/* Copyright (C) 1996-1997 Id Software, Inc. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ // net_wins.c struct sockaddr; #include "quakedef.h" #include "netinc.h" netadr_t net_local_cl_ipadr; //still used to match local ui requests (quake/gamespy), and to generate ip reports for q3 servers (which is probably pointless). netadr_t net_from; sizebuf_t net_message; //#define MAX_UDP_PACKET (MAX_MSGLEN*2) // one more than msg + header #define MAX_UDP_PACKET 8192 // one more than msg + header qbyte net_message_buffer[MAX_OVERALLMSGLEN]; #ifdef _WIN32 WSADATA winsockdata; #endif #ifdef IPPROTO_IPV6 #ifdef _WIN32 int (WINAPI *pgetaddrinfo) ( const char* nodename, const char* servname, const struct addrinfo* hints, struct addrinfo** res ); void (WSAAPI *pfreeaddrinfo) (struct addrinfo*); #else #define pgetaddrinfo getaddrinfo #define pfreeaddrinfo freeaddrinfo /*int (*pgetaddrinfo) ( const char* nodename, const char* servname, const struct addrinfo* hints, struct addrinfo** res ); void (*pfreeaddrinfo) (struct addrinfo*); */ #endif #endif void NET_GetLocalAddress (int socket, netadr_t *out); int TCP_OpenListenSocket (int port); extern cvar_t sv_port_ipv4; #ifdef IPPROTO_IPV6 int UDP6_OpenSocket (int port, qboolean bcast); extern cvar_t sv_port_ipv6; #endif #ifdef USEIPX void IPX_CloseSocket (int socket); extern cvar_t sv_port_ipx; #endif #ifdef TCPCONNECT extern cvar_t sv_port_tcp; extern cvar_t sv_port_tcp6; #endif cvar_t net_hybriddualstack = CVAR("net_hybriddualstack", "1"); extern cvar_t sv_public, sv_listen_qw, sv_listen_nq, sv_listen_dp, sv_listen_q3; static qboolean allowconnects = false; #define MAX_LOOPBACK 4 typedef struct { qbyte data[MAX_UDP_PACKET]; int datalen; } loopmsg_t; typedef struct { loopmsg_t msgs[MAX_LOOPBACK]; int get, send; } loopback_t; loopback_t loopbacks[2]; //============================================================================= int NetadrToSockadr (netadr_t *a, struct sockaddr_qstorage *s) { switch(a->type) { case NA_BROADCAST_IP: memset (s, 0, sizeof(struct sockaddr_in)); ((struct sockaddr_in*)s)->sin_family = AF_INET; *(int *)&((struct sockaddr_in*)s)->sin_addr = INADDR_BROADCAST; ((struct sockaddr_in*)s)->sin_port = a->port; return sizeof(struct sockaddr_in); case NA_TCP: case NA_IP: memset (s, 0, sizeof(struct sockaddr_in)); ((struct sockaddr_in*)s)->sin_family = AF_INET; *(int *)&((struct sockaddr_in*)s)->sin_addr = *(int *)&a->address.ip; ((struct sockaddr_in*)s)->sin_port = a->port; return sizeof(struct sockaddr_in); #ifdef IPPROTO_IPV6 case NA_BROADCAST_IP6: memset (s, 0, sizeof(struct sockaddr_in)); ((struct sockaddr_in6*)s)->sin6_family = AF_INET6; memset((int *)&((struct sockaddr_in6*)s)->sin6_addr, 0, sizeof(*(int *)&((struct sockaddr_in6*)s)->sin6_addr)); ((struct sockaddr_in6*)s)->sin6_addr.s6_addr[0] = 0xff; ((struct sockaddr_in6*)s)->sin6_addr.s6_addr[1] = 0x02; ((struct sockaddr_in6*)s)->sin6_addr.s6_addr[15] = 0x01; ((struct sockaddr_in6*)s)->sin6_port = a->port; return sizeof(struct sockaddr_in6); case NA_TCPV6: case NA_IPV6: memset (s, 0, sizeof(struct sockaddr_in6)); ((struct sockaddr_in6*)s)->sin6_family = AF_INET6; memcpy(&((struct sockaddr_in6*)s)->sin6_addr, a->address.ip6, sizeof(struct in6_addr)); ((struct sockaddr_in6*)s)->sin6_port = a->port; return sizeof(struct sockaddr_in6); #endif #ifdef USEIPX case NA_IPX: ((struct sockaddr_ipx *)s)->sa_family = AF_IPX; memcpy(((struct sockaddr_ipx *)s)->sa_netnum, &a->address.ipx[0], 4); memcpy(((struct sockaddr_ipx *)s)->sa_nodenum, &a->address.ipx[4], 6); ((struct sockaddr_ipx *)s)->sa_socket = a->port; return sizeof(struct sockaddr_ipx); case NA_BROADCAST_IPX: memset (s, 0, sizeof(struct sockaddr_ipx)); ((struct sockaddr_ipx*)s)->sa_family = AF_IPX; memset(&((struct sockaddr_ipx*)s)->sa_netnum, 0, 4); memset(&((struct sockaddr_ipx*)s)->sa_nodenum, 0xff, 6); ((struct sockaddr_ipx*)s)->sa_socket = a->port; return sizeof(struct sockaddr_ipx); #endif default: Sys_Error("Bad type - needs fixing"); return 0; } } void SockadrToNetadr (struct sockaddr_qstorage *s, netadr_t *a) { a->connum = 0; switch (((struct sockaddr*)s)->sa_family) { case AF_INET: a->type = NA_IP; *(int *)&a->address.ip = ((struct sockaddr_in *)s)->sin_addr.s_addr; a->port = ((struct sockaddr_in *)s)->sin_port; break; #ifdef IPPROTO_IPV6 case AF_INET6: a->type = NA_IPV6; memcpy(&a->address.ip6, &((struct sockaddr_in6 *)s)->sin6_addr, sizeof(a->address.ip6)); a->port = ((struct sockaddr_in6 *)s)->sin6_port; break; #endif #ifdef USEIPX case AF_IPX: a->type = NA_IPX; *(int *)a->address.ip = 0xffffffff; memcpy(&a->address.ipx[0], ((struct sockaddr_ipx *)s)->sa_netnum, 4); memcpy(&a->address.ipx[4], ((struct sockaddr_ipx *)s)->sa_nodenum, 6); a->port = ((struct sockaddr_ipx *)s)->sa_socket; break; #endif case AF_UNSPEC: memset(a, 0, sizeof(*a)); a->type = NA_INVALID; break; default: Sys_Error("SockadrToNetadr: bad socket family"); } } qboolean NET_CompareAdr (netadr_t a, netadr_t b) { if (a.type != b.type) return false; if (a.type == NA_LOOPBACK) return true; if (a.type == NA_IP || a.type == NA_BROADCAST_IP || a.type == NA_TCP) { if ((memcmp(a.address.ip, b.address.ip, sizeof(a.address.ip)) == 0) && a.port == b.port) return true; return false; } #ifdef IPPROTO_IPV6 if (a.type == NA_IPV6 || a.type == NA_BROADCAST_IP6 || a.type == NA_TCPV6) { if ((memcmp(a.address.ip6, b.address.ip6, sizeof(a.address.ip6)) == 0) && a.port == b.port) return true; return false; } #endif #ifdef USEIPX if (a.type == NA_IPX || a.type == NA_BROADCAST_IPX) { if ((memcmp(a.address.ipx, b.address.ipx, sizeof(a.address.ipx)) == 0) && a.port == b.port) return true; return false; } #endif #ifdef IRCCONNECT if (a.type == NA_IRC) { if (!strcmp(a.address.irc.user, b.address.irc.user)) return true; return false; } #endif Sys_Error("NET_CompareAdr: Bad address type"); return false; } /* =================== NET_CompareBaseAdr Compares without the port =================== */ qboolean NET_CompareBaseAdr (netadr_t a, netadr_t b) { if (a.type != b.type) return false; if (a.type == NA_LOOPBACK) return true; if (a.type == NA_IP || a.type == NA_TCP) { if ((memcmp(a.address.ip, b.address.ip, sizeof(a.address.ip)) == 0)) return true; return false; } #ifdef IPPROTO_IPV6 if (a.type == NA_IPV6 || a.type == NA_BROADCAST_IP6) { if ((memcmp(a.address.ip6, b.address.ip6, 16) == 0)) return true; return false; } #endif #ifdef USEIPX if (a.type == NA_IPX) { if ((memcmp(a.address.ipx, b.address.ipx, 10) == 0)) return true; return false; } #endif #ifdef IRCCONNECT if (a.type == NA_IRC) { if (!strcmp(a.address.irc.user, b.address.irc.user)) return true; return false; } #endif Sys_Error("NET_CompareBaseAdr: Bad address type"); return false; } qboolean NET_AddressSmellsFunny(netadr_t a) { int i; //rejects certain blacklisted addresses switch(a.type) { case NA_BROADCAST_IP: case NA_IP: //reject localhost if (a.address.ip[0] == 127)// && a.address.ip[1] == 0 && a.address.ip[2] == 0 && a.address.ip[3] == 1 ) return true; //'this' network (not an issue, but lets reject it anyway) if (a.address.ip[0] == 0 && a.address.ip[1] == 0 && a.address.ip[2] == 0 && a.address.ip[3] == 0 ) return true; //reject any broadcasts if (a.address.ip[0] == 255 && a.address.ip[1] == 255 && a.address.ip[2] == 255 && a.address.ip[3] == 0 ) return true; //not much else I can reject return false; #ifdef IPPROTO_IPV6 case NA_BROADCAST_IP6: case NA_IPV6: //reject [::XXXX] (this includes obsolete ipv4-compatible (not ipv4 mapped), and localhost) for (i = 0; i < 12; i++) if (a.address.ip6[i]) break; if (i == 12) return true; return false; #endif #ifdef USEIPX //no idea how this protocol's addresses work case NA_BROADCAST_IPX: case NA_IPX: return false; #endif case NA_LOOPBACK: return false; default: return true; } } char *NET_AdrToString (char *s, int len, netadr_t a) { char *rs = s; qboolean doneblank; char *p; int i; switch(a.type) { #ifdef TCPCONNECT case NA_TCP: if (len < 7) return "?"; snprintf (s, len, "tcp://"); s += 6; len -= 6; //fallthrough #endif case NA_BROADCAST_IP: case NA_IP: if (a.port) { snprintf (s, len, "%i.%i.%i.%i:%i", a.address.ip[0], a.address.ip[1], a.address.ip[2], a.address.ip[3], ntohs(a.port)); } else { snprintf (s, len, "%i.%i.%i.%i", a.address.ip[0], a.address.ip[1], a.address.ip[2], a.address.ip[3]); } break; #ifdef TCPCONNECT case NA_TCPV6: if (len < 7) return "?"; snprintf (s, len, "tcp://"); s += 6; len -= 6; //fallthrough #endif #ifdef IPPROTO_IPV6 case NA_BROADCAST_IP6: case NA_IPV6: if (!*(int*)&a.address.ip6[0] && !*(int*)&a.address.ip6[4] && !*(short*)&a.address.ip6[8] && *(short*)&a.address.ip6[10] == (short)0xffff) { if (a.port) snprintf (s, len, "%i.%i.%i.%i:%i", a.address.ip6[12], a.address.ip6[13], a.address.ip6[14], a.address.ip6[15], ntohs(a.port)); else snprintf (s, len, "%i.%i.%i.%i", a.address.ip6[12], a.address.ip6[13], a.address.ip6[14], a.address.ip6[15]); break; } *s = 0; doneblank = false; p = s; snprintf (s, len-strlen(s), "["); p += strlen(p); for (i = 0; i < 16; i+=2) { if (doneblank!=true && a.address.ip6[i] == 0 && a.address.ip6[i+1] == 0) { if (!doneblank) { snprintf (p, len-strlen(s), "::"); p += strlen(p); doneblank = 2; } } else { if (doneblank==2) doneblank = true; else if (i != 0) { snprintf (p, len-strlen(s), ":"); p += strlen(p); } if (a.address.ip6[i+0]) { snprintf (p, len-strlen(s), "%x%02x", a.address.ip6[i+0], a.address.ip6[i+1]); } else { snprintf (p, len-strlen(s), "%x", a.address.ip6[i+1]); } p += strlen(p); } } snprintf (p, len-strlen(s), "]:%i", ntohs(a.port)); break; #endif #ifdef USEIPX case NA_BROADCAST_IPX: case NA_IPX: snprintf (s, len, "%02x%02x%02x%02x:%02x%02x%02x%02x%02x%02x:%i", a.address.ipx[0], a.address.ipx[1], a.address.ipx[2], a.address.ipx[3], a.address.ipx[4], a.address.ipx[5], a.address.ipx[6], a.address.ipx[7], a.address.ipx[8], a.address.ipx[9], ntohs(a.port)); break; #endif case NA_LOOPBACK: snprintf (s, len, "QLoopBack"); break; #ifdef IRCCONNECT case NA_IRC: if (*a.address.irc.channel) snprintf (s, len, "irc://%s@%s", a.address.irc.user, a.address.irc.channel); else snprintf (s, len, "irc://%s", a.address.irc.user); break; #endif default: snprintf (s, len, "invalid netadr_t type"); // Sys_Error("NET_AdrToString: Bad netadr_t type"); } return rs; } char *NET_BaseAdrToString (char *s, int len, netadr_t a) { int i, doneblank; char *p; switch(a.type) { case NA_BROADCAST_IP: case NA_IP: snprintf (s, len, "%i.