/* $Id: miniupnpc.c,v 1.85 2010/12/21 16:13:14 nanard Exp $ */ /* Project : miniupnp * Author : Thomas BERNARD * copyright (c) 2005-2010 Thomas Bernard * This software is subjet to the conditions detailed in the * provided LICENSE file. */ #define __EXTENSIONS__ 1 #if !defined(MACOSX) && !defined(__sun) #if !defined(_XOPEN_SOURCE) && !defined(__OpenBSD__) && !defined(__NetBSD__) #ifndef __cplusplus #define _XOPEN_SOURCE 600 #endif #endif #ifndef __BSD_VISIBLE #define __BSD_VISIBLE 1 #endif #endif #include #include #include #ifdef WIN32 /* Win32 Specific includes and defines */ #include #include #include #include #define snprintf _snprintf #if defined(_MSC_VER) && (_MSC_VER >= 1400) #define strncasecmp _memicmp #else /* defined(_MSC_VER) && (_MSC_VER >= 1400) */ #define strncasecmp memicmp #endif /* defined(_MSC_VER) && (_MSC_VER >= 1400) */ #define MAXHOSTNAMELEN 64 #else /* #ifdef WIN32 */ /* Standard POSIX includes */ #include #if defined(__amigaos__) && !defined(__amigaos4__) /* Amiga OS 3 specific stuff */ #define socklen_t int #else #include #endif #include #include #include #include #include #include #if !defined(__amigaos__) && !defined(__amigaos4__) #include #endif #include #include #define closesocket close #define MINIUPNPC_IGNORE_EINTR #endif /* #else WIN32 */ #ifdef MINIUPNPC_SET_SOCKET_TIMEOUT #include #endif #if defined(__amigaos__) || defined(__amigaos4__) /* Amiga OS specific stuff */ #define TIMEVAL struct timeval #endif #include "miniupnpc.h" #include "minissdpc.h" #include "miniwget.h" #include "minisoap.h" #include "minixml.h" #include "upnpcommands.h" #include "connecthostport.h" #ifdef WIN32 #define PRINT_SOCKET_ERROR(x) printf("Socket error: %s, %d\n", x, WSAGetLastError()); #else #define PRINT_SOCKET_ERROR(x) perror(x) #endif #define SOAPPREFIX "s" #define SERVICEPREFIX "u" #define SERVICEPREFIX2 'u' /* root description parsing */ LIBSPEC void parserootdesc(const char * buffer, int bufsize, struct IGDdatas * data) { struct xmlparser parser; /* xmlparser object */ parser.xmlstart = buffer; parser.xmlsize = bufsize; parser.data = data; parser.starteltfunc = IGDstartelt; parser.endeltfunc = IGDendelt; parser.datafunc = IGDdata; parser.attfunc = 0; parsexml(&parser); #ifdef DEBUG printIGD(data); #endif } #if 0 /* getcontentlenfromline() : parse the Content-Length HTTP header line. * Content-length: nnn */ static int getcontentlenfromline(const char * p, int n) { static const char contlenstr[] = "content-length"; const char * p2 = contlenstr; int a = 0; while(*p2) { if(n==0) return -1; if(*p2 != *p && *p2 != (*p + 32)) return -1; p++; p2++; n--; } if(n==0) return -1; if(*p != ':') return -1; p++; n--; while(*p == ' ') { if(n==0) return -1; p++; n--; } while(*p >= '0' && *p <= '9') { if(n==0) return -1; a = (a * 10) + (*p - '0'); p++; n--; } return a; } /* getContentLengthAndHeaderLength() * retrieve header length and content length from an HTTP response * TODO : retrieve Transfer-Encoding: header value, in order to support * HTTP/1.1, chunked transfer encoding must be supported. */ static void getContentLengthAndHeaderLength(char * p, int n, int * contentlen, int * headerlen) { char * line; int linelen; int r; line = p; while(line < p + n) { linelen = 0; while(line[linelen] != '\r' && line[linelen] != '\r') { if(line+linelen >= p+n) return; linelen++; } r = getcontentlenfromline(line, linelen); if(r>0) *contentlen = r; line = line + linelen + 2; if(line[0] == '\r' && line[1] == '\n') { *headerlen = (line - p) + 2; return; } } } #endif /* simpleUPnPcommand2 : * not so simple ! * return values : * 0 - OK * -1 - error */ static int simpleUPnPcommand2(int s, const char * url, const char * service, const char * action, struct UPNParg * args, char * buffer, int * bufsize, const char * httpversion) { char hostname[MAXHOSTNAMELEN+1]; unsigned short port = 0; char * path; char soapact[128]; char soapbody[2048]; char * buf; /*int buffree;*/ int n; /*int contentlen, headerlen;*/ /* for the response */ snprintf(soapact, sizeof(soapact), "%s#%s", service, action); if(args==NULL) { /*soapbodylen = */snprintf(soapbody, sizeof(soapbody), "\r\n" "<" SOAPPREFIX ":Envelope " "xmlns:" SOAPPREFIX "=\"http://schemas.xmlsoap.org/soap/envelope/\" " SOAPPREFIX ":encodingStyle=\"http://schemas.xmlsoap.org/soap/encoding/\">" "<" SOAPPREFIX ":Body>" "<" SERVICEPREFIX ":%s xmlns:" SERVICEPREFIX "=\"%s\">" "" "" "\r\n", action, service, action); } else { char * p; const char * pe, * pv; int soapbodylen; soapbodylen = snprintf(soapbody, sizeof(soapbody), "\r\n" "<" SOAPPREFIX ":Envelope " "xmlns:" SOAPPREFIX "=\"http://schemas.xmlsoap.org/soap/envelope/\" " SOAPPREFIX ":encodingStyle=\"http://schemas.xmlsoap.org/soap/encoding/\">" "<" SOAPPREFIX ":Body>" "<" SERVICEPREFIX ":%s xmlns:" SERVICEPREFIX "=\"%s\">", action, service); p = soapbody + soapbodylen; while(args->elt) { /* check that we are never overflowing the string... */ if(soapbody + sizeof(soapbody) <= p + 100) { /* we keep a margin of at least 100 bytes */ *bufsize = 0; return -1; } *(p++) = '<'; pe = args->elt; while(*pe) *(p++) = *(pe++); *(p++) = '>'; if((pv = args->val)) { while(*pv) *(p++) = *(pv++); } *(p++) = '<'; *(p++) = '/'; pe = args->elt; while(*pe) *(p++) = *(pe++); *(p++) = '>'; args++; } *(p++) = '<'; *(p++) = '/'; *(p++) = SERVICEPREFIX2; *(p++) = ':'; pe = action; while(*pe) *(p++) = *(pe++); strncpy(p, ">\r\n", soapbody + sizeof(soapbody) - p); } if(!parseURL(url, hostname, &port, &path)) return -1; if(s<0) { s = connecthostport(hostname, port); if(s < 0) { *bufsize = 0; return -1; } } n = soapPostSubmit(s, path, hostname, port, soapact, soapbody, httpversion); if(n<=0) { #ifdef DEBUG printf("Error sending SOAP request\n"); #endif closesocket(s); return -1; } #if 0 contentlen = -1; headerlen = -1; buf = buffer; buffree = *bufsize; *bufsize = 0; while ((n = ReceiveData(s, buf, buffree, 5000)) > 0) { buffree -= n; buf += n; *bufsize += n; getContentLengthAndHeaderLength(buffer, *bufsize, &contentlen, &headerlen); #ifdef DEBUG printf("received n=%dbytes bufsize=%d ContLen=%d HeadLen=%d\n", n, *bufsize, contentlen, headerlen); #endif /* break if we received everything */ if(contentlen > 0 && headerlen > 0 && *bufsize >= contentlen+headerlen) break; } #endif buf = getHTTPResponse(s, &n); if(n > 0 && buf) { #ifdef DEBUG printf("SOAP Response :\n%.