/* * udp/udplayer.cc * * BitDHT: An Flexible DHT library. * * Copyright 2004-2010 by Robert Fernie * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License Version 3 as published by the Free Software Foundation. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 * USA. * * Please report all bugs and problems to "bitdht@lunamutt.com". * */ #include "udp/udplayer.h" #include "util/bdrandom.h" #include #include #include #include #include /*** * #define UDP_ENABLE_BROADCAST 1 * #define UDP_LOOPBACK_TESTING 1 * #define DEBUG_UDP_LAYER 1 ***/ //#define DEBUG_UDP_LAYER 1 static const int UDP_DEF_TTL = 64; /* NB: This #define makes the listener open 0.0.0.0:X port instead * of a specific port - this helps library communicate on systems * with multiple interfaces or unique network setups. * * - It should always be used! * * #define OPEN_UNIVERSAL_PORT 1 * */ #define OPEN_UNIVERSAL_PORT 1 class udpPacket { public: udpPacket(struct sockaddr_in *addr, void *dta, int dlen) :raddr(*addr), len(dlen) { data = malloc(len); memcpy(data, dta, len); } ~udpPacket() { if (data) { free(data); data = NULL; len = 0; } } struct sockaddr_in raddr; void *data; int len; }; //std::ostream &operator<<(std::ostream &out, const struct sockaddr_in &addr) std::ostream &operator<<(std::ostream &out, struct sockaddr_in &addr) { out << "[" << inet_ntoa(addr.sin_addr) << ":"; out << htons(addr.sin_port) << "]"; return out; } bool operator==(const struct sockaddr_in &addr, const struct sockaddr_in &addr2) { if (addr.sin_family != addr2.sin_family) return false; if (addr.sin_addr.s_addr != addr2.sin_addr.s_addr) return false; if (addr.sin_port != addr2.sin_port) return false; return true; } bool operator<(const struct sockaddr_in &addr, const struct sockaddr_in &addr2) { if (addr.sin_family != addr2.sin_family) return (addr.sin_family < addr2.sin_family); if (addr.sin_addr.s_addr != addr2.sin_addr.s_addr) return (addr.sin_addr.s_addr < addr2.sin_addr.s_addr); if (addr.sin_port != addr2.sin_port) return (addr.sin_port < addr2.sin_port); return false; } std::string printPkt(void *d, int size) { std::ostringstream out; out << "Packet:" << "**********************"; for(int i = 0; i < size; i++) { if (i % 16 == 0) out << std::endl; out << std::hex << std::setw(2) << (unsigned int) ((unsigned char *) d)[i] << " "; } out << std::endl << "**********************"; out << std::endl; return out.str(); } std::string printPktOffset(unsigned int offset, void *d, unsigned int size) { std::ostringstream out; out << "Packet:" << "**********************"; out << std::endl; out << "Offset: " << std::hex << offset << " -> " << offset + size; out << std::endl; out << "Packet:" << "**********************"; unsigned int j = offset % 16; if (j != 0) { out << std::endl; out << std::hex << std::setw(6) << (unsigned int) offset - j; out << ": "; for(unsigned int i = 0; i < j; i++) { out << "xx "; } } for(unsigned int i = offset; i < offset + size; i++) { if (i % 16 == 0) { out << std::endl; out << std::hex << std::setw(6) << (unsigned int) i; out << ": "; } out << std::hex << std::setw(2) << (unsigned int) ((unsigned char *) d)[i-offset] << " "; } out << std::endl << "**********************"; out << std::endl; return out.str(); } UdpLayer::UdpLayer(UdpReceiver *udpr, struct sockaddr_in &local) :recv(udpr), laddr(local), errorState(0), ttl(UDP_DEF_TTL) { openSocket(); return; } int UdpLayer::status(std::ostream &out) { out << "UdpLayer::status()" << std::endl; out << "localaddr: " << laddr << std::endl; out << "sockfd: " << sockfd << std::endl; out << std::endl; return 1; } int UdpLayer::reset(struct sockaddr_in &local) { #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::reset()" << std::endl; #endif /* stop the old thread */ { bdStackMutex stack(sockMtx); /********** LOCK MUTEX *********/ #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::reset() setting stopThread flag" << std::endl; #endif stopThread = true; } #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::reset() joining" << std::endl; #endif join(); #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::reset() closing socket" << std::endl; #endif closeSocket(); #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::reset() resetting variables" << std::endl; #endif laddr = local; errorState = 0; ttl = UDP_DEF_TTL; #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::reset() opening socket" << std::endl; #endif openSocket(); return 1 ; } int UdpLayer::closeSocket() { /* close socket if open */ sockMtx.lock(); /********** LOCK MUTEX *********/ if (sockfd > 0) { bdnet_close(sockfd); } sockMtx.unlock(); /******** UNLOCK MUTEX *********/ return 1; } void UdpLayer::run() { return recv_loop(); } /* higher level interface */ void UdpLayer::recv_loop() { int maxsize = 16000; void *inbuf = malloc(maxsize); int status; struct timeval timeout; while(1) { fd_set rset; for(;;) { /* check if we need to stop */ bool toStop = false; { bdStackMutex stack(sockMtx); /********** LOCK MUTEX *********/ toStop = stopThread; } if (toStop) { #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::recv_loop() stopping thread" << std::endl; #endif stop(); } FD_ZERO(&rset); FD_SET(sockfd, &rset); timeout.tv_sec = 0; timeout.tv_usec = 500000; /* 500 ms timeout */ status = select(sockfd+1, &rset, NULL, NULL, &timeout); if (status > 0) { break; /* data available, go read it */ } else if (status < 0) { #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::recv_loop() Error: " << bdnet_errno() << std::endl; #endif } }; int nsize = maxsize; struct sockaddr_in from; if (0 < receiveUdpPacket(inbuf, &nsize, from)) { #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::readPkt() from : " << from << std::endl; std::cerr << printPkt(inbuf, nsize); #endif // send to reciever. recv -> recvPkt(inbuf, nsize, from); } else { #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::readPkt() not ready" << from; std::cerr << std::endl; #endif } } free(inbuf) ; return; } int UdpLayer::sendPkt(const void *data, int size, const sockaddr_in &to, int ttl) { /* if ttl is different -> set it */ if (ttl != getTTL()) { setTTL(ttl); } /* and send! */ #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::sendPkt() to: " << to << std::endl; std::cerr << printPkt((void *) data, size); #endif sendUdpPacket(data, size, to); return size; } /* setup connections */ int UdpLayer::openSocket() { sockMtx.lock(); /********** LOCK MUTEX *********/ /* make a socket */ sockfd = bdnet_socket(PF_INET, SOCK_DGRAM, 0); #ifdef DEBUG_UDP_LAYER std::cerr << "UpdStreamer::openSocket()" << std::endl; #endif /* bind to address */ #ifdef UDP_LOOPBACK_TESTING bdnet_inet_aton("127.0.0.1", &(laddr.sin_addr)); #endif #ifdef OPEN_UNIVERSAL_PORT struct sockaddr_in tmpaddr = laddr; tmpaddr.sin_addr.s_addr = 0; if (0 != bdnet_bind(sockfd, (struct sockaddr *) (&tmpaddr), sizeof(tmpaddr))) #else