fteqw/engine/common/net_wins.c

9696 lines
267 KiB
C

/*
Copyright (C) 1996-1997 Id Software, Inc.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
// net_wins.c
#include "quakedef.h"
#include "netinc.h"
#include <stddef.h>
#ifdef UNIXSOCKETS
#include <sys/stat.h> //to delete the file/socket.
#endif
//try to be slightly cleaner about the protocols that'll get killed.
#ifdef TCPCONNECT
#define NP_STREAM_OR_INVALID NP_STREAM
#define NP_TLS_OR_INVALID NP_TLS
#define NP_WS_OR_INVALID NP_WS
#define NP_WSS_OR_INVALID NP_WSS
#else
#define NP_STREAM_OR_INVALID NP_INVALID
#define NP_TLS_OR_INVALID NP_INVALID
#define NP_WS_OR_INVALID NP_INVALID
#define NP_WSS_OR_INVALID NP_INVALID
#endif
#define NP_DTLS_OR_INVALID NP_DTLS
#ifndef HAVE_SSL
#undef NP_WSS_OR_INVALID
#define NP_WSS_OR_INVALID NP_INVALID
#undef NP_TLS_OR_INVALID
#define NP_TLS_OR_INVALID NP_INVALID
#undef NP_DTLS_OR_INVALID
#define NP_DTLS_OR_INVALID NP_INVALID
#endif
extern ftemanifest_t *fs_manifest;
// Eww, eww. This is hacky but so is netinc.h, so bite me
#ifdef _XBOX
struct sockaddr
{
short sa_family;
};
#define ntohs BigShort
#define htons BigShort
#define htonl BigLong
#define ntohl BigLong
#endif
#if defined(_WIN32) || defined(__linux__) && !defined(ANDROID)
#define USE_GETHOSTNAME_LOCALLISTING
#endif
netadr_t net_local_cl_ipadr; //still used to match local ui requests (quake/gamespy), and to generate ip reports for q3 servers (which is probably pointless).
struct ftenet_generic_connection_s *net_from_connection;
netadr_t net_from;
sizebuf_t net_message;
//#define MAX_UDP_PACKET (MAX_MSGLEN*2) // one more than msg + header
#define MAX_UDP_PACKET 8192 // one more than msg + header
//emscripten can misalign stuff, which is a problem when the leading int is checked directly in a few places. gah.
FTE_ALIGN(4) qbyte net_message_buffer[MAX_OVERALLMSGLEN];
#if defined(_WIN32) && defined(HAVE_PACKET)
WSADATA winsockdata;
#endif
#if defined(_WIN32)
#define getaddrinfo pgetaddrinfo
#define freeaddrinfo pfreeaddrinfo
#define getnameinfo pgetnameinfo
static int (WSAAPI *getaddrinfo) (
const char* nodename,
const char* servname,
const struct addrinfo* hints,
struct addrinfo** res
);
static void (WSAAPI *freeaddrinfo) (struct addrinfo*);
static int (WSAAPI *getnameinfo) (const struct sockaddr *addr, socklen_t addrlen, char *host, socklen_t hostlen, char *serv, socklen_t servlen, int flags);
#endif
#if defined(HAVE_IPV4) && defined(HAVE_SERVER)
#define HAVE_NATPMP
#endif
//#if !defined(HAVE_SERVER) && !defined(MASTERONLY)
// #undef HAVE_HTTPSV
//#endif
#ifdef HAVE_EPOLL
static int epoll_fd = -1;
#endif
void NET_GetLocalAddress (int socket, netadr_t *out);
//int TCP_OpenListenSocket (const char *localip, int port);
#ifdef HAVE_IPV6
int UDP6_OpenSocket (int port);
#endif
#ifdef HAVE_IPX
void IPX_CloseSocket (int socket);
#endif
cvar_t timeout = CVARD("timeout","65", "Connections will time out if no packets are received for this duration of time."); // seconds without any message
cvar_t net_hybriddualstack = CVARD("net_hybriddualstack", "1", "Uses hybrid ipv4+ipv6 sockets where possible. Not supported on xp or below.");
cvar_t net_fakeloss = CVARFD("net_fakeloss", "0", CVAR_CHEAT, "Simulates packetloss in both receiving and sending, on a scale from 0 to 1.");
static cvar_t net_dns_ipv4 = CVARD("net_dns_ipv4", "1", "If 0, disables dns resolution of names to ipv4 addresses (removing any associated error messages). Also hides ipv4 addresses in address:port listings.");
static cvar_t net_dns_ipv6 = CVARD("net_dns_ipv6", "1", "If 0, disables dns resolution of names to ipv6 addresses (removing any associated error messages). Also hides ipv6 addresses in address:port listings.");
cvar_t net_enabled = CVARD("net_enabled", "1", "If 0, disables all network access, including name resolution and socket creation. Does not affect loopback/internal connections.");
#if defined(HAVE_SSL)
cvar_t tls_ignorecertificateerrors = CVARFD("tls_ignorecertificateerrors", "0", CVAR_NOTFROMSERVER|CVAR_NOSAVE|CVAR_NOUNSAFEEXPAND|CVAR_NOSET, "This should NEVER be set to 1!");
static void QDECL NET_TLS_Provider_Changed(struct cvar_s *var, char *oldvalue);
static cvar_t tls_provider = CVARFCD("tls_provider", "", CVAR_NOTFROMSERVER, NET_TLS_Provider_Changed, "Controls which TLS provider to use.");
#endif
#if defined(TCPCONNECT) && (defined(HAVE_SERVER) || defined(HAVE_HTTPSV))
#ifdef HAVE_SERVER
cvar_t net_enable_qizmo = CVARD("net_enable_qizmo", "1", "Enables serverside support for 'connect tcp://foo' or 'connect tls://foo' (with net_enable_tls), as well as qizmo's tcp connections and compatibles.");
#endif
#ifdef MVD_RECORDING
cvar_t net_enable_qtv = CVARD("net_enable_qtv", "2", "Controls whether inbound qtv requests will be honoured (both proxies and clients using qtvplay).\n0: Don't accept qtv connections.\n1: Accept connections.\n2: Accept qtv connections only from host-scopped addresses (read: 127.*.*.*, ::1, or unix sockets).");
#endif
#if defined(HAVE_SSL)
cvar_t net_enable_tls = CVARD("net_enable_tls", "0", "If enabled, binary data sent to a non-tls tcp port will be interpretted as a tls handshake (enabling https or wss over the same tcp port.");
#endif
#ifdef HAVE_HTTPSV
#ifdef SV_MASTER
cvar_t net_enable_http = CVARD("net_enable_http", "1", "If enabled, tcp ports will accept inbound http clients, potentially serving large files which could distrupt gameplay (This does not affect outgoing http(s) requests).");
cvar_t net_enable_rtcbroker = CVARD("net_enable_rtcbroker", "1", "If 1, tcp ports will accept websocket connections from clients trying to broker direct webrtc connections. This should be low traffic, but might involve a lot of mostly-idle connections.");
cvar_t net_enable_websockets = CVARD("net_enable_websockets", "0", "If enabled, tcp ports will accept websocket game clients.");
#else
cvar_t net_enable_http = CVARD("net_enable_http", "0", "If enabled, tcp ports will accept inbound http clients, potentially serving large files which could distrupt gameplay (This does not affect outgoing http(s) requests).");
cvar_t net_enable_rtcbroker = CVARD("net_enable_rtcbroker", "0", "If 1, tcp ports will accept websocket connections from clients trying to broker direct webrtc connections. This should be low traffic, but might involve a lot of mostly-idle connections.");
cvar_t net_enable_websockets = CVARD("net_enable_websockets", "1", "If enabled, tcp ports will accept websocket game clients.");
#endif
#endif
#endif
#if defined(HAVE_DTLS)
#if defined(HAVE_SERVER)
static void QDECL NET_Enable_DTLS_Changed(struct cvar_s *var, char *oldvalue)
{
var->ival = var->value;
//set up the default value
if (!*var->string)
var->ival = 0; //FIXME: change to 1 then 2 when better tested.
if (svs.sockets)
{
svs.sockets->dtlsfuncs = (var->ival)?DTLS_InitServer():NULL;
if (!svs.sockets->dtlsfuncs && var->ival >= 2)
Con_Printf("%sUnable to set %s to \"%s\", no DTLS provider available.\n", (var->ival >= 2)?CON_ERROR:CON_WARNING, var->name, var->string);
}
}
cvar_t net_enable_dtls = CVARAFCD("net_enable_dtls", "", "sv_listen_dtls", 0, NET_Enable_DTLS_Changed, "Controls serverside dtls support.\n0: dtls blocked, not advertised.\n1: clientside choice.\n2: used where possible (recommended setting).\n3: disallow non-dtls clients (sv_port_tcp should be eg tls://[::]:27500 to also disallow unencrypted tcp connections).");
#endif
cvar_t dtls_psk_hint = CVARFD("dtls_psk_hint", "", CVAR_NOUNSAFEEXPAND, "For DTLS-PSK handshakes. This specifies the public server identity.");
cvar_t dtls_psk_user = CVARFD("dtls_psk_user", "", CVAR_NOUNSAFEEXPAND, "For DTLS-PSK handshakes. This specifies the username to use when the client+server's hints match.");
cvar_t dtls_psk_key = CVARFD("dtls_psk_key", "", CVAR_NOUNSAFEEXPAND, "For DTLS-PSK handshakes. This specifies the hexadecimal key which must match between client+server. Will only be used when client+server's hint settings match.");
#endif
#ifdef HAVE_CLIENT
static void QDECL cl_delay_packets_Announce(cvar_t *var, char *oldval)
{
if (cls.state >= ca_connected && cl.fpd & FPD_ANOUNCE_FAKE_LAG)
Cbuf_AddText(va("say Fake lag now %ims\n", var->ival), RESTRICT_LOCAL);
}
static cvar_t cl_delay_packets = CVARCD("cl_delay_packets", "0", cl_delay_packets_Announce, "Extra latency, in milliseconds.");
#endif
extern cvar_t sv_public, sv_listen_qw, sv_listen_nq, sv_listen_dp;
#ifdef QWOVERQ3
extern cvar_t sv_listen_q3;
#endif
#define MAX_LOOPBACK 64
typedef struct
{
qbyte *data;
int datalen;
int datamax;
} loopmsg_t;
typedef struct
{
qboolean inited;
loopmsg_t msgs[MAX_LOOPBACK];
int get, send;
} loopback_t;
loopback_t loopbacks[2];
#ifdef HAVE_DTLS
static neterr_t FTENET_DTLS_SendPacket(ftenet_connections_t *col, int length, const void *data, netadr_t *to);
#endif
static neterr_t NET_SendPacketCol (ftenet_connections_t *collection, int length, const void *data, netadr_t *to);
static void *cryptolibmodule[cryptolib_count];
ftecrypto_t *cryptolib[cryptolib_count] =
{
NULL,
NULL,
NULL,
NULL,
#ifdef HAVE_WINSSPI
&crypto_sspi,
#endif
#ifdef HAVE_GNUTLS
&crypto_gnutls,
#endif
};
#if defined(HAVE_SSL)
static void NET_TLS_Provider_Changed(struct cvar_s *var, char *oldvalue)
{
int i;
var->ival = 0;
if (!*var->string || !strcmp(var->string, "0"))
return;
for (i = 0; i < cryptolib_count; i++)
{
if (cryptolib[i] && !Q_strcasecmp(var->string, cryptolib[i]->drivername))
var->ival = i+1;
}
if (host_initialized && !var->ival)
{
Con_Printf("%s: \"%s\" not loaded, valid values are:", var->name, var->string);
for (i = 0; i < cryptolib_count; i++)
if (cryptolib[i])
Con_Printf(" %s", cryptolib[i]->drivername);
Con_Printf("\n");
}
#if defined(HAVE_DTLS) && defined(HAVE_SERVER)
if (net_enable_dtls.string) //might not be registered yet...
Cvar_ForceCallback(&net_enable_dtls);
#endif
}
#endif
qboolean NET_RegisterCrypto(void *module, ftecrypto_t *driver)
{
int i;
if (!driver)
{
for (i = 0; i < cryptolib_count; i++)
if (cryptolibmodule[i] == module)
cryptolibmodule[i] = NULL, cryptolib[i] = NULL;
#if defined(HAVE_SSL)
Cvar_ForceCallback(&tls_provider);
#endif
return true;
}
else
{
for (i = 0; i < cryptolib_count; i++)
if (!cryptolib[i])
{
cryptolibmodule[i] = module, cryptolib[i] = driver;
#if defined(HAVE_SSL)
Cvar_ForceCallback(&tls_provider);
#endif
return true;
}
return false;
}
}
//=============================================================================
int NetadrToSockadr (netadr_t *a, struct sockaddr_qstorage *s)
{
switch(a->type)
{
#ifdef HAVE_WEBSOCKCL
case NA_WEBSOCKET:
memset (s, 0, sizeof(struct sockaddr_websocket));
((struct sockaddr_websocket*)s)->sws_family = AF_WEBSOCK;
memcpy(((struct sockaddr_websocket*)s)->url, a->address.websocketurl, sizeof(((struct sockaddr_websocket*)s)->url));
return sizeof(struct sockaddr_websocket);
#endif
#ifdef HAVE_IPV4
case NA_IP:
memset (s, 0, sizeof(struct sockaddr_in));
((struct sockaddr_in*)s)->sin_family = AF_INET;
*(int *)&((struct sockaddr_in*)s)->sin_addr = *(int *)&a->address.ip;
((struct sockaddr_in*)s)->sin_port = a->port;
return sizeof(struct sockaddr_in);
#endif
#ifdef HAVE_IPV6
case NA_IPV6:
memset (s, 0, sizeof(struct sockaddr_in6));
((struct sockaddr_in6*)s)->sin6_family = AF_INET6;
memcpy(&((struct sockaddr_in6*)s)->sin6_addr, a->address.ip6, sizeof(struct in6_addr));
((struct sockaddr_in6*)s)->sin6_port = a->port;
((struct sockaddr_in6 *)s)->sin6_scope_id = a->scopeid;
return sizeof(struct sockaddr_in6);
#endif
#ifdef HAVE_IPX
case NA_IPX:
#ifdef _WIN32
((struct sockaddr_ipx *)s)->sa_family = AF_IPX;
memcpy(((struct sockaddr_ipx *)s)->sa_netnum, &a->address.ipx[0], 4);
memcpy(((struct sockaddr_ipx *)s)->sa_nodenum, &a->address.ipx[4], 6);
((struct sockaddr_ipx *)s)->sa_socket = a->port;
#else
((struct sockaddr_ipx *)s)->sipx_family = AF_IPX;
memcpy(&((struct sockaddr_ipx *)s)->sipx_network, &a->address.ipx[0], 4);
memcpy(((struct sockaddr_ipx *)s)->sipx_node, &a->address.ipx[4], 6);
((struct sockaddr_ipx *)s)->sipx_port = a->port;
#endif
return sizeof(struct sockaddr_ipx);
#endif
#ifdef UNIXSOCKETS
case NA_UNIX:
{
struct sockaddr_un *un = (struct sockaddr_un*)s;
un->sun_family = AF_UNIX;
memcpy(un->sun_path, a->address.un.path, a->address.un.len);
return offsetof(struct sockaddr_un, sun_path) + a->address.un.len;
}
#endif
default:
Sys_Error("NetadrToSockadr: Bad type %i", a->type);
return 0;
}
}
void SockadrToNetadr (struct sockaddr_qstorage *s, int sizeofsockaddr, netadr_t *a)
{
#ifndef HAVE_PACKET
memset(a, 0, sizeof(*a));
a->type = NA_INVALID;
#else
a->scopeid = 0;
a->connum = 0;
a->prot = NP_DGRAM;
if (sizeofsockaddr < offsetof(struct sockaddr, sa_family)+sizeof(((struct sockaddr*)s)->sa_family))
{ //truncated far too much...
memset(a, 0, sizeof(*a));
a->type = NA_INVALID;
return;
}
switch (((struct sockaddr*)s)->sa_family)
{
#ifdef HAVE_WEBSOCKCL
case AF_WEBSOCK:
a->type = NA_WEBSOCKET;
memcpy(a->address.websocketurl, ((struct sockaddr_websocket*)s)->url, sizeof(a->address.websocketurl));
a->port = 0;
break;
#endif
#ifdef HAVE_IPV4
case AF_INET:
a->type = NA_IP;
*(int *)&a->address.ip = ((struct sockaddr_in *)s)->sin_addr.s_addr;
a->port = ((struct sockaddr_in *)s)->sin_port;
break;
#endif
#ifdef HAVE_IPV6
case AF_INET6:
a->type = NA_IPV6;
memcpy(&a->address.ip6, &((struct sockaddr_in6 *)s)->sin6_addr, sizeof(a->address.ip6));
a->port = ((struct sockaddr_in6 *)s)->sin6_port;
a->scopeid = ((struct sockaddr_in6 *)s)->sin6_scope_id;
break;
#endif
#ifdef HAVE_IPX
case AF_IPX:
a->type = NA_IPX;
*(int *)a->address.ip = 0xffffffff;
#ifdef _WIN32
memcpy(&a->address.ipx[0], ((struct sockaddr_ipx *)s)->sa_netnum, 4);
memcpy(&a->address.ipx[4], ((struct sockaddr_ipx *)s)->sa_nodenum, 6);
a->port = ((struct sockaddr_ipx *)s)->sa_socket;
#else
memcpy(&a->address.ipx[0], &((struct sockaddr_ipx *)s)->sipx_network, 4);
memcpy(&a->address.ipx[4], ((struct sockaddr_ipx *)s)->sipx_node, 6);
a->port = ((struct sockaddr_ipx *)s)->sipx_port;
#endif
break;
#endif
#ifdef UNIXSOCKETS
case AF_UNIX:
{
struct sockaddr_un *un = (struct sockaddr_un*)s;
a->type = NA_UNIX;
a->address.un.len = sizeofsockaddr - offsetof(struct sockaddr_un, sun_path);
memcpy(a->address.un.path, un->sun_path, a->address.un.len);
if (a->address.un.len && a->address.un.path)
a->address.un.len = strnlen(a->address.un.path, a->address.un.len);
a->port = 0;
}
break;
#endif
default:
Con_Printf("SockadrToNetadr: bad socket family - %i", ((struct sockaddr*)s)->sa_family);
case AF_UNSPEC:
memset(a, 0, sizeof(*a));
a->type = NA_INVALID;
break;
}
#endif
}
char *NET_SockadrToString (char *s, int len, struct sockaddr_qstorage *a, size_t sizeofa)
{
netadr_t na;
SockadrToNetadr(a, sizeofa, &na);
return NET_AdrToString(s, len, &na);
}
qboolean NET_AddrIsReliable(netadr_t *adr) //hints that the protocol is reliable. if so, we don't need to wait for acks
{
switch(adr->prot)
{
case NP_DGRAM:
case NP_DTLS:
case NP_NATPMP:
default:
return false;
case NP_STREAM:
case NP_TLS:
case NP_WS:
case NP_WSS:
return true;
}
}
qboolean NET_CompareAdr (netadr_t *a, netadr_t *b)
{
if (a->prot != b->prot)
return false;
if (a->type != b->type)
{
if ((a->type == NA_INVALID || b->type == NA_INVALID) && (a->prot==NP_RTC_TCP||a->prot==NP_RTC_TLS)&&(b->prot==NP_RTC_TCP||b->prot==NP_RTC_TLS))
return true; //broker stuff can be written as /foo which doesn't necessarily have all the info.
