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GB28181: fix parse rtp-tcp failed (#2378)

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* fix parse rtp-tcp failed

* fix parse rtp-tcp failed

Co-authored-by: cfw <fangwei.cheng@transwarp.io>
This commit is contained in:
cfw11 2021-05-28 21:19:05 +08:00 committed by winlin
parent f270d42849
commit 3e7536c493
4 changed files with 71 additions and 442 deletions
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2
.gitignore vendored
View file

@ -34,3 +34,5 @@
.idea
.DS_Store
/cmake-build-debug/
/CMakeLists.txt

7
trunk/conf/push.gb28181.conf
View file

@ -33,8 +33,8 @@ stream_caster {
# 接收设备端rtp流的多路复用端口
listen 9000;
# 多路复用端口类型on为tcpoff为udp
# 默认off
tcp_enable off;
# 默认on
tcp_enable on;
# rtp接收监听端口范围最小值
rtp_port_min 58200;
@ -64,7 +64,8 @@ stream_caster {
# 是否开启rtp缓冲
# 开启之后能有效解决rtp乱序等问题
jitterbuffer_enable on;
# tcp模式建议关闭
jitterbuffer_enable off;
# 服务器主机号可以域名或ip地址
# 也就是设备端将媒体发送的地址,如果是服务器是内外网

426
trunk/src/app/srs_app_gb28181.cpp
View file

@ -202,6 +202,11 @@ srs_error_t SrsGb28181PsRtpProcessor::on_udp_packet(const sockaddr* from, const
return on_rtp_packet(from, fromlen, buf, nb_buf);
}
}
srs_error_t SrsGb28181PsRtpProcessor::on_tcp_packet(const sockaddr* from, const int fromlen, char* buf, int nb_buf)
{
on_udp_packet(from, fromlen, buf, nb_buf);
}
srs_error_t SrsGb28181PsRtpProcessor::on_rtp_packet(const sockaddr* from, const int fromlen, char* buf, int nb_buf)
{
@ -460,334 +465,6 @@ srs_error_t SrsGb28181PsRtpProcessor::on_rtp_packet_jitter(const sockaddr* from,
return err;
}
//SrsGb28181TcpPsRtpProcessor
SrsGb28181TcpPsRtpProcessor::SrsGb28181TcpPsRtpProcessor(SrsGb28181Config* c, std::string id)
{
config = c;
pprint = SrsPithyPrint::create_caster();
channel_id = id;
}
SrsGb28181TcpPsRtpProcessor::~SrsGb28181TcpPsRtpProcessor()
{
dispose();
srs_freep(pprint);
}
void SrsGb28181TcpPsRtpProcessor::dispose()
{
map<std::string, SrsPsRtpPacket*>::iterator it2;
for (it2 = cache_ps_rtp_packet.begin(); it2 != cache_ps_rtp_packet.end(); ++it2) {
srs_freep(it2->second);
}
cache_ps_rtp_packet.clear();
clear_pre_packet();
return;
}
void SrsGb28181TcpPsRtpProcessor::clear_pre_packet()
{
map<std::string, SrsPsRtpPacket*>::iterator it;
for (it = pre_packet.begin(); it != pre_packet.end(); ++it) {
srs_freep(it->second);
}
pre_packet.clear();
}
srs_error_t SrsGb28181TcpPsRtpProcessor::on_rtp(char* buf, int nb_buf, std::string ip, int port)
{
srs_error_t err = srs_success;
if (config->jitterbuffer_enable) {
err = on_rtp_packet_jitter(buf, nb_buf, ip, port);
if (err != srs_success) {
srs_warn("SrsGb28181TcpPsRtpProcessor::on_rtp on_rtp_packet_jitter err");
}
}
else {
return on_rtp_packet(buf, nb_buf, ip, port);
}
return err;
}
srs_error_t SrsGb28181TcpPsRtpProcessor::on_rtp_packet(char* buf, int nb_buf, std::string ip, int port)
{
srs_error_t err = srs_success;
bool completed = false;
pprint->elapse();
char address_string[64] = {0};
char port_string[16] = {0};
/*if (getnameinfo(from, fromlen,
(char*)&address_string, sizeof(address_string),
(char*)&port_string, sizeof(port_string),
