/* This file is a part of JRTPLIB Copyright (c) 1999-2007 Jori Liesenborgs Contact: jori.liesenborgs@gmail.com This library was developed at the "Expertisecentrum Digitale Media" (http://www.edm.uhasselt.be), a research center of the Hasselt University (http://www.uhasselt.be). The library is based upon work done for my thesis at the School for Knowledge Technology (Belgium/The Netherlands). Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "rtpudpv6transmitter.h" #ifdef RTP_SUPPORT_IPV6 #include "rtprawpacket.h" #include "rtpipv6address.h" #include "rtptimeutilities.h" #include "rtpdefines.h" #include #if (defined(WIN32) || defined(_WIN32_WCE)) #define RTPSOCKERR INVALID_SOCKET #define RTPCLOSE(x) closesocket(x) #define RTPSOCKLENTYPE int #define RTPIOCTL ioctlsocket #else // not Win32 #include #include #include #include #include #include #include #include #ifdef RTP_HAVE_SYS_FILIO #include #endif // RTP_HAVE_SYS_FILIO #ifdef RTP_HAVE_SYS_SOCKIO #include #endif // RTP_HAVE_SYS_SOCKIO #ifdef RTP_SUPPORT_IFADDRS #include #endif // RTP_SUPPORT_IFADDRS #define RTPSOCKERR -1 #define RTPCLOSE(x) close(x) #ifdef RTP_SOCKLENTYPE_UINT #define RTPSOCKLENTYPE unsigned int #else #define RTPSOCKLENTYPE int #endif // RTP_SOCKLENTYPE_UINT #define RTPIOCTL ioctl #endif // WIN32 #include "rtpdebug.h" #define RTPUDPV6TRANS_MAXPACKSIZE 65535 #define RTPUDPV6TRANS_IFREQBUFSIZE 8192 #define RTPUDPV6TRANS_IS_MCASTADDR(x) (x.s6_addr[0] == 0xFF) #define RTPUDPV6TRANS_MCASTMEMBERSHIP(socket,type,mcastip,status) {\ struct ipv6_mreq mreq;\ \ mreq.ipv6mr_multiaddr = mcastip;\ mreq.ipv6mr_interface = mcastifidx;\ status = setsockopt(socket,IPPROTO_IPV6,type,(const char *)&mreq,sizeof(struct ipv6_mreq));\ } #ifdef RTP_SUPPORT_THREAD #define MAINMUTEX_LOCK { if (threadsafe) mainmutex.Lock(); } #define MAINMUTEX_UNLOCK { if (threadsafe) mainmutex.Unlock(); } #define WAITMUTEX_LOCK { if (threadsafe) waitmutex.Lock(); } #define WAITMUTEX_UNLOCK { if (threadsafe) waitmutex.Unlock(); } #else #define MAINMUTEX_LOCK #define MAINMUTEX_UNLOCK #define WAITMUTEX_LOCK #define WAITMUTEX_UNLOCK #endif // RTP_SUPPORT_THREAD inline bool operator==(const in6_addr &ip1,const in6_addr &ip2) { if (memcmp(&ip1,&ip2,sizeof(in6_addr)) == 0) return true; return false; } RTPUDPv6Transmitter::RTPUDPv6Transmitter(RTPMemoryManager *mgr) : RTPTransmitter(mgr), destinations(GetMemoryManager(),RTPMEM_TYPE_CLASS_DESTINATIONLISTHASHELEMENT), multicastgroups(GetMemoryManager(),RTPMEM_TYPE_CLASS_MULTICASTHASHELEMENT), acceptignoreinfo(GetMemoryManager(),RTPMEM_TYPE_CLASS_ACCEPTIGNOREHASHELEMENT) { created = false; init = false; #if (defined(WIN32) || defined(_WIN32_WCE)) timeinit.Dummy(); #endif // WIN32 || _WIN32_WCE } RTPUDPv6Transmitter::~RTPUDPv6Transmitter() { Destroy(); } int RTPUDPv6Transmitter::Init(bool tsafe) { if (init) return ERR_RTP_UDPV6TRANS_ALREADYINIT; #ifdef RTP_SUPPORT_THREAD threadsafe = tsafe; if (threadsafe) { int status; status = mainmutex.Init(); if (status < 0) return ERR_RTP_UDPV6TRANS_CANTINITMUTEX; status = waitmutex.Init(); if (status < 0) return ERR_RTP_UDPV6TRANS_CANTINITMUTEX; } #else if (tsafe) return ERR_RTP_NOTHREADSUPPORT; #endif // RTP_SUPPORT_THREAD init = true; return 0; } int RTPUDPv6Transmitter::Create(size_t maximumpacketsize,const RTPTransmissionParams *transparams) { const RTPUDPv6TransmissionParams *params,defaultparams; struct sockaddr_in6 addr; RTPSOCKLENTYPE size; int status; if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_ALREADYCREATED; } // Obtain transmission parameters if (transparams == 0) params = &defaultparams; else { if (transparams->GetTransmissionProtocol() != RTPTransmitter::IPv6UDPProto) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_ILLEGALPARAMETERS; } params = (const RTPUDPv6TransmissionParams *)transparams; } // Check if portbase is even if (params->GetPortbase()%2 != 0) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_PORTBASENOTEVEN; } // create sockets rtpsock = socket(PF_INET6,SOCK_DGRAM,0); if (rtpsock == RTPSOCKERR) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTCREATESOCKET; } rtcpsock = socket(PF_INET6,SOCK_DGRAM,0); if (rtcpsock == RTPSOCKERR) { RTPCLOSE(rtpsock); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTCREATESOCKET; } // set socket buffer sizes size = params->GetRTPReceiveBuffer(); if (setsockopt(rtpsock,SOL_SOCKET,SO_RCVBUF,(const char *)&size,sizeof(int)) != 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTSETRTPRECEIVEBUF; } size = params->GetRTPSendBuffer(); if (setsockopt(rtpsock,SOL_SOCKET,SO_SNDBUF,(const char *)&size,sizeof(int)) != 