if (a->port != b->port)
return false;
#if defined(HAVE_IPV4) && defined(HAVE_IPV6)
if (a->type == NA_IP && b->type == NA_IPV6)
{
int i;
for (i = 0; i < 10; i++)
if (b->address.ip6[i] != 0)
return false; //only matches if they're 0s, otherwise its not an ipv4 address there
for (; i < 12; i++)
if (b->address.ip6[i] != 0xff)// && b->address.ip6[i] != 0x00) //0x00 is depricated
return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there
for (i = 0; i < 4; i++)
{
if (a->address.ip[i] != b->address.ip6[12+i])
return false; //mask doesn't match
}
return true; //its an ipv4 address in there, the mask matched the whole way through
}
if (a->type == NA_IPV6 && b->type == NA_IP)
{
int i;
for (i = 0; i < 10; i++)
if (a->address.ip6[i] != 0)
return false; //only matches if they're 0s, otherwise its not an ipv4 address there
for (; i < 12; i++)
if (a->address.ip6[i] != 0xff)// && a->address.ip6[i] != 0x00) //0x00 is depricated
return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there
for (i = 0; i < 4; i++)
{
if (a->address.ip6[12+i] != b->address.ip[i])
return false; //mask doesn't match
}
return true; //its an ipv4 address in there, the mask matched the whole way through
}
#endif
return false;
}
if (a->type == NA_LOOPBACK)
return true;
#ifdef HAVE_WEBSOCKCL
if (a->type == NA_WEBSOCKET)
{
if (!strcmp(a->address.websocketurl, b->address.websocketurl) && a->port == b->port)
return true;
return false;
}
#endif
#ifdef HAVE_IPV4
if (a->type == NA_IP)
{
if ((memcmp(a->address.ip, b->address.ip, sizeof(a->address.ip)) == 0) && a->port == b->port)
return true;
return false;
}
#endif
#ifdef HAVE_IPV6
if (a->type == NA_IPV6)
{
if ((memcmp(a->address.ip6, b->address.ip6, sizeof(a->address.ip6)) == 0) && a->port == b->port)
return true;
return false;
}
#endif
#ifdef HAVE_IPX
if (a->type == NA_IPX)
{
if ((memcmp(a->address.ipx, b->address.ipx, sizeof(a->address.ipx)) == 0) && a->port == b->port)
return true;
return false;
}
#endif
#ifdef IRCCONNECT
if (a->type == NA_IRC)
{
if (!strcmp(a->address.irc.user, b->address.irc.user))
return true;
return false;
}
#endif
#ifdef UNIXSOCKETS
if (a->type == NA_UNIX)
{
if (a->address.un.len == b->address.un.len && !memcmp(a->address.un.path, b->address.un.path, a->address.un.len))
return true;
return false;
}
#endif
#ifdef SUPPORT_ICE
if (a->type == NA_ICE)
{
if (!strcmp(a->address.icename, b->address.icename))
return true;
return false;
}
#endif
if (a->type == NA_INVALID && a->prot)
return true; //mneh...
Con_Printf("NET_CompareAdr: Bad address type\n");
return false;
}
/*
===================
NET_CompareBaseAdr
Compares without the port
(udp/tcp/etc must still match)
===================
*/
qboolean NET_CompareBaseAdr (netadr_t *a, netadr_t *b)
{
if (a->prot != b->prot)
return false;
if (a->type != b->type)
{
if ((a->type == NA_INVALID || b->type == NA_INVALID) && (a->prot==NP_RTC_TCP||a->prot==NP_RTC_TLS)&&(b->prot==NP_RTC_TCP||b->prot==NP_RTC_TLS))
return true; //broker stuff can be written as /foo which doesn't necessarily have all the info.
#if defined(HAVE_IPV4) && defined(HAVE_IPV6)
if (a->type == NA_IP && b->type == NA_IPV6)
{
int i;
for (i = 0; i < 10; i++)
if (b->address.ip6[i] != 0)
return false; //only matches if they're 0s, otherwise its not an ipv4 address there
for (; i < 12; i++)
if (b->address.ip6[i] != 0xff)// && b->address.ip6[i] != 0x00) //0x00 is depricated
return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there
for (i = 0; i < 4; i++)
{
if (a->address.ip[i] != b->address.ip6[12+i])
return false; //mask doesn't match
}
return true; //its an ipv4 address in there, the mask matched the whole way through
}
if (a->type == NA_IPV6 && b->type == NA_IP)
{
int i;
for (i = 0; i < 10; i++)
if (a->address.ip6[i] != 0)
return false; //only matches if they're 0s, otherwise its not an ipv4 address there
for (; i < 12; i++)
if (a->address.ip6[i] != 0xff)// && a->address.ip6[i] != 0x00) //0x00 is depricated
return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there
for (i = 0; i < 4; i++)
{
if (a->address.ip6[12+i] != b->address.ip[i])
return false; //mask doesn't match
}
return true; //its an ipv4 address in there, the mask matched the whole way through
}
#endif
return false;
}
if (a->type == NA_LOOPBACK)
return true;
#ifdef HAVE_IPV4
if (a->type == NA_IP)
{
if ((memcmp(a->address.ip, b->address.ip, sizeof(a->address.ip)) == 0))
return true;
return false;
}
#endif
#ifdef HAVE_IPV6
if (a->type == NA_IPV6)
{
if ((memcmp(a->address.ip6, b->address.ip6, 16) == 0))
return true;
return false;
}
#endif
#ifdef HAVE_IPX
if (a->type == NA_IPX)
{
if ((memcmp(a->address.ipx, b->address.ipx, 10) == 0))
return true;
return false;
}
#endif
#ifdef IRCCONNECT
if (a->type == NA_IRC)
{
if (!strcmp(a->address.irc.user, b->address.irc.user))
return true;
return false;
}
#endif
#ifdef HAVE_WEBSOCKCL
if (a->type == NA_WEBSOCKET)
{
if (!strcmp(a->address.websocketurl, b->address.websocketurl))
return true;
return false;
}
#endif
#ifdef UNIXSOCKETS
if (a->type == NA_UNIX)
{
if (a->address.un.len == b->address.un.len && !memcmp(a->address.un.path, b->address.un.path, a->address.un.len))
return true;
return false;
}
#endif
#ifdef SUPPORT_ICE
if (a->type == NA_ICE)
{
if (!strcmp(a->address.icename, b->address.icename))
return true;
return false;
}
#endif
if (a->type == NA_INVALID && a->prot)
return true; //mneh...
Sys_Error("NET_CompareBaseAdr: Bad address type");
return false;
}
qboolean NET_AddressSmellsFunny(netadr_t *a)
{
#ifdef HAVE_IPV6
int i;
#endif
//rejects certain blacklisted addresses
switch(a->type)
{
#ifdef HAVE_IPV4
case NA_IP:
//reject localhost
if (a->address.ip[0] == 127)// && a->address.ip[1] == 0 && a->address.ip[2] == 0 && a->address.ip[3] == 1 )
return true;
//'this' network (not an issue, but lets reject it anyway)
if (a->address.ip[0] == 0 && a->address.ip[1] == 0 && a->address.ip[2] == 0 && a->address.ip[3] == 0 )
return true;
//reject any broadcasts
if (a->address.ip[0] == 255 && a->address.ip[1] == 255 && a->address.ip[2] == 255 && a->address.ip[3] == 0 )
return true;
//not much else I can reject
return false;
#endif
#ifdef HAVE_IPV6
case NA_IPV6:
//reject [::XXXX] (this includes obsolete ipv4-compatible (not ipv4 mapped), and localhost)
for (i = 0; i < 12; i++)
if (a->address.ip6[i])
break;
if (i == 12)
return true;
return false;
#endif
#ifdef HAVE_IPX
//no idea how this protocol's addresses work
case NA_IPX:
return false;
#endif
case NA_LOOPBACK:
return false;
default:
return true;
}
}
#if (_POSIX_C_SOURCE >= 200112L || defined(getnameinfo)) && defined(HAVE_PACKET)
static void NET_AdrToStringDoResolve(void *ctx, void *data, size_t a, size_t b)
{
netadr_t *n = data;
struct sockaddr_qstorage s;
int ssz;
char *adrstring = Z_Malloc(NI_MAXHOST);
void (*resolved)(void *ctx, void *data, size_t a, size_t b) = *(void**)(n+1);
if (n->type == NA_LOOPBACK)
NET_BaseAdrToString(adrstring, NI_MAXHOST, n);
else
{
ssz = NetadrToSockadr(n, &s);
if (
#ifdef getnameinfo
!getnameinfo ||
#endif
getnameinfo((struct sockaddr *)&s, ssz, adrstring, NI_MAXHOST, NULL, 0, NI_NUMERICSERV|NI_DGRAM))
{
NET_BaseAdrToString(adrstring, NI_MAXHOST, n);
}
}
COM_AddWork(WG_MAIN, resolved, ctx, adrstring, a, b);
Z_Free(n);
}
void NET_AdrToStringResolve (netadr_t *adr, void (*resolved)(void *ctx, void *data, size_t a, size_t b), void *ctx, size_t a, size_t b)
{
netadr_t *n = Z_Malloc(sizeof(*n) + sizeof(void*));
*n = *adr;
*(void**)(n+1) = resolved;
COM_AddWork(WG_LOADER, NET_AdrToStringDoResolve, ctx, n, a, b);
}
#else
void NET_AdrToStringResolve (netadr_t *adr, void (*resolved)(void *ctx, void *data, size_t a, size_t b), void *ctx, size_t a, size_t b)
{
char adrstring[512];
NET_BaseAdrToString(adrstring, countof(adrstring), adr);
resolved(ctx, Z_StrDup(adrstring), a, b);
}
#endif
char *NET_AdrToString (char *s, int len, netadr_t *a)
{
char *rs = s;
char *prot = "";
#ifdef HAVE_IPV6
int doneblank;
#endif
switch(a->prot)
{
case NP_INVALID:prot = "invalid://";break;
case NP_DGRAM: prot = ""/*qw://*/; break;
case NP_DTLS: prot = "dtls://"; break;
case NP_STREAM: prot = "tcp://"; break; //not strictly true for ipx, but whatever.
case NP_TLS: prot = "tls://"; break;
case NP_WS: prot = "ws://"; break;
case NP_WSS: prot = "wss://"; break;
case NP_NATPMP: prot = "natpmp://"; break;
case NP_RTC_TCP:prot = "rtc://"; break;
case NP_RTC_TLS:prot = "rtcs://"; break;
}
switch(a->type)
{
#ifdef HAVE_WEBSOCKCL
case NA_WEBSOCKET: //ws / wss is part of the url
{
char *url = a->address.websocketurl;
prot = "";
if (a->port)
Q_snprintfz(s, len, "%s%s#%i", prot, url, ntohs(a->port));
else
Q_snprintfz(s, len, "%s%s", prot, url);
}
break;
#endif
#ifdef HAVE_IPV4
case NA_IP:
if (a->port)
{
Q_snprintfz(s, len, "%s%i.%i.%i.%i:%i",
prot,
a->address.ip[0],
a->address.ip[1],
a->address.ip[2],
a->address.ip[3],
ntohs(a->port));
}
else
{
snprintf (s, len, "%s%i.%i.%i.%i",
prot,
a->address.ip[0],
a->address.ip[1],
a->address.ip[2],
a->address.ip[3]);
}
break;
#endif
#ifdef HAVE_IPV6
case NA_IPV6:
{
char *p;
int i;
if (!*(int*)&a->address.ip6[0] &&
!*(int*)&a->address.ip6[4] &&
!*(short*)&a->address.ip6[8] &&
*(short*)&a->address.ip6[10] == (short)0xffff)
{
if (a->port)
snprintf (s, len, "%s%i.%i.%i.%i:%i",
prot,
a->address.ip6[12],
a->address.ip6[13],
a->address.ip6[14],
a->address.ip6[15],
ntohs(a->port));
else
snprintf (s, len, "%s%i.%i.%i.%i",
prot,
a->address.ip6[12],
a->address.ip6[13],
a->address.ip6[14],
a->address.ip6[15]);
break;
}
*s = 0;
doneblank = false;
p = s;
if (a->port)
snprintf (s, len-strlen(s), "%s[", prot);
else
snprintf (s, len-strlen(s), "%s", prot);
p += strlen(p);
for (i = 0; i < 16; i+=2)
{
if (doneblank!=true && a->address.ip6[i] == 0 && a->address.ip6[i+1] == 0)
{
if (!doneblank)
{
snprintf (p, len-strlen(s), "::");
p += strlen(p);
doneblank = 2;
}
}
else
{
if (doneblank==2)
doneblank = true;
else if (i != 0)
{
snprintf (p, len-strlen(s), ":");
p += strlen(p);
}
if (a->address.ip6[i+0])
{
snprintf (p, len-strlen(s), "%x%02x",
a->address.ip6[i+0],
a->address.ip6[i+1]);
}
else
{
snprintf (p, len-strlen(s), "%x",
a->address.ip6[i+1]);
}
p += strlen(p);
}
}
if (a->scopeid)
{
snprintf (p, len-strlen(s), "%%%u",
a->scopeid);
p += strlen(p);
}
if (a->port)
snprintf (p, len-strlen(s), "]:%i",
ntohs(a->port));
}
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
snprintf (s, len, "%s%02x%02x%02x%02x:%02x%02x%02x%02x%02x%02x:%i",
prot,
a->address.ipx[0],
a->address.ipx[1],
a->address.ipx[2],
a->address.ipx[3],
a->address.ipx[4],
a->address.ipx[5],
a->address.ipx[6],
a->address.ipx[7],
a->address.ipx[8],
a->address.ipx[9],
ntohs(a->port));
break;
#endif
case NA_LOOPBACK:
snprintf (s, len, "%sQLoopBack:%i", prot, a->port);
break;
#ifdef IRCCONNECT
case NA_IRC:
if (*a->address.irc.channel)
snprintf (s, len, "irc://%s@%s", a->address.irc.user, a->address.irc.channel);
else
snprintf (s, len, "irc://%s", a->address.irc.user);
break;
#endif
#ifdef UNIXSOCKETS
case NA_UNIX:
switch(a->prot)
{
case NP_DGRAM: prot = "udg://"; break;
case NP_STREAM: prot = "unix://"; break;
default:
snprintf (s, len, "unix+");
len-=strlen(s);
s+=strlen(s);
break;
}
snprintf (s, len, prot);
len-=strlen(s);
s+=strlen(s);
if (len) //hopefully this will always be true...
{
char *end = a->address.un.path+a->address.un.len, *in;
char c;
for (in = a->address.un.path; in < end; in++)
{
if (--len == 0)
break;
if (*in == '\\') //ugly encoding
c = '\\';
else if (*in == '\0') //null chars are always a problem. abstract sockets generally get them displayed using @ chars.
{
*s++ = '@';
continue;
}
else if (*in == '@') //which means actual @ chars need to be escaped
c = '@';
//don't screw up from these, either.
else if (*in == '\n')
c = 'n';
else if (*in == '\r')
c = 'r';
else if (*in == '\t')
c = 't';
//special quake chars can screw up display too
else if (*in == '\1')
c = '1';
else if (*in == '\2')
c = '2';
else if (*in == '\3')
c = '3';
else
{ //as-is.
*s++ = *in;
continue;
}
//marked up chars need extra storage.
if (--len == 0)
break;
*s++ = '\\';
*s++ = c;
}
*s = 0; //and always null terminate the string.