NI_NUMERICHOST | NI_NUMERICSERV)) {
return srs_error_new(ERROR_SYSTEM_IP_INVALID, "bad address");
}*/
//itoa(port, port_string, 10);
int peer_port = port;// atoi(port_string);
if (true) {
SrsBuffer stream(buf, nb_buf);
SrsPsRtpPacket pkt;
if ((err = pkt.decode(&stream)) != srs_success) {
return srs_error_wrap(err, "ps rtp decode error");
}
//TODO: fixme: the same device uses the same SSRC to send with different local ports
std::stringstream ss;
ss << pkt.ssrc << ":" << pkt.timestamp << ":" << port;// port_string;
std::string pkt_key = ss.str();
std::stringstream ss2;
ss2 << pkt.ssrc << ":" << port_string;
std::string pre_pkt_key = ss2.str();
if (pre_packet.find(pre_pkt_key) == pre_packet.end()) {
pre_packet[pre_pkt_key] = new SrsPsRtpPacket();
pre_packet[pre_pkt_key]->copy(&pkt);
}
//cache pkt by ssrc and timestamp
if (cache_ps_rtp_packet.find(pkt_key) == cache_ps_rtp_packet.end()) {
cache_ps_rtp_packet[pkt_key] = new SrsPsRtpPacket();
}
//get previous timestamp by ssrc
uint32_t pre_timestamp = pre_packet[pre_pkt_key]->timestamp;
uint32_t pre_sequence_number = pre_packet[pre_pkt_key]->sequence_number;
//TODO: check sequence number out of order
//it may be out of order, or multiple streaming ssrc are the same
if (((pre_sequence_number + 1) % 65536) != pkt.sequence_number &&
pre_sequence_number != pkt.sequence_number) {
srs_warn("gb28181: ps sequence_number out of order, ssrc=%#x, pre=%u, cur=%u, peer(%s, %s)",
pkt.ssrc, pre_sequence_number, pkt.sequence_number, ip.c_str(), port_string);
//return err;
}
//copy header to cache
cache_ps_rtp_packet[pkt_key]->copy(&pkt);
//accumulate one frame of data, to payload cache
cache_ps_rtp_packet[pkt_key]->payload->append(pkt.payload);
//detect whether it is a completed frame
if (pkt.marker) {// rtp maker is true, is a completed frame
completed = true;
}
else if (pre_timestamp != pkt.timestamp) {
//current timestamp is different from previous timestamp
//previous timestamp, is a completed frame
std::stringstream ss;
ss << pkt.ssrc << ":" << pre_timestamp << ":" << port_string;
pkt_key = ss.str();
if (cache_ps_rtp_packet.find(pkt_key) != cache_ps_rtp_packet.end()) {
completed = true;
}
}
if (pprint->can_print()) {
srs_trace("<- " SRS_CONSTS_LOG_GB28181_CASTER " gb28181: client_id %s, peer(%s, %d) ps rtp packet %dB, age=%d, vt=%d/%u, sts=%u/%u/%#x, paylod=%dB",
channel_id.c_str(), ip.c_str(), peer_port, nb_buf, pprint->age(), pkt.version,
pkt.payload_type, pkt.sequence_number, pkt.timestamp, pkt.ssrc,
pkt.payload->length()
);
}
//current packet becomes previous packet
srs_freep(pre_packet[pre_pkt_key]);
pre_packet[pre_pkt_key] = new SrsPsRtpPacket();
pre_packet[pre_pkt_key]->copy(&pkt);;
if (!completed) {
return err;
}
//process completed frame data
//clear processed one ps frame
//on completed frame data rtp packet in muxer enqueue
map<std::string, SrsPsRtpPacket*>::iterator key = cache_ps_rtp_packet.find(pkt_key);
if (key != cache_ps_rtp_packet.end())
{
SrsGb28181RtmpMuxer* muxer = NULL;
//First, search according to the channel_id. Otherwise, search according to the SSRC.
