);
RTMP_Log(RTMP_LOGDEBUG, "%s: server BW = %d", __FUNCTION__, r->m_nServerBW);
}
消息类型ID是0x06的消息功能是“设置对等端带宽(Set Peer Bandwidth)”,处理函数是HandleClientBW()。与上一种消息一样,该消息在Adobe官方公开的文档中叫“Set Peer Bandwidth”,但是在Adobe公开协议规范之前,破解RTMP协议的组织一直管该协议叫“ClientBW”。处理函数也不复杂:
static void
HandleClientBW(RTMP *r, const RTMPPacket *packet)
{
r->m_nClientBW = AMF_DecodeInt32(packet->m_body);
if (packet->m_nBodySize > 4)
r->m_nClientBW2 = packet->m_body[4];
else
r->m_nClientBW2 = -1;
RTMP_Log(RTMP_LOGDEBUG, "%s: client BW = %d %d", __FUNCTION__, r->m_nClientBW,
r->m_nClientBW2);
}
消息类型ID是0x08的消息用于传输音频数据,在这里不处理。
消息类型ID是0x09的消息用于传输音频数据,在这里不处理。
消息类型ID是0x0F-11的消息用于传输AMF3编码的命令。
消息类型ID是0x12-14的消息用于传输AMF0编码的命令。
注:消息类型ID是0x14的消息很重要,用于传输AMF0编码的命令,已经做过分析。
rtmpdump源代码(Linux):http://download.csdn.net/detail/leixiaohua1020/6376561
rtmpdump源代码(VC 2005 工程):http://download.csdn.net/detail/leixiaohua1020/6563163