}
break;
#endif
#ifdef SUPPORT_ICE
case NA_ICE:
snprintf (s, len, "%s[%s]", prot, a->address.icename);
break;
#endif
default:
if (a->prot == NP_RTC_TCP || a->prot == NP_RTC_TLS)
Q_strncpyz(s, prot, len);
else
snprintf (s, len, "invalid netadr_t type");
// Sys_Error("NET_AdrToString: Bad netadr_t type");
}
return rs;
}
char *NET_BaseAdrToString (char *s, int len, netadr_t *a)
{
char *prot = "";
switch(a->prot)
{
case NP_INVALID:prot = "invalid://";break;
case NP_DGRAM: prot = ""/*qw://*/; break;
case NP_DTLS: prot = "dtls://"; break;
case NP_STREAM: prot = "tcp://"; break; //not strictly true for ipx, but whatever.
case NP_TLS: prot = "tls://"; break;
case NP_WS: prot = "ws://"; break;
case NP_WSS: prot = "wss://"; break;
case NP_NATPMP: prot = "natpmp://"; break;
case NP_RTC_TCP:prot = "rtc://"; break;
case NP_RTC_TLS:prot = "rtcs://"; break;
}
switch(a->type)
{
#ifdef HAVE_WEBSOCKCL
case NA_WEBSOCKET: //ws / wss is part of the url
{
char *url = a->address.websocketurl;
Q_snprintfz(s, len, "%s%s", prot, url);
}
break;
#endif
case NA_IP:
snprintf (s, len, "%s%i.%i.%i.%i",
prot,
a->address.ip[0],
a->address.ip[1],
a->address.ip[2],
a->address.ip[3]);
break;
#ifdef HAVE_IPV6
case NA_IPV6:
{
char *p;
int i, doneblank;
if (!*(int*)&a->address.ip6[0] &&
!*(int*)&a->address.ip6[4] &&
!*(short*)&a->address.ip6[8] &&
*(short*)&a->address.ip6[10] == (short)0xffff)
{
snprintf (s, len, "%s%i.%i.%i.%i",
prot,
a->address.ip6[12],
a->address.ip6[13],
a->address.ip6[14],
a->address.ip6[15]);
break;
}
*s = 0;
doneblank = false;
p = s;
for (i = 0; i < 16; i+=2)
{
if (doneblank!=true && a->address.ip6[i] == 0 && a->address.ip6[i+1] == 0)
{
if (!doneblank)
{
snprintf (p, len-strlen(s), "::");
p += strlen(p);
doneblank = 2;
}
}
else
{
if (doneblank==2)
doneblank = true;
else if (i != 0)
{
snprintf (p, len-strlen(s), ":");
p += strlen(p);
}
if (a->address.ip6[i+0])
{
snprintf (p, len-strlen(s), "%x%02x",
a->address.ip6[i+0],
a->address.ip6[i+1]);
}
else
{
snprintf (p, len-strlen(s), "%x",
a->address.ip6[i+1]);
}
p += strlen(p);
}
}
}
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
snprintf (s, len, "%s%02x%02x%02x%02x:%02x%02x%02x%02x%02x%02x",
prot,
a->address.ipx[0],
a->address.ipx[1],
a->address.ipx[2],
a->address.ipx[3],
a->address.ipx[4],
a->address.ipx[5],
a->address.ipx[6],
a->address.ipx[7],
a->address.ipx[8],
a->address.ipx[9]);
break;
#endif
case NA_LOOPBACK:
snprintf (s, len, "%sQLoopBack", prot);
break;
#ifdef IRCCONNECT
case NA_IRC:
NET_AdrToString(s, len, a);
break;
#endif
#ifdef UNIXSOCKETS
case NA_UNIX:
//no ports, so no base paths.
return NET_AdrToString(s, len, a);
#endif
#ifdef SUPPORT_ICE
case NA_ICE:
snprintf (s, len, "%s[%s]", prot, a->address.icename);
break;
#endif
default:
if (a->prot == NP_RTC_TCP || a->prot == NP_RTC_TLS)
Q_strncpyz(s, prot, len);
else
Sys_Error("NET_BaseAdrToString: Bad netadr_t type");
}
return s;
}
/*
=============
NET_StringToAdr
idnewt
idnewt:28000
192.246.40.70
192.246.40.70:28000
any form of ipv6, including port number.
=============
*/
size_t NET_StringToSockaddr2 (const char *s, int defaultport, netadrtype_t afhint, struct sockaddr_qstorage *sadr, int *addrfamily, int *addrsize, size_t addresses)
{
size_t result = 0;
if (!(*s) || !addresses)
return result;
#ifdef WEBCLIENT
//EVIL HACK!
//updates.tth uses a known self-signed certificate (to protect against dns hijacks like fteqw.com suffered).
//its not meant to be used for browsers etc, and I cba to register dns stuff for it.
//besides, browsers/etc would just bitch about its cert, so w/e.
//redirect the dns to the base host without affecting http(s) hosts/certificates.
if (!strncmp(s, "updates.", 8))
{
conchar_t musite[256], *e;
char site[256];
char *oldprefix = "http://fte.";
e = COM_ParseFunString(CON_WHITEMASK, ENGINEWEBSITE, musite, sizeof(musite), false);
COM_DeFunString(musite, e, site, sizeof(site), true, true);
if (!strncmp(site, oldprefix, strlen(oldprefix)))
{
if (!strcmp(s+8,site+strlen(oldprefix)))
{
#ifdef HAVE_IPV4
struct sockaddr_in *a = (struct sockaddr_in*)sadr;
qbyte *ip = (qbyte*)&a->sin_addr;
memset (a, 0, sizeof(*sadr));
a->sin_family = AF_INET;
ip[0] = 213;
ip[1] = 219;
ip[2] = 36;
ip[3] = 248;
a->sin_port = htons(defaultport);
if (addrsize)
*addrsize = sizeof(*a);
if (addrfamily)
*addrfamily = AF_INET;
return 1;
#else
s += 8;
#endif
}
}
}
#endif
memset (sadr, 0, sizeof(*sadr));
#ifdef UNIXSOCKETS
if (afhint == NA_UNIX)
{
struct sockaddr_un *sa = (struct sockaddr_un *)sadr;
int i;
//limit to known prefixes. this allows for sandboxing.
const char *allowedprefixes[] = {"@"DISTRIBUTION, "/tmp/"DISTRIBUTION".", "/tmp/qsock.", "@FTE", "@qtv", "@qsock"};
for (i = 0; i < countof(allowedprefixes); i++)
{
if (!Q_strncasecmp(s, allowedprefixes[i], strlen(allowedprefixes[i])))
break;
}
if (i == countof(allowedprefixes))
{
Con_DPrintf(CON_WARNING "\"%s\" is not an accepted prefix for a unix socket. Forcing prefix.\n", s);
i = 0;
sa->sun_path[i++] = 0;
sa->sun_path[i++] = 'q';
sa->sun_path[i++] = 's';
sa->sun_path[i++] = 'o';
sa->sun_path[i++] = 'c';
sa->sun_path[i++] = 'k';
}
else i = 0;
sa->sun_family = AF_UNIX;
//this parsing is so annoying because I want to support abstract sockets too, which have nulls.
//we're using @ charsto represent nulls, to match 'lsof -U'
for ( ; *s && i < countof(sa->sun_path); )
{
if (*s == '@')
{
sa->sun_path[i++] = 0;
s++;
}
else if (*s == '\\')
{
if (s[1] == 0)
{
sa->sun_path[i++] = '\\';
break; //error.
}
else if (s[1] == '\\')
sa->sun_path[i++] = '\\';
else if (s[1] == '@')
sa->sun_path[i++] = '@';
else if (s[1] == 'n')
sa->sun_path[i++] = '\n';
else if (s[1] == 'r')
sa->sun_path[i++] = '\r';
else if (s[1] == 't')
sa->sun_path[i++] = '\t';
else if (s[1] == '1')
sa->sun_path[i++] = '\1';
else if (s[1] == '2')
sa->sun_path[i++] = '\2';
else if (s[1] == '3')
sa->sun_path[i++] = '\3';
else
sa->sun_path[i++] = '?';
s+=2;
}
else
sa->sun_path[i++] = *s++;
}
if (sa->sun_path[0]) //'pathname sockets should be null terminated'
sa->sun_path[i++] = 0;
if (i < countof(sa->sun_path))
sa->sun_path[i] = 'X';
if (addrsize)
*addrsize = offsetof(struct sockaddr_un, sun_path) + i;
if (addrfamily)
*addrfamily = AF_UNIX;
result++;
}
else
#endif
#ifdef HAVE_IPX
if ((strlen(s) >= 23) && (s[8] == ':') && (s[21] == ':')) // check for an IPX address
{
unsigned int val;
char copy[128];
((struct sockaddr_ipx *)sadr)->sa_family = AF_IPX;
#define DO(src,dest) \
copy[0] = s[src]; \
copy[1] = s[src + 1]; \
sscanf (copy, "%x", &val); \
((struct sockaddr_ipx *)sadr)->dest = val
copy[2] = 0;
DO(0, sa_netnum[0]);
DO(2, sa_netnum[1]);
DO(4, sa_netnum[2]);
DO(6, sa_netnum[3]);
DO(9, sa_nodenum[0]);
DO(11, sa_nodenum[1]);
DO(13, sa_nodenum[2]);
DO(15, sa_nodenum[3]);
DO(17, sa_nodenum[4]);
DO(19, sa_nodenum[5]);
sscanf (&s[22], "%u", &val);
#undef DO
((struct sockaddr_ipx *)sadr)->sa_socket = htons((unsigned short)val);
if (addrfamily)
*addrfamily = AF_IPX;
if (addrsize)
*addrsize = sizeof(struct sockaddr_ipx);
result++;
}
else
#endif
#ifdef HAVE_IPV6
#ifdef getaddrinfo
if (getaddrinfo)
#else
if (1)
#endif
{
struct addrinfo *addrinfo = NULL;
struct addrinfo *pos;
struct addrinfo udp6hint;
int error;
char *port;
char dupbase[256];
int len;
size_t i;
double restime = Sys_DoubleTime();
memset(&udp6hint, 0, sizeof(udp6hint));
switch(afhint)
{
#ifdef HAVE_IPV4
case NA_IP:
udp6hint.ai_family = AF_INET;
break;
#endif
#ifdef HAVE_IPV6
case NA_IPV6:
udp6hint.ai_family = AF_INET6;
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
udp6hint.ai_family = AF_IPX;
break;
#endif
default:
udp6hint.ai_family = 0;//Any... we check for AF_INET6 or 4
break;
}
udp6hint.ai_socktype = SOCK_DGRAM;
udp6hint.ai_protocol = 0;
if (*s == '[')
{
port = strstr(s, "]");
if (!port)
error = EAI_NONAME;
else
{
len = port - (s+1);
if (len >= sizeof(dupbase))
len = sizeof(dupbase)-1;
strncpy(dupbase, s+1, len);
dupbase[len] = '\0';
error = getaddrinfo(dupbase, (port[1] == ':')?port+2:NULL, &udp6hint, &addrinfo);
}
}
else
{
#if defined(AI_ADDRCONFIG) && !defined(_WIN32)
udp6hint.ai_flags |= AI_ADDRCONFIG; //don't return ipv6 if we can't send to ipv6 hosts
#endif
port = strrchr(s, ':');
if (port)
{
len = port - s;
if (len >= sizeof(dupbase))
len = sizeof(dupbase)-1;
strncpy(dupbase, s, len);
dupbase[len] = '\0';
error = getaddrinfo(dupbase, port+1, &udp6hint, &addrinfo);
}
else
error = EAI_NONAME;
if (error) //failed, try string with no port.
error = getaddrinfo(s, NULL, &udp6hint, &addrinfo); //remember, this func will return any address family that could be using the udp protocol... (ip4 or ip6)
}
restime = Sys_DoubleTime()-restime;
if (restime > 0.5)
{ //adding this in an attempt to debug somewhat periodic stalls that I'm being told about.
Con_DPrintf("DNS resolution of %s %s %f seconds (on %s thread)\n", s, error?"failed after":"took", restime, Sys_IsMainThread()?"main":"worker");
}
if (error)
{
return false;
}
((struct sockaddr*)sadr)->sa_family = 0;
for (pos = addrinfo; pos; pos = pos->ai_next)
{
switch(pos->ai_family)
{
case AF_INET6:
if (!net_dns_ipv6.ival)
continue;
if (result < addresses)
memcpy(&sadr[result++], pos->ai_addr, pos->ai_addrlen);
break;
#ifdef HAVE_IPV4
case AF_INET:
if (!net_dns_ipv4.ival)
continue;
//ipv4 addresses have a higher priority than ipv6 ones (too few other quake engines support ipv6).
if (result && ((struct sockaddr_in *)&sadr[0])->sin_family == AF_INET6)
{
if (result < addresses)
memcpy(&sadr[result++], &sadr[0], sizeof(sadr[0]));
memcpy(&sadr[0], pos->ai_addr, pos->ai_addrlen);
}
else if (result < addresses)
memcpy(&sadr[result++], pos->ai_addr, pos->ai_addrlen);
break;
#endif
}
}
freeaddrinfo (addrinfo);
for (i = 0; i < result; i++)
{
if (addrfamily)
addrfamily[i] = ((struct sockaddr*)sadr)->sa_family;
if (((struct sockaddr*)&sadr[i])->sa_family == AF_INET)
{
if (!((struct sockaddr_in *)&sadr[i])->sin_port)
((struct sockaddr_in *)&sadr[i])->sin_port = htons(defaultport);
if (addrsize)
addrsize[i] = sizeof(struct sockaddr_in);
}
else if (((struct sockaddr*)&sadr[i])->sa_family == AF_INET6)
{
if (!((struct sockaddr_in6 *)&sadr[i])->sin6_port)
((struct sockaddr_in6 *)&sadr[i])->sin6_port = htons(defaultport);
if (addrsize)
addrsize[i] = sizeof(struct sockaddr_in6);
}
}
}
else
#endif
{
#if defined(HAVE_IPV4) && defined(getaddrinfo) && !defined(HAVE_IPV6)
char copy[128];
char *colon;
((struct sockaddr_in *)sadr)->sin_family = AF_INET;
((struct sockaddr_in *)sadr)->sin_port = 0;
if (strlen(s) >= sizeof(copy)-1)
return false;
if (!net_dns_ipv4.ival)
return false;
((struct sockaddr_in *)sadr)->sin_port = htons(defaultport);
strcpy (copy, s);
// strip off a trailing :port if present
for (colon = copy ; *colon ; colon++)
if (*colon == ':')
{
*colon = 0;
((struct sockaddr_in *)sadr)->sin_port = htons((short)atoi(colon+1));
}
if (copy[0] >= '0' && copy[0] <= '9') //this is the wrong way to test. a server name may start with a number.
{
*(int *)&((struct sockaddr_in *)sadr)->sin_addr = inet_addr(copy);
}
else
{
struct hostent *h;
if (! (h = gethostbyname(copy)) )
return false;
if (h->h_addrtype != AF_INET)
return false;
*(int *)&((struct sockaddr_in *)sadr)->sin_addr = *(int *)h->h_addr_list[0];
}
if (addrfamily)
*addrfamily = AF_INET;
if (addrsize)
*addrsize = sizeof(struct sockaddr_in);
result++;
#endif
}
return result;
}
/*
accepts anything that NET_StringToSockaddr accepts plus certain url schemes
including: tcp, irc
FIXME: should move schemes out of here (so caller can handle paths+etc), using an address family hint for args.
*/
size_t NET_StringToAdr2 (const char *s, int defaultport, netadr_t *a, size_t numaddresses, const char **pathstart)
{
size_t result = 0, i;
struct sockaddr_qstorage sadr[8];
int asize[countof(sadr)];
netproto_t prot;
netadrtype_t afhint;
char *path;
struct
{
const char *name;
netproto_t prot;
netadrtype_t family;
} schemes[] =
{
{"udp://", NP_DGRAM, NA_INVALID}, //placeholder for dgram rather than an actual family.
{"udp4//", NP_DGRAM, NA_IP},
{"udp6//", NP_DGRAM, NA_IPV6},
{"ipx://", NP_DGRAM, NA_IPX},
//compat with qtv. we don't have any way to exclude specific protocols though.
{"qw://", NP_DGRAM, NA_INVALID},
{"nq://", NP_DGRAM, NA_INVALID},
{"dp://", NP_DGRAM, NA_INVALID},
{"q2://", NP_DGRAM, NA_INVALID},
{"q3://", NP_DGRAM, NA_INVALID},
{"tcp://", NP_STREAM_OR_INVALID, NA_INVALID}, //placeholder for dgram rather than an actual family.
{"tcp4//", NP_STREAM_OR_INVALID, NA_IP},
{"tcp6//", NP_STREAM_OR_INVALID, NA_IPV6},
{"spx://", NP_STREAM_OR_INVALID, NA_IPX},
{"ws://", NP_WS_OR_INVALID, NA_INVALID},
{"wss://", NP_WSS_OR_INVALID, NA_INVALID},
{"tls://", NP_TLS_OR_INVALID, NA_INVALID},
{"dtls://", NP_DTLS_OR_INVALID, NA_INVALID},
#if defined(SUPPORT_ICE) || defined(HAVE_WEBSOCKCL)
{"ice://", NP_RTC_TCP, NA_INVALID},
{"rtc://", NP_RTC_TCP, NA_INVALID},
{"ices://", NP_RTC_TLS, NA_INVALID},
{"rtcs://", NP_RTC_TLS, NA_INVALID},
#endif
{"irc://", NP_INVALID, NA_INVALID}, //should have been handled explicitly, if supported.
#ifdef UNIXSOCKETS
{"udg://", NP_DGRAM, NA_UNIX},
{"unix://", NP_STREAM_OR_INVALID, NA_UNIX},
#endif
};
memset(a, 0, sizeof(*a)*numaddresses);
if (pathstart)
*pathstart = NULL;
if (!numaddresses)
return false;
if (!strcmp (s, "internalserver"))
{
a->type = NA_LOOPBACK;
return true;
}
if (!strncmp(s, "QLoopBack", 9))
{
a->type = NA_LOOPBACK;
if (s[9] == ':')
a->port = atoi(s+10);
else
a->port = defaultport;
return true;
}
if (!net_enabled.ival)
return false;
Con_DPrintf("Resolving address: %s\n", s);
#ifdef HAVE_WEBSOCKCL
//with websockets we can't really resolve anything. failure happens only when trying to connect.
//`connect /GAMENAME` is equivelent to `connect rtc://broker/GAMENAME`
if (*s == '/')
{
char *broker = fs_manifest->rtcbroker;
if (!broker || !*broker)
{ //FIXME: use referrer? or the website's host?
Con_DPrintf("No default rtc broker\n");
return 0; //can't accept it
}
a->prot = NP_RTC_TLS;
a->type = NA_INVALID;
if (pathstart)
*pathstart = s;
return 1;
}
else if (!strncmp (s, "rtc://", 6) || !strncmp (s, "rtcs://", 7) || !strncmp (s, "ice://", 6) || !strncmp (s, "ices://", 7))
{ //basically ICE using sdp-via-websockets to a named relay server.
const char *path;
a->prot = NP_RTC_TLS;
if (s[4] == ':')
{
a->prot = NP_RTC_TLS;
s += 7;
}
else
{
a->prot = NP_RTC_TCP;
s += 6;
}
path = strchr(path, '/');
if (path)
{
if (s == path) //no hostname specified = use default broker (resolving it later)
a->type = NA_INVALID;
else if (path-s < sizeof(a->address.websocketurl))
{
memcpy(a->address.websocketurl, s, path-s);
a->address.websocketurl[path-s] = 0;
}
else
return 0; //too long
if (pathstart)
*pathstart = path;
}
else
return 0; //reject it when there's no path
return 1;
}
else if (!strncmp (s, "ws://", 5) || !strncmp (s, "wss://", 6))
{
a->type = NA_WEBSOCKET;
if (!strncmp (s, "wss://", 6))
a->prot = NP_WSS;
else
a->prot = NP_WS;
Q_strncpyz(a->address.websocketurl, s, sizeof(a->address.websocketurl));
return 1;
}
else
{
/*code for convienience - no other protocols work anyway*/
static float warned;
int i;
for (i = 0; s[i] == ':' || s[i] == '[' || s[i] == ']' || s[i] == '.' || (s[i] >= '0' && s[i] <= '9'); i++)
;
a->type = NA_WEBSOCKET;
if (s[i])
{ //assume there's part of some domain name in there. FIXME: this may be a false positive in the case of hex ipv6 addresses.
if (warned < realtime)
{
Con_DPrintf("Note: Assuming wss:// prefix\n");
warned = realtime + 1;
}
a->prot = NP_WSS;
memcpy(a->address.websocketurl, "wss://", 6);
Q_strncpyz(a->address.websocketurl+6, s, sizeof(a->address.websocketurl)-6);
}
else
{ //looks like a straight ip address.
