/*
===========================================================================
Doom 3 GPL Source Code
Copyright (C) 1999-2011 id Software LLC, a ZeniMax Media company.
This file is part of the Doom 3 GPL Source Code (?Doom 3 Source Code?).
Doom 3 Source Code 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.
Doom 3 Source Code 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 Doom 3 Source Code. If not, see .
In addition, the Doom 3 Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 Source Code. If not, please request a copy in writing from id Software at the address below.
If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA.
===========================================================================
*/
#include "../../idlib/precompiled.h"
#pragma hdrstop
#include
#include
#include "win_local.h"
static WSADATA winsockdata;
static bool winsockInitialized = false;
static bool usingSocks = false;
idCVar net_ip( "net_ip", "localhost", CVAR_SYSTEM, "local IP address" );
idCVar net_port( "net_port", "0", CVAR_SYSTEM | CVAR_INTEGER, "local IP port number" );
idCVar net_forceLatency( "net_forceLatency", "0", CVAR_SYSTEM | CVAR_INTEGER, "milliseconds latency" );
idCVar net_forceDrop( "net_forceDrop", "0", CVAR_SYSTEM | CVAR_INTEGER, "percentage packet loss" );
idCVar net_socksEnabled( "net_socksEnabled", "0", CVAR_SYSTEM | CVAR_ARCHIVE | CVAR_BOOL, "" );
idCVar net_socksServer( "net_socksServer", "", CVAR_SYSTEM | CVAR_ARCHIVE, "" );
idCVar net_socksPort( "net_socksPort", "1080", CVAR_SYSTEM | CVAR_ARCHIVE | CVAR_INTEGER, "" );
idCVar net_socksUsername( "net_socksUsername", "", CVAR_SYSTEM | CVAR_ARCHIVE, "" );
idCVar net_socksPassword( "net_socksPassword", "", CVAR_SYSTEM | CVAR_ARCHIVE, "" );
static struct sockaddr socksRelayAddr;
static SOCKET ip_socket;
static SOCKET socks_socket;
static char socksBuf[4096];
typedef struct {
unsigned long ip;
unsigned long mask;
} net_interface;
#define MAX_INTERFACES 32
int num_interfaces = 0;
net_interface netint[MAX_INTERFACES];
//=============================================================================
/*
====================
NET_ErrorString
====================
*/
char *NET_ErrorString( void ) {
int code;
code = WSAGetLastError();
switch( code ) {
case WSAEINTR: return "WSAEINTR";
case WSAEBADF: return "WSAEBADF";
case WSAEACCES: return "WSAEACCES";
case WSAEDISCON: return "WSAEDISCON";
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 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";
}
}
/*
====================
Net_NetadrToSockadr
====================
*/
void Net_NetadrToSockadr( const netadr_t *a, struct sockaddr *s ) {
memset( s, 0, sizeof(*s) );
if( a->type == NA_BROADCAST ) {
((struct sockaddr_in *)s)->sin_family = AF_INET;
((struct sockaddr_in *)s)->sin_addr.s_addr = INADDR_BROADCAST;
}
else if( a->type == NA_IP || a->type == NA_LOOPBACK ) {
((struct sockaddr_in *)s)->sin_family = AF_INET;
((struct sockaddr_in *)s)->sin_addr.s_addr = *(int *)&a->ip;
}
((struct sockaddr_in *)s)->sin_port = htons( (short)a->port );
}
/*
====================
Net_SockadrToNetadr
====================
*/
void Net_SockadrToNetadr( struct sockaddr *s, netadr_t *a ) {
unsigned int ip;
if (s->sa_family == AF_INET) {
ip = ((struct sockaddr_in *)s)->sin_addr.s_addr;
*(unsigned int *)&a->ip = ip;
a->port = htons( ((struct sockaddr_in *)s)->sin_port );
// we store in network order, that loopback test is host order..