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTSETRTPTRANSMITBUF; } size = params->GetRTCPReceiveBuffer(); if (setsockopt(rtcpsock,SOL_SOCKET,SO_RCVBUF,(const char *)&size,sizeof(int)) != 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTSETRTCPRECEIVEBUF; } size = params->GetRTCPSendBuffer(); if (setsockopt(rtcpsock,SOL_SOCKET,SO_SNDBUF,(const char *)&size,sizeof(int)) != 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTSETRTCPTRANSMITBUF; } // bind sockets bindIP = params->GetBindIP(); mcastifidx = params->GetMulticastInterfaceIndex(); memset(&addr,0,sizeof(struct sockaddr_in6)); addr.sin6_family = AF_INET6; addr.sin6_port = htons(params->GetPortbase()); addr.sin6_addr = bindIP; if (bind(rtpsock,(struct sockaddr *)&addr,sizeof(struct sockaddr_in6)) != 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTBINDRTPSOCKET; } memset(&addr,0,sizeof(struct sockaddr_in6)); addr.sin6_family = AF_INET6; addr.sin6_port = htons(params->GetPortbase()+1); addr.sin6_addr = bindIP; if (bind(rtcpsock,(struct sockaddr *)&addr,sizeof(struct sockaddr_in6)) != 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_CANTBINDRTCPSOCKET; } // Try to obtain local IP addresses localIPs = params->GetLocalIPList(); if (localIPs.empty()) // User did not provide list of local IP addresses, calculate them { int status; if ((status = CreateLocalIPList()) < 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return status; } #ifdef RTPDEBUG std::cout << "Found these local IP addresses:" << std::endl; std::list::const_iterator it; for (it = localIPs.begin() ; it != localIPs.end() ; it++) { RTPIPv6Address a(*it); std::cout << a.GetAddressString() << std::endl; } #endif // RTPDEBUG } #ifdef RTP_SUPPORT_IPV6MULTICAST if (SetMulticastTTL(params->GetMulticastTTL())) supportsmulticasting = true; else supportsmulticasting = false; #else // no multicast support enabled supportsmulticasting = false; #endif // RTP_SUPPORT_IPV6MULTICAST if ((status = CreateAbortDescriptors()) < 0) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); MAINMUTEX_UNLOCK return status; } if (maximumpacketsize > RTPUDPV6TRANS_MAXPACKSIZE) { RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); DestroyAbortDescriptors(); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_SPECIFIEDSIZETOOBIG; } maxpacksize = maximumpacketsize; portbase = params->GetPortbase(); multicastTTL = params->GetMulticastTTL(); receivemode = RTPTransmitter::AcceptAll; localhostname = 0; localhostnamelength = 0; waitingfordata = false; created = true; MAINMUTEX_UNLOCK return 0; } void RTPUDPv6Transmitter::Destroy() { if (!init) return; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK; return; } if (localhostname) { RTPDeleteByteArray(localhostname,GetMemoryManager()); localhostname = 0; localhostnamelength = 0; } RTPCLOSE(rtpsock); RTPCLOSE(rtcpsock); destinations.Clear(); #ifdef RTP_SUPPORT_IPV6MULTICAST multicastgroups.Clear(); #endif // RTP_SUPPORT_IPV6MULTICAST FlushPackets(); ClearAcceptIgnoreInfo(); localIPs.clear(); created = false; if (waitingfordata) { AbortWaitInternal(); DestroyAbortDescriptors(); MAINMUTEX_UNLOCK WAITMUTEX_LOCK // to make sure that the WaitForIncomingData function ended WAITMUTEX_UNLOCK } else DestroyAbortDescriptors(); MAINMUTEX_UNLOCK } RTPTransmissionInfo *RTPUDPv6Transmitter::GetTransmissionInfo() { if (!init) return 0; MAINMUTEX_LOCK RTPTransmissionInfo *tinf = RTPNew(GetMemoryManager(),RTPMEM_TYPE_CLASS_RTPTRANSMISSIONINFO) RTPUDPv6TransmissionInfo(localIPs,rtpsock,rtcpsock); MAINMUTEX_UNLOCK return tinf; } int RTPUDPv6Transmitter::GetLocalHostName(uint8_t *buffer,size_t *bufferlength) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (localhostname == 0) { if (localIPs.empty()) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOLOCALIPS; } std::list::const_iterator it; std::list hostnames; for (it = localIPs.begin() ; it != localIPs.end() ; it++) { bool founddouble = false; bool foundentry = true; while (!founddouble && foundentry) { struct hostent *he; in6_addr ip = (*it); he = gethostbyaddr((char *)&ip,sizeof(in6_addr),AF_INET6); if (he != 0) { std::string hname = std::string(he->h_name); std::list::const_iterator it; for (it = hostnames.begin() ; !founddouble && it != hostnames.end() ; it++) if ((*it) == hname) founddouble = true; if (!founddouble) hostnames.push_back(hname); int i = 0; while (!founddouble && he->h_aliases[i] != 0) { std::string hname = std::string(he->h_aliases[i]); for (it = hostnames.begin() ; !founddouble && it != hostnames.end() ; it++) if ((*it) == hname) founddouble = true; if (!founddouble) { hostnames.push_back(hname); i++; } } } else foundentry = false; } } bool found = false; if (!hostnames.empty()) // try to select the most appropriate hostname { std::list::const_iterator it; hostnames.sort(); for (it = hostnames.begin() ; !found && it != hostnames.end() ; it++) { if ((*it).find('.') != std::string::npos) { found = true; localhostnamelength = (*it).length(); localhostname = RTPNew(GetMemoryManager(),RTPMEM_TYPE_OTHER) uint8_t [localhostnamelength+1]; if (localhostname == 0) { MAINMUTEX_UNLOCK return ERR_RTP_OUTOFMEM; } memcpy(localhostname,(*it).c_str(),localhostnamelength); localhostname[localhostnamelength] = 0; } } } if (!found) // use an IP address { in6_addr ip; int len; char str[48]; uint16_t ip16[8]; int i,j; it = localIPs.begin(); ip = (*it); for (i = 0,j = 0 ; j < 8 ; j++,i += 2) { ip16[j] = (((uint16_t)ip.s6_addr[i])<<8); ip16[j] |= ((uint16_t)ip.s6_addr[i+1]); } RTP_SNPRINTF(str,48,"%04X:%04X:%04X:%04X:%04X:%04X:%04X:%04X",(int)ip16[0],(int)ip16[1],(int)ip16[2],(int)ip16[3],(int)ip16[4],(int)ip16[5],(int)ip16[6],(int)ip16[7]); len = strlen(str); localhostnamelength = len; localhostname = RTPNew(GetMemoryManager(),RTPMEM_TYPE_OTHER) uint8_t [localhostnamelength+1]; if (localhostname == 0) { MAINMUTEX_UNLOCK return ERR_RTP_OUTOFMEM; } memcpy(localhostname,str,localhostnamelength); localhostname[localhostnamelength] = 0; } } if ((*bufferlength) < localhostnamelength) { *bufferlength = localhostnamelength; // tell the application the required size of the buffer MAINMUTEX_UNLOCK return ERR_RTP_TRANS_BUFFERLENGTHTOOSMALL; } memcpy(buffer,localhostname,localhostnamelength); *bufferlength = localhostnamelength; MAINMUTEX_UNLOCK return 0; } bool RTPUDPv6Transmitter::ComesFromThisTransmitter(const RTPAddress *addr) { if (!init) return false; if (addr == 0) return false; MAINMUTEX_LOCK bool v; if (created && addr->GetAddressType() == RTPAddress::IPv6Address) { const RTPIPv6Address *addr2 = (const RTPIPv6Address *)addr; bool found = false; std::list::const_iterator it; it = localIPs.begin(); while (!found && it != localIPs.end()) { in6_addr itip = *it; in6_addr addrip = addr2->GetIP(); if (memcmp(&addrip,&itip,sizeof(in6_addr)) == 0) found = true; else ++it; } if (!found) v = false; else { if (addr2->GetPort() == portbase) // check for RTP port v = true; else if (addr2->GetPort() == (portbase+1)) // check for RTCP port v = true; else v = false; } } else v = false; MAINMUTEX_UNLOCK return v; } int RTPUDPv6Transmitter::Poll() { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; int status; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } status = PollSocket(true); // poll RTP socket if (status >= 0) status = PollSocket(false); // poll RTCP socket MAINMUTEX_UNLOCK return status; } int RTPUDPv6Transmitter::WaitForIncomingData(const RTPTime &delay,bool *dataavailable) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK fd_set fdset; struct timeval tv; if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (waitingfordata) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_ALREADYWAITING; } FD_ZERO(&fdset); FD_SET(rtpsock,&fdset); FD_SET(rtcpsock,&fdset); FD_SET(abortdesc[0],&fdset); tv.tv_sec = delay.GetSeconds(); tv.tv_usec = delay.GetMicroSeconds(); waitingfordata = true; WAITMUTEX_LOCK MAINMUTEX_UNLOCK if (select(FD_SETSIZE,&fdset,0,0,&tv) < 0) { MAINMUTEX_LOCK waitingfordata = false; MAINMUTEX_UNLOCK WAITMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_ERRORINSELECT; } MAINMUTEX_LOCK waitingfordata = false; if (!created) // destroy called { MAINMUTEX_UNLOCK; WAITMUTEX_UNLOCK return 0; } // if aborted, read from abort buffer if (FD_ISSET(abortdesc[0],&fdset)) { #if (defined(WIN32) || defined(_WIN32_WCE)) char buf[1]; recv(abortdesc[0],buf,1,0); #else unsigned char buf[1]; read(abortdesc[0],buf,1); #endif // WIN32 } if (dataavailable != 0) { if (FD_ISSET(rtpsock,&fdset) || FD_ISSET(rtcpsock,&fdset)) *dataavailable = true; else *dataavailable = false; } MAINMUTEX_UNLOCK WAITMUTEX_UNLOCK return 0; } int RTPUDPv6Transmitter::AbortWait() { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (!waitingfordata) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTWAITING; } AbortWaitInternal(); MAINMUTEX_UNLOCK return 0; } int RTPUDPv6Transmitter::SendRTPData(const void *data,size_t len) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (len > maxpacksize) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_SPECIFIEDSIZETOOBIG; } destinations.GotoFirstElement(); while (destinations.HasCurrentElement()) { sendto(rtpsock,(const char *)data,len,0,(const