/* net_ws.c - win network interface Copyright (C) 2007 Uncle Mike 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 3 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. */ #include "common.h" #include "client.h" // ConnectionProgress #include "netchan.h" #include "xash3d_mathlib.h" #include "ipv6text.h" #if XASH_WIN32 #include "platform/win32/net.h" #elif defined XASH_NO_NETWORK #include "platform/stub/net_stub.h" #else #include "platform/posix/net.h" #endif #if XASH_PSVITA #include "platform/psvita/net_psvita.h" static const struct in6_addr in6addr_any; #endif #define NET_USE_FRAGMENTS #define PORT_ANY -1 #define MAX_LOOPBACK 4 #define MASK_LOOPBACK (MAX_LOOPBACK - 1) #define MAX_ROUTEABLE_PACKET 1400 #define SPLITPACKET_MIN_SIZE 508 // RFC 791: 576(min ip packet) - 60 (ip header) - 8 (udp header) #define SPLITPACKET_MAX_SIZE 64000 #define NET_MAX_FRAGMENTS ( NET_MAX_FRAGMENT / (SPLITPACKET_MIN_SIZE - sizeof( SPLITPACKET ))) // ff02:1 static const uint8_t k_ipv6Bytes_LinkLocalAllNodes[16] = { 0xff, 0x02, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x01 }; typedef struct { byte data[NET_MAX_MESSAGE]; int datalen; } net_loopmsg_t; typedef struct { net_loopmsg_t msgs[MAX_LOOPBACK]; int get, send; } net_loopback_t; typedef struct packetlag_s { byte *data; // Raw stream data is stored. int size; netadr_t from; float receivedtime; struct packetlag_s *next; struct packetlag_s *prev; } packetlag_t; // split long packets. Anything over 1460 is failing on some routers. typedef struct { int current_sequence; int split_count; int total_size; char buffer[NET_MAX_FRAGMENT]; } LONGPACKET; // use this to pick apart the network stream, must be packed #pragma pack(push, 1) typedef struct { int net_id; int sequence_number; short packet_id; } SPLITPACKET; #pragma pack(pop) typedef struct { net_loopback_t loopbacks[NS_COUNT]; packetlag_t lagdata[NS_COUNT]; int losscount[NS_COUNT]; float fakelag; // cached fakelag value LONGPACKET split; int split_flags[NET_MAX_FRAGMENTS]; int sequence_number; int ip_sockets[NS_COUNT]; int ip6_sockets[NS_COUNT]; qboolean initialized; qboolean threads_initialized; qboolean configured; qboolean allow_ip; qboolean allow_ip6; #if XASH_WIN32 WSADATA winsockdata; #endif } net_state_t; static net_state_t net; static CVAR_DEFINE_AUTO( net_address, "0", FCVAR_PRIVILEGED|FCVAR_READ_ONLY, "contain local address of current client" ); static CVAR_DEFINE( net_ipname, "ip", "localhost", FCVAR_PRIVILEGED, "network ip address" ); static CVAR_DEFINE( net_iphostport, "ip_hostport", "0", FCVAR_READ_ONLY, "network ip host port" ); static CVAR_DEFINE( net_hostport, "hostport", "0", FCVAR_READ_ONLY, "network default host port" ); static CVAR_DEFINE( net_ipclientport, "ip_clientport", "0", FCVAR_READ_ONLY, "network ip client port" ); static CVAR_DEFINE( net_clientport, "clientport", "0", FCVAR_READ_ONLY, "network default client port" ); static CVAR_DEFINE( net_fakelag, "fakelag", "0", FCVAR_PRIVILEGED, "lag all incoming network data (including loopback) by xxx ms." ); static CVAR_DEFINE( net_fakeloss, "fakeloss", "0", FCVAR_PRIVILEGED, "act like we dropped the packet this % of the time." ); CVAR_DEFINE( net_clockwindow, "clockwindow", "0.5", FCVAR_PRIVILEGED, "timewindow to execute client moves" ); netadr_t net_local; netadr_t net6_local; // cvars equivalents for IPv6 static CVAR_DEFINE( net_ip6name, "ip6", "localhost", FCVAR_PRIVILEGED, "network ip6 address" ); static CVAR_DEFINE( net_ip6hostport, "ip6_hostport", "0", FCVAR_READ_ONLY, "network ip6 host port" ); static CVAR_DEFINE( net_ip6clientport, "ip6_clientport", "0", FCVAR_READ_ONLY, "network ip6 client port" ); static CVAR_DEFINE_AUTO( net6_address, "0", FCVAR_PRIVILEGED|FCVAR_READ_ONLY, "contain local IPv6 address of current client" ); /* ==================== NET_ErrorString ==================== */ char *NET_ErrorString( void ) { #if XASH_WIN32 int err = WSANOTINITIALISED; if( net.initialized ) err = WSAGetLastError(); switch( err ) { case WSAEINTR: return "WSAEINTR"; case WSAEBADF: return "WSAEBADF"; case WSAEACCES: return "WSAEACCES"; case WSAEFAULT: return "WSAEFAULT"; case WSAEINVAL: return "WSAEINVAL"; case WSAEMFILE: return "WSAEMFILE"; case WSAEWOULDBLOCK: return "WSAEWOULDBLOCK"; case WSAEINPROGRESS: return "WSAEINPROGRESS"; case WSAEALREADY: return "WSAEALREADY"; case WSAENOTSOCK: return "WSAENOTSOCK"; case WSAEDESTADDRREQ: return "WSAEDESTADDRREQ"; case WSAEMSGSIZE: return "WSAEMSGSIZE"; case WSAEPROTOTYPE: return "WSAEPROTOTYPE"; case WSAENOPROTOOPT: return "WSAENOPROTOOPT"; case WSAEPROTONOSUPPORT: return "WSAEPROTONOSUPPORT"; case WSAESOCKTNOSUPPORT: return "WSAESOCKTNOSUPPORT"; case WSAEOPNOTSUPP: return "WSAEOPNOTSUPP"; case WSAEPFNOSUPPORT: return "WSAEPFNOSUPPORT"; case WSAEAFNOSUPPORT: return "WSAEAFNOSUPPORT"; case WSAEADDRINUSE: return "WSAEADDRINUSE"; case WSAEADDRNOTAVAIL: return "WSAEADDRNOTAVAIL"; case WSAENETDOWN: return "WSAENETDOWN"; case WSAENETUNREACH: return "WSAENETUNREACH"; case WSAENETRESET: return "WSAENETRESET"; case WSAECONNABORTED: return "WSWSAECONNABORTEDAEINTR"; case WSAECONNRESET: return "WSAECONNRESET"; case WSAENOBUFS: return "WSAENOBUFS"; case WSAEISCONN: return "WSAEISCONN"; case WSAENOTCONN: return "WSAENOTCONN"; case WSAESHUTDOWN: return "WSAESHUTDOWN"; case WSAETOOMANYREFS: return "WSAETOOMANYREFS"; case WSAETIMEDOUT: return "WSAETIMEDOUT"; case WSAECONNREFUSED: return "WSAECONNREFUSED"; case WSAELOOP: return "WSAELOOP"; case WSAENAMETOOLONG: return "WSAENAMETOOLONG"; case WSAEHOSTDOWN: return "WSAEHOSTDOWN"; case WSAEDISCON: return "WSAEDISCON"; case WSASYSNOTREADY: return "WSASYSNOTREADY"; case WSAVERNOTSUPPORTED: return "WSAVERNOTSUPPORTED"; case WSANOTINITIALISED: return "WSANOTINITIALISED"; case WSAHOST_NOT_FOUND: return "WSAHOST_NOT_FOUND"; case WSATRY_AGAIN: return "WSATRY_AGAIN"; case WSANO_RECOVERY: return "WSANO_RECOVERY"; case WSANO_DATA: return "WSANO_DATA"; default: return "NO ERROR"; } #else return strerror( errno ); #endif } _inline socklen_t NET_SockAddrLen( const struct sockaddr_storage *addr ) { switch ( addr->ss_family ) { case AF_INET: return sizeof( struct sockaddr_in ); case AF_INET6: return sizeof( struct sockaddr_in6 ); default: return sizeof( *addr ); // what the fuck is this? } } _inline qboolean NET_IsSocketError( int retval ) { #if XASH_WIN32 || XASH_DOS4GW return retval == SOCKET_ERROR ? true : false; #else return retval < 0 ? true : false; #endif } _inline qboolean NET_IsSocketValid( int socket ) { #if XASH_WIN32 || XASH_DOS4GW return socket != INVALID_SOCKET; #else return socket >= 0; #endif } void NET_NetadrToIP6Bytes( uint8_t *ip6, const netadr_t *adr ) { #if XASH_LITTLE_ENDIAN memcpy( ip6, adr->ip6, sizeof( adr->ip6 )); #elif XASH_BIG_ENDIAN memcpy( ip6, adr->ip6_0, sizeof( adr->ip6_0 )); memcpy( ip6 + sizeof( adr->ip6_0 ), adr->ip6_2, sizeof( adr->ip6_2 )); #endif } void NET_IP6BytesToNetadr( netadr_t *adr, const uint8_t *ip6 ) { #if XASH_LITTLE_ENDIAN memcpy( adr->ip6, ip6, sizeof( adr->ip6 )); #elif XASH_BIG_ENDIAN memcpy( adr->ip6_0, ip6, sizeof( adr->ip6_0 )); memcpy( adr->ip6_2, ip6 + sizeof( adr->ip6_0 ), sizeof( adr->ip6_2 )); #endif } _inline int NET_NetadrIP6Compare( const netadr_t *a, const netadr_t *b ) { #if XASH_LITTLE_ENDIAN return memcmp( a->ip6, b->ip6, sizeof( a->ip6 )); #elif XASH_BIG_ENDIAN int ret = memcmp( a->ip6_0, b->ip6_0, sizeof( a->ip6_0 )); if( !ret ) return memcmp( a->ip6_2, b->ip6_2, sizeof( a->ip6_2 )); return ret; #endif } /* ==================== NET_NetadrToSockadr ==================== */ static void NET_NetadrToSockadr( netadr_t *a, struct sockaddr_storage *s ) { memset( s, 0, sizeof( *s )); if( a->type == NA_BROADCAST ) { ((struct sockaddr_in *)s)->sin_family = AF_INET; ((struct sockaddr_in *)s)->sin_port = a->port; ((struct sockaddr_in *)s)->sin_addr.s_addr = INADDR_BROADCAST; } else if( a->type == NA_IP ) { ((struct sockaddr_in *)s)->sin_family = AF_INET; ((struct sockaddr_in *)s)->sin_port = a->port; ((struct sockaddr_in *)s)->sin_addr.s_addr = a->ip4; } else if( a->type6 == NA_IP6 ) { struct in6_addr ip6; NET_NetadrToIP6Bytes( ip6.s6_addr, a ); if( IN6_IS_ADDR_V4MAPPED( &ip6 )) { ((struct sockaddr_in *)s)->sin_family = AF_INET; ((struct sockaddr_in *)s)->sin_addr.s_addr = *(uint32_t *)(ip6.s6_addr + 12); ((struct