%i.%i.%i", a.address.ip[0], a.address.ip[1], a.address.ip[2], a.address.ip[3]); break; case NA_TCP: snprintf (s, len, "tcp://%i.%i.%i.%i", a.address.ip[0], a.address.ip[1], a.address.ip[2], a.address.ip[3]); break; #ifdef IPPROTO_IPV6 case NA_BROADCAST_IP6: case NA_IPV6: if (!*(int*)&a.address.ip6[0] && !*(int*)&a.address.ip6[4] && !*(short*)&a.address.ip6[8] && *(short*)&a.address.ip6[10] == (short)0xffff) { snprintf (s, len, "%i.%i.%i.%i", a.address.ip6[12], a.address.ip6[13], a.address.ip6[14], a.address.ip6[15]); break; } *s = 0; doneblank = false; p = s; for (i = 0; i < 16; i+=2) { if (doneblank!=true && a.address.ip6[i] == 0 && a.address.ip6[i+1] == 0) { if (!doneblank) { snprintf (p, len-strlen(s), "::"); p += strlen(p); doneblank = 2; } } else { if (doneblank==2) doneblank = true; else if (i != 0) { snprintf (p, len-strlen(s), ":"); p += strlen(p); } if (a.address.ip6[i+0]) { snprintf (p, len-strlen(s), "%x%02x", a.address.ip6[i+0], a.address.ip6[i+1]); } else { snprintf (p, len-strlen(s), "%x", a.address.ip6[i+1]); } p += strlen(p); } } break; #endif #ifdef USEIPX case NA_BROADCAST_IPX: case NA_IPX: snprintf (s, len, "%02x%02x%02x%02x:%02x%02x%02x%02x%02x%02x", a.address.ipx[0], a.address.ipx[1], a.address.ipx[2], a.address.ipx[3], a.address.ipx[4], a.address.ipx[5], a.address.ipx[6], a.address.ipx[7], a.address.ipx[8], a.address.ipx[9]); break; #endif case NA_LOOPBACK: snprintf (s, len, "LocalHost"); break; #ifdef IRCCONNECT case NA_IRC: snprintf (s, len, "irc://%s", a.address.irc.user); break; #endif default: Sys_Error("NET_BaseAdrToString: Bad netadr_t type"); } return s; } /* ============= NET_StringToAdr idnewt idnewt:28000 192.246.40.70 192.246.40.70:28000 any form of ipv6, including port number. ============= */ #define DO(src,dest) \ copy[0] = s[src]; \ copy[1] = s[src + 1]; \ sscanf (copy, "%x", &val); \ ((struct sockaddr_ipx *)sadr)->dest = val qboolean NET_StringToSockaddr (const char *s, struct sockaddr_qstorage *sadr) { struct hostent *h; char *colon; char copy[128]; if (!(*s)) return false; memset (sadr, 0, sizeof(*sadr)); #ifdef USEIPX if ((strlen(s) >= 23) && (s[8] == ':') && (s[21] == ':')) // check for an IPX address { unsigned int val; ((struct sockaddr_ipx *)sadr)->sa_family = AF_IPX; copy[2] = 0; DO(0, sa_netnum[0]); DO(2, sa_netnum[1]); DO(4, sa_netnum[2]); DO(6, sa_netnum[3]); DO(9, sa_nodenum[0]); DO(11, sa_nodenum[1]); DO(13, sa_nodenum[2]); DO(15, sa_nodenum[3]); DO(17, sa_nodenum[4]); DO(19, sa_nodenum[5]); sscanf (&s[22], "%u", &val); ((struct sockaddr_ipx *)sadr)->sa_socket = htons((unsigned short)val); } else #endif #ifdef IPPROTO_IPV6 if (pgetaddrinfo) { struct addrinfo *addrinfo = NULL; struct addrinfo *pos; struct addrinfo udp6hint; int error; char *port; char dupbase[256]; int len; memset(&udp6hint, 0, sizeof(udp6hint)); udp6hint.ai_family = 0;//Any... we check for AF_INET6 or 4 udp6hint.ai_socktype = SOCK_DGRAM; udp6hint.ai_protocol = IPPROTO_UDP; if (*s == '[') { port = strstr(s, "]:"); if (!port) error = EAI_NONAME; else { len = port - (s+1); if (len >= sizeof(dupbase)) len = sizeof(dupbase)-1; strncpy(dupbase, s+1, len); dupbase[len] = '\0'; error = pgetaddrinfo(dupbase, port+2, &udp6hint, &addrinfo); } } else { port = strrchr(s, ':'); if (port) { len = port - s; if (len >= sizeof(dupbase)) len = sizeof(dupbase)-1; strncpy(dupbase, s, len); dupbase[len] = '\0'; error = pgetaddrinfo(dupbase, port+1, &udp6hint, &addrinfo); } else error = EAI_NONAME; if (error) //failed, try string with no port. error = pgetaddrinfo(s, NULL, &udp6hint, &addrinfo); //remember, this func will return any address family that could be using the udp protocol... (ip4 or ip6) } if (error) { return false; } ((struct sockaddr*)sadr)->sa_family = 0; for (pos = addrinfo; pos; pos = pos->ai_next) { switch(pos->ai_family) { case AF_INET6: if (((struct sockaddr_in *)sadr)->sin_family == AF_INET6) break; //first one should be best... //fallthrough case AF_INET: memcpy(sadr, pos->ai_addr, pos->ai_addrlen); if (pos->ai_family == AF_INET) goto dblbreak; //don't try finding any more, this is quake, they probably prefer ip4... break; } } dblbreak: pfreeaddrinfo (addrinfo); if (!((struct sockaddr*)sadr)->sa_family) //none suitablefound return false; } else #endif { ((struct sockaddr_in *)sadr)->sin_family = AF_INET; ((struct sockaddr_in *)sadr)->sin_port = 0; if (strlen(s) >= sizeof(copy)-1) return false; strcpy (copy, s); // strip off a trailing :port if present for (colon = copy ; *colon ; colon++) if (*colon == ':') { *colon = 0; ((struct sockaddr_in *)sadr)->sin_port = htons((short)atoi(colon+1)); } if (copy[0] >= '0' && copy[0] <= '9') //this is the wrong way to test. a server name may start with a number. { *(int *)&((struct sockaddr_in *)sadr)->sin_addr = inet_addr(copy); } else { if (! (h = gethostbyname(copy)) ) return false; if (h->h_addrtype != AF_INET) return false; *(int *)&((struct sockaddr_in *)sadr)->sin_addr = *(int *)h->h_addr_list[0]; } } return true; } #undef DO /* accepts anything that NET_StringToSockaddr accepts plus certain url schemes including: tcp, irc */ qboolean NET_StringToAdr (const char *s, netadr_t *a) { struct sockaddr_qstorage sadr; Con_DPrintf("Resolving address: %s\n", s); #ifdef TCPCONNECT if (!strncmp (s, "tcp://", 6)) { //make sure that the rest of the address is a valid ip address (4 or 6) if (!NET_StringToSockaddr (s+6, &sadr)) { a->type = NA_INVALID; return false; } SockadrToNetadr (&sadr, a); if (a->type == NA_IP) { a->type = NA_TCP; return true; } if (a->type == NA_IPV6) { a->type = NA_TCPV6; return true; } return false; } #endif #ifdef IRCCONNECT if (!strncmp (s, "irc://", 6)) { char *at; memset (a, 0, sizeof(*a)); a->type = NA_IRC; s+=6; at = strchr(s, '@'); if (at) { if (at-s+1 >= sizeof(a->address.irc.user)) return false; Q_strncpyz(a->address.irc.user, s, at-s+1); Q_strncpyz(a->address.irc.channel, at+1, sizeof(a->address.irc.channel)); } else { //just a user. Q_strncpyz(a->address.irc.user, s, sizeof(a->address.irc.user)); } return true; } #endif if (!strcmp (s, "internalserver")) { memset (a, 0, sizeof(*a)); a->type = NA_LOOPBACK; return true; } if (!NET_StringToSockaddr (s, &sadr)) { a->type = NA_INVALID; return false; } SockadrToNetadr (&sadr, a); return true; } // NET_IntegerToMask: given a source address pointer, a mask address pointer, and // desired number of bits, fills the mask pointer with given bits // (bits < 0 will always fill all bits) void NET_IntegerToMask (netadr_t *a, netadr_t *amask, int bits) { unsigned int i; qbyte *n; memset (amask, 0, sizeof(*amask)); amask->type = a->type; if (bits < 0) i = 8000; // fill all bits else i = bits; switch (amask->type) { case NA_INVALID: break; case NA_IP: case NA_BROADCAST_IP: n = amask->address.ip; if (i > 32) i = 32; for (; i >= 8; i -= 8) { *n = 0xFF; n++; } // fill last bit if (i) { i = 8 - i; i = 255 - ((1 << i) - 1); *n = i; } break; case NA_IPV6: case NA_BROADCAST_IP6: #ifdef IPPROTO_IPV6 n = amask->address.ip6; if (i > 128) i = 128; for (; i >= 8; i -= 8) { *n = 0xFF; n++; } // fill last bit if (i) { i = 8 - i; i = 255 - ((1 << i) - 1); *n = i; } #endif break; case NA_IPX: case NA_BROADCAST_IPX: #ifdef USEIPX n = amask->address.ipx; if (i > 80) i = 80; for (; i >= 8; i -= 8) { *n = 0xFF; n++; } // fill last bit if (i) { i = 8 - i; i = 255 - ((1 << i) - 1); *n = i; } #endif break; case NA_LOOPBACK: break; // warning: enumeration value âNA_*â not handled in switch case NA_TCP: case NA_TCPV6: case NA_IRC: break; } } // ParsePartialIPv4: check string to see if it is a partial IPv4 address and // return bits to mask and set netadr_t or 0 if not an address int ParsePartialIPv4(const char *s, netadr_t *a) { const char *colon = NULL; char *address = a->address.ip; int bits = 8; if (!*s) return 0; memset (a, 0, sizeof(*a)); while (*s) { if (*s == ':') { if (colon) // only 1 colon return 0; colon = s + 1; } else if (*s == '.') { if (colon) // no colons before periods (probably invalid anyway) return 0; else if (bits >= 32) // only 32 bits in ipv4 return 0; else if (*(s+1) == '.') return 0; else if (*(s+1) == '\0') break; // don't add more bits to the mask for x.x., etc bits += 8; address++; } else if (*s >= '0' && *s <= '9') *address = ((*address)*10) + (*s-'0'); else return 0; // invalid character s++; } a->type = NA_IP; if (colon) a->port = atoi(colon); return bits; } // NET_StringToAdrMasked: extension to NET_StringToAdr to handle IP addresses // with masks or integers representing the bit masks qboolean NET_StringToAdrMasked (const char *s, netadr_t *a, netadr_t *amask) { char t[64]; char *spoint; int i; spoint = strchr(s, '/'); if (spoint) { // we have a slash in the address so split and resolve separately char *c; i = (int)(spoint - s) + 1; if (i > sizeof(t)) i = sizeof(t); Q_strncpyz(t, s, i); if (!ParsePartialIPv4(t, a) && !NET_StringToAdr(t, a)) return false; spoint++; c = spoint; if (!