//Some channel_id are created by RTP pool, which are different ports.
//No channel_id are created by multiplexing ports, which are the same port
if (!channel_id.empty()) {
muxer = _srs_gb28181->fetch_rtmpmuxer(channel_id);
}
else {
muxer = _srs_gb28181->fetch_rtmpmuxer_by_ssrc(pkt.ssrc);
}
//auto crate channel
if (!muxer && config->auto_create_channel) {
//auto create channel generated id
std::stringstream ss, ss1;
ss << "chid" << pkt.ssrc;
std::string tmp_id = ss.str();
SrsGb28181StreamChannel channel;
channel.set_channel_id(tmp_id);
channel.set_port_mode(RTP_PORT_MODE_FIXED);
channel.set_ssrc(pkt.ssrc);
srs_error_t err2 = srs_success;
if ((err2 = _srs_gb28181->create_stream_channel(&channel)) != srs_success) {
srs_warn("gb28181: RtpProcessor create stream channel error %s", srs_error_desc(err2).c_str());
srs_error_reset(err2);
};
muxer = _srs_gb28181->fetch_rtmpmuxer(tmp_id);
}
if (muxer) {
//TODO: fixme: the same device uses the same SSRC to send with different local ports
//record the first peer port
muxer->set_channel_peer_port(peer_port);
muxer->set_channel_peer_ip(address_string);
//not the first peer port's non processing
if (muxer->channel_peer_port() != peer_port) {
srs_warn("<- " SRS_CONSTS_LOG_GB28181_CASTER " gb28181: client_id %s, ssrc=%#x, first peer_port=%d cur peer_port=%d",
muxer->get_channel_id().c_str(), pkt.ssrc, muxer->channel_peer_port(), peer_port);
srs_freep(key->second);
}
else {
//put it in queue, wait for consumer to process, and then free
muxer->ps_packet_enqueue(key->second);
}
}
else {
//no consumer process it, discarded
srs_freep(key->second);
}
cache_ps_rtp_packet.erase(pkt_key);
}
}
return err;
}
SrsGb28181RtmpMuxer* SrsGb28181TcpPsRtpProcessor::create_rtmpmuxer(std::string channel_id, uint32_t ssrc)
{
if (true) {
SrsGb28181RtmpMuxer* muxer = NULL;
//First, search according to the channel_id. Otherwise, search according to the SSRC.
//Some channel_id are created by RTP pool, which are different ports.
//No channel_id are created by multiplexing ports, which are the same port
if (!channel_id.empty()) {
muxer = _srs_gb28181->fetch_rtmpmuxer(channel_id);
}
else {
muxer = _srs_gb28181->fetch_rtmpmuxer_by_ssrc(ssrc);
}
//auto crate channel
if (!muxer && config->auto_create_channel) {
//auto create channel generated id
std::stringstream ss, ss1;
ss << "chid" << ssrc;
std::string tmp_id = ss.str();
SrsGb28181StreamChannel channel;
channel.set_channel_id(tmp_id);
channel.set_port_mode(RTP_PORT_MODE_FIXED);
channel.set_ssrc(ssrc);
srs_error_t err2 = srs_success;
if ((err2 = _srs_gb28181->create_stream_channel(&channel)) != srs_success) {
srs_warn("gb28181: RtpProcessor create stream channel error %s", srs_error_desc(err2).c_str());
srs_error_reset(err2);
};
muxer = _srs_gb28181->fetch_rtmpmuxer(tmp_id);
}
return muxer;
}//end if FoundFrame
}
srs_error_t SrsGb28181TcpPsRtpProcessor::rtmpmuxer_enqueue_data(SrsGb28181RtmpMuxer *muxer, uint32_t ssrc,
int peer_port, std::string address_string, SrsPsRtpPacket *pkt)
{
srs_error_t err = srs_success;
if (!muxer)
return err;
if (muxer) {
//TODO: fixme: the same device uses the same SSRC to send with different local ports
//record the first peer port
muxer->set_channel_peer_port(peer_port);
muxer->set_channel_peer_ip(address_string);
//not the first peer port's non processing
if (muxer->channel_peer_port() != peer_port) {