sockaddr_in *)s)->sin_port = a->port; } else { ((struct sockaddr_in6 *)s)->sin6_family = AF_INET6; memcpy( &((struct sockaddr_in6 *)s)->sin6_addr, &ip6, sizeof( struct in6_addr )); ((struct sockaddr_in6 *)s)->sin6_port = a->port; } } else if( a->type6 == NA_MULTICAST_IP6 ) { ((struct sockaddr_in6 *)s)->sin6_family = AF_INET6; memcpy(((struct sockaddr_in6 *)s)->sin6_addr.s6_addr, k_ipv6Bytes_LinkLocalAllNodes, sizeof( struct in6_addr )); ((struct sockaddr_in6 *)s)->sin6_port = a->port; } } /* ==================== NET_SockadrToNetAdr ==================== */ static void NET_SockadrToNetadr( const struct sockaddr_storage *s, netadr_t *a ) { if( s->ss_family == AF_INET ) { a->type = NA_IP; a->ip4 = ((struct sockaddr_in *)s)->sin_addr.s_addr; a->port = ((struct sockaddr_in *)s)->sin_port; } else if( s->ss_family == AF_INET6 ) { NET_IP6BytesToNetadr( a, ((struct sockaddr_in6 *)s)->sin6_addr.s6_addr ); if( IN6_IS_ADDR_V4MAPPED( &((struct sockaddr_in6 *)s)->sin6_addr )) a->type = NA_IP; else a->type6 = NA_IP6; a->port = ((struct sockaddr_in6 *)s)->sin6_port; } } /* ============ NET_GetHostByName ============ */ qboolean NET_GetHostByName( const char *hostname, int family, struct sockaddr_storage *addr ) { #if defined HAVE_GETADDRINFO struct addrinfo *ai = NULL, *cur; struct addrinfo hints; qboolean ret = false; memset( &hints, 0, sizeof( hints )); hints.ai_family = family; if( !getaddrinfo( hostname, NULL, &hints, &ai )) { for( cur = ai; cur; cur = cur->ai_next ) { if( family == AF_UNSPEC || cur->ai_family == family ) { memcpy( addr, cur->ai_addr, cur->ai_addrlen ); ret = true; break; } } if( ai ) freeaddrinfo( ai ); } return ret; #else struct hostent *h; if(!( h = gethostbyname( hostname ))) return false; ((struct sockaddr_in *)addr)->sin_family = AF_INET; ((struct sockaddr_in *)addr)->sin_addr = *(struct in_addr *)h->h_addr_list[0]; return true; #endif } #if !XASH_EMSCRIPTEN && !XASH_DOS4GW && !defined XASH_NO_ASYNC_NS_RESOLVE #define CAN_ASYNC_NS_RESOLVE #endif // !XASH_EMSCRIPTEN && !XASH_DOS4GW && !defined XASH_NO_ASYNC_NS_RESOLVE #ifdef CAN_ASYNC_NS_RESOLVE static void NET_ResolveThread( void ); #if !XASH_WIN32 #include #define mutex_lock pthread_mutex_lock #define mutex_unlock pthread_mutex_unlock #define exit_thread( x ) pthread_exit(x) #define create_thread( pfn ) !pthread_create( &nsthread.thread, NULL, (pfn), NULL ) #define detach_thread( x ) pthread_detach(x) #define mutex_t pthread_mutex_t #define thread_t pthread_t void *NET_ThreadStart( void *unused ) { NET_ResolveThread(); return NULL; } #else // WIN32 #define mutex_lock EnterCriticalSection #define mutex_unlock LeaveCriticalSection #define detach_thread( x ) CloseHandle(x) #define create_thread( pfn ) ( nsthread.thread = CreateThread( NULL, 0, pfn, NULL, 0, NULL )) #define mutex_t CRITICAL_SECTION #define thread_t HANDLE DWORD WINAPI NET_ThreadStart( LPVOID unused ) { NET_ResolveThread(); ExitThread( 0 ); return 0; } #endif // !_WIN32 #ifdef DEBUG_RESOLVE #define RESOLVE_DBG(x) Sys_PrintLog(x) #else #define RESOLVE_DBG(x) #endif // DEBUG_RESOLVE static struct nsthread_s { mutex_t mutexns; mutex_t mutexres; thread_t thread; int result; string hostname; int family; struct sockaddr_storage addr; qboolean busy; } nsthread #if !XASH_WIN32 = { PTHREAD_MUTEX_INITIALIZER, PTHREAD_MUTEX_INITIALIZER } #endif ; static void NET_InitializeCriticalSections( void ) { net.threads_initialized = true; #if XASH_WIN32 InitializeCriticalSection( &nsthread.mutexns ); InitializeCriticalSection( &nsthread.mutexres ); #endif } void NET_ResolveThread( void ) { struct sockaddr_storage addr; RESOLVE_DBG( "[resolve thread] starting resolve for " ); RESOLVE_DBG( nsthread.hostname ); #ifdef HAVE_GETADDRINFO RESOLVE_DBG( " with getaddrinfo\n" ); #else RESOLVE_DBG( " with gethostbyname\n" ); #endif if( NET_GetHostByName( nsthread.hostname, nsthread.family, &addr )) RESOLVE_DBG( "[resolve thread] success\n" ); else RESOLVE_DBG( "[resolve thread] failed\n" ); mutex_lock( &nsthread.mutexres ); nsthread.addr = addr; nsthread.busy = false; RESOLVE_DBG( "[resolve thread] returning result\n" ); mutex_unlock( &nsthread.mutexres ); RESOLVE_DBG( "[resolve thread] exiting thread\n" ); } #endif // CAN_ASYNC_NS_RESOLVE /* ============= NET_StringToAdr localhost idnewt idnewt:28000 192.246.40.70 192.246.40.70:28000 ============= */ static net_gai_state_t NET_StringToSockaddr( const char *s, struct sockaddr_storage *sadr, qboolean nonblocking, int family ) { int ret = 0, port; char *colon; char copy[128]; byte ip6[16]; struct sockaddr_storage temp; if( !net.initialized ) return NET_EAI_NONAME; memset( sadr, 0, sizeof( *sadr )); // try to parse it as IPv6 first if(( family == AF_UNSPEC || family == AF_INET6 ) && ParseIPv6Addr( s, ip6, &port, NULL )) { ((struct sockaddr_in6 *)sadr)->sin6_family = AF_INET6; ((struct sockaddr_in6 *)sadr)->sin6_port = htons((short)port); memcpy(((struct sockaddr_in6 *)sadr)->sin6_addr.s6_addr, ip6, sizeof( struct in6_addr )); return NET_EAI_OK; } Q_strncpy( copy, s, sizeof( copy )); // strip off a trailing :port if present ((struct sockaddr_in *)sadr)->sin_port = 0; for( colon = copy; *colon; colon++ ) { if( *colon == ':' ) { *colon = 0; ((struct sockaddr_in *)sadr)->sin_port = htons((short)Q_atoi( colon + 1 )); } } if( copy[0] >= '0' && copy[0] <= '9' ) { ((struct sockaddr_in *)sadr)->sin_family = AF_INET; ((struct sockaddr_in *)sadr)->sin_addr.s_addr = inet_addr( copy ); } else { qboolean asyncfailed = true; #ifdef CAN_ASYNC_NS_RESOLVE if( net.threads_initialized && nonblocking ) { mutex_lock( &nsthread.mutexres ); if( nsthread.busy ) { mutex_unlock( &nsthread.mutexres ); return NET_EAI_AGAIN; } if( !Q_strcmp( copy, nsthread.hostname )) { ret = nsthread.result; nsthread.hostname[0] = '\0'; nsthread.family = AF_UNSPEC; temp = nsthread.addr; memset( &nsthread.addr, 0, sizeof( nsthread.addr )); detach_thread( nsthread.thread ); } else { Q_strncpy( nsthread.hostname, copy, sizeof( nsthread.hostname )); nsthread.family = family; nsthread.busy = true; mutex_unlock( &nsthread.mutexres ); if( create_thread( NET_ThreadStart )) { asyncfailed = false; return NET_EAI_AGAIN; } else // failed to create thread { Con_Reportf( S_ERROR "NET_StringToSockaddr: failed to create thread!\n"); nsthread.busy = false; } } mutex_unlock( &nsthread.mutexres ); } #endif // CAN_ASYNC_NS_RESOLVE if( asyncfailed ) { ret = NET_GetHostByName( copy, family, &temp ); } if( !ret ) { if( family == AF_INET6 ) sadr->ss_family = AF_INET6; else sadr->ss_family = AF_INET; return NET_EAI_NONAME; } sadr->ss_family = temp.ss_family; if( temp.ss_family == AF_INET ) { ((struct sockaddr_in *)sadr)->sin_addr = ((struct sockaddr_in*)&temp)->sin_addr; } else if( temp.ss_family == AF_INET6 ) { memcpy(&((struct sockaddr_in6 *)sadr)->sin6_addr, &((struct sockaddr_in6*)&temp)->sin6_addr, sizeof( struct in6_addr )); } } return NET_EAI_OK; } /* ==================== NET_StringToFilterAdr ==================== */ qboolean NET_StringToFilterAdr( const char *s, netadr_t *adr, uint *prefixlen ) { char copy[128], *temp; qboolean hasCIDR = false; byte ip6[16]; uint len; if( !COM_CheckStringEmpty( s )) return false; memset( adr, 0, sizeof( *adr )); // copy the string and remove CIDR prefix Q_strncpy( copy, s, sizeof( copy )); temp = Q_strrchr( copy, '/' ); if( temp ) { *temp = 0; if( Q_isdigit( temp + 1 )) { len = Q_atoi( temp + 1 ); hasCIDR = len != 0; } } // try to parse as IPv6 first if( ParseIPv6Addr( copy, ip6, NULL, NULL )) { NET_IP6BytesToNetadr( adr, ip6 ); adr->type6 = NA_IP6; if( !hasCIDR ) *prefixlen = 128; else *prefixlen = len; } else { int num = 0; int octet = 0; // parse as ipv4 but we don't need to allow all forms here for( temp = copy; *temp; temp++ ) { char c = *temp; if( c >= '0' && c <= '9' ) { num *= 10; num += c - '0'; } else if( c == '.' ) { if( num > 255 ) return false; adr->ip[octet++] = num; num = 0; if( octet > 3 ) return false; } else { return false; } } if( num > 255 ) return false; adr->ip[octet++] = num; if( !hasCIDR ) { int i; *prefixlen = 32; for( i = 3; i >= 0; i-- ) { if( !adr->ip[i] ) *prefixlen -= 8; else break; } } else { uint32_t mask; len = bound( 0, len, 32 ); *prefixlen = len; // drop unneeded bits mask = htonl( adr->ip4 ) & ( 0xFFFFFFFF << ( 32 - len )); adr->ip4 = ntohl( mask ); } adr->type = NA_IP; } return true; } /* ==================== NET_AdrToString ==================== */ const char *NET_AdrToString( const netadr_t a ) { static char s[64]; if( a.type == NA_LOOPBACK ) return "loopback"; if( a.type6 == NA_IP6 || a.type6 == NA_MULTICAST_IP6 ) { uint8_t ip6[16]; NET_NetadrToIP6Bytes( ip6, &a ); IPv6AddrToString( s, ip6, ntohs( a.port ), 0 ); return s; } Q_snprintf( s, sizeof( s ), "%i.