*c) return false; while (*c) // check for non-numeric characters { if (*c < '0' || *c > '9') { c = NULL; break; } c++; } if (c == NULL) // we have an address so resolve it and return return ParsePartialIPv4(spoint, amask) || NET_StringToAdr(spoint, amask); // otherwise generate mask for given bits i = atoi(spoint); NET_IntegerToMask(a, amask, i); } else { // we don't have a slash, resolve and fill with a full mask i = ParsePartialIPv4(s, a); if (!i && !NET_StringToAdr(s, a)) return false; memset (amask, 0, sizeof(*amask)); amask->type = a->type; if (i) NET_IntegerToMask(a, amask, i); else NET_IntegerToMask(a, amask, -1); } return true; } // NET_CompareAdrMasked: given 3 addresses, 2 to compare with a complimentary mask, // returns true or false if they match qboolean NET_CompareAdrMasked(netadr_t a, netadr_t b, netadr_t mask) { int i; //make sure the address being checked against matches the mask if (b.type != mask.type) return false; // check port if both are non-zero if (a.port && b.port && a.port != b.port) return false; // check to make sure all types match if (a.type != b.type) { if (a.type == NA_IP && b.type == NA_IPV6 && mask.type == NA_IP) { for (i = 0; i < 10; i++) if (b.address.ip6[i] != 0) return false; //only matches if they're 0s, otherwise its not an ipv4 address there for (; i < 12; i++) if (b.address.ip6[i] != 0xff && b.address.ip6[i] != 0x00) //0x00 is depricated return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there for (i = 0; i < 4; i++) { if ((a.address.ip[i] & mask.address.ip[i]) != (b.address.ip6[12+i] & mask.address.ip[i])) return false; //mask doesn't match } return true; //its an ipv4 address in there, the mask matched the whole way through } if (a.type == NA_IPV6 && b.type == NA_IP && mask.type == NA_IP) { for (i = 0; i < 10; i++) if (a.address.ip6[i] != 0) return false; //only matches if they're 0s, otherwise its not an ipv4 address there for (; i < 12; i++) if (a.address.ip6[i] != 0xff && a.address.ip6[i] != 0x00) //0x00 is depricated return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there for (i = 0; i < 4; i++) { if ((a.address.ip6[12+i] & mask.address.ip[i]) != (b.address.ip[i] & mask.address.ip[i])) return false; //mask doesn't match } return true; //its an ipv4 address in there, the mask matched the whole way through } return false; } // match on protocol type and compare address switch (a.type) { case NA_LOOPBACK: return true; case NA_BROADCAST_IP: case NA_IP: for (i = 0; i < 4; i++) { if ((a.address.ip[i] & mask.address.ip[i]) != (b.address.ip[i] & mask.address.ip[i])) return false; } break; #ifdef IPPROTO_IPV6 case NA_BROADCAST_IP6: case NA_IPV6: for (i = 0; i < 16; i++) { if ((a.address.ip6[i] & mask.address.ip6[i]) != (b.address.ip6[i] & mask.address.ip6[i])) return false; } break; #endif #ifdef USEIPX case NA_BROADCAST_IPX: case NA_IPX: for (i = 0; i < 10; i++) { if ((a.address.ipx[i] & mask.address.ipx[i]) != (b.address.ipx[i] & mask.address.ipx[i])) return false; } break; #endif #ifdef IRCCONNECT case NA_IRC: //masks are not supported, match explicitly if (strcmp(a.address.irc.user, b.address.irc.user)) return false; break; #endif default: return false; // invalid protocol } return true; // all checks passed } // UniformMaskedBits: counts number of bits in an assumed uniform mask, returns // -1 if not uniform int UniformMaskedBits(netadr_t mask) { int bits; int b; unsigned int bs; qboolean bitenc = false; switch (mask.type) { case NA_BROADCAST_IP: case NA_IP: bits = 32; for (b = 3; b >= 0; b--) { if (mask.address.ip[b] == 0xFF) bitenc = true; else if (mask.address.ip[b]) { bs = (~mask.address.ip[b]) & 0xFF; while (bs) { if (bs & 1) { bits -= 1; if (bitenc) return -1; } else bitenc = true; bs >>= 1; } } else if (bitenc) return -1; else bits -= 8; } break; #ifdef IPPROTO_IPV6 case NA_BROADCAST_IP6: case NA_IPV6: bits = 128; for (b = 15; b >= 0; b--) { if (mask.address.ip6[b] == 0xFF) bitenc = true; else if (mask.address.ip6[b]) { bs = (~mask.address.ip6[b]) & 0xFF; while (bs) { if (bs & 1) { bits -= 1; if (bitenc) return -1; } else bitenc = true; bs >>= 1; } } else if (bitenc) return -1; else bits -= 8; } break; #endif #ifdef USEIPX case NA_BROADCAST_IPX: case NA_IPX: bits = 80; for (b = 9; b >= 0; b--) { if (mask.address.ipx[b] == 0xFF) bitenc = true; else if (mask.address.ipx[b]) { bs = (~mask.address.ipx[b]) & 0xFF; while (bs) { if (bs & 1) { bits -= 1; if (bitenc) return -1; } else bitenc = true; bs >>= 1; } } else if (bitenc) return -1; else bits -= 8; } break; #endif default: return -1; // invalid protocol } return bits; // all checks passed } char *NET_AdrToStringMasked (char *s, int len, netadr_t a, netadr_t amask) { int i; char adr[MAX_ADR_SIZE], mask[MAX_ADR_SIZE]; i = UniformMaskedBits(amask); if (i >= 0) snprintf(s, len, "%s/%i", NET_AdrToString(adr, sizeof(adr), a), i); else snprintf(s, len, "%s/%s", NET_AdrToString(adr, sizeof(adr), a), NET_AdrToString(mask, sizeof(mask), amask)); return s; } // Returns true if we can't bind the address locally--in other words, // the IP is NOT one of our interfaces. qboolean NET_IsClientLegal(netadr_t *adr) { #if 0 struct sockaddr_in sadr; int newsocket; if (adr->ip[0] == 127) return false; // no local connections period NetadrToSockadr (adr, &sadr); if ((newsocket = socket (PF_INET, SOCK_DGRAM, IPPROTO_UDP)) == INVALID_SOCKET) Sys_Error ("NET_IsClientLegal: socket:", strerror(qerrno)); sadr.sin_port = 0; if( bind (newsocket, (void *)&sadr, sizeof(sadr)) == -1) { // It is not a local address close(newsocket); return true; } close(newsocket); return false; #else return true; #endif } qboolean NET_IsLoopBackAddress (netadr_t adr) { // return (!strcmp(cls.servername, NET_AdrToString(net_local_adr)) || !strcmp(cls.servername, "local"); return adr.type == NA_LOOPBACK; } ///////////////////////////////////////////// //loopback stuff qboolean NET_GetLoopPacket (netsrc_t sock, netadr_t *from, sizebuf_t *message) { int i; loopback_t *loop; loop = &loopbacks[sock]; if (loop->send - loop->get > MAX_LOOPBACK) loop->get = loop->send - MAX_LOOPBACK; if (loop->get >= loop->send) return false; i = loop->get & (MAX_LOOPBACK-1); loop->get++; if (message->maxsize < loop->msgs[i].datalen) Sys_Error("NET_SendLoopPacket: Loopback buffer was too big"); memcpy (message->data, loop->msgs[i].data, loop->msgs[i].datalen); message->cursize = loop->msgs[i].datalen; memset (from, 0, sizeof(*from)); from->type = NA_LOOPBACK; message->packing = SZ_RAWBYTES; message->currentbit = 0; return true; } void NET_SendLoopPacket (netsrc_t sock, int length, void *data, netadr_t to) { int i; loopback_t *loop; loop = &loopbacks[sock^1]; i = loop->send & (MAX_LOOPBACK-1); loop->send++; if (length > sizeof(loop->msgs[i].data)) Sys_Error("NET_SendLoopPacket: Loopback buffer is too small"); memcpy (loop->msgs[i].data, data, length); loop->msgs[i].datalen = length; } //============================================================================= #define FTENET_ADDRTYPES 2 typedef struct ftenet_generic_connection_s { const char *name; int (*GetLocalAddress)(struct ftenet_generic_connection_s *con, netadr_t *local, int adridx); qboolean (*ChangeLocalAddress)(struct ftenet_generic_connection_s *con, const char *newaddress); qboolean (*GetPacket)(struct ftenet_generic_connection_s *con); qboolean (*SendPacket)(struct ftenet_generic_connection_s *con, int length, void *data, netadr_t to); void (*Close)(struct ftenet_generic_connection_s *con); netadrtype_t addrtype[FTENET_ADDRTYPES]; qboolean islisten; int thesocket; } ftenet_generic_connection_t; #define MAX_CONNECTIONS 8 typedef struct ftenet_connections_s { qboolean islisten; ftenet_generic_connection_t *conn[MAX_CONNECTIONS]; } ftenet_connections_t; ftenet_connections_t *FTENET_CreateCollection(qboolean listen) { ftenet_connections_t *col; col = Z_Malloc(sizeof(*col)); col->islisten = listen; return col; } qboolean FTENET_AddToCollection(ftenet_connections_t *col, const char *name, const char *address, ftenet_generic_connection_t *(*establish)(qboolean isserver, const char *address), qboolean islisten) { int count = 0; int i; if (!col) return false; if (name) { for (i = 0; i < MAX_CONNECTIONS; i++) { if (col->conn[i]) if (col->conn[i]->name && !strcmp(col->conn[i]->name, name)) { if (address && *address) if (col->conn[i]->ChangeLocalAddress) { if (col->conn[i]->ChangeLocalAddress(col->conn[i], address)) return true; } col->conn[i]->Close(col->conn[i]); col->conn[i] = NULL; } } } if (address && *address) { for (i = 0; i < MAX_CONNECTIONS; i++) { if (!col->conn[i]) { address = COM_Parse(address); col->conn[i] = establish(islisten, com_token); if (!col->conn[i]) break; col->conn[i]->name = name; count++; if (address && *address) continue; break; } } } return count > 0; } void FTENET_CloseCollection(ftenet_connections_t *col) { int i; if (!col) return; for (i = 0; i < MAX_CONNECTIONS; i++) { if (col->conn[i]) { col->conn[i]->Close(col->conn[i]); } } Z_Free(col); } void FTENET_Generic_Close(ftenet_generic_connection_t *con) { if (con->thesocket != INVALID_SOCKET) closesocket(con->thesocket); Z_Free(con); } #if !defined(CLIENTONLY) && !defined(SERVERONLY) int FTENET_Loop_GetLocalAddress(ftenet_generic_connection_t *con, netadr_t *out, int adrnum) { if (adrnum==0) { out->type = NA_LOOPBACK; out->port = con->islisten+1; } return 1; } qboolean FTENET_Loop_GetPacket(ftenet_generic_connection_t *con) { return NET_GetLoopPacket(con->islisten, &net_from, &net_message); } qboolean FTENET_Loop_SendPacket(ftenet_generic_connection_t *con, int length, void *data, netadr_t to) { if (to.type == NA_LOOPBACK) { NET_SendLoopPacket(con->islisten, length, data, to); return true; } return false; } ftenet_generic_connection_t *FTENET_Loop_EstablishConnection(qboolean isserver, const char *address) { ftenet_generic_connection_t *newcon; newcon = Z_Malloc(sizeof(*newcon)); if (newcon) { newcon->name = "Loopback"; newcon->GetLocalAddress = FTENET_Loop_GetLocalAddress; newcon->GetPacket = FTENET_Loop_GetPacket; newcon->SendPacket = FTENET_Loop_SendPacket; newcon->Close = FTENET_Generic_Close; newcon->islisten = isserver; newcon->addrtype[0] = NA_LOOPBACK; newcon->addrtype[1] = NA_INVALID; newcon->thesocket = INVALID_SOCKET; } return newcon; } #endif int FTENET_Generic_GetLocalAddress(ftenet_generic_connection_t *con, netadr_t *out, int count) { struct sockaddr_qstorage from; int fromsize = sizeof(from); netadr_t adr; char adrs[MAX_ADR_SIZE]; int b; struct hostent *h; int idx = 0; if (getsockname (con->thesocket, (struct sockaddr*)&from, &fromsize) != -1) { memset(&adr, 0, sizeof(adr)); SockadrToNetadr(&from, &adr); if (adr.type == NA_IPV6 && !