ip = ntohl( ip );
if ( ip == INADDR_LOOPBACK ) {
a->type = NA_LOOPBACK;
} else {
a->type = NA_IP;
}
}
}
/*
=============
Net_ExtractPort
=============
*/
static bool Net_ExtractPort( const char *src, char *buf, int bufsize, int *port ) {
char *p;
strncpy( buf, src, bufsize );
p = buf; p += Min( bufsize - 1, (int)strlen( src ) ); *p = '\0';
p = strchr( buf, ':' );
if ( !p ) {
return false;
}
*p = '\0';
*port = strtol( p+1, NULL, 10 );
if ( errno == ERANGE ) {
return false;
}
return true;
}
/*
=============
Net_StringToSockaddr
=============
*/
static bool Net_StringToSockaddr( const char *s, struct sockaddr *sadr, bool doDNSResolve ) {
struct hostent *h;
char buf[256];
int port;
memset( sadr, 0, sizeof( *sadr ) );
((struct sockaddr_in *)sadr)->sin_family = AF_INET;
((struct sockaddr_in *)sadr)->sin_port = 0;
if( s[0] >= '0' && s[0] <= '9' ) {
unsigned long ret = inet_addr(s);
if ( ret != INADDR_NONE ) {
*(int *)&((struct sockaddr_in *)sadr)->sin_addr = ret;
} else {
// check for port
if ( !Net_ExtractPort( s, buf, sizeof( buf ), &port ) ) {
return false;
}
ret = inet_addr( buf );
if ( ret == INADDR_NONE ) {
return false;
}
*(int *)&((struct sockaddr_in *)sadr)->sin_addr = ret;
((struct sockaddr_in *)sadr)->sin_port = htons( port );
}
} else if ( doDNSResolve ) {
// try to remove the port first, otherwise the DNS gets confused into multiple timeouts
// failed or not failed, buf is expected to contain the appropriate host to resolve
if ( Net_ExtractPort( s, buf, sizeof( buf ), &port ) ) {
((struct sockaddr_in *)sadr)->sin_port = htons( port );
}
h = gethostbyname( buf );
if ( h == 0 ) {
return false;
}
*(int *)&((struct sockaddr_in *)sadr)->sin_addr = *(int *)h->h_addr_list[0];
}
return true;
}
/*
====================
NET_IPSocket
====================
*/
int NET_IPSocket( const char *net_interface, int port, netadr_t *bound_to ) {
SOCKET newsocket;
struct sockaddr_in address;
unsigned long _true = 1;
int i = 1;
int err;
if( net_interface ) {
common->DPrintf( "Opening IP socket: %s:%i\n", net_interface, port );
} else {
common->DPrintf( "Opening IP socket: localhost:%i\n", port );
}
if( ( newsocket = socket( AF_INET, SOCK_DGRAM, IPPROTO_UDP ) ) == INVALID_SOCKET ) {
err = WSAGetLastError();
if( err != WSAEAFNOSUPPORT ) {
common->Printf( "WARNING: UDP_OpenSocket: socket: %s\n", NET_ErrorString() );
}
return 0;
}
// make it non-blocking
if( ioctlsocket( newsocket, FIONBIO, &_true ) == SOCKET_ERROR ) {
common->Printf( "WARNING: UDP_OpenSocket: ioctl FIONBIO: %s\n", NET_ErrorString() );
return 0;
}
// make it broadcast capable
if( setsockopt( newsocket, SOL_SOCKET, SO_BROADCAST, (char *)&i, sizeof(i) ) == SOCKET_ERROR ) {
common->Printf( "WARNING: UDP_OpenSocket: setsockopt SO_BROADCAST: %s\n", NET_ErrorString() );
return 0;
}
if( !net_interface || !net_interface[0] || !idStr::Icmp( net_interface, "localhost" ) ) {
address.sin_addr.s_addr = INADDR_ANY;
}
else {
Net_StringToSockaddr( net_interface, (struct sockaddr *)&address, true );
}
if( port == PORT_ANY ) {
address.sin_port = 0;
}
else {
address.sin_port = htons( (short)port );
}
address.sin_family = AF_INET;
if( bind( newsocket, (const struct sockaddr *)&address, sizeof(address) ) == SOCKET_ERROR ) {
common->Printf( "WARNING: UDP_OpenSocket: bind: %s\n", NET_ErrorString() );
closesocket( newsocket );
return 0;
}
// if the port was PORT_ANY, we need to query again to know the real port we got bound to