if (0 != bdnet_bind(sockfd, (struct sockaddr *) (&laddr), sizeof(laddr))) #endif { #ifdef DEBUG_UDP_LAYER std::cerr << "Socket Failed to Bind to : " << laddr << std::endl; std::cerr << "Error: " << bdnet_errno() << std::endl; #endif errorState = EADDRINUSE; //exit(1); sockMtx.unlock(); /******** UNLOCK MUTEX *********/ return -1; } if (-1 == bdnet_fcntl(sockfd, F_SETFL, O_NONBLOCK)) { #ifdef DEBUG_UDP_LAYER std::cerr << "Failed to Make Non-Blocking" << std::endl; #endif } #ifdef UDP_ENABLE_BROADCAST /* Setup socket for broadcast. */ int val = 1; if (-1 == setsockopt(sockfd, SOL_SOCKET, SO_BROADCAST, &val, sizeof(int))) { #ifdef DEBUG_UDP_LAYER std::cerr << "Failed to Make Socket Broadcast" << std::endl; #endif } #endif errorState = 0; #ifdef DEBUG_UDP_LAYER std::cerr << "Socket Bound to : " << laddr << std::endl; #endif sockMtx.unlock(); /******** UNLOCK MUTEX *********/ #ifdef DEBUG_UDP_LAYER std::cerr << "Setting TTL to " << UDP_DEF_TTL << std::endl; #endif setTTL(UDP_DEF_TTL); // start up our thread. { bdStackMutex stack(sockMtx); /********** LOCK MUTEX *********/ stopThread = false; } start(); return 1; } int UdpLayer::setTTL(int t) { sockMtx.lock(); /********** LOCK MUTEX *********/ int err = bdnet_setsockopt(sockfd, IPPROTO_IP, IP_TTL, &t, sizeof(int)); ttl = t; sockMtx.unlock(); /******** UNLOCK MUTEX *********/ #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::setTTL(" << t << ") returned: " << err; std::cerr << std::endl; #endif return err; } int UdpLayer::getTTL() { sockMtx.lock(); /********** LOCK MUTEX *********/ int t = ttl; sockMtx.unlock(); /******** UNLOCK MUTEX *********/ return t; } /* monitoring / updates */ int UdpLayer::okay() { sockMtx.lock(); /********** LOCK MUTEX *********/ bool nonFatalError = ((errorState == 0) || (errorState == EAGAIN) || (errorState == EINPROGRESS)); sockMtx.unlock(); /******** UNLOCK MUTEX *********/ #ifdef DEBUG_UDP_LAYER if (!nonFatalError) { std::cerr << "UdpLayer::NOT okay(): Error: " << errorState << std::endl; } #endif return nonFatalError; } int UdpLayer::tick() { #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::tick()" << std::endl; #endif return 1; } /******************* Internals *************************************/ int UdpLayer::receiveUdpPacket(void *data, int *size, struct sockaddr_in &from) { struct sockaddr_in fromaddr; socklen_t fromsize = sizeof(fromaddr); int insize = *size; sockMtx.lock(); /********** LOCK MUTEX *********/ insize = bdnet_recvfrom(sockfd,data,insize,0, (struct sockaddr*)&fromaddr,&fromsize); sockMtx.unlock(); /******** UNLOCK MUTEX *********/ if (0 < insize) { #ifdef DEBUG_UDP_LAYER std::cerr << "receiveUdpPacket() from: " << fromaddr; std::cerr << " Size: " << insize; std::cerr << std::endl; #endif *size = insize; from = fromaddr; return insize; } return -1; } int UdpLayer::sendUdpPacket(const void *data, int size, const struct sockaddr_in &to) { /* send out */ #ifdef DEBUG_UDP_LAYER std::cerr << "UdpLayer::sendUdpPacket(): size: " << size; std::cerr << " To: " << to << std::endl; #endif struct sockaddr_in toaddr = to; sockMtx.lock(); /********** LOCK MUTEX *********/ bdnet_sendto(sockfd, data, size, 0, (struct sockaddr *) &(toaddr), sizeof(toaddr)); sockMtx.unlock(); /******** UNLOCK MUTEX *********/ return 1; } /**************************** LossyUdpLayer - for Testing **************/ LossyUdpLayer::LossyUdpLayer(UdpReceiver *udpr, struct sockaddr_in &local, double