*s\n", n, buf); #endif if(*bufsize > n) { memcpy(buffer, buf, n); *bufsize = n; } else { memcpy(buffer, buf, *bufsize); } free(buf); buf = 0; } closesocket(s); return 0; } /* simpleUPnPcommand : * not so simple ! * return values : * 0 - OK * -1 - error */ int simpleUPnPcommand(int s, const char * url, const char * service, const char * action, struct UPNParg * args, char * buffer, int * bufsize) { int result; /*int origbufsize = *bufsize;*/ result = simpleUPnPcommand2(s, url, service, action, args, buffer, bufsize, "1.1"); /* result = simpleUPnPcommand2(s, url, service, action, args, buffer, bufsize, "1.0"); if (result < 0 || *bufsize == 0) { #if DEBUG printf("Error or no result from SOAP request; retrying with HTTP/1.1\n"); #endif *bufsize = origbufsize; result = simpleUPnPcommand2(s, url, service, action, args, buffer, bufsize, "1.1"); } */ return result; } /* parseMSEARCHReply() * the last 4 arguments are filled during the parsing : * - location/locationsize : "location:" field of the SSDP reply packet * - st/stsize : "st:" field of the SSDP reply packet. * The strings are NOT null terminated */ static void parseMSEARCHReply(const char * reply, int size, const char * * location, int * locationsize, const char * * st, int * stsize) { int a, b, i; i = 0; a = i; /* start of the line */ b = 0; while(isin6_family = AF_INET6; if(sameport) p->sin6_port = htons(PORT); p->sin6_addr = in6addr_any;//IN6ADDR_ANY_INIT;/*INADDR_ANY;*/ } else { struct sockaddr_in * p = (struct sockaddr_in *)&sockudp_r; p->sin_family = AF_INET; if(sameport) p->sin_port = htons(PORT); p->sin_addr.s_addr = INADDR_ANY; } #ifdef WIN32 /* This code could help us to use the right Network interface for * SSDP multicast traffic */ /* Get IP associated with the index given in the ip_forward struct * in order to give this ip to setsockopt(sudp, IPPROTO_IP, IP_MULTICAST_IF) */ if(GetBestRoute(inet_addr("223.255.255.255"), 0, &ip_forward) == NO_ERROR) { DWORD dwRetVal = 0; PMIB_IPADDRTABLE pIPAddrTable; DWORD dwSize = 0; #ifdef DEBUG IN_ADDR IPAddr; #endif int i; #ifdef DEBUG printf("ifIndex=%lu nextHop=%lx \n", ip_forward.dwForwardIfIndex, ip_forward.dwForwardNextHop); #endif pIPAddrTable = (MIB_IPADDRTABLE *) malloc(sizeof (MIB_IPADDRTABLE)); if (GetIpAddrTable(pIPAddrTable, &dwSize, 0) == ERROR_INSUFFICIENT_BUFFER) { free(pIPAddrTable); pIPAddrTable = (MIB_IPADDRTABLE *) malloc(dwSize); } if(pIPAddrTable) { dwRetVal = GetIpAddrTable( pIPAddrTable, &dwSize, 0 ); #ifdef DEBUG printf("\tNum Entries: %ld\n", pIPAddrTable->dwNumEntries); #endif for (i=0; i < (int) pIPAddrTable->dwNumEntries; i++) { #ifdef DEBUG printf("\n\tInterface Index[%d]:\t%ld\n", i, pIPAddrTable->table[i].dwIndex); IPAddr.S_un.S_addr = (u_long) pIPAddrTable->table[i].dwAddr; printf("\tIP Address[%d]: \t%s\n", i, inet_ntoa(IPAddr) ); IPAddr.S_un.S_addr = (u_long) pIPAddrTable->table[i].dwMask; printf("\tSubnet Mask[%d]: \t%s\n", i, inet_ntoa(IPAddr) ); IPAddr.S_un.S_addr = (u_long) pIPAddrTable->table[i].dwBCastAddr; printf("\tBroadCast[%d]: \t%s (%ld)\n", i, inet_ntoa(IPAddr), pIPAddrTable->table[i].dwBCastAddr); printf("\tReassembly size[%d]:\t%ld\n", i, pIPAddrTable->table[i].dwReasmSize); printf("\tType and State[%d]:", i); printf("\n"); #endif if (pIPAddrTable->table[i].dwIndex == ip_forward.dwForwardIfIndex) { /* Set the address of this interface to be used */ struct in_addr mc_if; memset(&mc_if, 0, sizeof(mc_if)); mc_if.s_addr = pIPAddrTable->table[i].dwAddr; if(setsockopt(sudp, IPPROTO_IP, IP_MULTICAST_IF, (const char *)&mc_if, sizeof(mc_if)) < 0) { PRINT_SOCKET_ERROR("setsockopt"); } ((struct sockaddr_in *)&sockudp_r)->sin_addr.s_addr = pIPAddrTable->table[i].dwAddr; #ifndef DEBUG break; #endif } } free(pIPAddrTable); pIPAddrTable = NULL; } } #endif #ifdef WIN32 if (setsockopt(sudp, SOL_SOCKET, SO_REUSEADDR, (const char *)&opt, sizeof (opt)) < 0) #else if (setsockopt(sudp, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof (opt)) < 0) #endif { PRINT_SOCKET_ERROR("setsockopt"); return NULL; } if(multicastif) { struct in_addr mc_if; mc_if.s_addr = inet_addr(multicastif); if(0/*ipv6*/) { } else { ((struct sockaddr_in *)&sockudp_r)->sin_addr.s_addr = mc_if.s_addr; } if(setsockopt(sudp, IPPROTO_IP, IP_MULTICAST_IF, (const char *)&mc_if, sizeof(mc_if)) < 0) { PRINT_SOCKET_ERROR("setsockopt"); } } /* Avant d'envoyer le paquet on bind pour recevoir la reponse */ if (bind(sudp, &sockudp_r, 0/*ipv6*/?sizeof(struct sockaddr_in6):sizeof(struct sockaddr_in)) != 0) { PRINT_SOCKET_ERROR("bind"); closesocket(sudp); return NULL; } /* Calculating maximum response time in seconds */ mx = ((unsigned int)delay) / 1000u; /* receiving SSDP response packet */ for(n = 0;;) { if(n == 0) { /* sending the SSDP M-SEARCH packet */ n = snprintf(bufr, sizeof(bufr), MSearchMsgFmt, deviceList[deviceIndex++], mx); /*printf("Sending %s", bufr);*/ #ifdef NO_GETADDRINFO /* the following code is not using getaddrinfo */ /* emission */ memset(&sockudp_w, 0, sizeof(struct sockaddr_in)); sockudp_w.sin_family = AF_INET; sockudp_w.sin_port = htons(PORT); sockudp_w.sin_addr.s_addr = inet_addr(UPNP_MCAST_ADDR); n = sendto(sudp, bufr, n, 0, (struct sockaddr *)&sockudp_w, sizeof(struct sockaddr_in)); if (n < 0) { PRINT_SOCKET_ERROR("sendto"); closesocket(sudp); return devlist; } #else /* #ifdef NO_GETADDRINFO */ memset(&hints, 0, sizeof(hints)); hints.ai_family = AF_UNSPEC; // AF_INET6 or AF_INET hints.ai_socktype = SOCK_DGRAM; /*hints.ai_flags = */ if ((rv = getaddrinfo(UPNP_MCAST_ADDR, XSTR(PORT), &hints, &servinfo)) != 0) { #ifdef WIN32 fprintf(stderr, "getaddrinfo() failed: %d\n", rv); #else fprintf(stderr, "getaddrinfo: %s\n", gai_strerror(rv)); #endif return devlist; } for(p = servinfo; p; p = p->ai_next) { n = sendto(sudp, bufr, n, 0, p->ai_addr, p->ai_addrlen); if (n < 0) { PRINT_SOCKET_ERROR("sendto"); continue; } } freeaddrinfo(servinfo); if(n < 0) { closesocket(sudp); return devlist; } #endif /* #ifdef NO_GETADDRINFO */ } /* Waiting for SSDP REPLY packet to M-SEARCH */ n = ReceiveData(sudp, bufr, sizeof(bufr), delay); if (n < 0) { /* error */ closesocket(sudp); return devlist; } else if (n == 0) { /* no data or Time Out */ if (devlist || (deviceList[deviceIndex] == 0)) { /* no more device type to look for... */ closesocket(sudp); return devlist; } } else { const char * descURL=NULL; int urlsize=0; const char * st=NULL; int stsize=0; /*printf("%d byte(s) :\n%s\n", n, bufr);*/ /* affichage du message */ parseMSEARCHReply(bufr, n, &descURL, &urlsize, &st, &stsize); if(st&&descURL) { #ifdef DEBUG printf("M-SEARCH Reply:\nST: %.*s\nLocation: %.