// ( this used to be in idPort::InitForPort )
if ( bound_to ) {
int len = sizeof( address );
getsockname( newsocket, (sockaddr *)&address, &len );
Net_SockadrToNetadr( (sockaddr *)&address, bound_to );
}
return newsocket;
}
/*
====================
NET_OpenSocks
====================
*/
void NET_OpenSocks( int port ) {
struct sockaddr_in address;
int err;
struct hostent *h;
int len;
bool rfc1929;
unsigned char buf[64];
usingSocks = false;
common->Printf( "Opening connection to SOCKS server.\n" );
if ( ( socks_socket = socket( AF_INET, SOCK_STREAM, IPPROTO_TCP ) ) == INVALID_SOCKET ) {
err = WSAGetLastError();
common->Printf( "WARNING: NET_OpenSocks: socket: %s\n", NET_ErrorString() );
return;
}
h = gethostbyname( net_socksServer.GetString() );
if ( h == NULL ) {
err = WSAGetLastError();
common->Printf( "WARNING: NET_OpenSocks: gethostbyname: %s\n", NET_ErrorString() );
return;
}
if ( h->h_addrtype != AF_INET ) {
common->Printf( "WARNING: NET_OpenSocks: gethostbyname: address type was not AF_INET\n" );
return;
}
address.sin_family = AF_INET;
address.sin_addr.s_addr = *(int *)h->h_addr_list[0];
address.sin_port = htons( (short)net_socksPort.GetInteger() );
if ( connect( socks_socket, (struct sockaddr *)&address, sizeof( address ) ) == SOCKET_ERROR ) {
err = WSAGetLastError();
common->Printf( "NET_OpenSocks: connect: %s\n", NET_ErrorString() );
return;
}
// send socks authentication handshake
if ( *net_socksUsername.GetString() || *net_socksPassword.GetString() ) {
rfc1929 = true;
}
else {
rfc1929 = false;
}
buf[0] = 5; // SOCKS version
// method count
if ( rfc1929 ) {
buf[1] = 2;
len = 4;
}
else {
buf[1] = 1;
len = 3;
}
buf[2] = 0; // method #1 - method id #00: no authentication
if ( rfc1929 ) {
buf[2] = 2; // method #2 - method id #02: username/password
}
if ( send( socks_socket, (const char *)buf, len, 0 ) == SOCKET_ERROR ) {
err = WSAGetLastError();
common->Printf( "NET_OpenSocks: send: %s\n", NET_ErrorString() );
return;
}
// get the response
len = recv( socks_socket, (char *)buf, 64, 0 );
if ( len == SOCKET_ERROR ) {
err = WSAGetLastError();
common->Printf( "NET_OpenSocks: recv: %s\n", NET_ErrorString() );
return;
}
if ( len != 2 || buf[0] != 5 ) {
common->Printf( "NET_OpenSocks: bad response\n" );
return;
}
switch( buf[1] ) {
case 0: // no authentication
break;
case 2: // username/password authentication
break;
default:
common->Printf( "NET_OpenSocks: request denied\n" );
return;
}
// do username/password authentication if needed
if ( buf[1] == 2 ) {
int ulen;
int plen;
// build the request
ulen = strlen( net_socksUsername.GetString() );
plen = strlen( net_socksPassword.GetString() );
buf[0] = 1; // username/password authentication version
buf[1] = ulen;
if ( ulen ) {
memcpy( &buf[2], net_socksUsername.GetString(), ulen );
}
buf[2 + ulen] = plen;
if ( plen ) {
memcpy( &buf[3 + ulen], net_socksPassword.GetString(), plen );
}
// send it
if ( send( socks_socket, (const char *)buf, 3 + ulen + plen, 0 ) == SOCKET_ERROR ) {
err = WSAGetLastError();
common->Printf( "NET_OpenSocks: send: %s\n", NET_ErrorString() );
return;
}
// get the response
len = recv( socks_socket, (char *)buf, 64, 0 );
if ( len == SOCKET_ERROR ) {
err = WSAGetLastError();
common->Printf( "NET_OpenSocks: recv: %s\n", NET_ErrorString() );
return;
}
if ( len != 2 || buf[0] != 1 ) {
common->Printf( "NET_OpenSocks: bad response\n" );
return;
}