%i.%i.%i:%i", a.ip[0], a.ip[1], a.ip[2], a.ip[3], ntohs( a.port )); return s; } /* ==================== NET_BaseAdrToString ==================== */ const char *NET_BaseAdrToString( const netadr_t a ) { static char s[64]; if( a.type == NA_LOOPBACK ) return "loopback"; if( a.type6 == NA_IP6 || a.type6 == NA_MULTICAST_IP6 ) { uint8_t ip6[16]; NET_NetadrToIP6Bytes( ip6, &a ); IPv6IPToString( s, ip6 ); return s; } Q_snprintf( s, sizeof( s ), "%i.%i.%i.%i", a.ip[0], a.ip[1], a.ip[2], a.ip[3] ); return s; } /* =================== NET_CompareBaseAdr Compares without the port =================== */ qboolean NET_CompareBaseAdr( const netadr_t a, const netadr_t b ) { if( a.type6 != b.type6 ) return false; if( a.type == NA_LOOPBACK ) return true; if( a.type == NA_IP ) return a.ip4 == b.ip4; if( a.type6 == NA_IP6 ) { if( !NET_NetadrIP6Compare( &a, &b )) return true; } return false; } /* ==================== NET_CompareClassBAdr Compare local masks ==================== */ qboolean NET_CompareClassBAdr( const netadr_t a, const netadr_t b ) { if( a.type6 != b.type6 ) return false; if( a.type == NA_LOOPBACK ) return true; if( a.type == NA_IP ) { if( a.ip[0] == b.ip[0] && a.ip[1] == b.ip[1] ) return true; } // NOTE: we don't check for IPv6 here // this check is very dumb and only used for LAN restriction // Actual check is in IsReservedAdr // for real mask compare use NET_CompareAdrByMask return false; } /* ==================== NET_CompareAdrByMask Checks if adr is a part of subnet ==================== */ qboolean NET_CompareAdrByMask( const netadr_t a, const netadr_t b, uint prefixlen ) { if( a.type6 != b.type6 || a.type == NA_LOOPBACK ) return false; if( a.type == NA_IP ) { uint32_t ipa = htonl( a.ip4 ); uint32_t ipb = htonl( b.ip4 ); if(( ipa & (( 0xFFFFFFFFU ) << ( 32 - prefixlen ))) == ipb ) return true; } else if( a.type6 == NA_IP6 ) { uint16_t a_[8], b_[8]; size_t check = prefixlen / 16; size_t remaining = prefixlen % 16; // convert to 16-bit pieces first NET_NetadrToIP6Bytes( (uint8_t*)a_, &a ); NET_NetadrToIP6Bytes( (uint8_t*)b_, &b ); // check complete hextets first, if not equal, then it's different subnets if( check && memcmp( a_, b_, check * sizeof( uint16_t ))) return false; // check by bits now, similar to v4 check but with 16-bit type if( remaining ) { uint16_t hexa, hexb, mask = 0xFFFFU << ( 16 - remaining ); hexa = htons( a_[check] ); hexb = htons( b_[check] ); if(( hexa & mask ) == ( hexb & mask )) return true; } else return true; } return false; } /* ==================== NET_IsReservedAdr Check for reserved ip's ==================== */ qboolean NET_IsReservedAdr( netadr_t a ) { if( a.type == NA_LOOPBACK ) return true; // Following checks was imported from GameNetworkingSockets library if( a.type == NA_IP ) { if(( a.ip[0] == 10 ) || // 10.x.x.x is reserved ( a.ip[0] == 127 ) || // 127.x.x.x ( a.ip[0] == 169 && a.ip[1] == 254 ) || // 169.254.x.x is link-local ipv4 ( a.ip[0] == 172 && a.ip[1] >= 16 && a.ip[1] <= 31 ) || // 172.16.x.x - 172.31.x.x ( a.ip[0] == 192 && a.ip[1] >= 168 )) // 192.168.x.x { return true; } } if( a.type6 == NA_IP6 ) { uint8_t ip6[16]; NET_NetadrToIP6Bytes( ip6, &a ); // Private addresses, fc00::/7 // Range is fc00:: to fdff:ffff:etc if( ip6[0] >= 0xFC && ip6[1] <= 0xFD ) { return true; } // Link-local fe80::/10 // Range is fe80:: to febf:: if( ip6[0] == 0xFE && ( ip6[1] >= 0x80 && ip6[1] <= 0xBF )) { return true; } } return false; } /* ==================== NET_CompareAdr Compare full address ==================== */ qboolean NET_CompareAdr( const netadr_t a, const netadr_t b ) { if( a.type6 != b.type6 ) return false; if( a.type == NA_LOOPBACK ) return true; if( a.type == NA_IP ) { if( a.ip4 == b.ip4 && a.port == b.port ) return true; return false; } if( a.type6 == NA_IP6 ) { if( a.port == b.port && !NET_NetadrIP6Compare( &a, &b )) return true; } Con_DPrintf( S_ERROR "NET_CompareAdr: bad address type\n" ); return false; } /* ==================== NET_CompareAdrSort Network address sorting comparator guaranteed to return -1, 0 or 1 ==================== */ int NET_CompareAdrSort( const void *_a, const void *_b ) { const netadr_t *a = _a, *b = _b; int porta, portb, portdiff, addrdiff; if( a->type6 != b->type6 ) return bound( -1, (int)a->type6 - (int)b->type6, 1 ); porta = ntohs( a->port ); portb = ntohs( b->port ); if( porta < portb ) portdiff = -1; else if( porta > portb ) portdiff = 1; else portdiff = 0; switch( a->type6 ) { case NA_IP6: if(( addrdiff = NET_NetadrIP6Compare( a, b ))) return addrdiff; // fallthrough case NA_MULTICAST_IP6: return portdiff; } // don't check for full type earlier, as it's value depends on v6 address if( a->type != b->type ) return bound( -1, (int)a->type - (int)b->type, 1 ); switch( a->type ) { case NA_IP: if(( addrdiff = memcmp( a->ip, b->ip, sizeof( a->ipx )))) return addrdiff; // fallthrough case NA_BROADCAST: return portdiff; case NA_IPX: if(( addrdiff = memcmp( a->ipx, b->ipx, sizeof( a->ipx )))) return addrdiff; // fallthrough case NA_BROADCAST_IPX: return portdiff; } return 0; } /* ==================== NET_IsLocalAddress ==================== */ qboolean NET_IsLocalAddress( netadr_t adr ) { return (adr.type == NA_LOOPBACK) ? true : false; } /* ============= NET_StringToAdr idnewt 192.246.40.70 ============= */ qboolean NET_StringToAdrEx( const char *string, netadr_t *adr, int family ) { struct sockaddr_storage s; memset( adr, 0, sizeof( netadr_t )); if( !Q_stricmp( string, "localhost" ) || !Q_stricmp( string, "loopback" )) { adr->type = NA_LOOPBACK; return true; } if( NET_StringToSockaddr( string, &s, false, family ) != NET_EAI_OK ) return false; NET_SockadrToNetadr( &s, adr ); return true; } qboolean NET_StringToAdr( const char *string, netadr_t *adr ) { return NET_StringToAdrEx( string, adr, AF_UNSPEC ); } net_gai_state_t NET_StringToAdrNB( const char *string, netadr_t *adr ) { struct sockaddr_storage s; net_gai_state_t res; memset( adr, 0, sizeof( netadr_t )); if( !Q_stricmp( string, "localhost" ) || !Q_stricmp( string, "loopback" )) { adr->type = NA_LOOPBACK; return NET_EAI_OK; } res = NET_StringToSockaddr( string, &s, true, AF_UNSPEC ); if( res == NET_EAI_OK ) NET_SockadrToNetadr( &s, adr ); return res; } /* ============================================================================= LOOPBACK BUFFERS FOR LOCAL PLAYER ============================================================================= */ /* ==================== NET_GetLoopPacket ==================== */ static qboolean NET_GetLoopPacket( netsrc_t sock, netadr_t *from, byte *data, size_t *length ) { net_loopback_t *loop; int i; if( !data || !length ) return false; loop = &net.