struct sockaddr *)destinations.GetCurrentElement().GetRTPSockAddr(),sizeof(struct sockaddr_in6)); destinations.GotoNextElement(); } MAINMUTEX_UNLOCK return 0; } int RTPUDPv6Transmitter::SendRTCPData(const void *data,size_t len) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (len > maxpacksize) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_SPECIFIEDSIZETOOBIG; } destinations.GotoFirstElement(); while (destinations.HasCurrentElement()) { sendto(rtcpsock,(const char *)data,len,0,(const struct sockaddr *)destinations.GetCurrentElement().GetRTCPSockAddr(),sizeof(struct sockaddr_in6)); destinations.GotoNextElement(); } MAINMUTEX_UNLOCK return 0; } int RTPUDPv6Transmitter::AddDestination(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } RTPIPv6Address &address = (RTPIPv6Address &)addr; RTPIPv6Destination dest(address.GetIP(),address.GetPort()); int status = destinations.AddElement(dest); MAINMUTEX_UNLOCK return status; } int RTPUDPv6Transmitter::DeleteDestination(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } RTPIPv6Address &address = (RTPIPv6Address &)addr; RTPIPv6Destination dest(address.GetIP(),address.GetPort()); int status = destinations.DeleteElement(dest); MAINMUTEX_UNLOCK return status; } void RTPUDPv6Transmitter::ClearDestinations() { if (!init) return; MAINMUTEX_LOCK if (created) destinations.Clear(); MAINMUTEX_UNLOCK } bool RTPUDPv6Transmitter::SupportsMulticasting() { if (!init) return false; MAINMUTEX_LOCK bool v; if (!created) v = false; else v = supportsmulticasting; MAINMUTEX_UNLOCK return v; } #ifdef RTP_SUPPORT_IPV6MULTICAST int RTPUDPv6Transmitter::JoinMulticastGroup(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK int status; if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } const RTPIPv6Address &address = (const RTPIPv6Address &)addr; in6_addr mcastIP = address.GetIP(); if (!RTPUDPV6TRANS_IS_MCASTADDR(mcastIP)) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTAMULTICASTADDRESS; } status = multicastgroups.AddElement(mcastIP); if (status >= 0) { RTPUDPV6TRANS_MCASTMEMBERSHIP(rtpsock,IPV6_JOIN_GROUP,mcastIP,status); if (status != 0) { multicastgroups.DeleteElement(mcastIP); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_COULDNTJOINMULTICASTGROUP; } RTPUDPV6TRANS_MCASTMEMBERSHIP(rtcpsock,IPV6_JOIN_GROUP,mcastIP,status); if (status != 0) { RTPUDPV6TRANS_MCASTMEMBERSHIP(rtpsock,IPV6_LEAVE_GROUP,mcastIP,status); multicastgroups.DeleteElement(mcastIP); MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_COULDNTJOINMULTICASTGROUP; } } MAINMUTEX_UNLOCK return status; } int RTPUDPv6Transmitter::LeaveMulticastGroup(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK int status; if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } const RTPIPv6Address &address = (const RTPIPv6Address &)addr; in6_addr mcastIP = address.GetIP(); if (!RTPUDPV6TRANS_IS_MCASTADDR(mcastIP)) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTAMULTICASTADDRESS; } status = multicastgroups.DeleteElement(mcastIP); if (status >= 0) { RTPUDPV6TRANS_MCASTMEMBERSHIP(rtpsock,IPV6_LEAVE_GROUP,mcastIP,status); RTPUDPV6TRANS_MCASTMEMBERSHIP(rtcpsock,IPV6_LEAVE_GROUP,mcastIP,status); status = 0; } MAINMUTEX_UNLOCK return status; } void RTPUDPv6Transmitter::LeaveAllMulticastGroups() { if (!init) return; MAINMUTEX_LOCK if (created) { multicastgroups.GotoFirstElement(); while (multicastgroups.HasCurrentElement()) { in6_addr mcastIP; int status = 0; mcastIP = multicastgroups.GetCurrentElement(); RTPUDPV6TRANS_MCASTMEMBERSHIP(rtpsock,IPV6_LEAVE_GROUP,mcastIP,status); RTPUDPV6TRANS_MCASTMEMBERSHIP(rtcpsock,IPV6_LEAVE_GROUP,mcastIP,status); multicastgroups.GotoNextElement(); } multicastgroups.Clear(); } MAINMUTEX_UNLOCK } #else // no multicast support int RTPUDPv6Transmitter::JoinMulticastGroup(const RTPAddress &addr) { return ERR_RTP_UDPV6TRANS_NOMULTICASTSUPPORT; } int RTPUDPv6Transmitter::LeaveMulticastGroup(const RTPAddress &addr) { return ERR_RTP_UDPV6TRANS_NOMULTICASTSUPPORT; } void RTPUDPv6Transmitter::LeaveAllMulticastGroups() { } #endif // RTP_SUPPORT_IPV6MULTICAST int RTPUDPv6Transmitter::SetReceiveMode(RTPTransmitter::ReceiveMode m) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (m != receivemode) { receivemode = m; acceptignoreinfo.Clear(); } MAINMUTEX_UNLOCK return 0; } int RTPUDPv6Transmitter::AddToIgnoreList(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK int status; if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } if (receivemode != RTPTransmitter::IgnoreSome) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_DIFFERENTRECEIVEMODE; } const