if ( buf[1] != 0 ) {
common->Printf( "NET_OpenSocks: authentication failed\n" );
return;
}
}
// send the UDP associate request
buf[0] = 5; // SOCKS version
buf[1] = 3; // command: UDP associate
buf[2] = 0; // reserved
buf[3] = 1; // address type: IPV4
*(int *)&buf[4] = INADDR_ANY;
*(short *)&buf[8] = htons( (short)port ); // port
if ( send( socks_socket, (const char *)buf, 10, 0 ) == SOCKET_ERROR ) {
err = WSAGetLastError();
common->Printf( "NET_OpenSocks: send: %s\n", NET_ErrorString() );
return;
}
// get the response
len = recv( socks_socket, (char *)buf, 64, 0 );
if( len == SOCKET_ERROR ) {
err = WSAGetLastError();
common->Printf( "NET_OpenSocks: recv: %s\n", NET_ErrorString() );
return;
}
if( len < 2 || buf[0] != 5 ) {
common->Printf( "NET_OpenSocks: bad response\n" );
return;
}
// check completion code
if( buf[1] != 0 ) {
common->Printf( "NET_OpenSocks: request denied: %i\n", buf[1] );
return;
}
if( buf[3] != 1 ) {
common->Printf( "NET_OpenSocks: relay address is not IPV4: %i\n", buf[3] );
return;
}
((struct sockaddr_in *)&socksRelayAddr)->sin_family = AF_INET;
((struct sockaddr_in *)&socksRelayAddr)->sin_addr.s_addr = *(int *)&buf[4];
((struct sockaddr_in *)&socksRelayAddr)->sin_port = *(short *)&buf[8];
memset( ((struct sockaddr_in *)&socksRelayAddr)->sin_zero, 0, 8 );
usingSocks = true;
}
/*
==================
Net_WaitForUDPPacket
==================
*/
bool Net_WaitForUDPPacket( int netSocket, int timeout ) {
int ret;
fd_set set;
struct timeval tv;
if ( !netSocket ) {
return false;
}
if ( timeout <= 0 ) {
return true;
}
FD_ZERO( &set );
FD_SET( netSocket, &set );
tv.tv_sec = 0;
tv.tv_usec = timeout * 1000;
ret = select( netSocket + 1, &set, NULL, NULL, &tv );
if ( ret == -1 ) {
common->DPrintf( "Net_WaitForUPDPacket select(): %s\n", strerror( errno ) );
return false;
}
// timeout with no data
if ( ret == 0 ) {
return false;
}
return true;
}
/*
==================
Net_GetUDPPacket
==================
*/
bool Net_GetUDPPacket( int netSocket, netadr_t &net_from, char *data, int &size, int maxSize ) {
int ret;
struct sockaddr from;
int fromlen;
int err;
if( !netSocket ) {
return false;
}
fromlen = sizeof(from);
ret = recvfrom( netSocket, data, maxSize, 0, (struct sockaddr *)&from, &fromlen );
if ( ret == SOCKET_ERROR ) {
err = WSAGetLastError();
if( err == WSAEWOULDBLOCK || err == WSAECONNRESET ) {
return false;
}
char buf[1024];
sprintf( buf, "Net_GetUDPPacket: %s\n", NET_ErrorString() );
OutputDebugString( buf );
return false;
}
if ( netSocket == ip_socket ) {
memset( ((struct sockaddr_in *)&from)->sin_zero, 0, 8 );
}
if ( usingSocks && netSocket == ip_socket && memcmp( &from, &socksRelayAddr, fromlen ) == 0 ) {
if ( ret < 10 || data[0] != 0 || data[1] != 0 || data[2] != 0 || data[3] != 1 ) {
return false;
}
net_from.type = NA_IP;
net_from.ip[0] = data[4];
net_from.ip[1] = data[5];
net_from.ip[2] = data[6];
net_from.ip[3] = data[7];
net_from.port = *(short *)&data[8];
memmove( data, &data[10], ret - 10 );
} else {
Net_SockadrToNetadr( &from, &net_from );
}
if( ret == maxSize ) {
char buf[1024];
sprintf( buf, "Net_GetUDPPacket: oversize packet from %s\n", Sys_NetAdrToString( net_from ) );
OutputDebugString( buf );
return false;
}
size = ret;
return true;
}
/*
==================
Net_SendUDPPacket
==================
*/
void Net_SendUDPPacket( int netSocket, int length, const void *data, const netadr_t to ) {
int ret;
struct sockaddr addr;