//assume most server-by-ip addresses will not have proper certificates set up with that specific ip address as an actual name, and fall back on unsecure rubbish instead.
if (warned < realtime)
{
Con_Printf("Note: Assuming ws:// prefix\n");
warned = realtime + 1;
}
a->prot = NP_WS;
memcpy(a->address.websocketurl, "ws://", 5);
Q_strncpyz(a->address.websocketurl+5, s, sizeof(a->address.websocketurl)-5);
}
return 1;
}
#endif
#ifdef IRCCONNECT
if (!strncmp (s, "irc://", 6))
{
char *at;
char *slash;
memset (a, 0, sizeof(*a));
a->type = NA_IRC;
s+=6;
slash = strchr(s, '/');
if (!slash)
return false;
if (slash - s+1 >= sizeof(a->address.irc.host))
return false;
memcpy(a->address.irc.host, s, slash - s);
a->address.irc.host[slash - s] = 0;
s = slash+1;
at = strchr(s, '@');
if (at)
{
if (at-s+1 >= sizeof(a->address.irc.user))
return false;
Q_strncpyz(a->address.irc.user, s, at-s+1);
Q_strncpyz(a->address.irc.channel, at+1, sizeof(a->address.irc.channel));
}
else
{
//just a user.
Q_strncpyz(a->address.irc.user, s, sizeof(a->address.irc.user));
}
return 1;
}
#endif
#ifdef HAVE_NATPMP
if (!strncmp (s, "natpmp://", 9))
{ //our natpmp thing omits the host part. FIXME: host should be the NAT that we're sending to
NET_PortToAdr(NA_IP, NP_NATPMP, s+9, a);
if (a->prot != NP_NATPMP)
return false;
return true;
}
#endif
for (prot = NP_DGRAM, afhint = NA_INVALID/*any*/, i = 0; i < countof(schemes); i++)
{
if (!strncmp(s, schemes[i].name, strlen(schemes[i].name)))
{
s += strlen(schemes[i].name);
prot = schemes[i].prot;
afhint = schemes[i].family;
if (prot == NP_RTC_TCP || prot == NP_RTC_TLS)
defaultport = PORT_ICEBROKER;
break;
}
}
path = strchr(s, '/');
#if !defined(HAVE_WEBSOCKCL) && defined(SUPPORT_ICE)
if (path == s && fs_manifest->rtcbroker && *fs_manifest->rtcbroker)
{
s = fs_manifest->rtcbroker;
if (!strncmp(s, "tls://", 6) || !strncmp(s, "wss://", 6))
s+=6, prot=NP_RTC_TLS;
else if (!strncmp(s, "tcp://", 6))
s+=6, prot=NP_RTC_TCP;
else if (!strncmp(s, "ws://", 5))
s+=5, prot=NP_RTC_TCP;
else
prot = NP_RTC_TLS; //best-practise by default.
if (pathstart)
*pathstart = path;
result = NET_StringToSockaddr2 (s, PORT_ICEBROKER, afhint, sadr, NULL, asize, min(numaddresses, countof(sadr)));
}
else
#endif
if (path && (path-s)<MAX_OSPATH)
{
char host[MAX_OSPATH];
if (pathstart)
*pathstart = path;
memcpy(host, s, path-s);
host[path-s] = 0;
result = NET_StringToSockaddr2 (host, defaultport, afhint, sadr, NULL, asize, min(numaddresses, countof(sadr)));
}
else
result = NET_StringToSockaddr2 (s, defaultport, afhint, sadr, NULL, asize, min(numaddresses, countof(sadr)));
for (i = 0; i < result; i++)
{
SockadrToNetadr (&sadr[i], asize[i], &a[i]);
a[i].prot = prot;
}
return result;
}
// NET_IntegerToMask: given a source address pointer, a mask address pointer, and
// desired number of bits, fills the mask pointer with given bits
// (bits < 0 will always fill all bits)
void NET_IntegerToMask (netadr_t *a, netadr_t *amask, int bits)
{
unsigned int i;
qbyte *n;
memset (amask, 0, sizeof(*amask));
amask->type = a->type;
if (bits < 0)
i = 8000; // fill all bits
else
i = bits;
switch (amask->type)
{
case NA_INVALID:
break;
case NA_IP:
n = amask->address.ip;
if (i > 32)
i = 32;
for (; i >= 8; i -= 8)
{
*n = 0xFF;
n++;
}
// fill last bit
if (i)
{
i = 8 - i;
i = 255 - ((1 << i) - 1);
*n = i;
}
break;
case NA_IPV6:
#ifdef HAVE_IPV6
n = amask->address.ip6;
if (i > 128)
i = 128;
for (; i >= 8; i -= 8)
{
*n = 0xFF;
n++;
}
// fill last bit
if (i)
{
i = 8 - i;
i = 255 - ((1 << i) - 1);
*n = i;
}
#endif
break;
case NA_IPX:
#ifdef HAVE_IPX
n = amask->address.ipx;
if (i > 80)
i = 80;
for (; i >= 8; i -= 8)
{
*n = 0xFF;
n++;
}
// fill last bit
if (i)
{
i = 8 - i;
i = 255 - ((1 << i) - 1);
*n = i;
}
#endif
break;
case NA_LOOPBACK:
break;
#ifdef UNIXSOCKETS
case NA_UNIX: //address masks/filtering don't make sense.
#endif
#ifdef HAVE_WEBSOCKCL
case NA_WEBSOCKET:
#endif
#ifdef IRCCONNECT
case NA_IRC:
#endif
#ifdef SUPPORT_ICE
case NA_ICE:
#endif
break;
}
}
// ParsePartialIP: check string to see if it is a partial IP address and
// return bits to mask and set netadr_t or 0 if not an address
int ParsePartialIP(const char *s, netadr_t *a)
{
char *colon;
int bits;
if (!*s)
return 0;
memset (a, 0, sizeof(*a));
//if its ::ffff:a.b.c.d then parse it as ipv4 by just skipping the prefix.
//we ought to leave it as ipv6, but any printing will show it as ipv4 anyway.
if (!strncasecmp(s, "::ffff:", 7) && strchr(s+7, '.') && !strchr(s+7, ':'))
s += 7;
//multiple colons == ipv6
//single colon = ipv4:port
colon = strchr(s, ':');
if (colon && strchr(colon+1, ':'))
{
qbyte *address = a->address.ip6;
unsigned long tmp;
int gapstart = -1; //in bytes...
bits = 0;
while(*s)
{
tmp = strtoul(s, &colon, 16);
if (colon == s)
{
if (bits)
return 0;
}
else
{
if (tmp > 0xffff)
return 0; //invalid
*address++ = (tmp>>8)&0xff;
*address++ = (tmp>>0)&0xff;
bits += 16;
}
if (bits == 128)
{
if (!*colon)
break;
return 0; //must have ended here
}
//double-colon is a gap (or partial end).
//hopefully the last 64 bits or whatever will be irrelevant anyway, so such addresses won't be common
if (colon[0] == ':' && colon[1] == ':')
{
if (gapstart >= 0)
return 0; //only one gap...
if (!colon[2])
break; //nothing after. its partial.
gapstart = bits/8;
colon+=2;
}
else if (*colon == ':' && bits)
colon++;
else if (*colon)
return 0; //gibberish here...
else
break; //end of address... anything more is a partial.
s = colon;
}
if (gapstart >= 0)
{
int tailsize = (bits/8)-gapstart; //bits to move to the end
int gapsize = 16 - gapstart - tailsize;
memmove(a->address.ip6+gapstart+gapsize, a->address.ip6+gapstart, tailsize); //move the bits we found to the end
memset(a->address.ip6+gapstart, 0, gapsize); //and make sure the gap is cleared
bits = 128; //found it all, or something.
}
if (!bits)
bits = 1; //FIXME: return of 0 is an error, but :: is 0-length... lie.
a->type = NA_IPV6;
a->port = 0;
}
else
{
char *address = a->address.ip;
int port = 0;
bits = 8;
while (*s)
{
if (*s == ':')
{
port = strtoul(s+1, &address, 10);
if (*address) //if there was something other than a number there, give up now
return 0;
break; //end-of-string
}
else if (*s == '.')
{
if (bits >= 32) // only 32 bits in ipv4
return 0;
else if (*(s+1) == '.')
return 0;
else if (*(s+1) == '\0')
break; // don't add more bits to the mask for x.x., etc
address++;
//many nq servers mask addresses with Xs.
if (s[1] == 'x' || s[1] == 'X')
{
s++;
while (*s == 'x' || *s == 'X' || *s == '.')
s++;
if (*s)
return 0;
break;
}
bits += 8;
}
else if (*s >= '0' && *s <= '9')
*address = ((*address)*10) + (*s-'0');
else
return 0; // invalid character
s++;
}
a->type = NA_IP;
a->port = port;
}
return bits;
}
// NET_StringToAdrMasked: extension to NET_StringToAdr to handle IP addresses
// with masks or integers representing the bit masks
qboolean NET_StringToAdrMasked (const char *s, qboolean allowdns, netadr_t *a, netadr_t *amask)
{
char t[64];
char *spoint;
int i;
spoint = strchr(s, '/');
if (spoint)
{
// we have a slash in the address so split and resolve separately
char *c;
i = (int)(spoint - s) + 1;
if (i > sizeof(t))
i = sizeof(t);
Q_strncpyz(t, s, i);
if (!ParsePartialIP(t, a) && (!allowdns || !NET_StringToAdr(t, 0, a)))
return false;
spoint++;
c = spoint;
if (!*c)
return false;
while (*c) // check for non-numeric characters
{
if (*c < '0' || *c > '9')
{
c = NULL;
break;
}
c++;
}
if (c == NULL) // we have an address so resolve it and return
return ParsePartialIP(spoint, amask) || (allowdns && NET_StringToAdr(spoint, 0, amask));
// otherwise generate mask for given bits
i = atoi(spoint);
NET_IntegerToMask(a, amask, i);
}
else
{
// we don't have a slash, resolve and fill with a full mask
i = ParsePartialIP(s, a);
if (!i && (!allowdns || !NET_StringToAdr(s, 0, a)))
return false;
memset (amask, 0, sizeof(*amask));
amask->type = a->type;
if (i)
NET_IntegerToMask(a, amask, i);
else
NET_IntegerToMask(a, amask, -1);
}
return true;
}
qboolean NET_IsEncrypted(netadr_t *adr)
{
if (adr->type == NA_LOOPBACK)
return true; //might as well claim it, others can't snoop on it so...
#ifdef SUPPORT_ICE
if (adr->type == NA_ICE && ICE_IsEncrypted(adr))
return true;
#endif
#if defined(FTE_TARGET_WEB)
if (adr->prot == NP_RTC_TLS) //web port works a bit differently... webrtc is ALWAYS encrypted, but only report it as secure when the broker connection is encrypted too.
return true;
#endif
if (adr->prot == NP_DTLS || adr->prot == NP_TLS || adr->prot == NP_WSS)
return true;
return false;
}
// NET_CompareAdrMasked: given 3 addresses, 2 to compare with a complimentary mask,
// returns true or false if they match
//WARNING: a is typically an ipv6 address, even if its an ipv4-mapped address.
//so ipv4ify first.
//this is not intended to identify any specific connection, so we can ignore udp/tcp distinctions (especially as this is usually used for bans).
qboolean NET_CompareAdrMasked(netadr_t *a, netadr_t *b, netadr_t *mask)
{
int i;
//make sure the address being checked against matches the mask
if (b->type != mask->type)
return false;
// check port if both are non-zero
if (a->port && b->port && a->port != b->port)
return false;
// check to make sure all types match
if (a->type != b->type)
{
if (a->type == NA_IP && b->type == NA_IPV6 && mask->type == NA_IP)
{
for (i = 0; i < 10; i++)
if (b->address.ip6[i] != 0)
return false; //only matches if they're 0s, otherwise its not an ipv4 address there
for (; i < 12; i++)
if (b->address.ip6[i] != 0xff)// && b->address.ip6[i] != 0x00) //0x00 is depricated
return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there
for (i = 0; i < 4; i++)
{
if ((a->address.ip[i] & mask->address.ip[i]) != (b->address.ip6[12+i] & mask->address.ip[i]))
return false; //mask doesn't match
}
return true; //its an ipv4 address in there, the mask matched the whole way through
}
if (a->type == NA_IPV6 && b->type == NA_IP && mask->type == NA_IP)
{
for (i = 0; i < 10; i++)
if (a->address.ip6[i] != 0)
return false; //only matches if they're 0s, otherwise its not an ipv4 address there
for (; i < 12; i++)
if (a->address.ip6[i] != 0xff)// && a->address.ip6[i] != 0x00) //0x00 is depricated
return false; //only matches if they're 0s or ffs, otherwise its not an ipv4 address there
for (i = 0; i < 4; i++)
{
if ((a->address.ip6[12+i] & mask->address.ip[i]) != (b->address.ip[i] & mask->address.ip[i]))
return false; //mask doesn't match
}
return true; //its an ipv4 address in there, the mask matched the whole way through
}
return false;
}
// match on protocol type and compare address
switch (a->type)
{
case NA_LOOPBACK:
return true;
case NA_IP:
for (i = 0; i < 4; i++)
{
if ((a->address.ip[i] & mask->address.ip[i]) != (b->address.ip[i] & mask->address.ip[i]))
return false;
}
break;
#ifdef HAVE_IPV6
case NA_IPV6:
for (i = 0; i < 16; i++)
{
if ((a->address.ip6[i] & mask->address.ip6[i]) != (b->address.ip6[i] & mask->address.ip6[i]))
return false;
}
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
for (i = 0; i < 10; i++)
{
if ((a->address.ipx[i] & mask->address.ipx[i]) != (b->address.ipx[i] & mask->address.ipx[i]))
return false;
}
break;
#endif
#ifdef IRCCONNECT
case NA_IRC:
//masks are not supported, match explicitly
if (strcmp(a->address.irc.user, b->address.irc.user))
return false;
break;
#endif
default:
return false; // invalid protocol
}
return true; // all checks passed
}
// UniformMaskedBits: counts number of bits in an assumed uniform mask, returns
// -1 if not uniform
int UniformMaskedBits(netadr_t *mask)
{
int bits;
int b;
unsigned int bs;
qboolean bitenc = false;
switch (mask->type)
{
case NA_IP:
bits = 32;
for (b = 3; b >= 0; b--)
{
if (mask->address.ip[b] == 0xFF)
bitenc = true;
else if (mask->address.ip[b])
{
bs = (~mask->address.ip[b]) & 0xFF;
while (bs)
{
if (bs & 1)
{
bits -= 1;
if (bitenc)
return -1;
}
else
bitenc = true;
bs >>= 1;
}
}
else if (bitenc)
return -1;
else
bits -= 8;
}
break;
#ifdef HAVE_IPV6
case NA_IPV6:
bits = 128;
for (b = 15; b >= 0; b--)
{
if (mask->address.ip6[b] == 0xFF)
bitenc = true;
else if (mask->address.ip6[b])
{
bs = (~mask->address.ip6[b]) & 0xFF;
while (bs)
{
if (bs & 1)
{
bits -= 1;
if (bitenc)
return -1;
}
else
bitenc = true;
bs >>= 1;
}
}
else if (bitenc)
return -1;
else
bits -= 8;
}
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
bits = 80;
for (b = 9; b >= 0; b--)
{
if (mask->address.ipx[b] == 0xFF)
bitenc = true;
else if (mask->address.ipx[b])
{
bs = (~mask->address.ipx[b]) & 0xFF;
while (bs)
{
if (bs & 1)
{
bits -= 1;
if (bitenc)
return -1;
}
else
bitenc = true;
bs >>= 1;
}
}
else if (bitenc)
return -1;
else
bits -= 8;
}
break;
#endif
default:
return -1; // invalid protocol
}
return bits; // all checks passed
}
char *NET_AdrToStringMasked (char *s, int len, netadr_t *a, netadr_t *amask)
{
int i;
char adr[MAX_ADR_SIZE], mask[MAX_ADR_SIZE];
i = UniformMaskedBits(amask);
if (i >= 0)
snprintf(s, len, "%s/%i", NET_AdrToString(adr, sizeof(adr), a), i);
else
snprintf(s, len, "%s/%s", NET_AdrToString(adr, sizeof(adr), a), NET_AdrToString(mask, sizeof(mask), amask));
return s;
}
// Returns true if we can't bind the address locally--in other words,
// the IP is NOT one of our interfaces.
qboolean NET_IsClientLegal(netadr_t *adr)
{
#if 0
struct sockaddr_in sadr;
int newsocket;
if (adr->ip[0] == 127)
return false; // no local connections period
NetadrToSockadr (adr, &sadr);
if ((newsocket = socket (PF_INET, SOCK_CLOEXEC|SOCK_DGRAM, IPPROTO_UDP)) == INVALID_SOCKET)
Sys_Error ("NET_IsClientLegal: socket:", strerror(qerrno));
sadr.sin_port = 0;
if( bind (newsocket, (void *)&sadr, sizeof(sadr)) == -1)
{
// It is not a local address
close(newsocket);
return true;
}
close(newsocket);
return false;
#else
return true;
#endif
}
qboolean NET_IsLoopBackAddress (netadr_t *adr)
{
// return (!strcmp(cls.servername, NET_AdrToString(net_local_adr)) || !strcmp(cls.servername, "local");
return adr->type == NA_LOOPBACK;
}
void *Auth_GetKnownCertificate(const char *certname, size_t *size)
{ //our 'code signing' certs
//we only allow packages to be installed into the root dir (or with dll/so/exe extensions) when their signature is signed by one of these certificates
#ifdef HAVE_SSL
static struct
{
const char *name;
qbyte *cert;
} certs[] =
{ //the contents of a -pubcert FILE
//note: not enforced for pk3 files (which we will otherwise happily randomly download of random servers anyway).