srs_warn("<- " SRS_CONSTS_LOG_GB28181_CASTER " gb28181: client_id %s, ssrc=%#x, first peer_port=%d cur peer_port=%d",
muxer->get_channel_id().c_str(), ssrc, muxer->channel_peer_port(), peer_port);
}
else {
//muxer->ps_packet_enqueue(pkt);
muxer->insert_jitterbuffer(pkt);
}//end if (muxer->channel_peer_port() != peer_port)
}//end if (muxer)
return err;
}
srs_error_t SrsGb28181TcpPsRtpProcessor::on_rtp_packet_jitter(char* buf, int nb_buf, std::string ip, int port)
{
srs_error_t err = srs_success;
pprint->elapse();
char address_string[64] = {0};
/*char port_string[16] = {0};
if (getnameinfo(from, fromlen,
(char*)&address_string, sizeof(address_string),
(char*)&port_string, sizeof(port_string),
NI_NUMERICHOST | NI_NUMERICSERV)) {
return srs_error_new(ERROR_SYSTEM_IP_INVALID, "bad address");
}*/
//itoa(port, port_string, 10);
int peer_port = port;// atoi(port_string);
if (true) {
SrsBuffer stream(buf, nb_buf);
SrsPsRtpPacket *pkt = new SrsPsRtpPacket();;
if ((err = pkt->decode(&stream)) != srs_success) {
srs_freep(pkt);
return srs_error_wrap(err, "ps rtp decode error");
}
std::stringstream ss3;
ss3 << pkt->ssrc << ":" << port;// port_string;
std::string jitter_key = ss3.str();
pkt->completed = pkt->marker;
if (pprint->can_print()) {
srs_trace("<- " SRS_CONSTS_LOG_GB28181_CASTER " SrsGb28181TcpPsRtpProcessor::on_rtp_packet_jitter gb28181: client_id %s, peer(%s, %d) ps rtp packet %dB, age=%d, vt=%d/%u, sts=%u/%u/%#x, paylod=%dB",
channel_id.c_str(), address_string, peer_port, nb_buf, pprint->age(), pkt->version,
pkt->payload_type, pkt->sequence_number, pkt->timestamp, pkt->ssrc,
pkt->payload->length()
);
}
SrsGb28181RtmpMuxer *muxer = create_rtmpmuxer(channel_id, pkt->ssrc);
if (muxer) {
rtmpmuxer_enqueue_data(muxer, pkt->ssrc, peer_port, ip, pkt);
}
SrsAutoFree(SrsPsRtpPacket, pkt);
}
return err;
}
//ISrsPsStreamHander ps stream raw video/audio hander interface
ISrsPsStreamHander::ISrsPsStreamHander()
@ -2830,9 +2507,10 @@ srs_error_t SrsGb28181Manger::query_device_list(std::string id, SrsJsonArray* ar
return sip_service->query_device_list(id, arr);
}
#define SRS_RTSP_BUFFER 262144
SrsGb28181Conn::SrsGb28181Conn(SrsGb28181Caster* c, srs_netfd_t fd, SrsGb28181TcpPsRtpProcessor *rtp_processor)
#define SRS_RTSP_BUFFER 8192
#define RTP_TCP_HEADER 2
#define MAX_PACKAGE_SIZE 1024 * 10
SrsGb28181Conn::SrsGb28181Conn(SrsGb28181Caster* c, srs_netfd_t fd, SrsGb28181PsRtpProcessor *rtp_processor)
{
caster = c;
stfd = fd;
@ -2881,85 +2559,59 @@ srs_error_t SrsGb28181Conn::do_cycle()
int fd = srs_netfd_fileno(stfd);
std::string ip = srs_get_peer_ip(fd);
int port = srs_get_peer_port(fd);
int addr_len = sizeof(sockaddr_in);
sockaddr_in *peer_sockaddr = (sockaddr_in*)malloc(addr_len);
peer_sockaddr->sin_family = AF_INET; //设置地址家族
peer_sockaddr->sin_port = htons(port); //设置端口
peer_sockaddr->sin_addr.s_addr = inet_addr(ip.c_str());
if (ip.empty() && !_srs_config->empty_ip_ok()) {
srs_warn("empty ip for fd=%d", srs_netfd_fileno(stfd));
}
srs_trace("rtsp: serve %s:%d", ip.c_str(), port);
srs_trace("gb28181 new connect by rtp-tcp from: %s:%d", ip.c_str(), port);
char* leftData = (char*)malloc(SRS_RTSP_BUFFER);;
uint32_t leftDataLength = 0;
int16_t length = 0;
char* pp = (char*)&length;
char* p = &(mbuffer[0]);
uint32_t left_data_len = 0; //缓存剩余数据
ssize_t nb_read = 0;
int16_t length2;
uint16_t packet_len = 0; //rtp包长度
// consume all rtp data.