if( !netSocket ) {
return;
}
Net_NetadrToSockadr( &to, &addr );
if( usingSocks && to.type == NA_IP ) {
socksBuf[0] = 0; // reserved
socksBuf[1] = 0;
socksBuf[2] = 0; // fragment (not fragmented)
socksBuf[3] = 1; // address type: IPV4
*(int *)&socksBuf[4] = ((struct sockaddr_in *)&addr)->sin_addr.s_addr;
*(short *)&socksBuf[8] = ((struct sockaddr_in *)&addr)->sin_port;
memcpy( &socksBuf[10], data, length );
ret = sendto( netSocket, socksBuf, length+10, 0, &socksRelayAddr, sizeof(socksRelayAddr) );
} else {
ret = sendto( netSocket, (const char *)data, length, 0, &addr, sizeof(addr) );
}
if( ret == SOCKET_ERROR ) {
int err = WSAGetLastError();
// wouldblock is silent
if( err == WSAEWOULDBLOCK ) {
return;
}
// some PPP links do not allow broadcasts and return an error
if( ( err == WSAEADDRNOTAVAIL ) && ( to.type == NA_BROADCAST ) ) {
return;
}
char buf[1024];
sprintf( buf, "Net_SendUDPPacket: %s\n", NET_ErrorString() );
OutputDebugString( buf );
}
}
/*
====================
Sys_InitNetworking
====================
*/
void Sys_InitNetworking( void ) {
int r;
r = WSAStartup( MAKEWORD( 1, 1 ), &winsockdata );
if( r ) {
common->Printf( "WARNING: Winsock initialization failed, returned %d\n", r );
return;
}
winsockInitialized = true;
common->Printf( "Winsock Initialized\n" );
PIP_ADAPTER_INFO pAdapterInfo;
PIP_ADAPTER_INFO pAdapter = NULL;
DWORD dwRetVal = 0;
PIP_ADDR_STRING pIPAddrString;
ULONG ulOutBufLen;
bool foundloopback;
num_interfaces = 0;
foundloopback = false;
pAdapterInfo = (IP_ADAPTER_INFO *)malloc( sizeof( IP_ADAPTER_INFO ) );
if( !pAdapterInfo ) {
common->FatalError( "Sys_InitNetworking: Couldn't malloc( %d )", sizeof( IP_ADAPTER_INFO ) );
}
ulOutBufLen = sizeof( IP_ADAPTER_INFO );
// Make an initial call to GetAdaptersInfo to get
// the necessary size into the ulOutBufLen variable
if( GetAdaptersInfo( pAdapterInfo, &ulOutBufLen ) == ERROR_BUFFER_OVERFLOW ) {
free( pAdapterInfo );
pAdapterInfo = (IP_ADAPTER_INFO *)malloc( ulOutBufLen );
if( !pAdapterInfo ) {
common->FatalError( "Sys_InitNetworking: Couldn't malloc( %ld )", ulOutBufLen );
}
}
if( ( dwRetVal = GetAdaptersInfo( pAdapterInfo, &ulOutBufLen) ) != NO_ERROR ) {
// happens if you have no network connection
common->Printf( "Sys_InitNetworking: GetAdaptersInfo failed (%ld).\n", dwRetVal );
} else {
pAdapter = pAdapterInfo;
while( pAdapter ) {
common->Printf( "Found interface: %s %s - ", pAdapter->AdapterName, pAdapter->Description );
pIPAddrString = &pAdapter->IpAddressList;
while( pIPAddrString ) {
unsigned long ip_a, ip_m;
if( !idStr::Icmp( "127.0.0.1", pIPAddrString->IpAddress.String ) ) {
foundloopback = true;
}
ip_a = ntohl( inet_addr( pIPAddrString->IpAddress.String ) );
ip_m = ntohl( inet_addr( pIPAddrString->IpMask.String ) );
//skip null netmasks
if( !ip_m ) {
common->Printf( "%s NULL netmask - skipped\n", pIPAddrString->IpAddress.String );
pIPAddrString = pIPAddrString->Next;
continue;
}
common->Printf( "%s/%s\n", pIPAddrString->IpAddress.String, pIPAddrString->IpMask.String );
netint[num_interfaces].ip = ip_a;
netint[num_interfaces].mask = ip_m;
num_interfaces++;
if( num_interfaces >= MAX_INTERFACES ) {
common->Printf( "Sys_InitNetworking: MAX_INTERFACES(%d) hit.\n", MAX_INTERFACES );
free( pAdapterInfo );
return;
}
pIPAddrString = pIPAddrString->Next;
}
pAdapter = pAdapter->Next;
}
}
// for some retarded reason, win32 doesn't count loopback as an adapter...