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 & MASK_LOOPBACK; loop->get++; memcpy( data, loop->msgs[i].data, loop->msgs[i].datalen ); *length = loop->msgs[i].datalen; memset( from, 0, sizeof( *from )); from->type = NA_LOOPBACK; return true; } /* ==================== NET_SendLoopPacket ==================== */ static void NET_SendLoopPacket( netsrc_t sock, size_t length, const void *data, netadr_t to ) { net_loopback_t *loop; int i; loop = &net.loopbacks[sock^1]; i = loop->send & MASK_LOOPBACK; loop->send++; memcpy( loop->msgs[i].data, data, length ); loop->msgs[i].datalen = length; } /* ==================== NET_ClearLoopback ==================== */ static void NET_ClearLoopback( void ) { net.loopbacks[0].send = net.loopbacks[0].get = 0; net.loopbacks[1].send = net.loopbacks[1].get = 0; } /* ============================================================================= LAG & LOSS SIMULATION SYSTEM (network debugging) ============================================================================= */ /* ================== NET_RemoveFromPacketList double linked list remove entry ================== */ static void NET_RemoveFromPacketList( packetlag_t *p ) { p->prev->next = p->next; p->next->prev = p->prev; p->prev = NULL; p->next = NULL; } /* ================== NET_ClearLaggedList double linked list remove queue ================== */ static void NET_ClearLaggedList( packetlag_t *list ) { packetlag_t *p, *n; p = list->next; while( p && p != list ) { n = p->next; NET_RemoveFromPacketList( p ); if( p->data ) { Mem_Free( p->data ); p->data = NULL; } Mem_Free( p ); p = n; } list->prev = list; list->next = list; } /* ================== NET_AddToLagged add lagged packet to stream ================== */ static void NET_AddToLagged( netsrc_t sock, packetlag_t *list, packetlag_t *packet, netadr_t *from, size_t length, const void *data, float timestamp ) { byte *pStart; if( packet->prev || packet->next ) return; packet->prev = list->prev; list->prev->next = packet; list->prev = packet; packet->next = list; pStart = (byte *)Z_Malloc( length ); memcpy( pStart, data, length ); packet->data = pStart; packet->size = length; packet->receivedtime = timestamp; memcpy( &packet->from, from, sizeof( netadr_t )); } /* ================== NET_AdjustLag adjust time to next fake lag ================== */ static void NET_AdjustLag( void ) { static double lasttime = 0.0; float diff, converge; double dt; dt = host.realtime - lasttime; dt = bound( 0.0, dt, 0.1 ); lasttime = host.realtime; if( host_developer.value || !net_fakelag.value ) { if( net_fakelag.value != net.fakelag ) { diff = net_fakelag.value - net.fakelag; converge = dt * 200.0f; if( fabs( diff ) < converge ) converge = fabs( diff ); if( diff < 0.0f ) converge = -converge; net.fakelag += converge; } } else { Con_Printf( "Server must enable dev-mode to activate fakelag\n" ); Cvar_SetValue( "fakelag", 0.0 ); net.fakelag = 0.0f; } } /* ================== NET_LagPacket add fake lagged packet into rececived message ================== */ static qboolean NET_LagPacket( qboolean newdata, netsrc_t sock, netadr_t *from, size_t *length, void *data ) { packetlag_t *pNewPacketLag; packetlag_t *pPacket; int ninterval; float curtime; if( net.fakelag <= 0.0f ) { NET_ClearLagData( true, true ); return newdata; } curtime = host.realtime; if( newdata ) { if( net_fakeloss.value != 0.0f ) { if( host_developer.value ) { net.losscount[sock]++; if( net_fakeloss.value <= 0.0f ) { ninterval = fabs( net_fakeloss.value ); if( ninterval < 2 ) ninterval = 2; if(( net.losscount[sock] % ninterval ) == 0 ) return false; } else { if( COM_RandomLong( 0, 100 ) <= net_fakeloss.value ) return false; } } else { Cvar_SetValue( "fakeloss", 0.0 ); } } pNewPacketLag = (packetlag_t *)Z_Malloc( sizeof( packetlag_t )); // queue packet to simulate fake lag NET_AddToLagged( sock, &net.lagdata[sock], pNewPacketLag, from, *length, data, curtime ); } pPacket = net.lagdata[sock].next; while( pPacket != &net.lagdata[sock] ) { if( pPacket->receivedtime <= curtime - ( net.fakelag / 1000.0f )) break; pPacket = pPacket->next; } if( pPacket == &net.lagdata[sock] ) return false; NET_RemoveFromPacketList( pPacket ); // delivery packet from fake lag queue memcpy( data, pPacket->data, pPacket->size ); memcpy( &net_from, &pPacket->from, sizeof( netadr_t )); *length = pPacket->size; if( pPacket->data ) Mem_Free( pPacket->data ); Mem_Free( pPacket ); return true; } /* ================== NET_GetLong receive long packet from network ================== */ qboolean NET_GetLong( byte *pData, int size, size_t *outSize, int splitsize ) { int i, sequence_number, offset; SPLITPACKET *pHeader = (SPLITPACKET *)pData; int packet_number; int packet_count; short packet_id; int body_size = splitsize - sizeof( SPLITPACKET ); if( body_size < 0 ) return false; if( size < sizeof( SPLITPACKET )) { Con_Printf( S_ERROR "invalid split packet length %i\n", size ); return false; } sequence_number = pHeader->sequence_number; packet_id = pHeader->packet_id; packet_count = ( packet_id & 0xFF ); packet_number = ( packet_id >> 8 ); if( packet_number >= NET_MAX_FRAGMENTS || packet_count > NET_MAX_FRAGMENTS ) { Con_Printf( S_ERROR "malformed packet number (%i/%i)\n", packet_number + 1, packet_count ); return false; } if( net.split.current_sequence == -1 || sequence_number != net.split.current_sequence ) { net.split.current_sequence = sequence_number; net.split.split_count = packet_count; net.split.total_size = 0; // clear part's sequence for( i = 0; i < NET_MAX_FRAGMENTS; i++ ) net.split_flags[i] = -1; if( net_showpackets.value == 4.0f ) Con_Printf( "<-- Split packet restart %i count %i seq\n", net.split.split_count, sequence_number ); } size -= sizeof( SPLITPACKET ); if( net.split_flags[packet_number] != sequence_number ) { if( packet_number == ( packet_count - 1 )) net.split.total_size = size + body_size * ( packet_count - 1 ); net.split.split_count--; net.split_flags[packet_number] = sequence_number; if( net_showpackets.value == 4.0f ) Con_Printf( "<-- Split packet %i of %i, %i bytes %i seq\n", packet_number + 1, packet_count, size, sequence_number ); } else { Con_DPrintf( "NET_GetLong: Ignoring duplicated split packet %i of %i ( %i bytes )\n", packet_number + 1, packet_count, size ); } offset = (packet_number * body_size); memcpy( net.split.buffer + offset, pData + sizeof( SPLITPACKET ), size ); // have we received all of the pieces to the packet? if( net.split.split_count <= 0 ) { net.split.current_sequence = -1; // Clear packet if( net.split.total_size > sizeof( net.split.buffer )) { Con_Printf( "Split packet too large! %d bytes\n", net.split.total_size ); return false; } memcpy( pData, net.split.buffer, net.split.total_size ); *outSize = net.split.total_size; return true; } return false; } /* ================== NET_QueuePacket queue normal and lagged packets ================== */ static qboolean NET_QueuePacket( netsrc_t sock, netadr_t *from, byte *data, size_t *length ) { byte buf[NET_MAX_FRAGMENT]; int ret, protocol; int net_socket; WSAsize_t addr_len; struct sockaddr_storage addr = { 0 }; *length = 0; for( protocol = 0; protocol < 2; protocol++ ) { switch( protocol ) { case 0: net_socket = net.ip_sockets[sock]; break; case 1: net_socket = net.ip6_sockets[sock]; break; } if( !NET_IsSocketValid( net_socket )) continue; addr_len = sizeof( addr ); ret = recvfrom( net_socket, buf, sizeof( buf ), 0, (struct sockaddr *)&addr, &addr_len ); NET_SockadrToNetadr( &addr, from ); if( !NET_IsSocketError( ret )) { if( ret < NET_MAX_FRAGMENT ) { // Transfer data memcpy( data, buf, ret ); *length = ret; #if !XASH_DEDICATED if( CL_LegacyMode( )) return NET_LagPacket( true, sock, from, length, data ); // check for split message if( sock == NS_CLIENT && *(int *)data == NET_HEADER_SPLITPACKET ) { return NET_GetLong( data, ret, length, CL_GetSplitSize( )); } #endif // lag the packet, if needed return NET_LagPacket( true, sock, from, length, data ); } else { Con_Reportf( "NET_QueuePacket: oversize packet from %s\n", NET_AdrToString( *from )); } } else { int err = WSAGetLastError(); switch( err ) { case WSAEWOULDBLOCK: case WSAECONNRESET: case WSAECONNREFUSED: case WSAEMSGSIZE: case WSAETIMEDOUT: break; default: // let's continue even after errors Con_DPrintf( S_ERROR "NET_QueuePacket: %s from %s\n", NET_ErrorString(), NET_AdrToString( *from )); break; } } } return NET_LagPacket( false, sock, from, length, data ); } /* ================== NET_GetPacket Never called by the game logic, just the system event queing ================== */ qboolean NET_GetPacket( netsrc_t sock, netadr_t *from, byte *data, size_t *length ) { if( !data || !length ) return false; NET_AdjustLag(); if( NET_GetLoopPacket( sock, from, data, length )) { return NET_LagPacket( true, sock, from, length, data ); } else { return NET_QueuePacket( sock, from, data, length ); } } /* ================== NET_SendLong Fragment long packets, send short directly ================== */ int NET_SendLong( netsrc_t sock, int net_socket, const char *buf, size_t len, int flags, const struct sockaddr_storage *to, size_t tolen, size_t splitsize ) { #ifdef NET_USE_FRAGMENTS // do we need to break this packet up? if( splitsize > sizeof( SPLITPACKET ) && sock == NS_SERVER && len > splitsize ) { char packet[SPLITPACKET_MAX_SIZE]; int total_sent, size, packet_count; int ret, packet_number; int body_size = splitsize - sizeof( SPLITPACKET ); SPLITPACKET *pPacket; net.sequence_number++; if( net.sequence_number <= 0 ) net.sequence_number = 