while (true) {
if ((err = trd->pull()) != srs_success) {
free(leftData);
return srs_error_wrap(err, "rtsp cycle");
}
//memset(buffer, 0, SRS_RTSP_BUFFER);
nb_read = 0;
if ((err = skt->read(mbuffer + leftDataLength, SRS_RTSP_BUFFER - leftDataLength, &nb_read)) != srs_success) {
free(leftData);
if ((err = skt->read(mbuffer + left_data_len, SRS_RTSP_BUFFER - left_data_len, &nb_read)) != srs_success) {
return srs_error_wrap(err, "recv data");
}
nb_read = nb_read + leftDataLength;
left_data_len = nb_read + left_data_len;
char * buf = mbuffer;
pp = (char*)&length;
p = &(mbuffer[0]);
pp[1] = *p++;
pp[0] = *p++;
if (nb_read < (length + 2)) {//Not enough one packet.
leftDataLength = leftDataLength + nb_read;
continue;
}
memset(leftData, 0, SRS_RTSP_BUFFER);
while (length > 0) {
if ((length + 2) == nb_read) {//Only one packet.
nb_read = nb_read - 2;
processor->on_rtp(mbuffer + 2, nb_read, ip, port);
leftDataLength = 0;
uint32_t index = 0;
for( ; index < left_data_len; ){
if (index + RTP_TCP_HEADER >= left_data_len){ //less rtp package
break;
}
else { //multi packets.
pp = (char*)&length2;
p = &(mbuffer[length + 2]);
pp[1] = *p++;
pp[0] = *p++;
processor->on_rtp(mbuffer + 2, length, ip, port);
leftDataLength = nb_read - (length + 2);
nb_read = leftDataLength;
memcpy(leftData, mbuffer + length + 2, leftDataLength);
pp = (char*)&length;
p = &(mbuffer[length + 2]);
pp[1] = *p++;
pp[0] = *p++;
if (leftDataLength < (length + 2)) {//Not enough one packet.
memcpy(mbuffer, leftData, leftDataLength);
packet_len = (((uint8_t *) buf)[index] << 8) | ((uint8_t *) buf)[index + 1];
if (packet_len > MAX_PACKAGE_SIZE){
//FIXME 自动重新invite?
srs_error("abnormal RTP packet length:%d, close the tcp conn:%s", packet_len, remote_ip().c_str());
return err;
}
if (index + RTP_TCP_HEADER + packet_len >= left_data_len){
break;
}
else {
memcpy(mbuffer, leftData, leftDataLength);
}
}
processor->on_tcp_packet((sockaddr*)peer_sockaddr, addr_len, buf + index + RTP_TCP_HEADER, packet_len);
index = index + RTP_TCP_HEADER + packet_len;
}
if (index != 0) { //update left data
left_data_len = left_data_len - index;
memmove(mbuffer, buf + index, left_data_len);
}
free(leftData);
}
free(peer_sockaddr);
return err;
}
@ -2996,7 +2648,7 @@ SrsGb28181Caster::SrsGb28181Caster(SrsConfDirective* c)
// TODO: FIXME: support reload.