if( !foundloopback && num_interfaces < MAX_INTERFACES ) {
common->Printf( "Sys_InitNetworking: adding loopback interface\n" );
netint[num_interfaces].ip = ntohl( inet_addr( "127.0.0.1" ) );
netint[num_interfaces].mask = ntohl( inet_addr( "255.0.0.0" ) );
num_interfaces++;
}
free( pAdapterInfo );
}
/*
====================
Sys_ShutdownNetworking
====================
*/
void Sys_ShutdownNetworking( void ) {
if ( !winsockInitialized ) {
return;
}
WSACleanup();
winsockInitialized = false;
}
/*
=============
Sys_StringToNetAdr
=============
*/
bool Sys_StringToNetAdr( const char *s, netadr_t *a, bool doDNSResolve ) {
struct sockaddr sadr;
if ( !Net_StringToSockaddr( s, &sadr, doDNSResolve ) ) {
return false;
}
Net_SockadrToNetadr( &sadr, a );
return true;
}
/*
=============
Sys_NetAdrToString
=============
*/
const char *Sys_NetAdrToString( const netadr_t a ) {
static int index = 0;
static char buf[ 4 ][ 64 ]; // flip/flop
char *s;
s = buf[index];
index = (index + 1) & 3;
if ( a.type == NA_LOOPBACK ) {
if ( a.port ) {
idStr::snPrintf( s, 64, "localhost:%i", a.port );
} else {
idStr::snPrintf( s, 64, "localhost" );
}
} else if ( a.type == NA_IP ) {
idStr::snPrintf( s, 64, "%i.%i.%i.%i:%i", a.ip[0], a.ip[1], a.ip[2], a.ip[3], a.port );
}
return s;
}
/*
==================
Sys_IsLANAddress
==================
*/
bool Sys_IsLANAddress( const netadr_t adr ) {
#if ID_NOLANADDRESS
common->Printf( "Sys_IsLANAddress: ID_NOLANADDRESS\n" );
return false;
#endif
if( adr.type == NA_LOOPBACK ) {
return true;
}
if( adr.type != NA_IP ) {
return false;
}
if( num_interfaces ) {
int i;
unsigned long *p_ip;
unsigned long ip;
p_ip = (unsigned long *)&adr.ip[0];
ip = ntohl( *p_ip );
for( i=0; i < num_interfaces; i++ ) {
if( ( netint[i].ip & netint[i].mask ) == ( ip & netint[i].mask ) ) {
return true;
}
}
}
return false;
}
/*
===================
Sys_CompareNetAdrBase
Compares without the port
===================
*/
bool Sys_CompareNetAdrBase( const netadr_t a, const netadr_t b ) {
if ( a.type != b.type ) {
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] && a.ip[2] == b.ip[2] && a.ip[3] == b.ip[3] ) {
return true;
}
return false;
}
common->Printf( "Sys_CompareNetAdrBase: bad address type\n" );
return false;
}
//=============================================================================
#define MAX_UDP_MSG_SIZE 1400
typedef struct udpMsg_s {
byte data[MAX_UDP_MSG_SIZE];
netadr_t address;
int size;
int time;
struct udpMsg_s * next;
} udpMsg_t;
class idUDPLag {
public:
idUDPLag( void );
~idUDPLag( void );
udpMsg_t * sendFirst;
udpMsg_t * sendLast;
udpMsg_t * recieveFirst;
udpMsg_t * recieveLast;
idBlockAlloc udpMsgAllocator;
};
idUDPLag::idUDPLag( void ) {
sendFirst = sendLast = recieveFirst = recieveLast = NULL;
}
idUDPLag::~idUDPLag( void ) {
udpMsgAllocator.Shutdown();
}
idUDPLag *udpPorts[65536];
/*
==================
idPort::idPort
==================
*/
idPort::idPort() {
netSocket = 0;
memset( &bound_to, 0, sizeof( bound_to ) );
}
/*
==================
idPort::~idPort
==================
*/
idPort::~idPort() {
Close();
}
/*
==================
InitForPort
==================
*/
bool idPort::InitForPort( int portNumber ) {
int len = sizeof( struct sockaddr_in );