1; pPacket = (SPLITPACKET *)packet; pPacket->sequence_number = net.sequence_number; pPacket->net_id = NET_HEADER_SPLITPACKET; packet_number = 0; total_sent = 0; packet_count = (len + body_size - 1) / body_size; while( len > 0 ) { size = Q_min( body_size, len ); pPacket->packet_id = (packet_number << 8) + packet_count; memcpy( packet + sizeof( SPLITPACKET ), buf + ( packet_number * body_size ), size ); if( net_showpackets.value == 3.0f ) { netadr_t adr; memset( &adr, 0, sizeof( adr )); NET_SockadrToNetadr( to, &adr ); Con_Printf( "Sending split %i of %i with %i bytes and seq %i to %s\n", packet_number + 1, packet_count, size, net.sequence_number, NET_AdrToString( adr )); } ret = sendto( net_socket, packet, size + sizeof( SPLITPACKET ), flags, (const struct sockaddr *)to, tolen ); if( ret < 0 ) return ret; // error if( ret >= size ) total_sent += size; len -= size; packet_number++; Sys_Sleep( 1 ); } return total_sent; } else #endif { // no fragmenantion for client connection return sendto( net_socket, buf, len, flags, (const struct sockaddr *)to, tolen ); } } /* ================== NET_SendPacketEx ================== */ void NET_SendPacketEx( netsrc_t sock, size_t length, const void *data, netadr_t to, size_t splitsize ) { int ret; struct sockaddr_storage addr = { 0 }; SOCKET net_socket = 0; if( !net.initialized || to.type == NA_LOOPBACK ) { NET_SendLoopPacket( sock, length, data, to ); return; } else if( to.type == NA_BROADCAST || to.type == NA_IP ) { net_socket = net.ip_sockets[sock]; if( !NET_IsSocketValid( net_socket )) return; } else if( to.type6 == NA_MULTICAST_IP6 || to.type6 == NA_IP6 ) { net_socket = net.ip6_sockets[sock]; if( !NET_IsSocketValid( net_socket )) return; } else { Host_Error( "NET_SendPacket: bad address type %i (%i)\n", to.type, to.type6 ); } NET_NetadrToSockadr( &to, &addr ); ret = NET_SendLong( sock, net_socket, data, length, 0, &addr, NET_SockAddrLen( &addr ), splitsize ); if( NET_IsSocketError( ret )) { int err = WSAGetLastError(); // WSAEWOULDBLOCK is silent if( err == WSAEWOULDBLOCK ) return; // some PPP links don't allow broadcasts if( err == WSAEADDRNOTAVAIL && ( to.type == NA_BROADCAST || to.type6 == NA_MULTICAST_IP6 )) return; if( Host_IsDedicated( )) { Con_DPrintf( S_ERROR "NET_SendPacket: %s to %s\n", NET_ErrorString(), NET_AdrToString( to )); } else if( err == WSAEADDRNOTAVAIL || err == WSAENOBUFS ) { Con_DPrintf( S_ERROR "NET_SendPacket: %s to %s\n", NET_ErrorString(), NET_AdrToString( to )); } else { Con_Printf( S_ERROR "NET_SendPacket: %s to %s\n", NET_ErrorString(), NET_AdrToString( to )); } } } /* ================== NET_SendPacket ================== */ void NET_SendPacket( netsrc_t sock, size_t length, const void *data, netadr_t to ) { NET_SendPacketEx( sock, length, data, to, 0 ); } /* ==================== NET_IPSocket ==================== */ static int NET_IPSocket( const char *net_iface, int port, int family ) { struct sockaddr_storage addr = { 0 }; int err, net_socket; uint optval = 1; dword _true = 1; int pfamily = PF_INET; if( family == AF_INET6 ) pfamily = PF_INET6; if( NET_IsSocketError(( net_socket = socket( pfamily, SOCK_DGRAM, IPPROTO_UDP )))) { err = WSAGetLastError(); if( err != WSAEAFNOSUPPORT ) Con_DPrintf( S_WARN "NET_UDPSocket: port: %d socket: %s\n", port, NET_ErrorString( )); return INVALID_SOCKET; } if( NET_IsSocketError( ioctlsocket( net_socket, FIONBIO, (void*)&_true ))) { struct timeval timeout; Con_DPrintf( S_WARN "NET_UDPSocket: port: %d ioctl FIONBIO: %s\n", port, NET_ErrorString( )); // try timeout instead of NBIO timeout.tv_sec = timeout.tv_usec = 0; setsockopt( net_socket, SOL_SOCKET, SO_RCVTIMEO, (char *)&timeout, sizeof(timeout)); } // make it broadcast capable if( NET_IsSocketError( setsockopt( net_socket, SOL_SOCKET, SO_BROADCAST, (char *)&_true, sizeof( _true )))) { Con_DPrintf( S_WARN "NET_UDPSocket: port: %d setsockopt SO_BROADCAST: %s\n", port, NET_ErrorString( )); } if( NET_IsSocketError( setsockopt( net_socket, SOL_SOCKET, SO_REUSEADDR, (const char *)&optval, sizeof( optval )))) { Con_DPrintf( S_WARN "NET_UDPSocket: port: %d setsockopt SO_REUSEADDR: %s\n", port, NET_ErrorString( )); closesocket( net_socket ); return INVALID_SOCKET; } addr.ss_family = family; if( family == AF_INET6 ) { if( NET_IsSocketError( setsockopt( net_socket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_true, sizeof( _true )))) { Con_DPrintf( S_WARN "NET_UDPSocket: port: %d setsockopt IPV6_V6ONLY: %s\n", port, NET_ErrorString( )); closesocket( net_socket ); return INVALID_SOCKET; } if( Sys_CheckParm( "-loopback" )) { if( NET_IsSocketError( setsockopt( net_socket, IPPROTO_IPV6, IPV6_MULTICAST_LOOP, (char *)&_true, sizeof( _true )))) Con_DPrintf( S_WARN "NET_UDPSocket: port %d setsockopt IPV6_MULTICAST_LOOP: %s\n", port, NET_ErrorString( )); } if( COM_CheckStringEmpty( net_iface ) && Q_stricmp( net_iface, "localhost" )) NET_StringToSockaddr( net_iface, &addr, false, AF_INET6 ); else memcpy(((struct sockaddr_in6 *)&addr)->sin6_addr.s6_addr, &in6addr_any, sizeof( struct in6_addr )); if( port == PORT_ANY ) ((struct sockaddr_in6 *)&addr)->sin6_port = 0; else ((struct sockaddr_in6 *)&addr)->sin6_port = htons((short)port); if( NET_IsSocketError( bind( net_socket, (struct sockaddr *)&addr, sizeof( struct sockaddr_in6 )))) { Con_DPrintf( S_WARN "NET_UDPSocket: port: %d bind6: %s\n", port, NET_ErrorString( )); closesocket( net_socket ); return INVALID_SOCKET; } } else if( family == AF_INET ) { if( Sys_CheckParm( "-tos" )) { optval = 0x10; // IPTOS_LOWDELAY Con_Printf( "Enabling LOWDELAY TOS option\n" ); if( NET_IsSocketError( setsockopt( net_socket, IPPROTO_IP, IP_TOS, (const char *)&optval, sizeof( optval )))) { err = WSAGetLastError(); if( err != WSAENOPROTOOPT ) Con_Printf( S_WARN "NET_UDPSocket: port: %d setsockopt IP_TOS: %s\n", port, NET_ErrorString( )); closesocket( net_socket ); return INVALID_SOCKET; } } if( Sys_CheckParm( "-loopback" )) { if( NET_IsSocketError( setsockopt( net_socket, IPPROTO_IP, IP_MULTICAST_LOOP, (char *)&_true, sizeof( _true )))) Con_DPrintf( S_WARN "NET_UDPSocket: port %d setsockopt IP_MULTICAST_LOOP: %s\n", port, NET_ErrorString( )); } if( COM_CheckStringEmpty( net_iface ) && Q_stricmp( net_iface, "localhost" )) NET_StringToSockaddr( net_iface, &addr, false, AF_INET ); else ((struct sockaddr_in *)&addr)->sin_addr.s_addr = INADDR_ANY; if( port == PORT_ANY ) ((struct sockaddr_in *)&addr)->sin_port = 0; else ((struct sockaddr_in *)&addr)->sin_port = htons((short)port); if( NET_IsSocketError( bind( net_socket, (struct sockaddr *)&addr, sizeof( struct sockaddr_in )))) { Con_DPrintf( S_WARN "NET_UDPSocket: port: %d bind: %s\n", port, NET_ErrorString( )); closesocket( net_socket ); return INVALID_SOCKET; } } return net_socket; } /* ==================== NET_OpenIP ==================== */ static void NET_OpenIP( qboolean change_port, int *sockets, const char *net_iface, int hostport, int clientport, int family ) { int port; qboolean sv_nat = Cvar_VariableInteger("sv_nat"); qboolean cl_nat = Cvar_VariableInteger("cl_nat"); if( change_port && ( FBitSet( net_hostport.flags, FCVAR_CHANGED ) || sv_nat )) { // reopen socket to set random port if( NET_IsSocketValid( sockets[NS_SERVER] )) closesocket( sockets[NS_SERVER] ); sockets[NS_SERVER] = INVALID_SOCKET; ClearBits( net_hostport.flags, FCVAR_CHANGED ); } if( !NET_IsSocketValid( sockets[NS_SERVER] )) { port = hostport; if( !port ) { port = sv_nat ? PORT_ANY : net_hostport.value; if( !port ) port = PORT_SERVER; // forcing to default } sockets[NS_SERVER] = NET_IPSocket( net_iface, port, family ); if( !NET_IsSocketValid( sockets[NS_SERVER] ) && Host_IsDedicated( )) return; } // dedicated servers don't need client ports if( Host_IsDedicated( )) return; if( change_port && ( FBitSet( net_clientport.flags, FCVAR_CHANGED ) || cl_nat )) { // reopen socket to set random port if( NET_IsSocketValid( sockets[NS_CLIENT] )) closesocket( sockets[NS_CLIENT] ); sockets[NS_CLIENT] = INVALID_SOCKET; ClearBits( net_clientport.flags, FCVAR_CHANGED ); } if( !NET_IsSocketValid( sockets[NS_CLIENT] )) { port = clientport; if( !port ) { port = cl_nat ? PORT_ANY : net_clientport.value; if( !port ) port = PORT_ANY; // forcing to default } sockets[NS_CLIENT] = NET_IPSocket( net_iface, port, family ); if( !NET_IsSocketValid( sockets[NS_CLIENT] )) sockets[NS_CLIENT] = NET_IPSocket( net_ipname.string, PORT_ANY, family ); } return; } /* ================ NET_GetLocalAddress Returns the servers' ip address as a string. ================ */ void NET_GetLocalAddress( void ) { char hostname[512]; char buff[512]; struct sockaddr_storage address; WSAsize_t namelen; const char *net_addr_string; memset( &net_local, 0, sizeof( netadr_t )); memset( &net6_local, 0, sizeof( netadr_t )); if( !net.allow_ip && !net.allow_ip6 ) { Con_Printf( "TCP/IP Disabled.