{"Spike", "-----BEGIN CERTIFICATE-----\n"
"MIIDnTCCAgUCCjE1ODQ4ODg2OTEwDQYJKoZIhvcNAQELBQAwEDEOMAwGA1UEAxMF\n"
"U3Bpa2UwHhcNMjAwMzIyMTQ1MTMwWhcNMzAwMzIwMTQ1MTMxWjAQMQ4wDAYDVQQD\n"
"EwVTcGlrZTCCAaIwDQYJKoZIhvcNAQEBBQADggGPADCCAYoCggGBAN07KHTPc0Pn\n"
"lC8MlQNiI+OEUEJBakTjfNq+IJzJ6oTWXxfQbHrN+UpKXwxploDbeyxTE1Fniisi\n"
"nLWhOkW/XQqyXLXAv/3lxiSwe4QcVMOhQlw5U05VrdB7xHvFMShLsyc12sNvBiIa\n"
"Vw05wFJgIXYTd9nJfm9x3kpxRoTJBvdDbYl8OagT6SxzJfHkdmfI2TYVYxGUH9nX\n"
"R9zvwXTIXvV47cko2ON8scH9QQ6KgwMfcwyIBL74Btvl4ye+TrL2srj38FBxyyPG\n"
"SSdKPk4LN2zsfNsJm31hzWrdLEkl3CTOX5gHHSweOKpuPwmX/GPd1xo0nIMwDou4\n"
"BsMMBAhK/JSyLpUUzk5gbRmy4PwFccktHdFW6LF8ZvPY7e7LEiD5KOWZ7a7c1WR/\n"
"4oJrjo0t+7OugVADolxzLXFrq9ACBGrD8r6QlsGC8O7WqpKGQCT+4q3tUup9tPkh\n"
"3dhjC0jEkKljS+39uukbisV702bHwoEZPzjMpz4O9bHf6JbIJLlQzQIDAQABMA0G\n"
"CSqGSIb3DQEBCwUAA4IBgQC5rj7R7a9LLnqgiXMUITGnygK1lp0EV2BdnIrg/MHr\n"
"y+Gk9BA+XgFSI4W9odiG/hJnA7aQ0S2kk1GNYQ+NNzU2bQIMkaobaZApV9ojD4lL\n"
"s33Qbgt/Ocpadtpj8EiMInjLkn1B+wnqcX3S76Zcrf8RT4WP2A4klxcN3zBNBiBL\n"
"DAJ3SrH8hZ9wmruwAY5tMZhQzDHkeK8uaDb7nE0HA5GXeT4QYA/L7Ys2nGYgxj1O\n"
"L5YlGddBcX3O6XyJpSeCO2Z2kwl4qg8oiM+Y546lILotuL5qD/+FTDeX3dGd8nyD\n"
"e1g/7xd0V4IyKUjii8Vu2V1F7t0xVTPWEe13TqU/JTfKX4zvQnMF7zxgGFIwabHX\n"
"lzk2olte4rPp+iQzPmnynLiUrdkxGXLnE0V545VO+iGO8+bwclbJ+7SG6N5l8xox\n"
"WjGunhXXkEjitAk+ssBjbEh8kIfpFdVA09v60rMdm7BdfO3//QOsjwiwKkBOXcYW\n"
"QGE0Ue4J7anLVAKiQq4n1aU=\n"
"-----END CERTIFICATE-----\n"},
};
size_t i;
for (i = 0; i < countof(certs); i++)
{
if (!strcmp(certname, certs[i].name))
{
*size = strlen(certs[i].cert);
return certs[i].cert;
}
}
#endif
return NULL;
}
#ifdef HAVE_SSL
void *TLS_GetKnownCertificate(const char *certname, size_t *size)
{
//Note: This is XORed because of shitty scanners flagging binaries through false positive, flagging the sites that they were downloaded from, flagging binaries that contain references to those sites, and flagging any site that contains binaries.
//the xor helps break that shitty recursive loop of mistrust from defects in other people's code.
//at least until there's a sandbox that checks the dns resolutions for our update requests anyway.
//I should probably just copy the downloadables file to sourceforge.
static struct
{
qbyte *data;
} knowncerts[] = {
{
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},
};
qbyte *r, *t;
size_t i, j, sz;
for (i = 0; i < countof(knowncerts); i++)
{
t = knowncerts[i].data;
for (j = 0; ; j++)
{
if (certname[j] != (t[j]^0xff))
break;
if (!certname[j])
{
j++;
t+=j;
sz = t[0] | (t[1]<<8);
t += 2;
r = BZ_Malloc(sz);
*size = sz;
while(sz --> 0)
r[sz] = t[sz]^0xff;
return r;
}
}
}
*size = 0;
//return Z_StrDup(""); //to force failure... gnutls debug code will dump out a cert that can be inserted above.
return NULL;
}
vfsfile_t *FS_OpenSSL(const char *peername, vfsfile_t *source, qboolean isserver)
{
int i;
vfsfile_t *f = NULL;
char hostname[MAX_OSPATH];
if (!source)
return NULL; //can happen if socket() fails.
if (peername)
{
//clean up the name, stripping any port or other weirdness.
if (!strncmp(peername, "tls://", 6))
peername+=6;
if (*peername == '[')
{ //an ipv6 address, strip the brackets (and trailing port)
Q_strncpyz(hostname, peername+1, sizeof(hostname));
if (strchr(hostname, ']'))
*strchr(hostname, ']') = 0;
}
else
{ //a hostname or ipv4 address, strip the port.
Q_strncpyz(hostname, peername, sizeof(hostname));
if (strchr(hostname, ':'))
*strchr(hostname, ':') = 0;
}
}
else
*hostname = 0;
i = tls_provider.ival-1;
if (i>=0 && i < cryptolib_count && cryptolib[i])
f = !cryptolib[i]->OpenStream?NULL:cryptolib[i]->OpenStream(hostname, source, isserver);
else for (i = 0; !f && i < cryptolib_count; i++)
{
if (cryptolib[i] && cryptolib[i]->OpenStream)
f = cryptolib[i]->OpenStream(hostname, source, isserver);
}
if (!f) //it all failed.
{
if (isserver && i < cryptolib_count && cryptolib[i] && cryptolib[i]->OpenStream)
{
Con_Printf("%s: no tls provider available. You may need to create a public certificate\n", peername?peername:"<HOST>");
}
else
Con_Printf("%s: no tls provider available\n", peername);
VFS_CLOSE(source);
}
return f;
}
int TLS_GetChannelBinding(vfsfile_t *stream, qbyte *data, size_t *datasize)
{
int r = -1;
int i;
for (i = 0; r==-1 && i < cryptolib_count; i++)
{
if (cryptolib[i] && cryptolib[i]->GetChannelBinding)
r = cryptolib[i]->GetChannelBinding(stream, data, datasize);
}
return r;
}
#endif
/////////////////////////////////////////////
//loopback stuff
#if defined(HAVE_SERVER) && defined(HAVE_CLIENT)
static qboolean NET_GetLoopPacket (int sock, netadr_t *from, sizebuf_t *message)
{
int i;
loopback_t *loop;
sock &= 1;
loop = &loopbacks[sock];
if (loop->send - loop->get > MAX_LOOPBACK)
{
extern cvar_t showdrop;
if (showdrop.ival)
Con_Printf("loopback dropping %i packets\n", (loop->send - MAX_LOOPBACK) - loop->get);
loop->get = loop->send - MAX_LOOPBACK;
}
if (loop->get >= loop->send)
return false;
i = loop->get & (MAX_LOOPBACK-1);
loop->get++;
if (message->maxsize < loop->msgs[i].datalen)
Sys_Error("NET_SendLoopPacket: Loopback buffer was too big");
memcpy (message->data, loop->msgs[i].data, loop->msgs[i].datalen);
message->cursize = loop->msgs[i].datalen;
memset (from, 0, sizeof(*from));
from->type = NA_LOOPBACK;
message->packing = SZ_RAWBYTES;
message->currentbit = 0;
loop->msgs[i].datalen = 0;
return true;
}
static neterr_t NET_SendLoopPacket (int sock, int length, const void *data, netadr_t *to)
{
int i;
loopback_t *loop;
if (!length && !data) //NET_EnsureRoute tests.
return NETERR_SENT;
sock &= 1;
loop = &loopbacks[sock^1];
if (!loop->inited)
return NETERR_NOROUTE;
i = loop->send & (MAX_LOOPBACK-1);
if (length > loop->msgs[i].datamax)
{
loop->msgs[i].datamax = length + 1024;
BZ_Free(loop->msgs[i].data);
loop->msgs[i].data = BZ_Malloc(loop->msgs[i].datamax);
}
if (loop->msgs[i].datalen)
Con_Printf("Warning: loopback queue overflow\n");
loop->send++;
memcpy (loop->msgs[i].data, data, length);
loop->msgs[i].datalen = length;
return NETERR_SENT;
}
static int FTENET_Loop_GetLocalAddresses(struct ftenet_generic_connection_s *con, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
if (maxaddresses)
{
addresses->type = NA_LOOPBACK;
addresses->port = con->thesocket+1;
*adrflags = 0;
*adrparams = NULL;
return 1;
}
return 0;
}
static qboolean FTENET_Loop_GetPacket(ftenet_generic_connection_t *con)
{
return NET_GetLoopPacket(con->thesocket, &net_from, &net_message);
}
#if defined(HAVE_PACKET) && !defined(HAVE_EPOLL)
//just a null function so we don't pass bad things to select.
static int FTENET_Loop_SetFDSets(ftenet_generic_connection_t *gcon, fd_set *readfdset, fd_set *writefdset)
{
return 0;
}
#endif
static neterr_t FTENET_Loop_SendPacket(ftenet_generic_connection_t *con, int length, const void *data, netadr_t *to)
{
if (to->type == NA_LOOPBACK)
{
return NET_SendLoopPacket(con->thesocket, length, data, to);
}
return NETERR_NOROUTE;
}
static void FTENET_Loop_Close(ftenet_generic_connection_t *con)
{
int i;
int sock = con->thesocket;
sock &= 1;
loopbacks[sock].inited = false;
loopbacks[sock].get = loopbacks[sock].send = 0;
for (i = 0; i < MAX_LOOPBACK; i++)
{
BZ_Free(loopbacks[sock].msgs[i].data);
loopbacks[sock].msgs[i].data = NULL;
loopbacks[sock].msgs[i].datalen = 0;
loopbacks[sock].msgs[i].datamax = 0;
}
Z_Free(con);
}
static ftenet_generic_connection_t *FTENET_Loop_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr)
{
ftenet_generic_connection_t *newcon;
int sock;
for (sock = 0; sock < countof(loopbacks); sock++)
if (!loopbacks[sock].inited)
break;
if (sock == countof(loopbacks))
return NULL;
newcon = Z_Malloc(sizeof(*newcon));
if (newcon)
{
loopbacks[sock].inited = true;
loopbacks[sock].get = loopbacks[sock].send = 0;
newcon->GetLocalAddresses = FTENET_Loop_GetLocalAddresses;
newcon->GetPacket = FTENET_Loop_GetPacket;
newcon->SendPacket = FTENET_Loop_SendPacket;
newcon->Close = FTENET_Loop_Close;
#if defined(HAVE_PACKET) && !defined(HAVE_EPOLL)
newcon->SetFDSets = FTENET_Loop_SetFDSets;
#endif
newcon->islisten = col->islisten;
newcon->addrtype[0] = NA_LOOPBACK;
newcon->addrtype[1] = NA_INVALID;
newcon->thesocket = sock;
}
return newcon;
}
#endif
//=============================================================================
ftenet_connections_t *FTENET_CreateCollection(qboolean listen, void(*ReadPacket)(void))
{
ftenet_connections_t *col;
col = Z_Malloc(sizeof(*col));
col->islisten = listen;
col->ReadGamePacket = ReadPacket;
return col;
}
#if defined(HAVE_CLIENT) && defined(HAVE_SERVER)
static ftenet_generic_connection_t *FTENET_Loop_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr);
#endif
#ifdef HAVE_PACKET
ftenet_generic_connection_t *FTENET_Datagram_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr);
#endif
#ifdef TCPCONNECT
static ftenet_generic_connection_t *FTENET_TCP_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr);
#endif
#ifdef HAVE_WEBSOCKCL
static ftenet_generic_connection_t *FTENET_WebSocket_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr);
static ftenet_generic_connection_t *FTENET_WebRTC_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr);
#endif
#ifdef IRCCONNECT
static ftenet_generic_connection_t *FTENET_IRCConnect_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr);
#endif
#ifdef HAVE_NATPMP
static ftenet_generic_connection_t *FTENET_NATPMP_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr);
#endif
#ifdef HAVE_NATPMP
typedef struct
{
ftenet_generic_connection_t pub;
ftenet_connections_t *col;
netadr_t reqpmpaddr;
netadr_t pmpaddr;
netadr_t natadr;
unsigned int refreshtime;
} pmpcon_t;
int FTENET_NATPMP_GetLocalAddresses(struct ftenet_generic_connection_s *con, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses);
static qboolean NET_Was_NATPMP(ftenet_connections_t *collection)
{
pmpcon_t *pmp;
struct
{
qbyte ver; qbyte op; short resultcode;
int age;
union
{
struct
{
short privport; short pubport;
int mapping_expectancy;
};
qbyte ipv4[4];
};
} *pmpreqrep;
int i;
for (i = 0; i < MAX_CONNECTIONS; i++)
{
if (!collection->conn[i])
continue;
if (collection->conn[i]->GetLocalAddresses == FTENET_NATPMP_GetLocalAddresses)
{
pmp = (pmpcon_t*)collection->conn[i];
if (NET_CompareAdr(&pmp->pmpaddr, &net_from))
{
pmpreqrep = (void*)net_message.data;
if (pmpreqrep->ver != 0)
return false;
if (net_message.cursize == 12 && pmpreqrep->op == 128)
{
char adrbuf[256];
pmp->natadr.type = NA_IP;
pmp->natadr.port = 0;
memcpy(pmp->natadr.address.ip, pmpreqrep->ipv4, sizeof(pmp->natadr.address.ip));
NET_AdrToString(adrbuf, sizeof(adrbuf), &pmp->natadr);
pmp->natadr.connum = i+1;
Con_DPrintf("NAT-PMP: Public ip is %s\n", adrbuf);
#ifdef SUPPORT_ICE
if (pmp->natadr.type && pmp->natadr.port)
ICE_AddLCandidateConn(collection, &pmp->natadr, ICE_SRFLX); //let ICE connections know about it
#endif
return true;
}
if (net_message.cursize == 16 && pmpreqrep->op == 129)
{
switch(BigShort(pmpreqrep->resultcode))
{
case 0:
break;
case 1:
Con_Printf("NAT-PMP: unsupported version\n");
return true;
case 2:
Con_Printf("NAT-PMP: refused - please reconfigure router\n");
return true;
case 3:
Con_Printf("NAT-PMP: network failure\n");
return true;
case 4:
Con_Printf("NAT-PMP: out of resources\n");
return true;
case 5:
Con_Printf("NAT-PMP: unsupported opcode\n");
return true;
default:
return false;
}
Con_DPrintf("NAT-PMP: Local port %u publicly available on port %u\n", (unsigned short)BigShort(pmpreqrep->privport), (unsigned short)BigShort(pmpreqrep->pubport));
pmp->natadr.port = pmpreqrep->pubport;
#ifdef SUPPORT_ICE
if (pmp->natadr.type && pmp->natadr.port)
ICE_AddLCandidateConn(collection, &pmp->natadr, ICE_SRFLX);
#endif
return true;
}
return false;
}
}
}
return false;
}
static void FTENET_NATPMP_Refresh(pmpcon_t *pmp, short oldport, ftenet_connections_t *collection)
{
int i, m;
netadr_t adr;
netadr_t addr[64];
struct ftenet_generic_connection_s *con[sizeof(addr)/sizeof(addr[0])];
int flags[sizeof(addr)/sizeof(addr[0])];
const char *params[sizeof(addr)/sizeof(addr[0])];
struct
{
qbyte ver; qbyte op; short reserved1;
short privport; short pubport;
int mapping_expectancy;
} pmpreqmsg;
pmpreqmsg.ver = 0;
pmpreqmsg.op = 1;
pmpreqmsg.reserved1 = BigShort(0);
pmpreqmsg.privport = BigShort(0);
pmpreqmsg.pubport = BigShort(0);
pmpreqmsg.mapping_expectancy = BigLong(60*5);
if (!collection)
return;
m = NET_EnumerateAddresses(collection, con, flags, addr, params, sizeof(addr)/sizeof(addr[0]));
for (i = 0; i < m; i++)
{
//ignore any ips which are proxied by other people. that would be too weird.
if (flags[i] & (ADDR_NATPMP|ADDR_UPNPIGP))
continue;
adr = addr[i];
//unipv6ify it if its a hybrid socket.
if (adr.type == NA_IPV6 &&
!*(int*)&adr.address.ip6[0] &&
!*(int*)&adr.address.ip6[4] &&
!*(short*)&adr.address.ip6[8] &&
*(short*)&adr.address.ip6[10]==(short)0xffff &&
!*(int*)&adr.address.ip6[12])
{
*(int*)adr.address.ip = *(int*)&adr.address.ip6[12];
adr.type = NA_IP;
}
if (adr.type == NA_IP)
{
if (adr.address.ip[0] == 127) //yes. loopback has a lot of ip addresses. wasteful but whatever.