netSocket = NET_IPSocket( net_ip.GetString(), portNumber, &bound_to );
if ( netSocket <= 0 ) {
netSocket = 0;
memset( &bound_to, 0, sizeof( bound_to ) );
return false;
}
#if 0
if ( net_socksEnabled.GetBool() ) {
NET_OpenSocks( portNumber );
}
#endif
udpPorts[ bound_to.port ] = new idUDPLag;
return true;
}
/*
==================
idPort::Close
==================
*/
void idPort::Close() {
if ( netSocket ) {
if ( udpPorts[ bound_to.port ] ) {
delete udpPorts[ bound_to.port ];
udpPorts[ bound_to.port ] = NULL;
}
closesocket( netSocket );
netSocket = 0;
memset( &bound_to, 0, sizeof( bound_to ) );
}
}
/*
==================
idPort::GetPacket
==================
*/
bool idPort::GetPacket( netadr_t &from, void *data, int &size, int maxSize ) {
udpMsg_t *msg;
bool ret;
while( 1 ) {
ret = Net_GetUDPPacket( netSocket, from, (char *)data, size, maxSize );
if ( !ret ) {
break;
}
if ( net_forceDrop.GetInteger() > 0 ) {
if ( rand() < net_forceDrop.GetInteger() * RAND_MAX / 100 ) {
continue;
}
}
packetsRead++;
bytesRead += size;
if ( net_forceLatency.GetInteger() > 0 ) {
assert( size <= MAX_UDP_MSG_SIZE );
msg = udpPorts[ bound_to.port ]->udpMsgAllocator.Alloc();
memcpy( msg->data, data, size );
msg->size = size;
msg->address = from;
msg->time = Sys_Milliseconds();
msg->next = NULL;
if ( udpPorts[ bound_to.port ]->recieveLast ) {
udpPorts[ bound_to.port ]->recieveLast->next = msg;
} else {
udpPorts[ bound_to.port ]->recieveFirst = msg;
}
udpPorts[ bound_to.port ]->recieveLast = msg;
} else {
break;
}
}
if ( net_forceLatency.GetInteger() > 0 || ( udpPorts[ bound_to.port] && udpPorts[ bound_to.port ]->recieveFirst ) ) {
msg = udpPorts[ bound_to.port ]->recieveFirst;
if ( msg && msg->time <= Sys_Milliseconds() - net_forceLatency.GetInteger() ) {
memcpy( data, msg->data, msg->size );
size = msg->size;
from = msg->address;
udpPorts[ bound_to.port ]->recieveFirst = udpPorts[ bound_to.port ]->recieveFirst->next;
if ( !udpPorts[ bound_to.port ]->recieveFirst ) {
udpPorts[ bound_to.port ]->recieveLast = NULL;
}
udpPorts[ bound_to.port ]->udpMsgAllocator.Free( msg );
return true;
}
return false;
} else {
return ret;
}
}
/*
==================
idPort::GetPacketBlocking
==================
*/
bool idPort::GetPacketBlocking( netadr_t &from, void *data, int &size, int maxSize, int timeout ) {
Net_WaitForUDPPacket( netSocket, timeout );
if ( GetPacket( from, data, size, maxSize ) ) {
return true;
}
return false;
}
/*
==================
idPort::SendPacket
==================
*/
void idPort::SendPacket( const netadr_t to, const void *data, int size ) {
udpMsg_t *msg;
if ( to.type == NA_BAD ) {
common->Warning( "idPort::SendPacket: bad address type NA_BAD - ignored" );
return;
}
packetsWritten++;
bytesWritten += size;
if ( net_forceDrop.GetInteger() > 0 ) {
if ( rand() < net_forceDrop.GetInteger() * RAND_MAX / 100 ) {
return;
}
}
if ( net_forceLatency.GetInteger() > 0 || ( udpPorts[ bound_to.port ] && udpPorts[ bound_to.port ]->sendFirst ) ) {
assert( size <= MAX_UDP_MSG_SIZE );
msg = udpPorts[ bound_to.port ]->udpMsgAllocator.Alloc();
memcpy( msg->data, data, size );
msg->size = size;
msg->address = to;
msg->time = Sys_Milliseconds();
msg->next = NULL;
if ( udpPorts[ bound_to.port ]->sendLast ) {
udpPorts[ bound_to.port ]->sendLast->next = msg;