\n" ); return; } gethostname( hostname, sizeof( hostname )); hostname[sizeof(hostname) - 1] = 0; if( net.allow_ip ) { // If we have changed the ip var from the command line, use that instead. if( Q_stricmp( net_ipname.string, "localhost" )) Q_strncpy( buff, net_ipname.string, sizeof( buff )); else Q_strncpy( buff, hostname, sizeof( buff )); if( NET_StringToAdrEx( buff, &net_local, AF_INET )) { namelen = sizeof( struct sockaddr_in ); if( !NET_IsSocketError( getsockname( net.ip_sockets[NS_SERVER], (struct sockaddr *)&address, &namelen ))) { net_local.port = ((struct sockaddr_in *)&address)->sin_port; net_addr_string = NET_AdrToString( net_local ); Con_Printf( "Server IPv4 address %s\n", net_addr_string ); Cvar_FullSet( "net_address", net_addr_string, net_address.flags ); } else Con_DPrintf( S_ERROR "Could not get TCP/IPv4 address. Reason: %s\n", NET_ErrorString( )); } else Con_DPrintf( S_ERROR "Could not get TCP/IPv4 address, Invalid hostname: '%s'\n", buff ); } if( net.allow_ip6 ) { // If we have changed the ip var from the command line, use that instead. if( Q_stricmp( net_ip6name.string, "localhost" )) Q_strncpy( buff, net_ip6name.string, sizeof( buff )); else Q_strncpy( buff, hostname, sizeof( buff )); if( NET_StringToAdrEx( buff, &net6_local, AF_INET6 )) { namelen = sizeof( struct sockaddr_in6 ); if( !NET_IsSocketError( getsockname( net.ip6_sockets[NS_SERVER], (struct sockaddr *)&address, &namelen ))) { net6_local.port = ((struct sockaddr_in6 *)&address)->sin6_port; net_addr_string = NET_AdrToString( net6_local ); Con_Printf( "Server IPv6 address %s\n", net_addr_string ); Cvar_FullSet( "net6_address", net_addr_string, net6_address.flags ); } else Con_DPrintf( S_ERROR "Could not get TCP/IPv6 address. Reason: %s\n", NET_ErrorString( )); } else Con_DPrintf( S_ERROR "Could not get TCP/IPv6 address, Invalid hostname: '%s'\n", buff ); } } /* ==================== NET_Config A single player game will only use the loopback code ==================== */ void NET_Config( qboolean multiplayer, qboolean changeport ) { static qboolean bFirst = true; static qboolean old_config; if( !net.initialized ) return; if( old_config == multiplayer ) return; old_config = multiplayer; if( multiplayer ) { // open sockets if( net.allow_ip ) NET_OpenIP( changeport, net.ip_sockets, net_ipname.string, net_iphostport.value, net_ipclientport.value, AF_INET ); if( net.allow_ip6 ) NET_OpenIP( changeport, net.ip6_sockets, net_ip6name.string, net_ip6hostport.value, net_ip6clientport.value, AF_INET6 ); // validate sockets for dedicated if( Host_IsDedicated( )) { qboolean nov4, nov6; nov4 = net.allow_ip && NET_IsSocketError( net.ip_sockets[NS_SERVER] ); nov6 = net.allow_ip6 && NET_IsSocketError( net.ip6_sockets[NS_SERVER] ); if( nov4 && nov6 ) Host_Error( "Couldn't allocate IPv4 and IPv6 server ports.\n" ); else if( nov4 && !nov6 ) Con_Printf( S_ERROR "Couldn't allocate IPv4 server port\n" ); else if( !nov4 && nov6 ) Con_Printf( S_ERROR "Couldn't allocate IPv6 server_port\n" ); } // get our local address, if possible if( bFirst ) { NET_GetLocalAddress(); bFirst = false; } } else { int i; // shut down any existing sockets for( i = 0; i < NS_COUNT; i++ ) { if( NET_IsSocketValid( net.ip_sockets[i] )) { closesocket( net.ip_sockets[i] ); net.ip_sockets[i] = INVALID_SOCKET; } if( NET_IsSocketValid( net.ip6_sockets[i] )) { closesocket( net.ip6_sockets[i] ); net.ip6_sockets[i] = INVALID_SOCKET; } } } NET_ClearLoopback (); net.configured = multiplayer ? true : false; } /* ==================== NET_IsConfigured Is winsock ip initialized? ==================== */ qboolean NET_IsConfigured( void ) { return net.configured; } /* ==================== NET_IsActive ==================== */ qboolean NET_IsActive( void ) { return net.initialized; } /* ==================== NET_Sleep sleeps msec or until net socket is ready ==================== */ void NET_Sleep( int msec ) { #ifndef XASH_NO_NETWORK struct timeval timeout; fd_set fdset; int i = 0; if( !net.initialized || host.type == HOST_NORMAL ) return; // we're not a dedicated server, just run full speed FD_ZERO( &fdset ); if( net.ip_sockets[NS_SERVER] != INVALID_SOCKET ) { FD_SET( net.ip_sockets[NS_SERVER], &fdset ); // network socket i = net.ip_sockets[NS_SERVER]; } timeout.tv_sec = msec / 1000; timeout.tv_usec = (msec % 1000) * 1000; select( i+1, &fdset, NULL, NULL, &timeout ); #endif } /* ==================== NET_ClearLagData clear fakelag list ==================== */ void NET_ClearLagData( qboolean bClient, qboolean bServer ) { if( bClient ) NET_ClearLaggedList( &net.lagdata[NS_CLIENT] ); if( bServer ) NET_ClearLaggedList( &net.lagdata[NS_SERVER] ); } /* ==================== NET_Init ==================== */ void NET_Init( void ) { char cmd[64]; int i = 1; if( net.initialized ) return; Cvar_RegisterVariable( &net_address ); Cvar_RegisterVariable( &net_ipname ); Cvar_RegisterVariable( &net_iphostport ); Cvar_RegisterVariable( &net_hostport ); Cvar_RegisterVariable( &net_ipclientport ); Cvar_RegisterVariable( &net_clientport ); Cvar_RegisterVariable( &net_fakelag ); Cvar_RegisterVariable( &net_fakeloss ); Q_snprintf( cmd, sizeof( cmd ), "%i", PORT_SERVER ); Cvar_FullSet( "hostport", cmd, FCVAR_READ_ONLY ); // cvar equivalents for IPv6 Cvar_RegisterVariable( &net_ip6name ); Cvar_RegisterVariable( &net_ip6hostport ); Cvar_RegisterVariable( &net_ip6clientport ); Cvar_RegisterVariable( &net6_address ); // prepare some network data for( i = 0; i < NS_COUNT; i++ ) { net.lagdata[i].prev = &net.lagdata[i]; net.lagdata[i].next = &net.lagdata[i]; net.ip_sockets[i] = INVALID_SOCKET; net.ip6_sockets[i] = INVALID_SOCKET; } #if XASH_WIN32 if( WSAStartup( MAKEWORD( 1, 1 ), &net.winsockdata )) { Con_DPrintf( S_ERROR "network initialization failed.\n" ); return; } #endif #ifdef CAN_ASYNC_NS_RESOLVE NET_InitializeCriticalSections(); #endif net.allow_ip = !Sys_CheckParm( "-noip" ); net.allow_ip6 = !Sys_CheckParm( "-noip6" ); // specify custom host port if( Sys_GetParmFromCmdLine( "-port", cmd ) && Q_isdigit( cmd )) Cvar_FullSet( "hostport", cmd, FCVAR_READ_ONLY ); // specify custom IPv6 host port if( Sys_GetParmFromCmdLine( "-port6", cmd ) && Q_isdigit( cmd )) Cvar_FullSet( "ip6_hostport", cmd, FCVAR_READ_ONLY ); // specify custom ip if( Sys_GetParmFromCmdLine( "-ip", cmd )) Cvar_FullSet( "ip", cmd, net_ipname.flags ); // specify custom ip6 if( Sys_GetParmFromCmdLine( "-ip6", cmd )) Cvar_FullSet( "ip6", cmd, net_ip6name.flags ); // adjust clockwindow if( Sys_GetParmFromCmdLine( "-clockwindow", cmd )) Cvar_SetValue( "clockwindow", Q_atof( cmd )); net.sequence_number = 1; net.initialized = true; Con_Reportf( "Base networking initialized.