*s\n", stsize, st, urlsize, descURL); #endif for(tmp=devlist; tmp; tmp = tmp->pNext) { if(memcmp(tmp->descURL, descURL, urlsize) == 0 && tmp->descURL[urlsize] == '\0' && memcmp(tmp->st, st, stsize) == 0 && tmp->st[stsize] == '\0') break; } /* at the exit of the loop above, tmp is null if * no duplicate device was found */ if(tmp) continue; tmp = (struct UPNPDev *)malloc(sizeof(struct UPNPDev)+urlsize+stsize); tmp->pNext = devlist; tmp->descURL = tmp->buffer; tmp->st = tmp->buffer + 1 + urlsize; memcpy(tmp->buffer, descURL, urlsize); tmp->buffer[urlsize] = '\0'; memcpy(tmp->buffer + urlsize + 1, st, stsize); tmp->buffer[urlsize+1+stsize] = '\0'; devlist = tmp; } } } } /* freeUPNPDevlist() should be used to * free the chained list returned by upnpDiscover() */ LIBSPEC void freeUPNPDevlist(struct UPNPDev * devlist) { struct UPNPDev * next; while(devlist) { next = devlist->pNext; free(devlist); devlist = next; } } static void url_cpy_or_cat(char * dst, const char * src, int n) { if( (src[0] == 'h') &&(src[1] == 't') &&(src[2] == 't') &&(src[3] == 'p') &&(src[4] == ':') &&(src[5] == '/') &&(src[6] == '/')) { strncpy(dst, src, n); } else { int l = strlen(dst); if(src[0] != '/') dst[l++] = '/'; if(l<=n) strncpy(dst + l, src, n - l); } } /* Prepare the Urls for usage... */ LIBSPEC void GetUPNPUrls(struct UPNPUrls * urls, struct IGDdatas * data, const char * descURL) { char * p; int n1, n2, n3; n1 = strlen(data->urlbase); if(n1==0) n1 = strlen(descURL); n1 += 2; /* 1 byte more for Null terminator, 1 byte for '/' if needed */ n2 = n1; n3 = n1; n1 += strlen(data->first.scpdurl); n2 += strlen(data->first.controlurl); n3 += strlen(data->CIF.controlurl); urls->ipcondescURL = (char *)malloc(n1); urls->controlURL = (char *)malloc(n2); urls->controlURL_CIF = (char *)malloc(n3); /* maintenant on chope la desc du WANIPConnection */ if(data->urlbase[0] != '\0') strncpy(urls->ipcondescURL, data->urlbase, n1); else strncpy(urls->ipcondescURL, descURL, n1); p = strchr(urls->ipcondescURL+7, '/'); if(p) p[0] = '\0'; strncpy(urls->controlURL, urls->ipcondescURL, n2); strncpy(urls->controlURL_CIF, urls->ipcondescURL, n3); url_cpy_or_cat(urls->ipcondescURL, data->first.scpdurl, n1); url_cpy_or_cat(urls->controlURL, data->first.controlurl, n2); url_cpy_or_cat(urls->controlURL_CIF, data->CIF.controlurl, n3); #ifdef DEBUG printf("urls->ipcondescURL='%s' %u n1=%d\n", urls->ipcondescURL, (unsigned)strlen(urls->ipcondescURL), n1); printf("urls->controlURL='%s' %u n2=%d\n", urls->controlURL, (unsigned)strlen(urls->controlURL), n2); printf("urls->controlURL_CIF='%s' %u n3=%d\n", urls->controlURL_CIF, (unsigned)strlen(urls->controlURL_CIF), n3); #endif } LIBSPEC void FreeUPNPUrls(struct UPNPUrls * urls) { if(!urls) return; free(urls->controlURL); urls->controlURL = 0; free(urls->ipcondescURL); urls->ipcondescURL = 0; free(urls->controlURL_CIF); urls->controlURL_CIF = 0; } int ReceiveData(int socket, char * data, int length, int timeout) { int n; #if !defined(WIN32) && !defined(__amigaos__) && !defined(__amigaos4__) struct pollfd fds[1]; /* for the poll */ #ifdef MINIUPNPC_IGNORE_EINTR do { #endif fds[0].fd = socket; fds[0].events = POLLIN; n = poll(fds, 1, timeout); #ifdef MINIUPNPC_IGNORE_EINTR } while(n < 0 && errno == EINTR); #endif if(n < 0) { PRINT_SOCKET_ERROR("poll"); return -1; } else if(n == 0) { return 0; } #else fd_set socketSet; TIMEVAL timeval; FD_ZERO(&socketSet); FD_SET(socket, &socketSet); timeval.tv_sec = timeout / 1000; timeval.tv_usec = (timeout % 1000) * 1000; n = select(FD_SETSIZE, &socketSet, NULL, NULL, &timeval); if(n < 0) { PRINT_SOCKET_ERROR("select"); return -1; } else if(n == 0) { return 0; } #endif n = recv(socket, data, length, 