output = _srs_config->get_stream_caster_output(c);
config = new SrsGb28181Config(c);
rtp_processor = new SrsGb28181TcpPsRtpProcessor(config, "");
rtp_processor = new SrsGb28181PsRtpProcessor(config, "");
manager = new SrsResourceManager("GB28181TCP", true);
}

34
trunk/src/app/srs_app_gb28181.hpp
View file

@ -94,7 +94,6 @@ class SrsSipRequest;
class SrsGb28181RtmpMuxer;
class SrsGb28181Config;
class SrsGb28181PsRtpProcessor;
class SrsGb28181TcpPsRtpProcessor;
class SrsGb28181SipService;
class SrsGb28181StreamChannel;
class SrsGb28181SipSession;
@ -176,37 +175,12 @@ private:
// Interface ISrsUdpHandler
public:
virtual srs_error_t on_udp_packet(const sockaddr* from, const int fromlen, char* buf, int nb_buf);
virtual srs_error_t on_tcp_packet(const sockaddr* from, const int fromlen, char* buf, int nb_buf);
public:
virtual srs_error_t on_rtp_packet_jitter(const sockaddr* from, const int fromlen, char* buf, int nb_buf);
virtual srs_error_t on_rtp_packet(const sockaddr* from, const int fromlen, char* buf, int nb_buf);
};
class SrsGb28181TcpPsRtpProcessor
{
private:
SrsPithyPrint* pprint;
SrsGb28181Config* config;
std::map<std::string, SrsPsRtpPacket*> cache_ps_rtp_packet;
std::map<std::string, SrsPsRtpPacket*> pre_packet;
std::string channel_id;
bool auto_create_channel;
public:
SrsGb28181TcpPsRtpProcessor(SrsGb28181Config* c, std::string sid);
virtual ~SrsGb28181TcpPsRtpProcessor();
private:
bool can_send_ps_av_packet();
void dispose();
void clear_pre_packet();
SrsGb28181RtmpMuxer* create_rtmpmuxer(std::string channel_id, uint32_t ssrc);
srs_error_t rtmpmuxer_enqueue_data(SrsGb28181RtmpMuxer *muxer, uint32_t ssrc,
int peer_port, std::string address_string, SrsPsRtpPacket *pkt);
// Interface ISrsTcpHandler
public:
virtual srs_error_t on_rtp(char* buf, int nb_buf, std::string ip, int port);
public:
virtual srs_error_t on_rtp_packet_jitter(char* buf, int nb_buf, std::string ip, int port);
virtual srs_error_t on_rtp_packet(char* buf, int nb_buf, std::string ip, int port);
};
//ps stream processing parsing interface
class ISrsPsStreamHander
@ -581,9 +555,9 @@ private:
SrsRtspStack* rtsp;
SrsGb28181Caster* caster;
SrsCoroutine* trd;
SrsGb28181TcpPsRtpProcessor *processor;
SrsGb28181PsRtpProcessor *processor;
public:
SrsGb28181Conn(SrsGb28181Caster* c, srs_netfd_t fd, SrsGb28181TcpPsRtpProcessor *rtp_processor);
SrsGb28181Conn(SrsGb28181Caster* c, srs_netfd_t fd, SrsGb28181PsRtpProcessor *rtp_processor);
virtual ~SrsGb28181Conn();
public:
virtual srs_error_t serve();
@ -603,7 +577,7 @@ class SrsGb28181Caster : public ISrsTcpHandler
private:
std::string output;
SrsGb28181Config *config;
SrsGb28181TcpPsRtpProcessor *rtp_processor;
SrsGb28181PsRtpProcessor *rtp_processor;
private:
std::vector<SrsGb28181Conn*> clients;
SrsResourceManager* manager;