\n" ); } /* ==================== NET_Shutdown ==================== */ void NET_Shutdown( void ) { if( !net.initialized ) return; NET_ClearLagData( true, true ); NET_Config( false, false ); #if XASH_WIN32 WSACleanup(); #endif net.initialized = false; } /* ================================================= HTTP downloader ================================================= */ typedef struct httpserver_s { char host[256]; int port; char path[MAX_SYSPATH]; qboolean needfree; struct httpserver_s *next; } httpserver_t; enum connectionstate { HTTP_QUEUE = 0, HTTP_OPENED, HTTP_SOCKET, HTTP_NS_RESOLVED, HTTP_CONNECTED, HTTP_REQUEST, HTTP_REQUEST_SENT, HTTP_RESPONSE_RECEIVED, HTTP_FREE }; typedef struct httpfile_s { struct httpfile_s *next; httpserver_t *server; char path[MAX_SYSPATH]; file_t *file; int socket; int size; int downloaded; int lastchecksize; float checktime; float blocktime; int id; enum connectionstate state; qboolean process; // query or response char buf[BUFSIZ+1]; int header_size, query_length, bytes_sent; } httpfile_t; static struct http_static_s { // file and server lists httpfile_t *first_file, *last_file; httpserver_t *first_server, *last_server; } http; static CVAR_DEFINE_AUTO( http_useragent, "", FCVAR_ARCHIVE | FCVAR_PRIVILEGED, "User-Agent string" ); static CVAR_DEFINE_AUTO( http_autoremove, "1", FCVAR_ARCHIVE | FCVAR_PRIVILEGED, "remove broken files" ); static CVAR_DEFINE_AUTO( http_timeout, "45", FCVAR_ARCHIVE | FCVAR_PRIVILEGED, "timeout for http downloader" ); static CVAR_DEFINE_AUTO( http_maxconnections, "4", FCVAR_ARCHIVE | FCVAR_PRIVILEGED, "maximum http connection number" ); /* ======================== HTTP_ClearCustomServers ======================== */ void HTTP_ClearCustomServers( void ) { if( http.first_file ) return; // may be referenced while( http.first_server && http.first_server->needfree ) { httpserver_t *tmp = http.first_server; http.first_server = http.first_server->next; Mem_Free( tmp ); } } /* ============== HTTP_FreeFile Skip to next server/file ============== */ static void HTTP_FreeFile( httpfile_t *file, qboolean error ) { char incname[256]; // Allways close file and socket if( file->file ) FS_Close( file->file ); file->file = NULL; if( file->socket != -1 ) closesocket( file->socket ); file->socket = -1; Q_snprintf( incname, 256, "downloaded/%s.incomplete", file->path ); if( error ) { // Switch to next fastdl server if present if( file->server && ( file->state > HTTP_QUEUE ) && ( file->state != HTTP_FREE )) { file->server = file->server->next; file->state = HTTP_QUEUE; // Reset download state, HTTP_Run() will open file again return; } // Called because there was no servers to download, free file now if( http_autoremove.value == 1 ) // remove broken file FS_Delete( incname ); else // autoremove disabled, keep file Con_Printf( "cannot download %s from any server. " "You may remove %s now\n", file->path, incname ); // Warn about trash file if( file->process ) CL_ProcessFile( false, file->path ); // Process file, increase counter } else { // Success, rename and process file char name[256]; Q_snprintf( name, 256, "downloaded/%s", file->path ); FS_Rename( incname, name ); if( file->process ) CL_ProcessFile( true, name ); else Con_Printf( "successfully downloaded %s, processing disabled!\n", name ); } file->state = HTTP_FREE; } /* =================== HTTP_AutoClean remove files with HTTP_FREE state from list =================== */ static void HTTP_AutoClean( void ) { httpfile_t *curfile, *prevfile = 0; // clean all files marked to free for( curfile = http.first_file; curfile; curfile = curfile->next ) { if( curfile->state != HTTP_FREE ) { prevfile = curfile; continue; } if( curfile == http.first_file ) { http.first_file = http.first_file->next; Mem_Free( curfile ); curfile = http.first_file; if( !curfile ) break; continue; } if( prevfile ) prevfile->next = curfile->next; Mem_Free( curfile ); curfile = prevfile; if( !curfile ) break; } http.last_file = prevfile; } /* =================== HTTP_ProcessStream process incoming data =================== */ static qboolean HTTP_ProcessStream( httpfile_t *curfile ) { char buf[BUFSIZ+1]; char *begin = 0; int res; if( curfile->header_size >= BUFSIZ ) { Con_Reportf( S_ERROR "Header to big\n"); HTTP_FreeFile( curfile, true ); return false; } while( ( res = recv( curfile->socket, buf, BUFSIZ - curfile->header_size, 0 )) > 0) // if we got there, we are receiving data { curfile->blocktime = 0; if( curfile->state < HTTP_RESPONSE_RECEIVED ) // Response still not received { memcpy( curfile->buf + curfile->header_size, buf, res ); curfile->buf[curfile->header_size + res] = 0; begin = Q_strstr( curfile->buf, "\r\n\r\n" ); if( begin ) // Got full header { int cutheadersize = begin - curfile->buf + 4; // after that begin of data char *length; Con_Reportf( "HTTP: Got response!\n" ); if( !Q_strstr( curfile->buf, "200 OK" )) { *begin = 0; // cut string to print out response begin = Q_strchr( curfile->buf, '\r' ); if( !begin ) begin = Q_strchr( curfile->buf, '\n' ); if( begin ) *begin = 0; Con_Printf( S_ERROR "%s: bad response: %s\n", curfile->path, curfile->buf ); HTTP_FreeFile( curfile, true ); return false; } // print size length = Q_stristr( curfile->buf, "Content-Length: " ); if( length ) { int size = Q_atoi( length += 16 ); Con_Reportf( "HTTP: File size is %d\n", size ); if( ( curfile->size != -1 ) && ( curfile->size != size )) // check size if specified, not used Con_Reportf( S_WARN "Server reports wrong file size!\n" ); curfile->size = size; curfile->header_size = 0; } if( curfile->size == -1 ) { // Usually fastdl's reports file size if link is correct Con_Printf( S_ERROR "file size is unknown, refusing download!\n" ); HTTP_FreeFile( curfile, true ); return false; } curfile->state = HTTP_RESPONSE_RECEIVED; // got response, let's start download begin += 4; // Write remaining message part if( res - cutheadersize - curfile->header_size > 0 ) { int ret = FS_Write( curfile->file, begin, res - cutheadersize - curfile->header_size ); if( ret != res - cutheadersize - curfile->header_size ) // could not write file { // close it and go to next Con_Printf( S_ERROR "write failed for %s!\n", curfile->path ); HTTP_FreeFile( curfile, true ); return false; } curfile->downloaded += ret; } } else curfile->header_size += res; } else if( res > 0 ) { // data download int ret = FS_Write( curfile->file, buf, res ); if ( ret != res ) { // close it and go to next Con_Printf( S_ERROR "write failed for %s!\n", curfile->path ); curfile->state = HTTP_FREE; HTTP_FreeFile( curfile, true ); return false; } curfile->downloaded += ret; curfile->lastchecksize += ret; // as after it will run in same frame if( curfile->checktime > 5 ) { float speed = (float)curfile->lastchecksize / ( 5.0f * 1024 ); curfile->checktime = 0; Con_Reportf( "download speed %f KB/s\n", speed ); curfile->lastchecksize = 0; } } } curfile->checktime += host.frametime; return true; } /* ============== HTTP_Run Download next file block of each active file Call every frame ============== */ void HTTP_Run( void ) { httpfile_t *curfile; int iActiveCount = 0; int iProgressCount = 0; float flProgress = 0; qboolean fResolving = false; for( curfile = http.first_file; curfile; curfile = curfile->next ) { struct sockaddr_storage addr; if( curfile->state == HTTP_FREE ) continue; if( curfile->state == HTTP_QUEUE ) { char name[MAX_SYSPATH]; if( iActiveCount > http_maxconnections.value ) continue; if( !curfile->server ) { Con_Printf( S_ERROR "no servers to download %s!\n", curfile->path ); HTTP_FreeFile( curfile, true ); break; } Con_Reportf( "HTTP: Starting download %s from %s\n", curfile->path, curfile->server->host ); Q_snprintf( name, sizeof( name ), "downloaded/%s.incomplete", curfile->path ); curfile->file = FS_Open( name, "wb", true ); if( !curfile->file ) { Con_Printf( S_ERROR "cannot open %s!\n", name ); HTTP_FreeFile( curfile, true ); break; } curfile->state = HTTP_OPENED; curfile->blocktime = 0; curfile->downloaded = 0; curfile->lastchecksize = 0; curfile->checktime = 0; } iActiveCount++; if( curfile->state < HTTP_SOCKET ) // Socket is not created { dword mode; curfile->socket = socket( AF_INET, SOCK_STREAM, IPPROTO_TCP ); // Now set non-blocking mode // You may skip this if not supported by system, // but download will lock engine, maybe you will need to add manual returns mode = 1; ioctlsocket( curfile->socket, FIONBIO, (void*)&mode ); #if XASH_LINUX // SOCK_NONBLOCK is not portable, so use fcntl fcntl( curfile->socket, F_SETFL, fcntl( curfile->socket, F_GETFL, 0 ) | O_NONBLOCK ); #endif curfile->state = HTTP_SOCKET; } if( curfile->state < HTTP_NS_RESOLVED ) { net_gai_state_t res; char hostport[MAX_VA_STRING]; if( fResolving ) continue; Q_snprintf( hostport, sizeof( hostport ), "%s:%d", curfile->server->host, curfile->server->port ); res = NET_StringToSockaddr( hostport, &addr, true, AF_INET ); if( res == NET_EAI_AGAIN ) { fResolving = true; continue; } if( res == NET_EAI_NONAME ) { Con_Printf( S_ERROR "failed to resolve server address for %s!