*(int*)&adr.address.ip6[0] && !*(int*)&adr.address.ip6[4] && !*(short*)&adr.address.ip6[8] && *(short*)&adr.address.ip6[10]==(short)0xffff && !*(int*)&adr.address.ip6[12]) { /*ipv4-mapped address ANY, pretend we read blank*/ b = sizeof(adr.address); } else { for (b = 0; b < sizeof(adr.address); b++) if (((unsigned char*)&adr.address)[b] != 0) break; } if (b == sizeof(adr.address)) { gethostname(adrs, sizeof(adrs)); #ifdef IPPROTO_IPV6 if (pgetaddrinfo) { struct addrinfo hints, *result, *itr; memset(&hints, 0, sizeof(struct addrinfo)); hints.ai_family = 0; /* Allow IPv4 or IPv6 */ hints.ai_socktype = SOCK_DGRAM; /* Datagram socket */ hints.ai_flags = 0; hints.ai_protocol = 0; /* Any protocol */ if (pgetaddrinfo(adrs, NULL, &hints, &result) != 0) { if (idx++ == count) *out = adr; } else { for (itr = result; itr; itr = itr->ai_next) { if (itr->ai_addr->sa_family != ((struct sockaddr_in*)&from)->sin_family) { #ifdef IPV6_V6ONLY if (((struct sockaddr_in*)&from)->sin_family == AF_INET6 && itr->ai_addr->sa_family == AF_INET) { int ipv6only = true; int optlen = sizeof(ipv6only); getsockopt(con->thesocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&ipv6only, &optlen); if (ipv6only) continue; } else #endif continue; } if (idx++ == count) { SockadrToNetadr((struct sockaddr_qstorage*)itr->ai_addr, out); out->port = ((struct sockaddr_in*)&from)->sin_port; } } pfreeaddrinfo(result); /*if none found, fill in the 0.0.0.0 or whatever*/ if (!idx) { idx++; *out = adr; } } } else #endif { h = gethostbyname(adrs); b = 0; if(h && h->h_addrtype == AF_INET) { for (b = 0; h->h_addr_list[b]; b++) { ((struct sockaddr_in*)&from)->sin_family = AF_INET; memcpy(&((struct sockaddr_in*)&from)->sin_addr, h->h_addr_list[b], sizeof(((struct sockaddr_in*)&from)->sin_addr)); SockadrToNetadr(&from, &adr); if (idx++ == count) *out = adr; } } #ifdef IPPROTO_IPV6 else if(h && h->h_addrtype == AF_INET6) { for (b = 0; h->h_addr_list[b]; b++) { ((struct sockaddr_in*)&from)->sin_family = AF_INET6; memcpy(&((struct sockaddr_in6*)&from)->sin6_addr, h->h_addr_list[b], sizeof(((struct sockaddr_in6*)&from)->sin6_addr)); SockadrToNetadr(&from, &adr); if (idx++ == count) *out = adr; } } #endif if (b == 0) { if (idx++ == count) *out = adr; } } } else { if (idx++ == count) *out = adr; } } return idx; } qboolean FTENET_Generic_GetPacket(ftenet_generic_connection_t *con) { struct sockaddr_qstorage from; int fromlen; int ret; int err; char adr[MAX_ADR_SIZE]; if (con->thesocket == INVALID_SOCKET) return false; fromlen = sizeof(from); ret = recvfrom (con->thesocket, (char *)net_message_buffer, sizeof(net_message_buffer), 0, (struct sockaddr*)&from, &fromlen); if (ret == -1) { err = qerrno; if (err == EWOULDBLOCK) return false; if (err == EMSGSIZE) { SockadrToNetadr (&from, &net_from); Con_TPrintf (TL_OVERSIZEPACKETFROM, NET_AdrToString (adr, sizeof(adr), net_from)); return false; } if (err == ECONNABORTED || err == ECONNRESET) { Con_TPrintf (TL_CONNECTIONLOSTORABORTED); //server died/connection lost. #ifndef SERVERONLY if (cls.state != ca_disconnected && !con->islisten) { if (cls.lastarbiatarypackettime+5 < Sys_DoubleTime()) //too many mvdsv Cbuf_AddText("disconnect\nreconnect\n", RESTRICT_LOCAL); //retry connecting. else Con_Printf("Packet was not delivered - server might be badly configured\n"); return false; } #endif return false; } Con_Printf ("NET_GetPacket: Error (%i): %s\n", err, strerror(err)); return false; } SockadrToNetadr (&from, &net_from); net_message.packing = SZ_RAWBYTES; net_message.currentbit = 0; net_message.cursize = ret; if (net_message.cursize == sizeof(net_message_buffer) ) { Con_TPrintf (TL_OVERSIZEPACKETFROM, NET_AdrToString (adr, sizeof(adr), net_from)); return false; } return true; } qboolean FTENET_Generic_SendPacket(ftenet_generic_connection_t *con, int length, void *data, netadr_t to) { struct sockaddr_qstorage addr; int size; int ret; for (size = 0; size < FTENET_ADDRTYPES; size++) if (to.type == con->addrtype[size]) break; if (size == FTENET_ADDRTYPES) return false; #ifdef IPPROTO_IPV6 /*special code to handle sending to hybrid sockets*/ if (con->addrtype[1] == NA_IPV6 && to.type == NA_IP) { memset(&addr, 0, sizeof(struct sockaddr_in6)); ((struct sockaddr_in6*)&addr)->sin6_family = AF_INET6; *(short*)&((struct sockaddr_in6*)&addr)->sin6_addr.s6_addr[10] = 0xffff; *(int*)&((struct sockaddr_in6*)&addr)->sin6_addr.s6_addr[12] = *(int*)&to.address.ip; ((struct sockaddr_in6*)&addr)->sin6_port = to.port; size = sizeof(struct sockaddr_in6); } else #endif { NetadrToSockadr (&to, &addr); switch(to.type) { default: Con_Printf("Bad address type\n"); break; #ifdef USEIPX //who uses ipx nowadays anyway? case NA_BROADCAST_IPX: case NA_IPX: size = sizeof(struct sockaddr_ipx); break; #endif case NA_BROADCAST_IP: case NA_IP: size = sizeof(struct sockaddr_in); break; #ifdef IPPROTO_IPV6 case NA_BROADCAST_IP6: case NA_IPV6: size = sizeof(struct sockaddr_in6); break; #endif } } ret = sendto (con->thesocket, data, length, 0, (struct sockaddr*)&addr, size ); if (ret == -1) { int ecode = qerrno; // wouldblock is silent if (ecode == EWOULDBLOCK) return true; if (ecode == ECONNREFUSED) return true; #ifndef SERVERONLY if (ecode == EADDRNOTAVAIL) Con_DPrintf("NET_SendPacket Warning: %i\n", ecode); else #endif Con_TPrintf (TL_NETSENDERROR, ecode); } return true; } qboolean NET_PortToAdr (int adrfamily, const char *s, netadr_t *a) { char *e; int port; port = strtoul(s, &e, 10); if (*e) return NET_StringToAdr(s, a); else if (port) { memset(a, 0, sizeof(*a)); a->port = htons((unsigned short)port); if (adrfamily == AF_INET) a->type = NA_IP; #ifdef IPPROTO_IPV6 else if (adrfamily == AF_INET6) a->type = NA_IPV6; #endif #ifdef USEIPX else if (adrfamily == AF_IPX) a->type = NA_IPX; #endif else { a->type = NA_INVALID; return false; } return true; } a->type = NA_INVALID; return false; } ftenet_generic_connection_t *FTENET_Generic_EstablishConnection(int adrfamily, int protocol, qboolean isserver, const char *address) { //this is written to support either ipv4 or ipv6, depending on the remote addr. ftenet_generic_connection_t *newcon; unsigned long _true = true; SOCKET newsocket = INVALID_SOCKET; int temp; netadr_t adr; struct sockaddr_qstorage qs; int family; int port; int bindtries; int bufsz; qboolean hybrid = false; if (!NET_PortToAdr(adrfamily, address, &adr)) { Con_Printf("unable to resolve local address %s\n", address); return NULL; //couldn't resolve the name } temp = NetadrToSockadr(&adr, &qs); family = ((struct sockaddr*)&qs)->sa_family; #ifdef IPV6_V6ONLY if (isserver && family == AF_INET && net_hybriddualstack.ival && !((struct sockaddr_in*)&qs)->sin_addr.s_addr) { unsigned long _false = false; if ((newsocket = socket (AF_INET6, SOCK_DGRAM, protocol)) != INVALID_SOCKET) { if (0 == setsockopt(newsocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_false, sizeof(_false))) { int ip = ((struct sockaddr_in*)&qs)->sin_addr.s_addr; int port = ((struct sockaddr_in*)&qs)->sin_port; ip = ((struct sockaddr_in*)&qs)->sin_addr.s_addr; memset(&qs, 0, sizeof(struct sockaddr_in6)); ((struct sockaddr_in6*)&qs)->sin6_family = AF_INET6; /* if (((struct sockaddr_in*)&qs)->sin_addr.s_addr) { ((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[10] = 0xff; ((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[11] = 0xff; ((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[12] = ((qbyte*)&ip)[0]; ((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[13] = ((qbyte*)&ip)[1]; ((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[14] = ((qbyte*)&ip)[2]; ((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[15] = ((qbyte*)&ip)[3]; } */ ((struct sockaddr_in6*)&qs)->sin6_port = port; temp = sizeof(struct sockaddr_in6); hybrid = true; } else { /*v6only failed... if the option doesn't exist, chances are this is a hybrid system which doesn't support both simultaneously anyway*/ closesocket(newsocket); newsocket = INVALID_SOCKET; } } } #endif if (newsocket == INVALID_SOCKET) if ((newsocket = socket (family, SOCK_DGRAM, protocol)) == INVALID_SOCKET) { return NULL; } #ifdef IPV6_V6ONLY if (family == AF_INET6) setsockopt(newsocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_true, sizeof(_true)); #endif bufsz = 1<<18; setsockopt(newsocket, SOL_SOCKET, SO_RCVBUF, (void*)&bufsz, sizeof(bufsz)); //try and find an unused port. port = ntohs(((struct sockaddr_in*)&qs)->sin_port); for (bindtries = 100; bindtries > 0; bindtries--) { ((struct sockaddr_in*)&qs)->sin_port = htons((unsigned short)(port+100-bindtries)); if ((bind(newsocket, (struct sockaddr *)&qs, temp) == INVALID_SOCKET)) { continue; } break; } if (!bindtries) { SockadrToNetadr(&qs, &adr); //mneh, reuse qs. NET_AdrToString((char*)&qs, sizeof(qs), adr); Con_Printf("Unable to listen at %s\n", (char*)&qs); closesocket(newsocket); return NULL; } if (ioctlsocket (newsocket, FIONBIO, &_true) == -1) Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(qerrno)); // // determine my name & address if we don't already know it // if (!net_local_cl_ipadr.type == NA_INVALID) NET_GetLocalAddress (newsocket, &net_local_cl_ipadr); newcon = Z_Malloc(sizeof(*newcon)); if (newcon) { newcon->name = "Generic"; newcon->GetLocalAddress = FTENET_Generic_GetLocalAddress; newcon->GetPacket = FTENET_Generic_GetPacket; newcon->SendPacket = FTENET_Generic_SendPacket; newcon->Close = FTENET_Generic_Close; newcon->islisten = isserver; if (hybrid) { newcon->addrtype[0] = NA_IP; newcon->addrtype[1] = NA_IPV6; } else { newcon->addrtype[0] = adr.type; newcon->addrtype[1] = NA_INVALID; } newcon->thesocket = newsocket; return newcon; } else { closesocket(newsocket); return NULL; } } #ifdef IPPROTO_IPV6 ftenet_generic_connection_t *FTENET_UDP6_EstablishConnection(qboolean isserver, const char *address) { return FTENET_Generic_EstablishConnection(AF_INET6, IPPROTO_UDP, isserver, address); } #endif ftenet_generic_connection_t *FTENET_UDP4_EstablishConnection(qboolean isserver, const char *address) { return FTENET_Generic_EstablishConnection(AF_INET, IPPROTO_UDP, isserver, address); } #ifdef USEIPX ftenet_generic_connection_t *FTENET_IPX_EstablishConnection(qboolean isserver, const char *address) { return FTENET_Generic_EstablishConnection(AF_IPX, NSPROTO_IPX, isserver, address); } #endif #ifdef TCPCONNECT typedef struct ftenet_tcpconnect_stream_s { int socketnum; int inlen; qboolean waitingforprotocolconfirmation; char inbuffer[1500]; float timeouttime; netadr_t remoteaddr; struct ftenet_tcpconnect_stream_s *next; } ftenet_tcpconnect_stream_t; typedef struct { ftenet_generic_connection_t generic; int active; ftenet_tcpconnect_stream_t *tcpstreams; } ftenet_tcpconnect_connection_t; qboolean FTENET_TCPConnect_GetPacket(ftenet_generic_connection_t *gcon) { ftenet_tcpconnect_connection_t *con = (ftenet_tcpconnect_connection_t*)gcon; int ret; int err; char adr[MAX_ADR_SIZE]; struct sockaddr_qstorage from; int fromlen; float timeval = Sys_DoubleTime(); ftenet_tcpconnect_stream_t *st; st = con->tcpstreams; //remove any stale ones while (con->tcpstreams && con->tcpstreams->socketnum == INVALID_SOCKET) { st = con->tcpstreams; con->tcpstreams = con->tcpstreams->next; BZ_Free(st); } for (st = con->tcpstreams; st; st = st->next) {//client receiving only via tcp while (st->next && st->next->socketnum == INVALID_SOCKET) { ftenet_tcpconnect_stream_t *temp; temp = st->next; st->next = st->next->next; BZ_Free(temp); con->active--; } //due to the above checks about invalid sockets, the socket is always open for st below. if (st->timeouttime < timeval) goto closesvstream; ret = recv(st->socketnum, st->inbuffer+st->inlen, sizeof(st->inbuffer)-st->inlen, 0); if (ret == 0) goto closesvstream; else if (ret == -1) { err = qerrno; if (err == EWOULDBLOCK) ret = 0; else { if (err == ECONNABORTED || err == ECONNRESET) { Con_TPrintf (TL_CONNECTIONLOSTORABORTED); //server died/connection lost. } else Con_Printf ("TCPConnect_GetPacket: Error (%i): %s\n", err, strerror(err)); closesvstream: closesocket(st->socketnum); st->socketnum = INVALID_SOCKET; continue; } } st->inlen += ret; if (st->waitingforprotocolconfirmation) { if (st->inlen < 6) continue; if (strncmp(st->inbuffer, "qizmo\n", 6)) { Con_Printf ("Unknown TCP client\n"); goto closesvstream; } memmove(st->inbuffer, st->inbuffer+6, st->inlen - (6)); st->inlen -= 6; st->waitingforprotocolconfirmation = false; } if (st->inlen < 2) continue; net_message.cursize = BigShort(*(short*)st->inbuffer); if (net_message.cursize >= sizeof(net_message_buffer) ) { Con_TPrintf (TL_OVERSIZEPACKETFROM, NET_AdrToString (adr, sizeof(adr), net_from)); goto closesvstream; } if (net_message.cursize+2 > st->inlen) { //not enough buffered to read a packet out of it. continue; } memcpy(net_message_buffer, st->inbuffer+2, net_message.cursize); memmove(st->inbuffer, st->inbuffer+net_message.cursize+2, st->inlen - (net_message.cursize+2)); st->inlen -= net_message.cursize+2; net_message.packing = SZ_RAWBYTES; net_message.currentbit = 0; net_from = st->remoteaddr; return true; } if (con->generic.thesocket != INVALID_SOCKET && con->active < 256) { int newsock; fromlen = sizeof(from); newsock = accept(con->generic.thesocket, (struct sockaddr*)&from, &fromlen); if (newsock != INVALID_SOCKET) { int _true = true; ioctlsocket(newsock, FIONBIO, (u_long *)&_true); setsockopt(newsock, IPPROTO_TCP, TCP_NODELAY, (char *)&_true, sizeof(_true)); con->active++; st = Z_Malloc(sizeof(*con->tcpstreams)); st->waitingforprotocolconfirmation = true; st->next = con->tcpstreams; con->tcpstreams = st; st->socketnum = newsock; st->inlen = 0; /*grab the net address*/ SockadrToNetadr(&from, &st->remoteaddr); /*sockadr doesn't contain transport info, so fix that up here*/ if (st->remoteaddr.type == NA_IP) st->remoteaddr.type = NA_TCP; else if (st->remoteaddr.type == NA_IPV6) st->remoteaddr.type = NA_TCPV6; //send the qizmo greeting. send(newsock, "qizmo\n", 6, 0); st->timeouttime = timeval + 30; } } return false; } qboolean FTENET_TCPConnect_SendPacket(ftenet_generic_connection_t *gcon, int length, void *data, netadr_t to) { ftenet_tcpconnect_connection_t *con = (ftenet_tcpconnect_connection_t*)gcon; ftenet_tcpconnect_stream_t *st; for (st = con->tcpstreams; st; st = st->next) { if (st->socketnum == INVALID_SOCKET) continue; if (NET_CompareAdr(to, st->remoteaddr)) { unsigned short slen = BigShort((unsigned short)length); #pragma warningmsg("TCPConnect: these calls can fail, corrupting the message stream") send(st->socketnum, (char*)&slen, sizeof(slen), 0); send(st->socketnum, data, length, 0); st->timeouttime = Sys_DoubleTime() + 20; return true; } } return false; } void FTENET_TCPConnect_Close(ftenet_generic_connection_t *gcon) { ftenet_tcpconnect_connection_t *con = (ftenet_tcpconnect_connection_t*)gcon; ftenet_tcpconnect_stream_t *st; st = con->tcpstreams; while (con->tcpstreams) { st = con->tcpstreams; con->tcpstreams = st->next; if (st->socketnum != INVALID_SOCKET) closesocket(st->socketnum); BZ_Free(st); } FTENET_Generic_Close(gcon); } ftenet_generic_connection_t *FTENET_TCPConnect_EstablishConnection(int affamily, qboolean isserver, const char *address) { //this is written to support either ipv4 or ipv6, depending on the remote addr. ftenet_tcpconnect_connection_t *newcon; unsigned long _true = true; int newsocket; int temp; netadr_t adr; struct sockaddr_qstorage qs; int family; if (!strncmp(address, "tcp://", 6)) address += 6; if (isserver) { if (!NET_PortToAdr(affamily, address, &adr)) return NULL; //couldn't resolve the name if (adr.type == NA_IP) adr.type = NA_TCP; temp = NetadrToSockadr(&adr, &qs); family = ((struct sockaddr_in*)&qs)->sin_family; if ((newsocket = socket (family, SOCK_STREAM, IPPROTO_TCP)) == INVALID_SOCKET) { Con_Printf("operating system doesn't support that\n"); return NULL; } if ((bind(newsocket, (struct sockaddr *)&qs, temp) == INVALID_SOCKET) || (listen(newsocket, 2) == INVALID_SOCKET)) { SockadrToNetadr(&qs, &adr); //mneh, reuse qs. NET_AdrToString((char*)&qs, sizeof(qs), adr); Con_Printf("Unable to listen at %s\n", (char*)&qs); closesocket(newsocket); return NULL; } if (ioctlsocket (newsocket, FIONBIO, &_true) == -1) Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(qerrno)); } else { if (!NET_PortToAdr(affamily, address, &adr)) return NULL; //couldn't resolve the name if (adr.type == NA_IP) adr.type = NA_TCP; newsocket = TCP_OpenStream(adr); if (newsocket == INVALID_SOCKET) return NULL; } //this isn't fatal setsockopt(newsocket, IPPROTO_TCP, TCP_NODELAY, (char *)&_true, sizeof(_true)); newcon = Z_Malloc(sizeof(*newcon)); if (newcon) { newcon->generic.name = "TCPConnect"; if (isserver) newcon->generic.GetLocalAddress = FTENET_Generic_GetLocalAddress; newcon->generic.GetPacket = FTENET_TCPConnect_GetPacket; newcon->generic.SendPacket = FTENET_TCPConnect_SendPacket; newcon->generic.Close = FTENET_TCPConnect_Close; newcon->generic.islisten = isserver; newcon->generic.addrtype[0] = adr.type; newcon->generic.addrtype[1] = NA_INVALID; newcon->active = 0; if (!isserver) { newcon->generic.thesocket = INVALID_SOCKET; newcon->active++; newcon->tcpstreams = Z_Malloc(sizeof(*newcon->tcpstreams)); newcon->tcpstreams->waitingforprotocolconfirmation = true; newcon->tcpstreams->next = NULL; newcon->tcpstreams->socketnum = newsocket; newcon->tcpstreams->inlen = 0; newcon->tcpstreams->remoteaddr = adr; //send the qizmo greeting. send(newsocket, "qizmo\n", 6, 0); newcon->tcpstreams->timeouttime = Sys_DoubleTime() + 30; } else { newcon->tcpstreams = NULL; newcon->generic.thesocket = newsocket; } return &newcon->generic; } else { closesocket(newsocket); return NULL; } } #ifdef IPPROTO_IPV6 ftenet_generic_connection_t *FTENET_TCP6Connect_EstablishConnection(qboolean isserver, const char *address) { return FTENET_TCPConnect_EstablishConnection(AF_INET6, isserver, address); } #endif ftenet_generic_connection_t *FTENET_TCP4Connect_EstablishConnection(qboolean isserver, const char *address) { return FTENET_TCPConnect_EstablishConnection(AF_INET, isserver, address); } #endif #ifdef IRCCONNECT typedef struct ftenet_ircconnect_stream_s { char theiruser[16]; int inlen; char inbuffer[1500]; float timeouttime; netadr_t remoteaddr; struct ftenet_ircconnect_stream_s *next; } ftenet_ircconnect_stream_t; typedef struct { ftenet_generic_connection_t generic; netadr_t ircserver; char incoming[512+1]; int income; char ourusername[16]; char usechannel[16]; char outbuf[8192]; unsigned int outbufcount; ftenet_ircconnect_stream_t *streams; } ftenet_ircconnect_connection_t; qboolean FTENET_IRCConnect_GetPacket(ftenet_generic_connection_t *gcon) { unsigned char *s, *start, *end, *endl; int read; unsigned char *from; int fromlen; int code; char adr[128]; ftenet_ircconnect_connection_t *con = (ftenet_ircconnect_connection_t*)gcon; if (con->generic.thesocket == INVALID_SOCKET) { if (con->income == 0) { cvar_t *ircuser = Cvar_Get("ircuser", "none", 0, "IRC Connect"); cvar_t *irchost = Cvar_Get("irchost", "none", 0, "IRC Connect"); cvar_t *ircnick = Cvar_Get("ircnick", "ftesv", 0, "IRC Connect"); //cvar_t *ircchannel = Cvar_Get("ircchannel", "#ftetest", 0, "IRC Connect"); //warning: unused variable ‘ircchannel’ cvar_t *ircsomething = Cvar_Get("ircsomething", "moo", 0, "IRC Connect"); cvar_t *ircclientaddr = Cvar_Get("ircclientaddr", "127.0.0.1", 0, "IRC Connect"); con->generic.thesocket = TCP_OpenStream(con->ircserver); Q_strncpyz(con->ourusername, ircnick->string, sizeof(con->ourusername)); send(con->generic.thesocket, "USER ", 5, 0); send(con->generic.thesocket, ircuser->string, strlen(ircuser->string), 0); send(con->generic.thesocket, " ", 1, 0); send(con->generic.thesocket, irchost->string, strlen(irchost->string), 0); send(con->generic.thesocket, " ", 1, 0); send(con->generic.thesocket, ircclientaddr->string, strlen(ircclientaddr->string), 0); send(con->generic.thesocket, " :", 2, 0); send(con->generic.thesocket, ircsomething->string, strlen(ircsomething->string), 0); send(con->generic.thesocket, "\r\n", 2, 0); send(con->generic.thesocket, "NICK ", 5, 0); send(con->generic.thesocket, con->ourusername, strlen(con->ourusername), 0); send(con->generic.thesocket, "\r\n", 2, 0); } } else { read = recv(con->generic.thesocket, con->incoming+con->income, sizeof(con->incoming)-1 - con->income, 0); if (read < 0) { read = qerrno; switch(read) { case ECONNABORTED: case ECONNRESET: closesocket(con->generic.thesocket); con->generic.thesocket = INVALID_SOCKET; break; default: break; } read = 0;//return false; } else if (read == 0) //they disconnected. { closesocket(con->generic.thesocket); con->generic.thesocket = INVALID_SOCKET; } con->income += read; con->incoming[con->income] = 0; } start = con->incoming; end = start+con->income; while (start < end) { endl = NULL; for (s = start; s < end; s++) { if (*s == '\n') { endl = s; break; } } if (endl == NULL) //not got a complete command. break; s = start; while(*s == ' ') s++; if (*s == ':') { s++; from = s; while(s sizeof(net_from.address.irc.user)-1) fromlen = sizeof(net_from.address.irc.user)-1; for (code = 0; code < fromlen; code++) if (from[code] == '!') { fromlen = code; break; } net_from.type = NA_IRC; memcpy(net_from.address.irc.user, from, fromlen); net_from.address.irc.user[fromlen] = 0; dest = s; //discard the destination name while(s= sizeof(net_from.address.irc.channel)) { //no space, just pretend it was direct. net_from.address.irc.channel[0] = 0; } else { memcpy(net_from.address.irc.channel, dest, s-dest); net_from.address.irc.channel[s-dest] = 0; if (!strcmp(net_from.address.irc.channel, con->ourusername)) { //this was aimed at us. clear the channel. net_from.address.irc.channel[0] = 0; } } while(*s == ' ') s++; if (*s == ':') { s++; if (*s == '!') { s++; /*interpret as a connectionless packet*/ net_message.cursize = 4 + endl - s; if (net_message.cursize >= sizeof(net_message_buffer) ) { Con_TPrintf (TL_OVERSIZEPACKETFROM, NET_AdrToString (adr, sizeof(adr), net_from)); break; } *(unsigned int*)net_message_buffer = ~0; memcpy(net_message_buffer+4, s, net_message.cursize); net_message.packing = SZ_RAWBYTES; net_message.currentbit = 0; //clean up the incoming data memmove(con->incoming, start, end - (endl+1)); con->income = end - (endl+1); con->incoming[con->income] = 0; return true; } if (*s == '$') { unsigned char *nstart = s; while (*s != '\r' && *s != '\n' && *s != '#' && *s != ' ' && *s != ':') s++; if (*s == '#') { if (strncmp(nstart, con->ourusername, strlen(con->ourusername)) || strlen(con->ourusername) != s - nstart) while(*s == '#') s++; } } if (*s == '#') { ftenet_ircconnect_stream_t *st; int psize; for (st = con->streams; st; st = st->next) { if (!strncmp(st->remoteaddr.address.irc.user, from, fromlen) && st->remoteaddr.address.irc.user[fromlen] == 0) break; } if (!st) { st = Z_Malloc(sizeof(*st)); st->remoteaddr = net_from; st->next = con->streams; con->streams = st; } //skip over the hash s++; psize = 0; if (*s >= 'a' && *s <= 'f') psize += *s - 'a' + 10; else if (*s >= '0' && *s <= '9') psize += *s - '0'; s++; psize*=16; if (*s >= 'a' && *s <= 'f') psize += *s - 'a' + 10; else if (*s >= '0' && *s <= '9') psize += *s - '0'; s++; psize*=16; if (*s >= 'a' && *s <= 'f') psize += *s - 'a' + 10; else if (*s >= '0' && *s <= '9') psize += *s - '0'; s++; while (s < endl && st->inlen < sizeof(st->inbuffer)) { switch (*s) { //handle markup case '\\': s++; if (s < endl) { switch(*s) { case '\\': st->inbuffer[st->inlen++] = *s; break; case 'n': st->inbuffer[st->inlen++] = '\n'; break; case 'r': st->inbuffer[st->inlen++] = '\r'; break; case '0': st->inbuffer[st->inlen++] = 0; break; default: st->inbuffer[st->inlen++] = '?'; break; } } break; //ignore these case '\n': case '\r': case '\0': //this one doesn't have to be ignored. break; //handle normal char default: st->inbuffer[st->inlen++] = *s; break; } s++; } if (st->inlen > psize || psize >= sizeof(net_message_buffer) ) { st->inlen = 0; Con_Printf ("Corrupt packet from %s\n", NET_AdrToString (adr, sizeof(adr), net_from)); } else if (st->inlen == psize) { /*interpret as a connectionless packet*/ net_message.cursize = st->inlen; if (net_message.cursize >= sizeof(net_message_buffer) ) { Con_TPrintf (TL_OVERSIZEPACKETFROM, NET_AdrToString (adr, sizeof(adr), net_from)); break; } memcpy(net_message_buffer, st->inbuffer, net_message.cursize); net_message.packing = SZ_RAWBYTES; net_message.currentbit = 0; st->inlen = 0; //clean up the incoming data memmove(con->incoming, start, end - (endl+1)); con->income = end - (endl+1); con->incoming[con->income] = 0; return true; } } } } else if (!strncmp(s, "PING ", 5)) { send(con->generic.thesocket, "PONG ", 5, 0); send(con->generic.thesocket, s+5, endl - s - 5, 0); send(con->generic.thesocket, "\r\n", 2, 0); } else { code = strtoul(s, (char **)&s, 10); switch (code) { case 001: { cvar_t *ircchannel = Cvar_Get("ircchannel", "", 0, "IRC Connect"); if (*ircchannel->string) { send(con->generic.thesocket, "JOIN ", 5, 0); send(con->generic.thesocket, ircchannel->string, strlen(ircchannel->string), 0); send(con->generic.thesocket, "\r\n", 2, 0); } } break; case 433: //nick already in use send(con->generic.thesocket, "NICK ", 5, 0); { cvar_t *ircnick2 = Cvar_Get("ircnick2", "YIBBLE", 0, "IRC Connect"); Q_strncpyz(con->ourusername, ircnick2->string, sizeof(con->ourusername)); send(con->generic.thesocket, con->ourusername, strlen(con->ourusername), 0); } send(con->generic.thesocket, "\r\n", 2, 0); break; case 0: //non-numerical event. break; } } while(*s == ' ') s++; start = s = endl+1; } memmove(con->incoming, start, end - start); con->income = end - start; con->incoming[con->income] = 0; if (con->generic.thesocket == INVALID_SOCKET) con->income = 0; return false; } qboolean FTENET_IRCConnect_SendPacket(ftenet_generic_connection_t *gcon, int length, void *data, netadr_t to) { ftenet_ircconnect_connection_t *con = (ftenet_ircconnect_connection_t*)gcon; unsigned char *buffer; unsigned char *lenofs; int packed; int fulllen = length; int newoutcount; for (packed = 0; packed < FTENET_ADDRTYPES; packed++) if (to.type == con->generic.addrtype[packed]) break; if (packed == FTENET_ADDRTYPES) return false; packed = 0; if (con->generic.thesocket == INVALID_SOCKET) return true; /* if (*(unsigned int *)data == ~0 && !strchr(data, '\n') && !strchr(data, '\r') && strlen(data) == length) { if (send(con->generic.thesocket, va("PRIVMSG %s :!", to.address.irc.user), 15, 0) != 15) Con_Printf("bad send\n"); else if (send(con->generic.thesocket, (char*)data+4, length - 4, 0) != length-4) Con_Printf("bad send\n"); else if (send(con->generic.thesocket, "\r\n", 2, 0) != 2) Con_Printf("bad send\n"); return true; } */ newoutcount = con->outbufcount; if (!con->outbufcount) while(length) { buffer = con->outbuf + newoutcount; if (*to.address.irc.channel) { int unamelen; int chanlen; unamelen = strlen(to.address.irc.user); chanlen = strlen(to.address.irc.channel); packed = 8+chanlen+3+unamelen+1 + 3; if (packed+1 + newoutcount > sizeof(con->outbuf)) break; memcpy(buffer, "PRIVMSG ", 8); memcpy(buffer+8, to.address.irc.channel, chanlen); memcpy(buffer+8+chanlen, " :$", 3); memcpy(buffer+8+chanlen+3, to.address.irc.user, unamelen); memcpy(buffer+8+chanlen+3+unamelen, "#", 1); lenofs = buffer+8+chanlen+3+unamelen+1; sprintf(lenofs, "%03x", fulllen); } else { int unamelen; unamelen = strlen(to.address.irc.user); packed = 8 + unamelen + 3 + 3; if (packed+1 + newoutcount > sizeof(con->outbuf)) break; memcpy(buffer, "PRIVMSG ", 8); memcpy(buffer+8, to.address.irc.user, unamelen); memcpy(buffer+8+unamelen, " :#", 3); lenofs = buffer+8+unamelen+3; sprintf(lenofs, "%03x", fulllen); } while(length && packed < 400 && packed+newoutcount < sizeof(con->outbuf)-2) //make sure there's always space { switch(*(unsigned char*)data) { case '\\': buffer[packed++] = '\\'; buffer[packed++] = '\\'; break; case '\n': buffer[packed++] = '\\'; buffer[packed++] = 'n'; break; case '\r': buffer[packed++] = '\\'; buffer[packed++] = 'r'; break; case '\0': buffer[packed++] = '\\'; buffer[packed++] = '0'; break; default: buffer[packed++] = *(unsigned char*)data; break; } length--; data = (char*)data + 1; } buffer[packed++] = '\r'; buffer[packed++] = '\n'; newoutcount += packed; packed = 0; } if (!length) { //only if we flushed all con->outbufcount = newoutcount; } //try and flush it length = send(con->generic.thesocket, con->outbuf, con->outbufcount, 0); if (length > 0) { memmove(con->outbuf, con->outbuf+length, con->outbufcount-length); con->outbufcount -= length; } return true; } void FTENET_IRCConnect_Close(ftenet_generic_connection_t *gcon) { ftenet_ircconnect_connection_t *con = (ftenet_ircconnect_connection_t *)gcon; ftenet_ircconnect_stream_t *st; while(con->streams) { st = con->streams; con->streams = st->next; Z_Free(st); } FTENET_Generic_Close(gcon); } struct ftenet_generic_connection_s *FTENET_IRCConnect_EstablishConnection(qboolean isserver, const char *address) { //this is written to support either ipv4 or ipv6, depending on the remote addr. ftenet_ircconnect_connection_t *newcon; netadr_t adr; if (!NET_StringToAdr(address, &adr)) return NULL; //couldn't resolve the name newcon = Z_Malloc(sizeof(*newcon)); if (newcon) { newcon->generic.name = "IRCConnect"; newcon->generic.GetPacket = FTENET_IRCConnect_GetPacket; newcon->generic.SendPacket = FTENET_IRCConnect_SendPacket; newcon->generic.Close = FTENET_IRCConnect_Close; newcon->generic.islisten = isserver; newcon->generic.addrtype[0] = NA_IRC; newcon->generic.addrtype[1] = NA_INVALID; newcon->generic.thesocket = INVALID_SOCKET; newcon->ircserver = adr; return &newcon->generic; } else { return NULL; } } #endif /*firstsock is a cookie*/ int NET_GetPacket (netsrc_t netsrc, int firstsock) { ftenet_connections_t *collection; if (netsrc == NS_SERVER) { #ifdef CLIENTONLY Sys_Error("NET_GetPacket: Bad netsrc"); collection = NULL; #else collection = svs.sockets; #endif } else { #ifdef SERVERONLY Sys_Error("NET_GetPacket: Bad netsrc"); collection = NULL; #else collection = cls.sockets; #endif } if (!collection) return -1; for (; firstsock < MAX_CONNECTIONS; firstsock+=1) { if (!collection->conn[firstsock]) break; if (collection->conn[firstsock]->GetPacket(collection->conn[firstsock])) { net_from.connum = firstsock+1; return firstsock; } } return -1; } int NET_LocalAddressForRemote(ftenet_connections_t *collection, netadr_t *remote, netadr_t *local, int idx) { if (!remote->connum) return 0; if (!collection->conn[remote->connum-1]) return 0; if (!collection->conn[remote->connum-1]->GetLocalAddress) return 0; return collection->conn[remote->connum-1]->GetLocalAddress(collection->conn[remote->connum-1], local, idx); } void NET_SendPacket (netsrc_t netsrc, int length, void *data, netadr_t to) { ftenet_connections_t *collection; int i; if (netsrc == NS_SERVER) { #ifdef CLIENTONLY Sys_Error("NET_GetPacket: Bad netsrc"); return; #else collection = svs.sockets; #endif } else { #ifdef SERVERONLY Sys_Error("NET_GetPacket: Bad netsrc"); return; #else collection = cls.sockets; #endif } if (!collection) return; if (to.connum) { if (collection->conn[to.connum-1]) if (collection->conn[to.connum-1]->SendPacket(collection->conn[to.connum-1], length, data, to)) return; } for (i = 0; i < MAX_CONNECTIONS; i++) { if (!collection->conn[i]) continue; if (collection->conn[i]->SendPacket(collection->conn[i], length, data, to)) return; } Con_Printf("No route - open some ports\n"); } qboolean NET_EnsureRoute(ftenet_connections_t *collection, char *routename, char *host, qboolean islisten) { netadr_t adr; NET_StringToAdr(host, &adr); switch(adr.type) { #ifdef TCPCONNECT case NA_TCP: if (!FTENET_AddToCollection(collection, routename, host, FTENET_TCP4Connect_EstablishConnection, islisten)) return false; break; #ifdef IPPROTO_IPV6 case NA_TCPV6: if (!FTENET_AddToCollection(collection, routename, host, FTENET_TCP6Connect_EstablishConnection, islisten)) return false; break; #endif #endif #ifdef IRCCONNECT case NA_IRC: if (!FTENET_AddToCollection(collection, routename, host, FTENET_IRCConnect_EstablishConnection, islisten)) return false; break; #endif default: //not recognised, or not needed break; } return true; } void NET_PrintAddresses(ftenet_connections_t *collection) { int i; int adrno, adrcount=1; netadr_t adr; char adrbuf[MAX_ADR_SIZE]; if (!collection) return; for (i = 0; i < MAX_CONNECTIONS; i++) { if (!collection->conn[i]) continue; if (collection->conn[i]->GetLocalAddress) { for (adrno = 0, adrcount=1; (adrcount = collection->conn[i]->GetLocalAddress(collection->conn[i], &adr, adrno)) && adrno < adrcount; adrno++) { Con_Printf("net address: %s\n", NET_AdrToString(adrbuf, sizeof(adrbuf), adr)); } } else Con_Printf("%s\n", collection->conn[i]->name); } } //============================================================================= int TCP_OpenStream (netadr_t remoteaddr) { unsigned long _true = true; int newsocket; int temp; struct sockaddr_qstorage qs; // struct sockaddr_qstorage loc; temp = NetadrToSockadr(&remoteaddr, &qs); if ((newsocket = socket (((struct sockaddr_in*)&qs)->sin_family, SOCK_STREAM, IPPROTO_TCP)) == INVALID_SOCKET) return INVALID_SOCKET; // memset(&loc, 0, sizeof(loc)); // ((struct sockaddr*)&loc)->sa_family = ((struct sockaddr*)&loc)->sa_family; // bind(newsocket, (struct sockaddr *)&loc, ((struct sockaddr_in*)&qs)->sin_family == AF_INET?sizeof(struct sockaddr_in):sizeof(struct sockaddr_in6)); if (connect(newsocket, (struct sockaddr *)&qs, temp) == INVALID_SOCKET) { closesocket(newsocket); return INVALID_SOCKET; } if (ioctlsocket (newsocket, FIONBIO, &_true) == -1) Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(qerrno)); return newsocket; } int TCP_OpenListenSocket (int port) { int newsocket; struct sockaddr_in address; unsigned long _true = true; int i; int maxport = port + 100; if ((newsocket = socket (PF_INET, SOCK_STREAM, IPPROTO_TCP)) == INVALID_SOCKET) return INVALID_SOCKET; if (ioctlsocket (newsocket, FIONBIO, &_true) == -1) Sys_Error ("TCP_OpenListenSocket: ioctl FIONBIO: %s", strerror(qerrno)); address.sin_family = AF_INET; //ZOID -- check for interface binding option if ((i = COM_CheckParm("-ip")) != 0 && i < com_argc) { address.sin_addr.s_addr = inet_addr(com_argv[i+1]); Con_TPrintf(TL_NETBINDINTERFACE, inet_ntoa(address.sin_addr)); } else address.sin_addr.s_addr = INADDR_ANY; for(;;) { if (port == PORT_ANY) address.sin_port = 0; else address.sin_port = htons((short)port); if( bind (newsocket, (void *)&address, sizeof(address)) == -1) { if (!port) { Con_Printf("Cannot bind tcp socket\n"); closesocket(newsocket); return INVALID_SOCKET; } port++; if (port > maxport) { Con_Printf("Cannot bind tcp socket\n"); closesocket(newsocket); return INVALID_SOCKET; } } else break; } if (listen(newsocket, 1) == INVALID_SOCKET) { Con_Printf("Cannot listen on tcp socket\n"); closesocket(newsocket); return INVALID_SOCKET; } return newsocket; } int UDP_OpenSocket (int port, qboolean bcast) { SOCKET newsocket; struct sockaddr_in address; unsigned long _true = true; int i; int maxport = port + 100; if ((newsocket = socket (PF_INET, SOCK_DGRAM, IPPROTO_UDP)) == INVALID_SOCKET) return INVALID_SOCKET; if (ioctlsocket (newsocket, FIONBIO, &_true) == -1) Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(qerrno)); if (bcast) { _true = true; if (setsockopt(newsocket, SOL_SOCKET, SO_BROADCAST, (char *)&_true, sizeof(_true)) == -1) { Con_Printf("Cannot create broadcast socket\n"); return INVALID_SOCKET; } } address.sin_family = AF_INET; //ZOID -- check for interface binding option if ((i = COM_CheckParm("-ip")) != 0 && i < com_argc) { address.sin_addr.s_addr = inet_addr(com_argv[i+1]); Con_TPrintf(TL_NETBINDINTERFACE, inet_ntoa(address.sin_addr)); } else address.sin_addr.s_addr = INADDR_ANY; for(;;) { if (port == PORT_ANY) address.sin_port = 0; else address.sin_port = htons((short)port); if( bind (newsocket, (void *)&address, sizeof(address)) == -1) { if (!port) Sys_Error ("UDP_OpenSocket: bind: %s", strerror(qerrno)); port++; if (port > maxport) Sys_Error ("UDP_OpenSocket: bind: %s", strerror(qerrno)); } else break; } return newsocket; } #ifdef IPPROTO_IPV6 int UDP6_OpenSocket (int port, qboolean bcast) { int err; SOCKET newsocket; struct sockaddr_in6 address; unsigned long _true = true; // int i; int maxport = port + 100; memset(&address, 0, sizeof(address)); if ((newsocket = socket (PF_INET6, SOCK_DGRAM, 0)) == INVALID_SOCKET) { Con_Printf("IPV6 is not supported: %s\n", strerror(qerrno)); return INVALID_SOCKET; } if (ioctlsocket (newsocket, FIONBIO, &_true) == -1) Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(qerrno)); if (bcast) { // address.sin6_addr // _true = true; // if (setsockopt(newsocket, SOL_SOCKET, IP_ADD_MEMBERSHIP, (char *)&_true, sizeof(_true)) == -1) // { Con_Printf("Cannot create broadcast socket\n"); closesocket(newsocket); return INVALID_SOCKET; // } } #ifdef IPV6_V6ONLY setsockopt(newsocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_true, sizeof(_true)); #endif address.sin6_family = AF_INET6; //ZOID -- check for interface binding option // if ((i = COM_CheckParm("-ip6")) != 0 && i < com_argc) { // address.sin6_addr = inet_addr(com_argv[i+1]); /// Con_TPrintf(TL_NETBINDINTERFACE, // inet_ntoa(address.sin6_addr)); // } else memset(&address.sin6_addr, 0, sizeof(struct in6_addr)); for(;;) { if (port == PORT_ANY) address.sin6_port = 0; else address.sin6_port = htons((short)port); if( bind (newsocket, (void *)&address, sizeof(address)) == -1) { if (!port) { err = qerrno; Con_Printf ("UDP6_OpenSocket: bind: (%i) %s", err, strerror(err)); closesocket(newsocket); return INVALID_SOCKET; } port++; if (port > maxport) { err = qerrno; Con_Printf ("UDP6_OpenSocket: bind: (%i) %s", err, strerror(err)); closesocket(newsocket); return INVALID_SOCKET; } } else break; } return newsocket; } #endif void UDP_CloseSocket (int socket) { closesocket(socket); } int IPX_OpenSocket (int port, qboolean bcast) { #ifndef USEIPX return 0; #else SOCKET newsocket; struct sockaddr_ipx address; u_long _true = 1; if ((newsocket = socket (PF_IPX, SOCK_DGRAM, NSPROTO_IPX)) == INVALID_SOCKET) { if (qerrno != EAFNOSUPPORT) Con_Printf ("WARNING: IPX_Socket: socket: %i\n", qerrno); return INVALID_SOCKET; } // make it non-blocking if (ioctlsocket (newsocket, FIONBIO, &_true) == -1) { Con_Printf ("WARNING: IPX_Socket: ioctl FIONBIO: %i\n", qerrno); return INVALID_SOCKET; } if (bcast) { // make it broadcast capable if (setsockopt(newsocket, SOL_SOCKET, SO_BROADCAST, (char *)&_true, sizeof(_true)) == -1) { Con_Printf ("WARNING: IPX_Socket: setsockopt SO_BROADCAST: %i\n", qerrno); return INVALID_SOCKET; } } address.sa_family = AF_IPX; memset (address.sa_netnum, 0, 4); memset (address.sa_nodenum, 0, 6); if (port == PORT_ANY) address.sa_socket = 0; else address.sa_socket = htons((short)port); if( bind (newsocket, (void *)&address, sizeof(address)) == -1) { Con_Printf ("WARNING: IPX_Socket: bind: %i\n", qerrno); closesocket (newsocket); return INVALID_SOCKET; } return newsocket; #endif } void IPX_CloseSocket (int socket) { #ifdef USEIPX closesocket(socket); #endif } // sleeps msec or until net socket is ready //stdin can sometimes be a socket. As a result, //we give the option to select it for nice console imput with timeouts. #ifndef CLIENTONLY qboolean NET_Sleep(int msec, qboolean stdinissocket) { struct timeval timeout; fd_set fdset; int maxfd; int con, sock; FD_ZERO(&fdset); if (stdinissocket) FD_SET(0, &fdset); //stdin tends to be socket 0 maxfd = 0; if (svs.sockets) for (con = 0; con < MAX_CONNECTIONS; con++) { if (!svs.sockets->conn[con]) continue; sock = svs.sockets->conn[con]->thesocket; if (sock != INVALID_SOCKET) { FD_SET(sock, &fdset); // network socket if (sock > maxfd) maxfd = sock; } } timeout.tv_sec = msec/1000; timeout.tv_usec = (msec%1000)*1000; select(maxfd+1, &fdset, NULL, NULL, &timeout); if (stdinissocket) return FD_ISSET(0, &fdset); return true; } #endif void NET_GetLocalAddress (int socket, netadr_t *out) { char buff[512]; char adrbuf[MAX_ADR_SIZE]; struct sockaddr_qstorage address; int namelen; netadr_t adr = {0}; qboolean notvalid = false; strcpy(buff, "localhost"); gethostname(buff, 512); buff[512-1] = 0; if (!NET_StringToAdr (buff, &adr)) //urm NET_StringToAdr ("127.0.0.1", &adr); namelen = sizeof(address); if (getsockname (socket, (struct sockaddr *)&address, &namelen) == -1) { notvalid = true; NET_StringToSockaddr("0.0.0.0", (struct sockaddr_qstorage *)&address); // Sys_Error ("NET_Init: getsockname:", strerror(qerrno)); } SockadrToNetadr(&address, out); if (out->type == NA_IP) { if (!*(int*)out->address.ip) //socket was set to auto *(int *)out->address.ip = *(int *)adr.address.ip; //change it to what the machine says it is, rather than the socket. } if (notvalid) Con_Printf("Couldn't detect local ip\n"); else Con_TPrintf(TL_IPADDRESSIS, NET_AdrToString (adrbuf, sizeof(adrbuf), *out) ); } #ifndef CLIENTONLY void SVNET_AddPort_f(void) { netadr_t adr; char *s = Cmd_Argv(1); //just in case if (!svs.sockets) { svs.sockets = FTENET_CreateCollection(true); #ifndef SERVERONLY FTENET_AddToCollection(svs.sockets, "SVLoopback", "27500", FTENET_Loop_EstablishConnection, true); #endif } NET_PortToAdr(AF_INET, s, &adr); switch(adr.type) { case NA_IP: FTENET_AddToCollection(svs.sockets, NULL, s, FTENET_UDP4_EstablishConnection, true); break; #ifdef IPPROTO_IPV6 case NA_IPV6: FTENET_AddToCollection(svs.sockets, NULL, s, FTENET_UDP6_EstablishConnection, true); break; #endif case NA_IPX: #ifdef USEIPX FTENET_AddToCollection(svs.sockets, NULL, s, FTENET_IPX_EstablishConnection, true); #endif break; #ifdef IRCCONNECT case NA_IRC: FTENET_AddToCollection(svs.sockets, NULL, s, FTENET_IRCConnect_EstablishConnection, true); break; #endif #ifdef IRCCONNECT case NA_TCP: FTENET_AddToCollection(svs.sockets, NULL, s, FTENET_TCP4Connect_EstablishConnection, true); break; #ifdef IPPROTO_IPV6 case NA_TCPV6: FTENET_AddToCollection(svs.sockets, NULL, s, FTENET_TCP6Connect_EstablishConnection, true); break; #endif #endif // warning: enumeration value ‘NA_*’ not handled in switch case NA_INVALID: case NA_LOOPBACK: case NA_BROADCAST_IP: case NA_BROADCAST_IP6: case NA_BROADCAST_IPX: break; } } #endif /* ==================== NET_Init ==================== */ void NET_Init (void) { #ifdef _WIN32 WORD wVersionRequested; int r; #ifdef IPPROTO_IPV6 HMODULE ws2_32dll; ws2_32dll = LoadLibrary("ws2_32.dll"); if (ws2_32dll) { pfreeaddrinfo = (void *)GetProcAddress(ws2_32dll, "freeaddrinfo"); pgetaddrinfo = (void *)GetProcAddress(ws2_32dll, "getaddrinfo"); if (!pgetaddrinfo || !pfreeaddrinfo) { pgetaddrinfo = NULL; pfreeaddrinfo = NULL; FreeLibrary(ws2_32dll); } } else pgetaddrinfo = NULL; #endif wVersionRequested = MAKEWORD(1, 1); r = WSAStartup (MAKEWORD(1, 1), &winsockdata); if (r) Sys_Error ("Winsock initialization failed."); #endif Cvar_Register(&net_hybriddualstack, "networking"); #ifndef CLIENTONLY Cmd_AddCommand("sv_addport", SVNET_AddPort_f); #endif } #ifndef SERVERONLY void NET_InitClient(void) { const char *port; int p; port = STRINGIFY(PORT_QWCLIENT); p = COM_CheckParm ("-port"); if (p && p < com_argc) { port = com_argv[p+1]; } p = COM_CheckParm ("-clport"); if (p && p < com_argc) { port = com_argv[p+1]; } cls.sockets = FTENET_CreateCollection(false); #ifndef CLIENTONLY FTENET_AddToCollection(cls.sockets, "CLLoopback", port, FTENET_Loop_EstablishConnection, false); #endif FTENET_AddToCollection(cls.sockets, "CLUDP4", port, FTENET_UDP4_EstablishConnection, true); #ifdef IPPROTO_IPV6 FTENET_AddToCollection(cls.sockets, "CLUDP6", port, FTENET_UDP6_EstablishConnection, true); #endif #ifdef USEIPX FTENET_AddToCollection(cls.sockets, "CLIPX", port, FTENET_IPX_EstablishConnection, true); #endif // // init the message buffer // net_message.maxsize = sizeof(net_message_buffer); net_message.data = net_message_buffer; Con_TPrintf(TL_CLIENTPORTINITED); } #endif #ifndef CLIENTONLY #ifndef CLIENTONLY void SV_Tcpport_Callback(struct cvar_s *var, char *oldvalue) { FTENET_AddToCollection(svs.sockets, "SVTCP4", var->string, FTENET_TCP4Connect_EstablishConnection, true); } #ifdef IPPROTO_IPV6 void SV_Tcpport6_Callback(struct cvar_s *var, char *oldvalue) { FTENET_AddToCollection(svs.sockets, "SVTCP6", var->string, FTENET_TCP6Connect_EstablishConnection, true); } #endif void SV_Port_Callback(struct cvar_s *var, char *oldvalue) { FTENET_AddToCollection(svs.sockets, "SVUDP4", var->string, FTENET_UDP4_EstablishConnection, true); } #ifdef IPPROTO_IPV6 void SV_PortIPv6_Callback(struct cvar_s *var, char *oldvalue) { FTENET_AddToCollection(svs.sockets, "SVUDP6", var->string, FTENET_UDP6_EstablishConnection, true); } #endif #ifdef USEIPX void SV_PortIPX_Callback(struct cvar_s *var, char *oldvalue) { FTENET_AddToCollection(svs.sockets, "SVIPX", var->string, FTENET_IPX_EstablishConnection, true); } #endif #endif void NET_CloseServer(void) { allowconnects = false; FTENET_CloseCollection(svs.sockets); svs.sockets = NULL; } void NET_InitServer(void) { char *port; port = STRINGIFY(PORT_QWSERVER); if (sv_listen_nq.value || sv_listen_dp.value || sv_listen_qw.value || sv_listen_q3.value) { if (!svs.sockets) { svs.sockets = FTENET_CreateCollection(true); #ifndef SERVERONLY FTENET_AddToCollection(svs.sockets, "SVLoopback", port, FTENET_Loop_EstablishConnection, true); #endif } allowconnects = true; Cvar_ForceCallback(&sv_port_ipv4); #ifdef IPPROTO_IPV6 Cvar_ForceCallback(&sv_port_ipv6); #endif #ifdef USEIPX Cvar_ForceCallback(&sv_port_ipx); #endif #ifdef TCPCONNECT Cvar_ForceCallback(&sv_port_tcp); #ifdef IPPROTO_IPV6 Cvar_ForceCallback(&sv_port_tcp6); #endif #endif } else { NET_CloseServer(); #ifndef SERVERONLY svs.sockets = FTENET_CreateCollection(true); FTENET_AddToCollection(svs.sockets, "SVLoopback", port, FTENET_Loop_EstablishConnection, true); #endif } // // init the message buffer // net_message.maxsize = sizeof(net_message_buffer); net_message.data = net_message_buffer; } #endif /* ==================== NET_Shutdown ==================== */ void NET_Shutdown (void) { #ifndef CLIENTONLY NET_CloseServer(); #endif #ifndef SERVERONLY FTENET_CloseCollection(cls.sockets); cls.sockets = NULL; #endif #ifdef _WIN32 #ifdef SERVERTONLY if (!serverthreadID) //running as subsystem of client. Don't close all of it's sockets too. #endif WSACleanup (); #endif } typedef struct { vfsfile_t funcs; int sock; char readbuffer[65536]; int readbuffered; } tcpfile_t; void VFSTCP_Error(tcpfile_t *f) { if (f->sock != INVALID_SOCKET) { closesocket(f->sock); f->sock = INVALID_SOCKET; } } int VFSTCP_ReadBytes (struct vfsfile_s *file, void *buffer, int bytestoread) { tcpfile_t *tf = (tcpfile_t*)file; int len; int trying; if (tf->sock != INVALID_SOCKET) { trying = sizeof(tf->readbuffer) - tf->readbuffered; if (trying > 1500) trying = 1500; len = recv(tf->sock, tf->readbuffer + tf->readbuffered, trying, 0); if (len == -1) { if (errno != EWOULDBLOCK) printf("socket error\n"); //fixme: figure out wouldblock or error } else if (len == 0 && trying != 0) { VFSTCP_Error(tf); } else { tf->readbuffered += len; } } //return a partially filled buffer. if (bytestoread > tf->readbuffered) bytestoread = tf->readbuffered; if (bytestoread < 0) VFSTCP_Error(tf); if (bytestoread > 0) { memcpy(buffer, tf->readbuffer, bytestoread); tf->readbuffered -= bytestoread; memmove(tf->readbuffer, tf->readbuffer+bytestoread, tf->readbuffered); return bytestoread; } else { if (tf->sock == INVALID_SOCKET) return -1; //signal an error return 0; //signal nothing available } } int VFSTCP_WriteBytes (struct vfsfile_s *file, const void *buffer, int bytestoread) { tcpfile_t *tf = (tcpfile_t*)file; int len; if (tf->sock == INVALID_SOCKET) return 0; len = send(tf->sock, buffer, bytestoread, 0); if (len == -1 || len == 0) { VFSTCP_Error(tf); return 0; } return len; } qboolean VFSTCP_Seek (struct vfsfile_s *file, unsigned long pos) { VFSTCP_Error((tcpfile_t*)file); return false; } unsigned long VFSTCP_Tell (struct vfsfile_s *file) { VFSTCP_Error((tcpfile_t*)file); return 0; } unsigned long VFSTCP_GetLen (struct vfsfile_s *file) { return 0; } void VFSTCP_Close (struct vfsfile_s *file) { VFSTCP_Error((tcpfile_t*)file); Z_Free(file); } vfsfile_t *FS_OpenTCP(const char *name) { tcpfile_t *newf; int sock; netadr_t adr = {0}; if (NET_StringToAdr(name, &adr)) { sock = TCP_OpenStream(adr); if (sock == INVALID_SOCKET) return NULL; newf = Z_Malloc(sizeof(*newf)); newf->sock = sock; newf->funcs.Close = VFSTCP_Close; newf->funcs.Flush = NULL; newf->funcs.GetLen = VFSTCP_GetLen; newf->funcs.ReadBytes = VFSTCP_ReadBytes; newf->funcs.Seek = VFSTCP_Seek; newf->funcs.Tell = VFSTCP_Tell; newf->funcs.WriteBytes = VFSTCP_WriteBytes; newf->funcs.seekingisabadplan = true; return &newf->funcs; } else return NULL; }