continue;
//assume a netmask of 255.255.255.0
adr.address.ip[3] = 1;
}
// else if (adr.type == NA_IPV6)
// {
// }
else
continue;
pmpreqmsg.privport = adr.port;
pmpreqmsg.pubport = oldport?oldport:adr.port;
if (*(int*)pmp->reqpmpaddr.address.ip == INADDR_ANY)
{
pmp->pmpaddr = adr;
pmp->pmpaddr.port = pmp->reqpmpaddr.port;
}
else
pmp->pmpaddr = pmp->reqpmpaddr;
if (*(int*)pmp->pmpaddr.address.ip == INADDR_ANY)
continue;
//get the public ip.
pmpreqmsg.op = 0;
NET_SendPacket(collection, 2, &pmpreqmsg, &pmp->pmpaddr);
//open the firewall/nat.
pmpreqmsg.op = 1;
NET_SendPacket(collection, sizeof(pmpreqmsg), &pmpreqmsg, &pmp->pmpaddr);
break;
}
}
#define PMP_POLL_TIME (1000*30)//every 30 seconds
qboolean Net_OpenUDPPort(char *privateip, int privateport, char *publicip, size_t publiciplen, int *publicport);
int FTENET_NATPMP_GetLocalAddresses(struct ftenet_generic_connection_s *con, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
pmpcon_t *pmp = (pmpcon_t*)con;
/*
char pubip[256];
int pubport;
if (Net_OpenUDPPort("192.168.1.4", 27500, pubip, sizeof(pubip), &pubport))
{
*adrflags = ADDR_UPNPIGP;
NET_StringToAdr(pubip, pubport, addresses);
return 1;
}
*/
if (maxaddresses)
{
*adrflags = ADDR_NATPMP;
*adrparams = NULL;
*addresses = pmp->natadr;
return (pmp->natadr.type != NA_INVALID) && (pmp->natadr.port != 0);
}
return 0;
}
qboolean FTENET_NATPMP_GetPacket(struct ftenet_generic_connection_s *con)
{
pmpcon_t *pmp = (pmpcon_t*)con;
unsigned int now = Sys_Milliseconds();
if (now - pmp->refreshtime > PMP_POLL_TIME) //weird logic to cope with wrapping
{
pmp->refreshtime = now;
FTENET_NATPMP_Refresh(pmp, pmp->natadr.port, pmp->col);
}
return false;
}
neterr_t FTENET_NATPMP_SendPacket(struct ftenet_generic_connection_s *con, int length, const void *data, netadr_t *to)
{
return NETERR_NOROUTE;
}
void FTENET_NATPMP_Close(struct ftenet_generic_connection_s *con)
{
//FIXME: we should send a packet to close the port
Z_Free(con);
}
//qboolean Net_OpenUDPPort(char *privateip, int privateport, char *publicip, size_t publiciplen, int *publicport);
ftenet_generic_connection_t *FTENET_NATPMP_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t pmpadr)
{
pmpcon_t *pmp;
if (pmpadr.prot == NP_NATPMP)
pmpadr.prot = NP_DGRAM;
if (pmpadr.type != NA_IP)
return NULL;
pmp = Z_Malloc(sizeof(*pmp));
pmp->col = svs.sockets;
Q_strncpyz(pmp->pub.name, "natpmp", sizeof(pmp->pub.name));
pmp->reqpmpaddr = pmpadr;
pmp->pub.GetLocalAddresses = FTENET_NATPMP_GetLocalAddresses;
pmp->pub.GetPacket = FTENET_NATPMP_GetPacket;
//qboolean (*ChangeLocalAddress)(struct ftenet_generic_connection_s *con, const char *newaddress);
pmp->pub.SendPacket = FTENET_NATPMP_SendPacket;
pmp->pub.Close = FTENET_NATPMP_Close;
pmp->pub.thesocket = INVALID_SOCKET;
pmp->refreshtime = Sys_Milliseconds() + PMP_POLL_TIME*64;
// Net_OpenUDPPort();
return &pmp->pub;
}
#endif
#ifdef HAVE_DTLS
struct dtlspeer_s
{
const dtlsfuncs_t *funcs;
ftenet_connections_t *col;
void *dtlsstate;
netadr_t addr;
float timeout;
struct dtlspeer_s *next;
struct dtlspeer_s **link;
};
void NET_DTLS_Timeouts(ftenet_connections_t *col)
{
struct dtlspeer_s *peer, **link;
if (!col)
return;
for (link = &col->dtls; (peer=*link); )
{
if (peer->timeout < realtime)
{
peer->funcs->DestroyContext(peer->dtlsstate);
*link = peer->next;
continue;
}
peer->funcs->Timeouts(peer->dtlsstate);
link = &peer->next;
}
}
const dtlsfuncs_t *DTLS_InitServer(void)
{
const dtlsfuncs_t *f = NULL;
int i;
const char *provname;
if (tls_provider.ival>0 && tls_provider.ival <= cryptolib_count && cryptolib[tls_provider.ival-1])
{
f = !cryptolib[tls_provider.ival-1]->DTLS_InitServer?NULL:cryptolib[tls_provider.ival-1]->DTLS_InitServer();
provname = cryptolib[tls_provider.ival-1]->drivername;
}
else for (i = 0; !f && i < cryptolib_count; i++)
{
if (cryptolib[i] && cryptolib[i]->DTLS_InitServer)
{
f = cryptolib[i]->DTLS_InitServer();
provname = cryptolib[i]->drivername;
if (!f)
Con_Printf("DTLS provider %s failed\n", cryptolib[i]->drivername);
}
}
if (f)
Con_DPrintf("Using DTLS provider %s\n", provname);
return f;
}
const dtlsfuncs_t *DTLS_InitClient(void)
{
const dtlsfuncs_t *f = NULL;
int i;
if (tls_provider.ival>0 && tls_provider.ival <= cryptolib_count && cryptolib[tls_provider.ival-1])
f = !cryptolib[tls_provider.ival-1]->DTLS_InitClient?NULL:cryptolib[tls_provider.ival-1]->DTLS_InitClient();
else for (i = 0; !f && i < cryptolib_count; i++)
{
if (cryptolib[i] && cryptolib[i]->DTLS_InitClient)
f = cryptolib[i]->DTLS_InitClient();
}
return f;
}
static neterr_t NET_SendPacketCol (ftenet_connections_t *collection, int length, const void *data, netadr_t *to);
static neterr_t FTENET_DTLS_DoSendPacket(void *cbctx, const qbyte *data, size_t length)
{ //callback that does the actual sending
struct dtlspeer_s *peer = cbctx;
return NET_SendPacketCol(peer->col, length, data, &peer->addr);
}
qboolean NET_DTLS_Create(ftenet_connections_t *col, netadr_t *to, const dtlscred_t *cred)
{
extern cvar_t timeout;
struct dtlspeer_s *peer;
if (to->prot != NP_DGRAM)
return false;
for (peer = col->dtls; peer; peer = peer->next)
{
if (NET_CompareAdr(&peer->addr, to))
break;
}
if (!peer)
{
peer = Z_Malloc(sizeof(*peer));
peer->addr = *to;
peer->col = col;
if (col->islisten)
peer->funcs = DTLS_InitServer();
else
peer->funcs = DTLS_InitClient();
if (peer->funcs)
peer->dtlsstate = peer->funcs->CreateContext(cred, peer, FTENET_DTLS_DoSendPacket, col->islisten);
peer->timeout = realtime+timeout.value;
if (peer->dtlsstate)
{
peer->link = &col->dtls;
peer->next = col->dtls;
if (peer->next)
peer->next->link = &peer->next;
col->dtls = peer;
}
else
{
Z_Free(peer);
peer = NULL;
}
}
return peer!=NULL;
}
#ifdef HAVE_SERVER
static void FTENET_DTLS_Established(void **ctx, void *state)
{
ftenet_connections_t *col;
struct dtlspeer_s *peer = Z_Malloc(sizeof(*peer));
memcpy(peer, *ctx, sizeof(*peer));
*ctx = peer;
col = peer->col;
peer->dtlsstate = state;
peer->timeout = realtime+timeout.value;
peer->link = &col->dtls;
peer->next = col->dtls;
if (peer->next)
peer->next->link = &peer->next;
col->dtls = peer;
}
qboolean NET_DTLS_CheckInbound(ftenet_connections_t *col)
{
extern cvar_t timeout, net_enable_dtls;
struct dtlspeer_s *peer;
netadr_t *from = &net_from;
if (from->prot != NP_DGRAM || !net_enable_dtls.ival || !col->dtlsfuncs)
return false;
if (!net_message.cursize || !(20 <= net_message.data[0] && net_message.data[0] <= 63))
return false; //lead byte must be between 20 and 63 to be valid dtls.
for (peer = col->dtls; peer; peer = peer->next)
{
if (NET_CompareAdr(&peer->addr, from))
break;
}
if (!peer)
{
if (col->dtlsfuncs->CheckConnection)
{
struct dtlspeer_s peer;
//fill it with preliminary info
peer.addr = *from;
peer.col = col;
peer.funcs = col->dtlsfuncs;
return col->dtlsfuncs->CheckConnection(&peer, from, sizeof(*from), net_message.data, net_message.cursize, FTENET_DTLS_DoSendPacket, FTENET_DTLS_Established);
}
}
return false;
}
#endif
static void NET_DTLS_DisconnectPeer(ftenet_connections_t *col, struct dtlspeer_s *peer)
{
// Sys_Printf("Destroy %p\n", peer->dtlsstate);
if (peer->next)
peer->next->link = peer->link;
*peer->link = peer->next;
peer->funcs->DestroyContext(peer->dtlsstate);
Z_Free(peer);
}
qboolean NET_DTLS_Disconnect(ftenet_connections_t *col, netadr_t *to)
{
struct dtlspeer_s *peer;
netadr_t n = *to;
if (!col || (to->prot != NP_DGRAM && to->prot != NP_DTLS))
return false;
n.prot = NP_DGRAM;
for (peer = col->dtls; peer; peer = peer->next)
{
if (NET_CompareAdr(&peer->addr, &n))
{
NET_DTLS_DisconnectPeer(col, peer);
break;
}
}
return peer?true:false;
}
static neterr_t FTENET_DTLS_SendPacket(ftenet_connections_t *col, int length, const void *data, netadr_t *to)
{
struct dtlspeer_s *peer;
to->prot = NP_DGRAM;
for (peer = col->dtls; peer; peer = peer->next)
{
if (NET_CompareAdr(&peer->addr, to))
break;
}
to->prot = NP_DTLS;
if (peer)
return peer->funcs->Transmit(peer->dtlsstate, data, length);
else
return NETERR_NOROUTE;
}
qboolean NET_DTLS_Decode(ftenet_connections_t *col)
{
extern cvar_t timeout;
struct dtlspeer_s *peer;
for (peer = col->dtls; peer; peer = peer->next)
{
if (NET_CompareAdr(&peer->addr, &net_from))
{
peer->timeout = realtime+timeout.value; //refresh the timeout if our peer is still alive.
switch(peer->funcs->Received(peer->dtlsstate, &net_message))
{
case NETERR_DISCONNECTED:
NET_DTLS_DisconnectPeer(col, peer);
net_message.cursize = 0;
break;
case NETERR_NOROUTE:
return false; //not a valid dtls packet.
default:
case NETERR_CLOGGED:
//ate it
net_message.cursize = 0;
break;
case NETERR_SENT:
//we decoded it properly
net_from.prot = NP_DTLS;
break;
}
net_from.prot = NP_DTLS;
return true;
}
}
return false;
}
#endif
size_t NET_GetConnectionCertificate(struct ftenet_connections_s *col, netadr_t *a, enum certprops_e prop, char *out, size_t outsize)
{
if (!col)
return 0;
switch(prop)
{
default:
break;
case QCERT_PEERFINGERPRINT:
#if 0//def HAVE_DTLS
if (a->prot == NP_DTLS)
{
struct dtlspeer_s *peer;
{
a->prot = NP_DGRAM;
for (peer = col->dtls; peer; peer = peer->next)
{
if (NET_CompareAdr(&peer->addr, a))
break;
}
a->prot = NP_DTLS;
}
if (peer)
return peer->funcs->GetPeerCertificate(peer->dtlsstate, data, length);
}
#endif
return 0;
}
return 0;
}
static qboolean FTENET_AddToCollection_Ptr(ftenet_connections_t *col, const char *name, ftenet_generic_connection_t *(*establish)(ftenet_connections_t *col, const char *address, netadr_t adr), const char *address, netadr_t *adr)
{
int count = 0;
int i;
if (!col)
return false;
if (name)
{
for (i = 0; i < MAX_CONNECTIONS; i++)
{
if (col->conn[i])
if (*col->conn[i]->name && !strcmp(col->conn[i]->name, name))
{
if (adr && (adr->type != NA_INVALID||adr->prot != NP_INVALID) && col->islisten)
if (col->conn[i]->ChangeLocalAddress)
{
if (col->conn[i]->ChangeLocalAddress(col->conn[i], address, adr))
return true;
}
col->conn[i]->Close(col->conn[i]);
col->conn[i] = NULL;
}
}
}
if (adr && establish)
{
for (i = 0; i < MAX_CONNECTIONS; i++)
{
if (!col->conn[i])
{
col->conn[i] = establish(col, address, *adr);
if (!col->conn[i])
break;
col->conn[i]->connum = i+1;
if (name)
Q_strncpyz(col->conn[i]->name, name, sizeof(col->conn[i]->name));
count++;
break;
}
}
}
return count > 0;
}
qboolean FTENET_AddToCollection(ftenet_connections_t *col, const char *name, const char *addresslist, netadrtype_t addrtype, netproto_t addrprot)
{
netadr_t adr[8];
ftenet_generic_connection_t *(*establish[countof(adr)])(ftenet_connections_t *col, const char *address, netadr_t adr);
char address[countof(adr)][256];
unsigned int i, j;
qboolean success = false;
if (!col)
return false;
if (name && strchr(name, ':'))
return false;
for (i = 0; addresslist && *addresslist && i < countof(adr); i++)
{
addresslist = COM_ParseStringSet(addresslist, address[i], sizeof(address[i]));
//resolve the address to something sane so we can determine the address type and thus the connection type to use
if (!*address[i])
adr[i].type = NA_INVALID, adr[i].prot = NP_INVALID;
else //if (islisten)
{
if (!NET_PortToAdr(addrtype, addrprot, address[i], &adr[i]))
return false;
}
#ifdef HAVE_WEBSOCKCL
if (adr[i].prot == NP_WS && adr[i].type == NA_WEBSOCKET) establish[i] = FTENET_WebSocket_EstablishConnection; else
if (adr[i].prot == NP_WSS && adr[i].type == NA_WEBSOCKET) establish[i] = FTENET_WebSocket_EstablishConnection; else
if (adr[i].prot == NP_RTC_TCP) establish[i] = FTENET_WebRTC_EstablishConnection; else
if (adr[i].prot == NP_RTC_TLS) establish[i] = FTENET_WebRTC_EstablishConnection; else
#endif
#ifdef HAVE_NATPMP
if (adr[i].prot == NP_NATPMP&& adr[i].type == NA_IP) establish[i] = FTENET_NATPMP_EstablishConnection; else
#endif
#if defined(HAVE_CLIENT) && defined(HAVE_SERVER)
if (adr[i].prot == NP_DGRAM && adr[i].type == NA_LOOPBACK) establish[i] = FTENET_Loop_EstablishConnection; else
#endif
#ifdef HAVE_IPV4
if ((adr[i].prot == NP_DGRAM) && adr[i].type == NA_IP) establish[i] = FTENET_Datagram_EstablishConnection; else
#endif
#ifdef HAVE_IPV6
if ((adr[i].prot == NP_DGRAM) && adr[i].type == NA_IPV6) establish[i] = FTENET_Datagram_EstablishConnection; else
#endif
#ifdef HAVE_IPX
if (adr[i].prot == NP_DGRAM && adr[i].type == NA_IPX) establish[i] = FTENET_Datagram_EstablishConnection; else
#endif
#ifdef UNIXSOCKETS
if (adr[i].prot == NP_DGRAM && adr[i].type == NA_UNIX) establish[i] = FTENET_Datagram_EstablishConnection; else
#if defined(TCPCONNECT)
if (adr[i].prot == NP_STREAM&& adr[i].type == NA_UNIX) establish[i] = FTENET_TCP_EstablishConnection; else
if (adr[i].prot == NP_WS && adr[i].type == NA_UNIX) establish[i] = FTENET_TCP_EstablishConnection; else
if (adr[i].prot == NP_TLS && adr[i].type == NA_UNIX) establish[i] = FTENET_TCP_EstablishConnection; else
#endif
#endif
#if defined(TCPCONNECT) && defined(HAVE_IPV4)
if (adr[i].prot == NP_WS && adr[i].type == NA_IP) establish[i] = FTENET_TCP_EstablishConnection; else
if (adr[i].prot == NP_STREAM&& adr[i].type == NA_IP) establish[i] = FTENET_TCP_EstablishConnection; else
if (adr[i].prot == NP_TLS && adr[i].type == NA_IP) establish[i] = FTENET_TCP_EstablishConnection; else
#endif
#if defined(TCPCONNECT) && defined(HAVE_IPV6)
if (adr[i].prot == NP_WS && adr[i].type == NA_IPV6) establish[i] = FTENET_TCP_EstablishConnection; else
if (adr[i].prot == NP_STREAM&& adr[i].type == NA_IPV6) establish[i] = FTENET_TCP_EstablishConnection; else
if (adr[i].prot == NP_TLS && adr[i].type == NA_IPV6) establish[i] = FTENET_TCP_EstablishConnection; else
#endif
#ifdef SUPPORT_ICE
if (adr[i].prot == NP_RTC_TCP) establish[i] = FTENET_ICE_EstablishConnection; else
if (adr[i].prot == NP_RTC_TLS) establish[i] = FTENET_ICE_EstablishConnection; else
#endif
#ifdef IRCCONNECT
if (adr[i].prot == NP_TLS) establish[i] = FTENET_IRCConnect_EstablishConnection; else
#endif
establish[i] = NULL;
}
if (i == 1)
{
success |= FTENET_AddToCollection_Ptr(col, name, establish[0], address[0], &adr[0]);
i = 0;
}
else
success |= FTENET_AddToCollection_Ptr(col, name, NULL, NULL, NULL);
for (j = 0; j < i; j++)
success |= FTENET_AddToCollection_Ptr(col, va("%s:%i", name, j), establish[j], address[j], &adr[j]);
for (; j < countof(adr); j++)
success |= FTENET_AddToCollection_Ptr(col, va("%s:%i", name, j), NULL, NULL, NULL);
return success;
}
void FTENET_CloseCollection(ftenet_connections_t *col)
{
int i;
if (!col)
return;
for (i = 0; i < MAX_CONNECTIONS; i++)
{
if (col->conn[i])
{
col->conn[i]->Close(col->conn[i]);
col->conn[i] = NULL;
}
}
Z_Free(col);
}
#if defined(_WIN32) && defined(HAVE_PACKET)
int FTENET_GetLocalAddress(int port, qboolean ipx, qboolean ipv4, qboolean ipv6, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
//in win32, we can look up our own hostname to retrieve a list of local interface addresses.