frac) :UdpLayer(udpr, local), lossFraction(frac) { return; } LossyUdpLayer::~LossyUdpLayer() { return; } int LossyUdpLayer::receiveUdpPacket(void *data, int *size, struct sockaddr_in &from) { if (0 < UdpLayer::receiveUdpPacket(data, size, from)) { float prob = bdRandom::random_f32(); if (prob < lossFraction) { /* discard */ std::cerr << "LossyUdpLayer::receiveUdpPacket() Dropping packet!"; std::cerr << std::endl; std::cerr << printPkt(data, *size); std::cerr << std::endl; std::cerr << "LossyUdpLayer::receiveUdpPacket() Packet Dropped!"; std::cerr << std::endl; *size = 0; return -1; } return *size; } return -1; } int LossyUdpLayer::sendUdpPacket(const void *data, int size, const struct sockaddr_in &to) { double prob = (1.0 * (rand() / (RAND_MAX + 1.0))); if (prob < lossFraction) { /* discard */ std::cerr << "LossyUdpLayer::sendUdpPacket() Dropping packet!"; std::cerr << std::endl; std::cerr << printPkt((void *) data, size); std::cerr << std::endl; std::cerr << "LossyUdpLayer::sendUdpPacket() Packet Dropped!"; std::cerr << std::endl; return size; } // otherwise read normally; return UdpLayer::sendUdpPacket(data, size, to); } /**************************** LossyUdpLayer - for Testing **************/ PortRange::PortRange() :lport(0), uport(0) { return; } PortRange::PortRange(uint16_t lp, uint16_t up) :lport(lp), uport(up) { return; } bool PortRange::inRange(uint16_t port) { if (port < lport) { return false; } if (port > uport) { return false; } return true; } RestrictedUdpLayer::RestrictedUdpLayer(UdpReceiver *udpr, struct sockaddr_in &local) :UdpLayer(udpr, local) { return; } RestrictedUdpLayer::~RestrictedUdpLayer() { return; } void RestrictedUdpLayer::addRestrictedPortRange(int lp, int up) { PortRange pr(lp, up); mLostPorts.push_back(pr); } int RestrictedUdpLayer::receiveUdpPacket(void *data, int *size, struct sockaddr_in &from) { if (0 < UdpLayer::receiveUdpPacket(data, size, from)) { /* check the port against list */ uint16_t inPort = ntohs(from.sin_port); std::list::iterator it; for(it = mLostPorts.begin(); it != mLostPorts.end(); it++) { if (it->inRange(inPort)) { #ifdef DEBUG_UDP_LAYER std::cerr << "RestrictedUdpLayer::receiveUdpPacket() Dropping packet"; std::cerr << ", Port(" << inPort << ") in restricted range!"; std::cerr << std::endl; //std::cerr << printPkt(data, *size); //std::cerr << std::endl; #endif *size = 0; return -1; } } #ifdef DEBUG_UDP_LAYER std::cerr << "RestrictedUdpLayer::receiveUdpPacket() Accepting packet"; std::cerr << ", Port(" << inPort << ") in Okay range!"; std::cerr << std::endl; #endif /* acceptable port */ return *size; } return -1; } int RestrictedUdpLayer::sendUdpPacket(const void *data, int size, const struct sockaddr_in &to) { /* check the port against list */ uint16_t outPort = ntohs(to.sin_port); std::list::iterator it; for(it = mLostPorts.begin(); it != mLostPorts.end(); it++) { if (it->inRange(outPort)) { /* drop */ #ifdef DEBUG_UDP_LAYER std::cerr << "RestrictedUdpLayer::sendUdpPacket() Dropping packet"; std::cerr << ", Port(" << outPort << ") in restricted range!"; std::cerr << std::endl; //std::cerr << printPkt(data, *size); //std::cerr << std::endl; #endif return size; } } #ifdef DEBUG_UDP_LAYER std::cerr << "RestrictedUdpLayer::sendUdpPacket() Sending packet"; std::cerr << ", Port(" << outPort << ") in Okay range!"; std::cerr << std::endl; #endif // otherwise read normally; return UdpLayer::sendUdpPacket(data, size, to); }