} else {
udpPorts[ bound_to.port ]->sendFirst = msg;
}
udpPorts[ bound_to.port ]->sendLast = msg;
for ( msg = udpPorts[ bound_to.port ]->sendFirst; msg && msg->time <= Sys_Milliseconds() - net_forceLatency.GetInteger(); msg = udpPorts[ bound_to.port ]->sendFirst ) {
Net_SendUDPPacket( netSocket, msg->size, msg->data, msg->address );
udpPorts[ bound_to.port ]->sendFirst = udpPorts[ bound_to.port ]->sendFirst->next;
if ( !udpPorts[ bound_to.port ]->sendFirst ) {
udpPorts[ bound_to.port ]->sendLast = NULL;
}
udpPorts[ bound_to.port ]->udpMsgAllocator.Free( msg );
}
} else {
Net_SendUDPPacket( netSocket, size, data, to );
}
}
//=============================================================================
/*
==================
idTCP::idTCP
==================
*/
idTCP::idTCP() {
fd = 0;
memset( &address, 0, sizeof( address ) );
}
/*
==================
idTCP::~idTCP
==================
*/
idTCP::~idTCP() {
Close();
}
/*
==================
idTCP::Init
==================
*/
bool idTCP::Init( const char *host, short port ) {
unsigned long _true = 1;
struct sockaddr sadr;
if ( !Sys_StringToNetAdr( host, &address, true ) ) {
common->Printf( "Couldn't resolve server name \"%s\"\n", host );
return false;
}
address.type = NA_IP;
if ( !address.port ) {
address.port = port;
}
common->Printf( "\"%s\" resolved to %i.%i.%i.%i:%i\n", host,
address.ip[0], address.ip[1], address.ip[2], address.ip[3], address.port );
Net_NetadrToSockadr( &address, &sadr );
if ( fd ) {
common->Warning( "idTCP::Init: already initialized?" );
}
if ( ( fd = socket( AF_INET, SOCK_STREAM, 0 ) ) == INVALID_SOCKET ) {
fd = 0;
common->Printf( "ERROR: idTCP::Init: socket: %s\n", NET_ErrorString() );
return false;
}
if ( connect( fd, &sadr, sizeof(sadr)) == SOCKET_ERROR ) {
common->Printf( "ERROR: idTCP::Init: connect: %s\n", NET_ErrorString() );
closesocket( fd );
fd = 0;
return false;
}
// make it non-blocking
if( ioctlsocket( fd, FIONBIO, &_true ) == SOCKET_ERROR ) {
common->Printf( "ERROR: idTCP::Init: ioctl FIONBIO: %s\n", NET_ErrorString() );
closesocket( fd );
fd = 0;
return false;
}
common->DPrintf( "Opened TCP connection\n" );
return true;
}
/*
==================
idTCP::Close
==================
*/
void idTCP::Close() {
if ( fd ) {
closesocket( fd );
}
fd = 0;
}
/*
==================
idTCP::Read
==================
*/
int idTCP::Read( void *data, int size ) {
int nbytes;
if ( !fd ) {
common->Printf("idTCP::Read: not initialized\n");
return -1;
}
if ( ( nbytes = recv( fd, (char *)data, size, 0 ) ) == SOCKET_ERROR ) {
if ( WSAGetLastError() == WSAEWOULDBLOCK ) {
return 0;
}
common->Printf( "ERROR: idTCP::Read: %s\n", NET_ErrorString() );
Close();
return -1;
}
// a successful read of 0 bytes indicates remote has closed the connection
if ( nbytes == 0 ) {
common->DPrintf( "idTCP::Read: read 0 bytes - assume connection closed\n" );
return -1;
}
return nbytes;
}
/*
==================
idTCP::Write
==================
*/
int idTCP::Write( void *data, int size ) {
int nbytes;
if ( !fd ) {
common->Printf("idTCP::Write: not initialized\n");
return -1;
}
if ( ( nbytes = send( fd, (char *)data, size, 0 ) ) == SOCKET_ERROR ) {
common->Printf( "ERROR: idTCP::Write: %s\n", NET_ErrorString() );
Close();
return -1;
}
return nbytes;
}