char adrs[MAX_ADR_SIZE];
int found = 0;
gethostname(adrs, sizeof(adrs));
#ifndef pgetaddrinfo
if (!pgetaddrinfo)
{
struct hostent *h = gethostbyname(adrs);
int b = 0;
#ifdef HAVE_IPV4
if(h && h->h_addrtype == AF_INET)
{
for (b = 0; h->h_addr_list[b] && maxaddresses; b++)
{
struct sockaddr_in from;
from.sin_family = AF_INET;
from.sin_port = port;
memcpy(&from.sin_addr, h->h_addr_list[b], sizeof(from.sin_addr));
SockadrToNetadr((struct sockaddr_qstorage*)&from, sizeof(from), addresses);
*adrflags++ = 0;
*adrparams++ = NULL;
addresses++;
maxaddresses--;
found++;
}
}
#endif
#ifdef HAVE_IPV6
if(h && h->h_addrtype == AF_INET6)
{
for (b = 0; h->h_addr_list[b] && maxaddresses; b++)
{
struct sockaddr_in6 from;
from.sin6_family = AF_INET6;
from.sin6_port = port;
from.sin6_scope_id = 0;
memcpy(&from.sin6_addr, h->h_addr_list[b], sizeof(((struct sockaddr_in6*)&from)->sin6_addr));
SockadrToNetadr((struct sockaddr_qstorage*)&from, sizeof(from), addresses);
*adrflags++ = 0;
*adrparams++ = NULL;
addresses++;
maxaddresses--;
found++;
}
}
#endif
}
else
#endif
{
struct addrinfo hints, *result, *itr;
memset(&hints, 0, sizeof(struct addrinfo));
hints.ai_family = 0; /* Allow IPv4 or IPv6 */
hints.ai_socktype = SOCK_DGRAM; /* Datagram socket */
hints.ai_flags = 0;
hints.ai_protocol = 0; /* Any protocol */
if (pgetaddrinfo(adrs, NULL, &hints, &result) == 0)
{
for (itr = result; itr; itr = itr->ai_next)
{
if (0
#ifdef HAVE_IPV4
|| (itr->ai_addr->sa_family == AF_INET && ipv4)
#endif
#ifdef HAVE_IPV6
|| (itr->ai_addr->sa_family == AF_INET6 && ipv6)
#endif
#ifdef HAVE_IPX
|| (itr->ai_addr->sa_family == AF_IPX && ipx)
#endif
)
if (maxaddresses)
{
SockadrToNetadr((struct sockaddr_qstorage*)itr->ai_addr, sizeof(struct sockaddr_qstorage), addresses);
addresses->port = port;
*adrflags++ = 0;
*adrparams++ = NULL;
addresses++;
maxaddresses--;
found++;
}
}
freeaddrinfo(result);
/*if none found, fill in the 0.0.0.0 or whatever*/
if (!found && maxaddresses)
{
memset(addresses, 0, sizeof(*addresses));
addresses->port = port;
if (ipv6)
addresses->type = NA_IPV6;
else if (ipv4)
addresses->type = NA_IP;
else if (ipx)
addresses->type = NA_IPX;
else
addresses->type = NA_INVALID;
*adrflags++ = 0;
*adrparams++ = NULL;
addresses++;
maxaddresses--;
found++;
}
}
}
return found;
}
#elif defined(__linux__) && !defined(ANDROID)
//in linux, looking up our own hostname to retrieve a list of local interface addresses will give no indication that other systems are able to do the same thing and is thus not supported.
//there's some special api instead
//glibc 2.3.
//also available with certain bsds, I'm but unsure which preprocessor we can use.
#include <ifaddrs.h>
static struct ifaddrs *iflist;
unsigned int iftime; //requery sometimes.
int FTENET_GetLocalAddress(int port, qboolean ipx, qboolean ipv4, qboolean ipv6, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
struct ifaddrs *ifa;
int fam;
int idx = 0;
unsigned int time = Sys_Milliseconds();
ipv4 = ipv4 && net_dns_ipv4.ival;
ipv6 = ipv6 && net_dns_ipv6.ival;
if (time - iftime > 1000 && iflist)
{
freeifaddrs(iflist);
iflist = NULL;
}
if (!iflist)
{
iftime = time;
getifaddrs(&iflist);
}
for (ifa = iflist; ifa && idx < maxaddresses; ifa = ifa->ifa_next)
{
//can happen if the interface is not bound.
if (ifa->ifa_addr == NULL)
continue;
//filter out families that we're not interested in.
fam = ifa->ifa_addr->sa_family;
if (
#ifdef HAVE_IPV4
(fam == AF_INET && ipv4) ||
#endif
#ifdef HAVE_IPV6
(fam == AF_INET6 && ipv6) ||
#endif
#ifdef HAVE_IPX
(fam == AF_IPX && ipx) ||
#endif
0)
{
SockadrToNetadr((struct sockaddr_qstorage*)ifa->ifa_addr, sizeof(struct sockaddr_qstorage), &addresses[idx]);
addresses[idx].port = port;
adrflags[idx] = 0;
adrparams[idx] = NULL;
idx++;
}
}
return idx;
}
#else
int FTENET_GetLocalAddress(int port, qboolean ipx, qboolean ipv4, qboolean ipv6, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
return 0;
}
#endif
int FTENET_Generic_GetLocalAddresses(struct ftenet_generic_connection_s *con, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
#ifndef HAVE_PACKET
return 0;
#else
struct sockaddr_qstorage from;
int fromsize = sizeof(from);
netadr_t adr;
int found = 0;
if (getsockname (con->thesocket, (struct sockaddr*)&from, &fromsize) != -1)
{
memset(&adr, 0, sizeof(adr));
SockadrToNetadr(&from, fromsize, &adr);
#ifdef USE_GETHOSTNAME_LOCALLISTING
//if its bound to 'any' address, ask the system what addresses it actually accepts.
if ((adr.type == NA_IPV6) &&
!*(int*)&adr.address.ip6[0] &&
!*(int*)&adr.address.ip6[4] &&
!*(short*)&adr.address.ip6[8] &&
*(short*)&adr.address.ip6[10]==(short)0xffff &&
!*(int*)&adr.address.ip6[12])
{
//ipv6 socket bound to the ipv4-any address is a bit weird, but oh well.
#ifdef _WIN32
//win32 is buggy and treats binding to [::] as [::ffff:0.0.0.0] (even with pure ipv6 sockets)
//explicitly binding to [::ffff:0.0.0.0] appears to fail in windows, thus any such socket will definitely support ipv6.
qboolean canipv4 = (con->addrtype[0] == NA_IP) || (con->addrtype[1] == NA_IP);
found = FTENET_GetLocalAddress(adr.port, false, canipv4, true, adrflags, addresses, adrparams, maxaddresses);
#else
//FIXME: we should validate that we support hybrid sockets?
found = FTENET_GetLocalAddress(adr.port, false, true, false, adrflags, addresses, adrparams, maxaddresses);
#endif
}
else
{
int b;
for (b = 0; b < sizeof(adr.address); b++)
if (((unsigned char*)&adr.address)[b] != 0)
break;
if (b == sizeof(adr.address))
{
qboolean ipx=false, ipv4=false, ipv6=false;
if (adr.type == NA_IP)
ipv4 = true;
else if (adr.type == NA_IPX)
ipx = true;
else if (adr.type == NA_IPV6)
{
ipv4 = (con->addrtype[0] == NA_IP) || (con->addrtype[1] == NA_IP);
ipv6 = true;
}
found = FTENET_GetLocalAddress(adr.port, ipx, ipv4, ipv6, adrflags, addresses, adrparams, maxaddresses);
}
}
#endif
//and use the bound address (even if its 0.0.0.0) if we didn't grab a list from the system.
if (!found)
{
if (maxaddresses && adr.type == NA_IPV6 &&
!*(int*)&adr.address.ip6[0] &&
!*(int*)&adr.address.ip6[4] &&
!*(int*)&adr.address.ip6[8] &&
!*(int*)&adr.address.ip6[12])
{
*addresses = adr;
addresses->type = NA_IP;
*adrflags++ = 0;
*adrparams++ = NULL;
addresses++;
maxaddresses--;
found++;
}
if (maxaddresses)
{
*addresses = adr;
*adrflags++ = 0;
*adrparams++ = NULL;
addresses++;
maxaddresses--;
found++;
}
}
}
return found;
#endif
}
qboolean FTENET_Datagram_GetPacket(ftenet_generic_connection_t *con)
{
#ifndef HAVE_PACKET
return false;
#else
struct sockaddr_qstorage from;
int fromlen;
int ret;
int err;
char adr[MAX_ADR_SIZE];
if (con->thesocket == INVALID_SOCKET)
return false;
fromlen = sizeof(from);
((struct sockaddr*)&from)->sa_family = AF_UNSPEC;
ret = recvfrom (con->thesocket, (char *)net_message_buffer, sizeof(net_message_buffer), 0, (struct sockaddr*)&from, &fromlen);
if (ret == -1)
{
err = neterrno();
if (err == NET_EWOULDBLOCK)
return false;
if (err == NET_EMSGSIZE)
{
static unsigned int resettime;
unsigned int curtime = Sys_Milliseconds();
if (curtime-resettime >= 5000) //throttle prints to once per 5 secs (even if they're about different clients, yay ddos)
{
SockadrToNetadr (&from, fromlen, &net_from);
Con_TPrintf ("Warning: Oversize packet from %s\n",
NET_AdrToString (adr, sizeof(adr), &net_from));
}
return false;
}
if (err == NET_ECONNABORTED || err == NET_ECONNRESET)
{
static unsigned int resettime;
unsigned int curtime = Sys_Milliseconds();
if (curtime-resettime >= 5000 || err == NET_ECONNRESET) //throttle prints to once per 5 secs (even if they're about different clients, yay ddos)
{
if (((struct sockaddr*)&from)->sa_family != AF_UNSPEC)
{
SockadrToNetadr (&from, fromlen, &net_from);
Con_TPrintf ("Connection lost or aborted (%s)\n", NET_AdrToString (adr, sizeof(adr), &net_from)); //server died/connection lost.
}
else
Con_TPrintf ("Connection lost or aborted\n"); //server died/connection lost.
resettime = curtime;
#ifdef HAVE_CLIENT
//fixme: synthesise a reset packet for the caller to handle? "\xff\xff\xff\xffreset" ?
if (cls.state != ca_disconnected && !con->islisten)
{
if (cls.lastarbiatarypackettime+5 < Sys_DoubleTime()) //too many mvdsv
Cbuf_AddText("disconnect\nreconnect\n", RESTRICT_LOCAL); //retry connecting.
else
Con_Printf("Packet was not delivered - server might be badly configured\n");
return false;
}
#endif
}
return false;
}
if (((struct sockaddr*)&from)->sa_family != AF_UNSPEC)
Con_Printf ("NET_GetPacket: Error (%i): %s (%s)\n", err, strerror(err), NET_AdrToString (adr, sizeof(adr), &net_from));
else
Con_Printf ("NET_GetPacket: Error (%i): %s\n", err, strerror(err));
return false;
}
SockadrToNetadr (&from, fromlen, &net_from);
if (net_from.type == NA_INVALID)
{ //this really shouldn't happen. Blame the OS.
Con_TPrintf ("Warning: sender's address type not known (%i)\n", (int)((struct sockaddr*)&from)->sa_family);
return false; //packet from an unsupported protocol? no way can we respond, so what's the point
}
net_message.packing = SZ_RAWBYTES;
net_message.currentbit = 0;
net_message.cursize = ret;
if (net_message.cursize >= sizeof(net_message_buffer) )
{
Con_TPrintf ("Warning: Oversize packet from %s\n", NET_AdrToString (adr, sizeof(adr), &net_from));
return false;
}
return true;
#endif
}
neterr_t FTENET_Datagram_SendPacket(ftenet_generic_connection_t *con, int length, const void *data, netadr_t *to)
{
#ifndef HAVE_PACKET
return NETERR_DISCONNECTED;
#else
struct sockaddr_qstorage addr;
int size;
int ret;
if (to->prot != NP_DGRAM)
return NETERR_NOROUTE;
for (size = 0; size < FTENET_ADDRTYPES; size++)
if (to->type == con->addrtype[size])
break;
if (size == FTENET_ADDRTYPES)
return NETERR_NOROUTE;
#ifdef HAVE_IPV6
/*special code to handle sending to hybrid sockets*/
if (con->addrtype[1] == NA_IPV6 && to->type == NA_IP)
{
memset(&addr, 0, sizeof(struct sockaddr_in6));
((struct sockaddr_in6*)&addr)->sin6_family = AF_INET6;
*(short*)&((struct sockaddr_in6*)&addr)->sin6_addr.s6_addr[10] = 0xffff;
*(int*)&((struct sockaddr_in6*)&addr)->sin6_addr.s6_addr[12] = *(int*)&to->address.ip;
((struct sockaddr_in6*)&addr)->sin6_port = to->port;
size = sizeof(struct sockaddr_in6);
}
else
#endif
{
size = NetadrToSockadr (to, &addr);
}
if (!data)
ret = 0; //don't send a runt, but pretend we did... yes, this'll confuse EnsureRoute, but at least it'll ensure there's a udp socket open, somewhere.
else
ret = sendto (con->thesocket, data, length, 0, (struct sockaddr*)&addr, size );
if (ret == -1)
{
int ecode = neterrno();
// wouldblock is silent
if (ecode == NET_EWOULDBLOCK)
return NETERR_CLOGGED;
if (ecode == NET_ECONNREFUSED)
return NETERR_DISCONNECTED;
if (ecode == NET_EMSGSIZE)
return NETERR_MTU;
if (ecode == NET_EADDRNOTAVAIL)
return NETERR_NOROUTE; //this interface doesn't actually support that (eg: happens when ipv6 is disabled on a specific interface).
if (ecode == NET_EACCES)
{
Con_Printf("Access denied: check firewall\n");
return NETERR_DISCONNECTED;
}
{
char adr[256];
if (ecode==NET_ENETUNREACH&&to->type==NA_IPV6) //ipv6 support STILL sucks too much. don't spam non-developers, its just annoying.
Con_DPrintf("NET_SendPacket(%s) Warning: %i\n", NET_AdrToString (adr, sizeof(adr), to), ecode);
#ifdef HAVE_CLIENT
else if (ecode == NET_EADDRNOTAVAIL || (ecode==NET_ENETUNREACH&&to->type==NA_IPV6))
Con_DPrintf("NET_SendPacket(%s) Warning: %i\n", NET_AdrToString (adr, sizeof(adr), to), ecode);
else
#endif
{
#ifdef _WIN32
Con_Printf ("NET_SendPacket(%s) ERROR: %i\n", NET_AdrToString (adr, sizeof(adr), to), ecode);
#else
Con_Printf ("NET_SendPacket(%s) ERROR: %s\n", NET_AdrToString (adr, sizeof(adr), to), strerror(ecode));
#endif
}
}
}
else if (ret < length)
return NETERR_MTU;
return NETERR_SENT;
#endif
}
qboolean NET_PortToAdr (netadrtype_t adrfamily, netproto_t adrprot, const char *s, netadr_t *a)
{
char *e;
if (net_enabled.ival || adrfamily == NA_LOOPBACK)
{
int port = strtoul(s, &e, 10);
if (*e) //if *e then its not just a single number in there, so treat it as a proper address.
return NET_StringToAdr(s, 0, a);
else if (e != s) //if we actually read something (even a 0)
{
memset(a, 0, sizeof(*a));
a->port = htons((unsigned short)port);
a->type = adrfamily;
a->prot = adrprot;
return a->type != NA_INVALID;
}
}
a->type = NA_INVALID;
return false;
}
#ifdef HAVE_PACKET
/*just here to prevent the client from spamming new sockets, which can be a problem with certain q2 servers*/
static qboolean FTENET_Datagram_ChangeLocalAddress(struct ftenet_generic_connection_s *con, const char *addressstring, netadr_t *adr)
{
struct sockaddr_qstorage address;
netadr_t current;
int namelen = sizeof(address);
if (getsockname (con->thesocket, (struct sockaddr *)&address, &namelen) == 0)
{
SockadrToNetadr(&address, namelen, &current);
//make sure the types match (special check for ipv6 hybrid sockets that accept ipv4 too)
if (adr->type == current.type
#if defined(HAVE_IPV4) && defined(HAVE_IPV6)
|| (net_hybriddualstack.ival && adr->type == NA_IP && current.type == NA_IPV6)
#endif
)
{ //make sure the port is currect (or they don't care which port)
if (adr->port == current.port || !adr->port)
return true; //then pretend we changed it, because needed to change in the first place.