0); if(n<0) { PRINT_SOCKET_ERROR("recv"); } return n; } int UPNPIGD_IsConnected(struct UPNPUrls * urls, struct IGDdatas * data) { char status[64]; unsigned int uptime; status[0] = '\0'; UPNP_GetStatusInfo(urls->controlURL, data->first.servicetype, status, &uptime, NULL); if(0 == strcmp("Connected", status)) { return 1; } else return 0; } /* UPNP_GetValidIGD() : * return values : * 0 = NO IGD found * 1 = A valid connected IGD has been found * 2 = A valid IGD has been found but it reported as * not connected * 3 = an UPnP device has been found but was not recognized as an IGD * * In any non zero return case, the urls and data structures * passed as parameters are set. Donc forget to call FreeUPNPUrls(urls) to * free allocated memory. */ LIBSPEC int UPNP_GetValidIGD(struct UPNPDev * devlist, struct UPNPUrls * urls, struct IGDdatas * data, char * lanaddr, int lanaddrlen) { char * descXML; int descXMLsize = 0; struct UPNPDev * dev; int ndev = 0; int state; /* state 1 : IGD connected. State 2 : IGD. State 3 : anything */ if(!devlist) { #ifdef DEBUG printf("Empty devlist\n"); #endif return 0; } for(state = 1; state <= 3; state++) { for(dev = devlist; dev; dev = dev->pNext) { /* we should choose an internet gateway device. * with st == urn:schemas-upnp-org:device:InternetGatewayDevice:1 */ descXML = miniwget_getaddr(dev->descURL, &descXMLsize, lanaddr, lanaddrlen); if(descXML) { ndev++; memset(data, 0, sizeof(struct IGDdatas)); memset(urls, 0, sizeof(struct UPNPUrls)); parserootdesc(descXML, descXMLsize, data); free(descXML); descXML = NULL; if(0==strcmp(data->CIF.servicetype, "urn:schemas-upnp-org:service:WANCommonInterfaceConfig:1") || state >= 3 ) { GetUPNPUrls(urls, data, dev->descURL); #ifdef DEBUG printf("UPNPIGD_IsConnected(%s) = %d\n", urls->controlURL, UPNPIGD_IsConnected(urls, data)); #endif if((state >= 2) || UPNPIGD_IsConnected(urls, data)) return state; FreeUPNPUrls(urls); if(data->second.servicetype[0] != '\0') { #ifdef DEBUG printf("We tried %s, now we try %s !\n", data->first.servicetype, data->second.servicetype); #endif /* swaping WANPPPConnection and WANIPConnection ! */ memcpy(&data->tmp, &data->first, sizeof(struct IGDdatas_service)); memcpy(&data->first, &data->second, sizeof(struct IGDdatas_service)); memcpy(&data->second, &data->tmp, sizeof(struct IGDdatas_service)); GetUPNPUrls(urls, data, dev->descURL); #ifdef DEBUG printf("UPNPIGD_IsConnected(%s) = %d\n", urls->controlURL, UPNPIGD_IsConnected(urls, data)); #endif if((state >= 2) || UPNPIGD_IsConnected(urls, data)) return state; FreeUPNPUrls(urls); } } memset(data, 0, sizeof(struct IGDdatas)); } #ifdef DEBUG else { printf("error getting XML description %s\n", dev->descURL); } #endif } } return 0; } /* UPNP_GetIGDFromUrl() * Used when skipping the discovery process. * return value : * 0 - Not ok * 1 - OK */ int UPNP_GetIGDFromUrl(const char * rootdescurl, struct UPNPUrls * urls, struct IGDdatas * data, char * lanaddr, int lanaddrlen) { char * descXML; int descXMLsize = 0; descXML = miniwget_getaddr(rootdescurl, &descXMLsize, lanaddr, lanaddrlen); if(descXML) { memset(data, 0, sizeof(struct IGDdatas)); memset(urls, 0, sizeof(struct UPNPUrls)); parserootdesc(descXML, descXMLsize, data); free(descXML); descXML = NULL; GetUPNPUrls(urls, data, rootdescurl); return 1; } else { return 0; } }