\n", curfile->server->host ); HTTP_FreeFile( curfile, true ); // Cannot connect break; } curfile->state = HTTP_NS_RESOLVED; } if( curfile->state < HTTP_CONNECTED ) // Connection not enstabilished { int res = connect( curfile->socket, (struct sockaddr*)&addr, NET_SockAddrLen( &addr ) ); if( res ) { if( WSAGetLastError() == WSAEINPROGRESS || WSAGetLastError() == WSAEWOULDBLOCK ) // Should give EWOOLDBLOCK if try recv too soon curfile->state = HTTP_CONNECTED; else { Con_Printf( S_ERROR "cannot connect to server: %s\n", NET_ErrorString( )); HTTP_FreeFile( curfile, true ); // Cannot connect break; } continue; // skip to next file } curfile->state = HTTP_CONNECTED; } if( curfile->state < HTTP_REQUEST ) // Request not formatted { string useragent; if( !COM_CheckStringEmpty( http_useragent.string ) || !Q_strcmp( http_useragent.string, "xash3d" )) { Q_snprintf( useragent, sizeof( useragent ), "%s/%s (%s-%s; build %d; %s)", XASH_ENGINE_NAME, XASH_VERSION, Q_buildos( ), Q_buildarch( ), Q_buildnum( ), Q_buildcommit( )); } else { Q_strncpy( useragent, http_useragent.string, sizeof( useragent )); } curfile->query_length = Q_snprintf( curfile->buf, sizeof( curfile->buf ), "GET %s%s HTTP/1.0\r\n" "Host: %s\r\n" "User-Agent: %s\r\n\r\n", curfile->server->path, curfile->path, curfile->server->host, useragent ); curfile->header_size = 0; curfile->bytes_sent = 0; curfile->state = HTTP_REQUEST; } if( curfile->state < HTTP_REQUEST_SENT ) // Request not sent { qboolean wait = false; while( curfile->bytes_sent < curfile->query_length ) { int res = send( curfile->socket, curfile->buf + curfile->bytes_sent, curfile->query_length - curfile->bytes_sent, 0 ); if( res < 0 ) { if( WSAGetLastError() != WSAEWOULDBLOCK && WSAGetLastError() != WSAENOTCONN ) { Con_Printf( S_ERROR "failed to send request: %s\n", NET_ErrorString( )); HTTP_FreeFile( curfile, true ); wait = true; break; } // blocking while waiting connection // increase counter when blocking curfile->blocktime += host.frametime; wait = true; if( curfile->blocktime > http_timeout.value ) { Con_Printf( S_ERROR "timeout on request send:\n%s\n", curfile->buf ); HTTP_FreeFile( curfile, true ); break; } break; } else { curfile->bytes_sent += res; curfile->blocktime = 0; } } if( wait ) continue; Con_Reportf( "HTTP: Request sent!\n"); memset( curfile->buf, 0, sizeof( curfile->buf )); curfile->state = HTTP_REQUEST_SENT; } if( !HTTP_ProcessStream( curfile )) break; if( curfile->size > 0 ) { flProgress += (float)curfile->downloaded / curfile->size; iProgressCount++; } if( curfile->size > 0 && curfile->downloaded >= curfile->size ) { HTTP_FreeFile( curfile, false ); // success break; } else if(( WSAGetLastError( ) != WSAEWOULDBLOCK ) && ( WSAGetLastError( ) != WSAEINPROGRESS )) Con_Reportf( "problem downloading %s:\n%s\n", curfile->path, NET_ErrorString( )); else curfile->blocktime += host.frametime; if( curfile->blocktime > http_timeout.value ) { Con_Printf( S_ERROR "timeout on receiving data!\n"); HTTP_FreeFile( curfile, true ); break; } } // update progress if( !Host_IsDedicated() && iProgressCount != 0 ) Cvar_SetValue( "scr_download", flProgress/iProgressCount * 100 ); HTTP_AutoClean(); } /* =================== HTTP_AddDownload Add new download to end of queue =================== */ void HTTP_AddDownload( const char *path, int size, qboolean process ) { httpfile_t *httpfile = Z_Calloc( sizeof( httpfile_t )); Con_Reportf( "File %s queued to download\n", path ); httpfile->size = size; httpfile->downloaded = 0; httpfile->socket = -1; Q_strncpy ( httpfile->path, path, sizeof( httpfile->path )); if( http.last_file ) { // Add next to last download httpfile->id = http.last_file->id + 1; http.last_file->next= httpfile; http.last_file = httpfile; } else { // It will be the only download httpfile->id = 0; http.last_file = http.first_file = httpfile; } httpfile->file = NULL; httpfile->next = NULL; httpfile->state = HTTP_QUEUE; httpfile->server = http.first_server; httpfile->process = process; } /* =============== HTTP_Download_f Console wrapper =============== */ static void HTTP_Download_f( void ) { if( Cmd_Argc() < 2 ) { Con_Printf( S_USAGE "download \n"); return; } HTTP_AddDownload( Cmd_Argv( 1 ), -1, false ); } /* ============== HTTP_ParseURL ============== */ static httpserver_t *HTTP_ParseURL( const char *url ) { httpserver_t *server; int i; url = Q_strstr( url, "http://" ); if( !url ) return NULL; url += 7; server = Z_Calloc( sizeof( httpserver_t )); i = 0; while( *url && ( *url != ':' ) && ( *url != '/' ) && ( *url != '\r' ) && ( *url != '\n' )) { if( i > sizeof( server->host )) return NULL; server->host[i++] = *url++; } server->host[i] = 0; if( *url == ':' ) { server->port = Q_atoi( ++url ); while( *url && ( *url != '/' ) && ( *url != '\r' ) && ( *url != '\n' )) url++; } else server->port = 80; i = 0; while( *url && ( *url != '\r' ) && ( *url != '\n' )) { if( i > sizeof( server->path )) return NULL; server->path[i++] = *url++; } server->path[i] = 0; server->next = NULL; server->needfree = false; return server; } /* ======================= HTTP_AddCustomServer ======================= */ void HTTP_AddCustomServer( const char *url ) { httpserver_t *server = HTTP_ParseURL( url ); if( !server ) { Con_Printf( S_ERROR "\"%s\" is not valid url!\n", url ); return; } server->needfree = true; server->next = http.first_server; http.first_server = server; } /* ======================= HTTP_AddCustomServer_f ======================= */ static void HTTP_AddCustomServer_f( void ) { if( Cmd_Argc() == 2 ) { HTTP_AddCustomServer( Cmd_Argv( 1 )); } } /* ============ HTTP_Clear_f Clear all queue ============ */ static void HTTP_Clear_f( void ) { http.last_file = NULL; while( http.first_file ) { httpfile_t *file = http.first_file; http.first_file = http.first_file->next; if( file->file ) FS_Close( file->file ); if( file->socket != -1 ) closesocket( file->socket ); Mem_Free( file ); } } /* ============== HTTP_Cancel_f Stop current download, skip to next file ============== */ static void HTTP_Cancel_f( void ) { if( !http.first_file ) return; http.first_file->state = HTTP_FREE; HTTP_FreeFile( http.first_file, true ); } /* ============= HTTP_Skip_f Stop current download, skip to next server ============= */ static void HTTP_Skip_f( void ) { if( http.first_file ) HTTP_FreeFile( http.first_file, true ); } /* ============= HTTP_List_f Print all pending downloads to console ============= */ static void HTTP_List_f( void ) { httpfile_t *file = http.first_file; while( file ) { if ( file->server ) Con_Printf ( "\t%d %d http://%s:%d/%s%s %d\n", file->id, file->state, file->server->host, file->server->port, file->server->path, file->path, file->downloaded ); else Con_Printf ( "\t%d %d (no server) %s\n", file->id, file->state, file->path ); file = file->next; } } /* ================ HTTP_ResetProcessState When connected to new server, all old files should not increase counter ================ */ void HTTP_ResetProcessState( void ) { httpfile_t *file = http.first_file; while( file ) { file->process = false; file = file->next; } } /* ============= HTTP_Init ============= */ void HTTP_Init( void ) { char *serverfile, *line, token[1024]; http.last_server = NULL; http.first_file = http.last_file = NULL; Cmd_AddRestrictedCommand( "http_download", HTTP_Download_f, "add file to download queue" ); Cmd_AddRestrictedCommand( "http_skip", HTTP_Skip_f, "skip current download server" ); Cmd_AddRestrictedCommand( "http_cancel", HTTP_Cancel_f, "cancel current download" ); Cmd_AddRestrictedCommand( "http_clear", HTTP_Clear_f, "cancel all downloads" ); Cmd_AddRestrictedCommand( "http_list", HTTP_List_f, "list all queued downloads" ); Cmd_AddCommand( "http_addcustomserver", HTTP_AddCustomServer_f, "add custom fastdl server"); Cvar_RegisterVariable( &http_useragent ); Cvar_RegisterVariable( &http_autoremove ); Cvar_RegisterVariable( &http_timeout ); Cvar_RegisterVariable( &http_maxconnections ); // Read servers from fastdl.txt line = serverfile = (char *)FS_LoadFile( "fastdl.txt", 0, false ); if( serverfile ) { while(( line = COM_ParseFile( line, token, sizeof( token )))) { httpserver_t *server = HTTP_ParseURL( token ); if( !server ) continue; if( !http.last_server ) http.last_server = http.first_server = server; else { http.last_server->next = server; http.last_server = server; } } Mem_Free( serverfile ); } } /* ==================== HTTP_Shutdown ==================== */ void HTTP_Shutdown( void ) { HTTP_Clear_f(); while( http.first_server ) { httpserver_t *tmp = http.first_server; http.first_server = http.first_server->next; Mem_Free( tmp ); } http.last_server = NULL; }