RTPIPv6Address &address = (const RTPIPv6Address &)addr; status = ProcessAddAcceptIgnoreEntry(address.GetIP(),address.GetPort()); MAINMUTEX_UNLOCK return status; } int RTPUDPv6Transmitter::DeleteFromIgnoreList(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK int status; if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } if (receivemode != RTPTransmitter::IgnoreSome) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_DIFFERENTRECEIVEMODE; } const RTPIPv6Address &address = (const RTPIPv6Address &)addr; status = ProcessDeleteAcceptIgnoreEntry(address.GetIP(),address.GetPort()); MAINMUTEX_UNLOCK return status; } void RTPUDPv6Transmitter::ClearIgnoreList() { if (!init) return; MAINMUTEX_LOCK if (created && receivemode == RTPTransmitter::IgnoreSome) ClearAcceptIgnoreInfo(); MAINMUTEX_UNLOCK } int RTPUDPv6Transmitter::AddToAcceptList(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK int status; if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } if (receivemode != RTPTransmitter::AcceptSome) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_DIFFERENTRECEIVEMODE; } const RTPIPv6Address &address = (const RTPIPv6Address &)addr; status = ProcessAddAcceptIgnoreEntry(address.GetIP(),address.GetPort()); MAINMUTEX_UNLOCK return status; } int RTPUDPv6Transmitter::DeleteFromAcceptList(const RTPAddress &addr) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK int status; if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (addr.GetAddressType() != RTPAddress::IPv6Address) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_INVALIDADDRESSTYPE; } if (receivemode != RTPTransmitter::AcceptSome) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_DIFFERENTRECEIVEMODE; } const RTPIPv6Address &address = (const RTPIPv6Address &)addr; status = ProcessDeleteAcceptIgnoreEntry(address.GetIP(),address.GetPort()); MAINMUTEX_UNLOCK return status; } void RTPUDPv6Transmitter::ClearAcceptList() { if (!init) return; MAINMUTEX_LOCK if (created && receivemode == RTPTransmitter::AcceptSome) ClearAcceptIgnoreInfo(); MAINMUTEX_UNLOCK } int RTPUDPv6Transmitter::SetMaximumPacketSize(size_t s) { if (!init) return ERR_RTP_UDPV6TRANS_NOTINIT; MAINMUTEX_LOCK if (!created) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_NOTCREATED; } if (s > RTPUDPV6TRANS_MAXPACKSIZE) { MAINMUTEX_UNLOCK return ERR_RTP_UDPV6TRANS_SPECIFIEDSIZETOOBIG; } maxpacksize = s; MAINMUTEX_UNLOCK return 0; } bool RTPUDPv6Transmitter::NewDataAvailable() { if (!init) return false; MAINMUTEX_LOCK bool v; if (!created) v = false; else { if (rawpacketlist.empty()) v = false; else v = true; } MAINMUTEX_UNLOCK return v; } RTPRawPacket *RTPUDPv6Transmitter::GetNextPacket() { if (!init) return 0; MAINMUTEX_LOCK RTPRawPacket *p; if (!created) { MAINMUTEX_UNLOCK return 0; } if (rawpacketlist.empty()) { MAINMUTEX_UNLOCK return 0; } p = *(rawpacketlist.begin()); rawpacketlist.pop_front(); MAINMUTEX_UNLOCK return p; } // Here the private functions start... #ifdef RTP_SUPPORT_IPV6MULTICAST bool RTPUDPv6Transmitter::SetMulticastTTL(uint8_t ttl) { int ttl2,status; ttl2 = (int)ttl; status = setsockopt(rtpsock,IPPROTO_IPV6,IPV6_MULTICAST_HOPS,(const char *)&ttl2,sizeof(int)); if (status != 0) return false; status = setsockopt(rtcpsock,IPPROTO_IPV6,IPV6_MULTICAST_HOPS,(const char *)&ttl2,sizeof(int)); if (status != 0) return false; return true; } #endif // RTP_SUPPORT_IPV6MULTICAST void RTPUDPv6Transmitter::FlushPackets() { std::list::const_iterator it; for (it = rawpacketlist.begin() ; it != rawpacketlist.end() ; ++it) RTPDelete(*it,GetMemoryManager()); rawpacketlist.clear(); } int RTPUDPv6Transmitter::PollSocket(bool rtp) { RTPSOCKLENTYPE fromlen; int recvlen; char packetbuffer[RTPUDPV6TRANS_MAXPACKSIZE]; #if (defined(WIN32) || defined(_WIN32_WCE)) SOCKET sock; unsigned long len; #else size_t len; int sock; #endif // WIN32 struct sockaddr_in6 srcaddr; if (rtp) sock = rtpsock; else sock = rtcpsock; len = 0; RTPIOCTL(sock,FIONREAD,&len); if (len <= 0) return 0; while (len > 0) { RTPTime curtime = RTPTime::CurrentTime(); fromlen = sizeof(struct sockaddr_in6); recvlen = recvfrom(sock,packetbuffer,RTPUDPV6TRANS_MAXPACKSIZE,0,(struct sockaddr *)&srcaddr,&fromlen); if (recvlen > 0) { bool acceptdata; // got data, process it if (receivemode == RTPTransmitter::AcceptAll) acceptdata = true; else acceptdata = ShouldAcceptData(srcaddr.sin6_addr,ntohs(srcaddr.sin6_port)); if (acceptdata) { RTPRawPacket *pack; RTPIPv6Address *addr; uint8_t *datacopy; addr = RTPNew(GetMemoryManager(),RTPMEM_TYPE_CLASS_RTPADDRESS) RTPIPv6Address(srcaddr.sin6_addr,ntohs(srcaddr.sin6_port)); if (addr == 0) return ERR_RTP_OUTOFMEM; datacopy = RTPNew(GetMemoryManager(),(rtp)?RTPMEM_TYPE_BUFFER_RECEIVEDRTPPACKET:RTPMEM_TYPE_BUFFER_RECEIVEDRTCPPACKET) uint8_t[recvlen]; if (datacopy == 0) { RTPDelete(addr,GetMemoryManager()); return ERR_RTP_OUTOFMEM; } memcpy(datacopy,packetbuffer,recvlen); pack = RTPNew(GetMemoryManager(),RTPMEM_TYPE_CLASS_RTPRAWPACKET) RTPRawPacket(datacopy,recvlen,addr,curtime,rtp,GetMemoryManager()); if (pack == 0) { RTPDelete(addr,GetMemoryManager()); RTPDeleteByteArray(datacopy,GetMemoryManager()); return ERR_RTP_OUTOFMEM; } rawpacketlist.push_back(pack); } } len = 0; RTPIOCTL(sock,FIONREAD,&len); } return 0; } int RTPUDPv6Transmitter::ProcessAddAcceptIgnoreEntry(in6_addr ip,uint16_t port) { acceptignoreinfo.GotoElement(ip); if (acceptignoreinfo.HasCurrentElement()) // An entry for this IP address already exists { PortInfo *portinf = acceptignoreinfo.GetCurrentElement(); if (port == 0) // select all ports { portinf->all = true; portinf->portlist.clear(); } else if (!portinf->all) { std::list::const_iterator it,begin,end; begin = portinf->portlist.begin(); end = portinf->portlist.end(); for (it = begin ; it != end ; it++) { if (*it == port) // already in list return 0; } portinf->portlist.push_front(port); } } else // got to create an entry for this IP address { PortInfo *portinf; int status; portinf = RTPNew(GetMemoryManager(),RTPMEM_TYPE_CLASS_ACCEPTIGNOREPORTINFO) PortInfo(); if (port == 0) // select all ports portinf->all = true; else portinf->portlist.push_front(port); status = acceptignoreinfo.AddElement(ip,portinf); if (status < 0) { RTPDelete(portinf,GetMemoryManager()); return status; } } return 0; } void RTPUDPv6Transmitter::ClearAcceptIgnoreInfo() { acceptignoreinfo.GotoFirstElement(); while (acceptignoreinfo.HasCurrentElement()) { PortInfo *inf; inf = acceptignoreinfo.GetCurrentElement(); RTPDelete(inf,GetMemoryManager()); acceptignoreinfo.GotoNextElement(); } acceptignoreinfo.Clear(); } int RTPUDPv6Transmitter::ProcessDeleteAcceptIgnoreEntry(in6_addr ip,uint16_t port) { acceptignoreinfo.GotoElement(ip); if (!acceptignoreinfo.HasCurrentElement()) return ERR_RTP_UDPV6TRANS_NOSUCHENTRY; PortInfo *inf; inf = acceptignoreinfo.GetCurrentElement(); if (port == 0) // delete all entries { inf->all = false; inf->portlist.clear(); } else // a specific port was selected { if (inf->all) // currently, all ports are selected. Add the one to remove to the list { // we have to check if the list doesn't contain the port already std::list::const_iterator it,begin,end; begin = inf->portlist.begin(); end = inf->portlist.end(); for (it = begin ; it != end ; it++) { if (*it == port) // already in list: this means we already deleted the entry return ERR_RTP_UDPV6TRANS_NOSUCHENTRY; } inf->portlist.push_front(port); } else // check if we can find the port in the list { std::list::iterator it,begin,end; begin = inf->portlist.begin(); end = inf->portlist.end(); for (it = begin ; it != end ; ++it) { if (*it == port) // found it! { inf->portlist.erase(it); return 0; } } // didn't find it return ERR_RTP_UDPV6TRANS_NOSUCHENTRY; } } return 0; } bool RTPUDPv6Transmitter::ShouldAcceptData(in6_addr srcip,uint16_t srcport) { if (receivemode == RTPTransmitter::AcceptSome) { PortInfo *inf; acceptignoreinfo.GotoElement(srcip); if (!acceptignoreinfo.HasCurrentElement()) return false; inf = acceptignoreinfo.GetCurrentElement(); if (!inf->all) // only accept the ones in the list { std::list::const_iterator it,begin,end; begin = inf->portlist.begin(); end = inf->portlist.end(); for (it = begin ; it != end ; it++) { if (*it == srcport) return true; } return false; } else // accept all, except the ones in the list { std::list::const_iterator it,begin,end; begin = inf->portlist.begin(); end = inf->portlist.end(); for (it = begin ; it != end ; it++) { if (*it == srcport) return false; } return true; } } else // IgnoreSome { PortInfo *inf; acceptignoreinfo.GotoElement(srcip); if (!acceptignoreinfo.HasCurrentElement()) return true; inf = acceptignoreinfo.GetCurrentElement(); if (!inf->all) // ignore the ports in the list { std::list::const_iterator it,begin,end; begin = inf->portlist.begin(); end = inf->portlist.end(); for (it = begin ; it != end ; it++) { if (*it == srcport) return false; } return true; } else // ignore all, except the ones in the list { std::list::const_iterator it,begin,end; begin = inf->portlist.begin(); end = inf->portlist.end(); for (it = begin ; it != end ; it++) { if (*it == srcport) return true; } return false; } } return true; } #if (defined(WIN32) || defined(_WIN32_WCE)) int RTPUDPv6Transmitter::CreateAbortDescriptors() { SOCKET listensock; int size; struct sockaddr_in6 addr; listensock = socket(PF_INET6,SOCK_STREAM,0); if (listensock == RTPSOCKERR) return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; memset(&addr,0,sizeof(struct sockaddr_in6)); addr.sin6_family = AF_INET6; if (bind(listensock,(struct sockaddr *)&addr,sizeof(struct sockaddr_in6)) != 0) { RTPCLOSE(listensock); return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; } memset(&addr,0,sizeof(struct sockaddr_in6)); size = sizeof(struct sockaddr_in6); if (getsockname(listensock,(struct sockaddr*)&addr,&size) != 0) { RTPCLOSE(listensock); return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; } unsigned short connectport = ntohs(addr.sin6_port); abortdesc[0] = socket(PF_INET6,SOCK_STREAM,0); if (abortdesc[0] == RTPSOCKERR) { RTPCLOSE(listensock); return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; } memset(&addr,0,sizeof(struct sockaddr_in6)); addr.sin6_family = AF_INET6; if (bind(abortdesc[0],(struct sockaddr *)&addr,sizeof(struct sockaddr_in6)) != 0) { RTPCLOSE(listensock); RTPCLOSE(abortdesc[0]); return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; } if (listen(listensock,1) != 0) { RTPCLOSE(listensock); RTPCLOSE(abortdesc[0]); return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; } memset(&addr,0,sizeof(struct sockaddr_in6)); addr.sin6_family = AF_INET6; addr.sin6_addr = in6addr_loopback; addr.sin6_port = htons(connectport); if (connect(abortdesc[0],(struct sockaddr *)&addr,sizeof(struct sockaddr_in6)) != 0) { RTPCLOSE(listensock); RTPCLOSE(abortdesc[0]); return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; } memset(&addr,0,sizeof(struct sockaddr_in6)); size = sizeof(struct sockaddr_in6); abortdesc[1] = accept(listensock,(struct sockaddr *)&addr,&size); if (abortdesc[1] == RTPSOCKERR) { RTPCLOSE(listensock); RTPCLOSE(abortdesc[0]); return ERR_RTP_UDPV6TRANS_CANTCREATEABORTDESCRIPTORS; } // okay, got the connection, close the listening socket RTPCLOSE(listensock); return 0; } void RTPUDPv6Transmitter::DestroyAbortDescriptors() { RTPCLOSE(abortdesc[0]); RTPCLOSE(abortdesc[1]); } #else // in a non winsock environment we can use pipes int RTPUDPv6Transmitter::CreateAbortDescriptors() { if (pipe(abortdesc) < 0) return ERR_RTP_UDPV6TRANS_CANTCREATEPIPE; return 0; } void RTPUDPv6Transmitter::DestroyAbortDescriptors() { close(abortdesc[0]); close(abortdesc[1]); } #endif // WIN32 int RTPUDPv6Transmitter::CreateLocalIPList() { // first try to obtain the list from the network interface info if (!GetLocalIPList_Interfaces()) { // If this fails, we'll have to depend on DNS info GetLocalIPList_DNS(); } AddLoopbackAddress(); return 0; } #if (defined(WIN32) || defined(_WIN32_WCE)) bool RTPUDPv6Transmitter::GetLocalIPList_Interfaces() { unsigned char buffer[RTPUDPV6TRANS_IFREQBUFSIZE]; DWORD outputsize; DWORD numaddresses,i; SOCKET_ADDRESS_LIST *addrlist; if (WSAIoctl(rtpsock,SIO_ADDRESS_LIST_QUERY,NULL,0,&buffer,RTPUDPV6TRANS_IFREQBUFSIZE,&outputsize,NULL,NULL)) return false; addrlist = (SOCKET_ADDRESS_LIST *)buffer; numaddresses = addrlist->iAddressCount; for (i = 0 ; i < numaddresses ; i++) { SOCKET_ADDRESS *sockaddr = &(addrlist->Address[i]); if (sockaddr->iSockaddrLength == sizeof(struct sockaddr_in6)) // IPv6 address { struct sockaddr_in6 *addr = (struct sockaddr_in6 *)sockaddr->lpSockaddr; localIPs.push_back(addr->sin6_addr); } } if (localIPs.empty()) return false; return true; } #else #ifdef RTP_SUPPORT_IFADDRS bool RTPUDPv6Transmitter::GetLocalIPList_Interfaces() { struct ifaddrs *addrs,*tmp; getifaddrs(&addrs); tmp = addrs; while (tmp != 0) { if (tmp->ifa_addr != 0 && tmp->ifa_addr->sa_family == AF_INET6) { struct sockaddr_in6 *inaddr = (struct sockaddr_in6 *)tmp->ifa_addr; localIPs.push_back(inaddr->sin6_addr); } tmp = tmp->ifa_next; } freeifaddrs(addrs); if (localIPs.empty()) return false; return true; } #else bool RTPUDPv6Transmitter::GetLocalIPList_Interfaces() { return false; } #endif // RTP_SUPPORT_IFADDRS #endif // WIN32 void RTPUDPv6Transmitter::GetLocalIPList_DNS() { int status; char name[1024]; gethostname(name,1023); name[1023] = 0; struct addrinfo hints; struct addrinfo *res,*tmp; memset(&hints,0,sizeof(struct addrinfo)); hints.ai_family = AF_INET6; hints.ai_socktype = 0; hints.ai_protocol = 0; if ((status = getaddrinfo(name,0,&hints,&res)) != 0) return; tmp = res; while (tmp != 0) { if (tmp->ai_family == AF_INET6) { struct sockaddr_in6 *addr = (struct sockaddr_in6 *)(tmp->ai_addr); localIPs.push_back(addr->sin6_addr); } tmp = tmp->ai_next; } freeaddrinfo(res); } void RTPUDPv6Transmitter::AbortWaitInternal() { #if (defined(WIN32) || defined(_WIN32_WCE)) send(abortdesc[1],"*",1,0); #else write(abortdesc[1],"*",1); #endif // WIN32 } void RTPUDPv6Transmitter::AddLoopbackAddress() { std::list::const_iterator it; bool found = false; for (it = localIPs.begin() ; !found && it != localIPs.end() ; it++) { if ((*it) == in6addr_loopback) found = true; } if (!found) localIPs.push_back(in6addr_loopback); } #ifdef RTPDEBUG void RTPUDPv6Transmitter::Dump() { if (!init) std::cout << "Not initialized" << std::endl; else { MAINMUTEX_LOCK if (!created) std::cout << "Not created" << std::endl; else { char str[48]; in6_addr ip; uint16_t ip16[8]; std::list::const_iterator it; int i,j; std::cout << "Portbase: " << portbase << std::endl; std::cout << "RTP socket descriptor: " << rtpsock << std::endl; std::cout << "RTCP socket descriptor: " << rtcpsock << std::endl; ip = bindIP; for (i = 0,j = 0 ; j < 8 ; j++,i += 2) { ip16[j] = (((uint16_t)ip.s6_addr[i])<<8); ip16[j] |= ((uint16_t)ip.s6_addr[i+1]); } RTP_SNPRINTF(str,48,"%04X:%04X:%04X:%04X:%04X:%04X:%04X:%04X",(int)ip16[0],(int)ip16[1],(int)ip16[2],(int)ip16[3],(int)ip16[4],(int)ip16[5],(int)ip16[6],(int)ip16[7]); std::cout << "Bind IP address: " << str << std::endl; std::Cout << "Multicast interface index: " << mcastifidx << std::endl; std::cout << "Local IP addresses:" << std::endl; for (it = localIPs.begin() ; it != localIPs.end() ; it++) { ip = (*it); for (i = 0,j = 0 ; j < 8 ; j++,i += 2) { ip16[j] = (((uint16_t)ip.s6_addr[i])<<8); ip16[j] |= ((uint16_t)ip.s6_addr[i+1]); } RTP_SNPRINTF(str,48,"%04X:%04X:%04X:%04X:%04X:%04X:%04X:%04X",(int)ip16[0],(int)ip16[1],(int)ip16[2],(int)ip16[3],(int)ip16[4],(int)ip16[5],(int)ip16[6],(int)ip16[7]); std::cout << " " << str << std::endl; } std::cout << "Multicast TTL: " << (int)multicastTTL << std::endl; std::cout << "Receive mode: "; switch (receivemode) { case RTPTransmitter::AcceptAll: std::cout << "Accept all"; break; case RTPTransmitter::AcceptSome: std::cout << "Accept some"; break; case RTPTransmitter::IgnoreSome: std::cout << "Ignore some"; } std::cout << std::endl; if (receivemode != RTPTransmitter::AcceptAll) { acceptignoreinfo.GotoFirstElement(); while(acceptignoreinfo.HasCurrentElement()) { ip = acceptignoreinfo.GetCurrentKey(); for (i = 0,j = 0 ; j < 8 ; j++,i += 2) { ip16[j] = (((uint16_t)ip.s6_addr[i])<<8); ip16[j] |= ((uint16_t)ip.s6_addr[i+1]); } RTP_SNPRINTF(str,48,"%04X:%04X:%04X:%04X:%04X:%04X:%04X:%04X",(int)ip16[0],(int)ip16[1],(int)ip16[2],(int)ip16[3],(int)ip16[4],(int)ip16[5],(int)ip16[6],(int)ip16[7]); PortInfo *pinfo = acceptignoreinfo.GetCurrentElement(); std::cout << " " << str << ": "; if (pinfo->all) { std::cout << "All ports"; if (!pinfo->portlist.empty()) std::cout << ", except "; } std::list::const_iterator it; for (it = pinfo->portlist.begin() ; it != pinfo->portlist.end() ; ) { std::cout << (*it); it++; if (it != pinfo->portlist.end()) std::cout << ", "; } std::cout << std::endl; } } std::cout << "Local host name: "; if (localhostname == 0) std::cout << "Not set"; else std::cout << localhostname; std::cout << std::endl; std::cout << "List of destinations: "; destinations.GotoFirstElement(); if (destinations.HasCurrentElement()) { std::cout << std::endl; do { std::cout << " " << destinations.GetCurrentElement().GetDestinationString() << std::endl; destinations.GotoNextElement(); } while (destinations.HasCurrentElement()); } else std::cout << "Empty" << std::endl; std::cout << "Supports multicasting: " << ((supportsmulticasting)?"Yes":"No") << std::endl; #ifdef RTP_SUPPORT_IPV6MULTICAST std::cout << "List of multicast groups: "; multicastgroups.GotoFirstElement(); if (multicastgroups.HasCurrentElement()) { std::cout << std::endl; do { ip = multicastgroups.GetCurrentElement(); for (i = 0,j = 0 ; j < 8 ; j++,i += 2) { ip16[j] = (((uint16_t)ip.s6_addr[i])<<8); ip16[j] |= ((uint16_t)ip.s6_addr[i+1]); } RTP_SNPRINTF(str,48,"%04X:%04X:%04X:%04X:%04X:%04X:%04X:%04X",(int)ip16[0],(int)ip16[1],(int)ip16[2],(int)ip16[3],(int)ip16[4],(int)ip16[5],(int)ip16[6],(int)ip16[7]); std::cout << " " << str << std::endl; multicastgroups.GotoNextElement(); } while (multicastgroups.HasCurrentElement()); } else std::cout << "Empty" << std::endl; #endif // RTP_SUPPORT_IPV6MULTICAST std::cout << "Number of raw packets in queue: " << rawpacketlist.size() << std::endl; std::cout << "Maximum allowed packet size: " << maxpacksize << std::endl; } MAINMUTEX_UNLOCK } } #endif // RTPDEBUG #endif // RTP_SUPPORT_IPV6