}
}
//doesn't match how its currently bound, so I guess we need to rebind then.
return false;
}
static void FTENET_Datagram_Close(ftenet_generic_connection_t *con)
{
if (con->thesocket != INVALID_SOCKET)
{
#ifdef HAVE_EPOLL
epoll_ctl(epoll_fd, EPOLL_CTL_DEL, con->thesocket, NULL);
#endif
closesocket(con->thesocket);
}
Z_Free(con);
}
#endif
#ifdef HAVE_EPOLL
static void FTENET_Datagram_Polled(epollctx_t *ctx, unsigned int events)
{
ftenet_generic_connection_t *con = NULL;
con = (ftenet_generic_connection_t *)((qbyte*)ctx - ((qbyte*)&con->epoll-(qbyte*)con));
while (FTENET_Datagram_GetPacket(con))
{
net_from.connum = con->connum;
net_from_connection = con;
con->owner->ReadGamePacket();
}
}
#endif
ftenet_generic_connection_t *FTENET_Datagram_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr)
{
#ifndef HAVE_PACKET
return NULL;
#else
//this is written to support either ipv4 or ipv6, depending on the remote addr.
ftenet_generic_connection_t *newcon;
qboolean isserver = col->islisten;
unsigned long _true = true;
SOCKET newsocket = INVALID_SOCKET;
int temp;
struct sockaddr_qstorage qs;
int family;
int port;
int bindtries;
const int bindmaxtries = 100;
int bufsz;
qboolean hybrid = false;
int protocol;
char addrstr[128];
switch(adr.type)
{
#if defined(HAVE_IPV4) || defined(HAVE_IPV6)
case NA_IP:
case NA_IPV6:
protocol = IPPROTO_UDP;
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
protocol = NSPROTO_IPX;
break;
#endif
default:
protocol = 0;
break;
}
if (adr.type == NA_INVALID)
{
Con_Printf(CON_ERROR "unable to resolve local address %s\n", address);
return NULL; //couldn't resolve the name
}
temp = NetadrToSockadr(&adr, &qs);
family = ((struct sockaddr*)&qs)->sa_family;
#if defined(HAVE_IPV6) && defined(IPV6_V6ONLY)
if (/*isserver &&*/ family == AF_INET && net_hybriddualstack.ival && !((struct sockaddr_in*)&qs)->sin_addr.s_addr)
{
unsigned long _false = false;
if ((newsocket = socket (AF_INET6, SOCK_CLOEXEC|SOCK_DGRAM, protocol)) != INVALID_SOCKET)
{
if (0 == setsockopt(newsocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_false, sizeof(_false)))
{
// int ip = ((struct sockaddr_in*)&qs)->sin_addr.s_addr;
int port = ((struct sockaddr_in*)&qs)->sin_port;
// ip = ((struct sockaddr_in*)&qs)->sin_addr.s_addr;
memset(&qs, 0, sizeof(struct sockaddr_in6));
((struct sockaddr_in6*)&qs)->sin6_family = AF_INET6;
/*
if (((struct sockaddr_in*)&qs)->sin_addr.s_addr)
{
((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[10] = 0xff;
((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[11] = 0xff;
((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[12] = ((qbyte*)&ip)[0];
((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[13] = ((qbyte*)&ip)[1];
((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[14] = ((qbyte*)&ip)[2];
((struct sockaddr_in6*)&qs)->sin6_addr.s6_addr[15] = ((qbyte*)&ip)[3];
}
*/
((struct sockaddr_in6*)&qs)->sin6_port = port;
temp = sizeof(struct sockaddr_in6);
adr.type = NA_IPV6;
hybrid = true;
}
else
{
/*v6only failed... if the option doesn't exist, chances are this is a hybrid system which doesn't support both simultaneously anyway*/
closesocket(newsocket);
newsocket = INVALID_SOCKET;
}
}
}
#endif
if (newsocket == INVALID_SOCKET)
if ((newsocket = socket (family, SOCK_CLOEXEC|SOCK_DGRAM, protocol)) == INVALID_SOCKET)
{
return NULL;
}
#if defined(HAVE_IPV6) && defined(IPV6_V6ONLY)
if (family == AF_INET6)
setsockopt(newsocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_true, sizeof(_true));
#endif
#if defined(_WIN32) && defined(SO_EXCLUSIVEADDRUSE)
//win32 is so fucked up
setsockopt(newsocket, SOL_SOCKET, SO_EXCLUSIVEADDRUSE, (char *)&_true, sizeof(_true));
#endif
bufsz = 1<<18;
setsockopt(newsocket, SOL_SOCKET, SO_RCVBUF, (void*)&bufsz, sizeof(bufsz));
switch(family)
{
#ifdef UNIXSOCKETS
case AF_UNIX:
{
struct sockaddr_un *sa = (struct sockaddr_un *)&qs;
if (!isserver)
temp = (char*)&sa->sun_path[0] - (char*)sa; //linux-specific: bind to an automatic abstract address.
if (*sa->sun_path && isserver)
{ //non-abstract sockets don't clean up the filesystem when the socket is closed
//and we can't re-bind to it while it still exists.
//so standard practise is to delete it before the bind.
//we do want to make sure the file is actually a socket before we remove it (so people can't abuse stuffcmds)
//FIXME: use lock-files
struct stat s;
if (stat(sa->sun_path, &s)!=-1)
{
if ((s.st_mode & S_IFMT) == S_IFSOCK)
unlink(sa->sun_path);
}
}
if (bind(newsocket, (struct sockaddr *)sa, temp) == INVALID_SOCKET)
{
// perror("gah");
SockadrToNetadr(&qs, temp, &adr);
NET_AdrToString(addrstr, sizeof(addrstr), &adr);
Con_Printf(CON_ERROR "Unable to bind to %s\n", addrstr);
closesocket(newsocket);
return NULL;
}
}
break;
#endif
// case AF_INET:
// case AF_INET6:
// case AF_IPX:
default:
//try and find an unused port.
port = ntohs(((struct sockaddr_in*)&qs)->sin_port);
for (bindtries = 0; bindtries < bindmaxtries; bindtries++)
{
((struct sockaddr_in*)&qs)->sin_port = htons((unsigned short)(port+bindtries));
if ((bind(newsocket, (struct sockaddr *)&qs, temp) == INVALID_SOCKET))
{
if (port == 0)
{ //if binding to an ephemerial port failed, binding to the admin-only ports won't work any better...
bindtries = bindmaxtries;
break;
}
continue;
}
break;
}
if (bindtries == bindmaxtries)
{
SockadrToNetadr(&qs, temp, &adr);
NET_AdrToString(addrstr, sizeof(addrstr), &adr);
Con_Printf(CON_ERROR "Unable to listen at %s\n", addrstr);
closesocket(newsocket);
return NULL;
}
else if (bindtries && isserver)
{
SockadrToNetadr(&qs, temp, &adr);
NET_AdrToString(addrstr, sizeof(addrstr), &adr);
if (SSV_IsSubServer())
Con_DLPrintf(2, CON_ERROR "Unable to bind to port %i, bound to %s instead\n", port, addrstr);
else
Con_Printf(CON_ERROR "Unable to bind to port %i, bound to %s instead\n", port, addrstr);
}
break;
}
if (ioctlsocket (newsocket, FIONBIO, &_true) == -1)
Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(neterrno()));
//ipv6 sockets need to add themselves to a multicast group, so that we can receive broadcasts on a lan
#if defined(HAVE_IPV6)
if (family == AF_INET6 || hybrid || isserver)
{
struct ipv6_mreq req;
memset(&req, 0, sizeof(req));
req.ipv6mr_multiaddr.s6_addr[0] = 0xff;
req.ipv6mr_multiaddr.s6_addr[1] = 0x02;
req.ipv6mr_multiaddr.s6_addr[15]= 0x01;
req.ipv6mr_interface = 0;
setsockopt(newsocket, IPPROTO_IPV6, IPV6_JOIN_GROUP, (char *)&req, sizeof(req));
}
#endif
//
// determine my name & address if we don't already know it
//
if (!isserver && net_local_cl_ipadr.type == NA_INVALID)
NET_GetLocalAddress (newsocket, &net_local_cl_ipadr);
newcon = Z_Malloc(sizeof(*newcon));
if (newcon)
{
newcon->GetLocalAddresses = FTENET_Generic_GetLocalAddresses;
newcon->GetPacket = FTENET_Datagram_GetPacket;
newcon->SendPacket = FTENET_Datagram_SendPacket;
newcon->Close = FTENET_Datagram_Close;
newcon->ChangeLocalAddress = FTENET_Datagram_ChangeLocalAddress;
newcon->owner = col;
newcon->islisten = isserver;
if (hybrid)
{
newcon->addrtype[0] = NA_IP;
newcon->addrtype[1] = NA_IPV6;
}
else
{
newcon->addrtype[0] = adr.type;
newcon->addrtype[1] = NA_INVALID;
}
newcon->thesocket = newsocket;
#ifdef HAVE_EPOLL
{
struct epoll_event event = {EPOLLIN|EPOLLET, {&newcon->epoll}};
newcon->epoll.Polled = FTENET_Datagram_Polled;
if (epoll_ctl(epoll_fd, EPOLL_CTL_ADD, newsocket, &event) < 0)
{
int err = errno;
Con_Printf("epoll_ctl failed - errno %i\n", err);
}
}
#endif
return newcon;
}
else
{
closesocket(newsocket);
return NULL;
}
#endif
}
#ifdef TCPCONNECT
typedef struct ftenet_tcp_stream_s {
vfsfile_t *clientstream;
int inlen;
int outlen;
#ifdef HAVE_EPOLL
epollctx_t epoll; //so our epoll dispatcher knows which connection/stream
struct ftenet_tcp_connection_s *con;
#endif
enum
{
TCPC_UNKNOWN, //waiting to see what they send us.
//TCPC_QTV, //included for completeness. qtv handles the sockets itself, we just parse initial handshake and then pass it over (as either a tcp or tls vfsfile_t)
TCPC_QIZMO, //'qizmo\n' handshake, followed by packets prefixed with a 16bit packet length.
#ifdef HAVE_HTTPSV
TCPC_WEBSOCKETU, //utf-8 encoded data.
TCPC_WEBSOCKETB, //binary encoded data (subprotocol = 'binary')
TCPC_WEBSOCKETNQ, //raw nq msg buffers with no encapsulation or handshake
TCPC_HTTPCLIENT, //we're sending a file to this victim.
TCPC_WEBRTC_HOST, //for brokering webrtc connections, doesn't carry any actual game data itself.
TCPC_WEBRTC_CLIENT, //for brokering webrtc connections, doesn't carry any actual game data itself.
#endif
} clienttype;
qbyte inbuffer[MAX_OVERALLMSGLEN];
qbyte outbuffer[MAX_OVERALLMSGLEN];
vfsfile_t *dlfile; //if the client looked like an http client, this is the file that they're downloading.
float timeouttime;
qboolean pinging;
netadr_t remoteaddr;
struct ftenet_tcp_stream_s *next;
SOCKET socketnum; //for select. not otherwise used.
int fakesequence; //TCPC_WEBSOCKETNQ
#ifdef HAVE_HTTPSV
struct
{
qboolean connection_close;
} httpstate;
#ifdef MVD_RECORDING
qtvpendingstate_t qtvstate;
#endif
struct
{
char resource[64];
int clientnum;
#ifdef SUPPORT_RTC_ICE
struct icestate_s *ice;
#endif
} webrtc;
#endif
} ftenet_tcp_stream_t;
typedef struct ftenet_tcp_connection_s {
ftenet_generic_connection_t generic;
qboolean tls;
int active;
ftenet_tcp_stream_t *tcpstreams;
} ftenet_tcp_connection_t;
void tobase64(unsigned char *out, int outlen, const unsigned char *in, int inlen)
{
static unsigned char tab[64] =
{
'A','B','C','D','E','F','G','H','I','J','K','L','M','N','O','P',
'Q','R','S','T','U','V','W','X','Y','Z','a','b','c','d','e','f',
'g','h','i','j','k','l','m','n','o','p','q','r','s','t','u','v',
'w','x','y','z','0','1','2','3','4','5','6','7','8','9','+','/'
};
unsigned int usedbits = 0;
unsigned int val = 0;
outlen--;
while(inlen)
{
while(usedbits < 24 && inlen)
{
val <<= 8;
val |= (*in++);
inlen--;
usedbits += 8;
}
if (outlen < 4)
return;
val <<= 24 - usedbits;
*out++ = (usedbits > 0)?tab[(val>>18)&0x3f]:'=';
*out++ = (usedbits > 6)?tab[(val>>12)&0x3f]:'=';
*out++ = (usedbits > 12)?tab[(val>>6)&0x3f]:'=';
*out++ = (usedbits > 18)?tab[(val>>0)&0x3f]:'=';
val=0;
usedbits = 0;
}
*out = 0;
}
neterr_t FTENET_TCP_WebSocket_Splurge(ftenet_tcp_stream_t *st, enum websocketpackettype_e packettype, const qbyte *data, unsigned int length)
{
/*as a server, we don't need the mask stuff*/
unsigned short ctrl = 0x8000 | (packettype<<8);
unsigned int paylen = 0;
unsigned int payoffs = st->outlen;
int i;
switch((ctrl>>8) & 0xf)
{
case WS_PACKETTYPE_TEXTFRAME:
for (i = 0; i < length; i++)
{
paylen += (data[i] == 0 || data[i] >= 0x80)?2:1;
}
break;
default:
paylen = length;
break;
}
if (paylen >= 126)
ctrl |= 126;
else
ctrl |= paylen;
if (6 + paylen > sizeof(st->outbuffer))
return NETERR_MTU;
if (payoffs + 6 + paylen > sizeof(st->outbuffer))
return NETERR_CLOGGED;
st->outbuffer[payoffs++] = ctrl>>8;
st->outbuffer[payoffs++] = ctrl&0xff;
if ((ctrl&0x7f) == 126)
{
st->outbuffer[payoffs++] = paylen>>8;
st->outbuffer[payoffs++] = paylen&0xff;
}
switch((ctrl>>8) & 0xf)
{
case WS_PACKETTYPE_TEXTFRAME:/*utf8ify the data*/
for (i = 0; i < length; i++)
{
if (!data[i])
{ /*0 is encoded as 0x100 to avoid safety checks*/
st->outbuffer[payoffs++] = 0xc0 | (0x100>>6);
st->outbuffer[payoffs++] = 0x80 | (0x100&0x3f);
}
else if (data[i] >= 0x80)
{ /*larger bytes require markup*/
st->outbuffer[payoffs++] = 0xc0 | (data[i]>>6);
st->outbuffer[payoffs++] = 0x80 | (data[i]&0x3f);
}
else
{ /*lower 7 bits are as-is*/
st->outbuffer[payoffs++] = data[i];
}
}
break;
default: //raw data
memcpy(st->outbuffer+payoffs, data, length);
payoffs += length;
break;
}
st->outlen = payoffs;
if (st->outlen && st->clientstream)
{ /*try and flush the old data*/
int done;
done = VFS_WRITE(st->clientstream, st->outbuffer, st->outlen);
if (done > 0)
{
memmove(st->outbuffer, st->outbuffer + done, st->outlen - done);
st->outlen -= done;
}
}
return NETERR_SENT;
}
#ifdef HAVE_HTTPSV
enum
{
WCATTR_METHOD,
WCATTR_URL,
WCATTR_HTTP,
WCATTR_HOST,
WCATTR_CONNECTION,
WCATTR_UPGRADE,
WCATTR_WSKEY,
//WCATTR_ORIGIN,
WCATTR_WSPROTO,
//WCATTR_WSEXT,
WCATTR_IFNONEMATCH,
WCATTR_COUNT,
WCATTR_WSVER,
WCATTR_CONTENT_LENGTH,
WCATTR_ACCEPT_ENCODING,
WCATTR_TRANSFER_ENCODING
};
typedef char httparg_t[64];
#include "fs.h"
#ifdef _WIN32
#include "resource.h"
#endif
void SV_UserCmdMVDList_HTML (vfsfile_t *pipe);
qboolean FTENET_TCP_HTTPResponse(ftenet_tcp_stream_t *st, httparg_t arg[WCATTR_COUNT], qboolean allowgzip)
{
char adr[256];
int i;
const char *filetype = NULL;
const char *resp = NULL; //response headers (no length/gap)
const char *body = NULL; //response body
int method;
net_from = st->remoteaddr;
if (!strcmp(arg[WCATTR_METHOD], "GET"))
method = 0;
else if (!strcmp(arg[WCATTR_METHOD], "HEAD"))
method = 1;
else //if (!strcmp(arg[WCATTR_METHOD], "POST") || !strcmp(arg[WCATTR_METHOD], "PUT") || !strcmp(arg[WCATTR_METHOD], "OPTIONS"))
{
method = 404;
resp = "HTTP/1.1 405 Method Not Allowed\r\n";
st->httpstate.connection_close = true;
body = NULL;
}
if (!stricmp(arg[WCATTR_CONNECTION], "Close"))
st->httpstate.connection_close = true; //peer wants us to kill the connection on completion.
st->dlfile = NULL;
if (!resp && *arg[WCATTR_URL] == '/')
{ //'can't use SV_LocateDownload, as that assumes an active client.
const char *name = arg[WCATTR_URL]+1;
char *extraheaders = "";
time_t modificationtime = 0;
char *query = strchr(arg[WCATTR_URL]+1, '?');
#ifdef HAVE_SERVER
func_t func = 0;
#endif
if (query)
*query++ = 0;
//FIXME: remove ?
//FIXME: any path that ends with / should be sent to index.html or something
if (!*name)
name = "index.html";
#ifdef HAVE_SERVER
if (sv.state && svs.gametype == GT_PROGS && svprogfuncs)
func = svprogfuncs->FindFunction(svprogfuncs, "HTTP_GeneratePage", PR_ANY);
if (func)
{
void *pr_globals = PR_globals(svprogfuncs, PR_CURRENT);
((string_t *)pr_globals)[OFS_PARM0] = svprogfuncs->TempString(svprogfuncs, query?va("%s?%s", name, query):name);
((string_t *)pr_globals)[OFS_PARM1] = svprogfuncs->TempString(svprogfuncs, arg[WCATTR_METHOD]);
((string_t *)pr_globals)[OFS_PARM2] = 0; //we don't support any postdata at this time.
((string_t *)pr_globals)[OFS_PARM3] = 0; //we don't support any request headers at this time.
((string_t *)pr_globals)[OFS_PARM4] = 0; //we don't have any default response headers yet.
((string_t *)pr_globals)[OFS_PARM5] = 0;
((string_t *)pr_globals)[OFS_PARM6] = 0;
((string_t *)pr_globals)[OFS_PARM7] = 0;
svprogfuncs->ExecuteProgram(svprogfuncs, func);
if (((string_t *)pr_globals)[OFS_RETURN])
{ //note that "" is not null
body = svprogfuncs->StringToNative(svprogfuncs, ((string_t *)pr_globals)[OFS_RETURN]);
resp = svprogfuncs->StringToNative(svprogfuncs, ((string_t *)pr_globals)[OFS_PARM4]);
resp = va("%s%s", *body?"HTTP/1.1 200 Ok\r\n":"HTTP/1.1 404 File Not Found\r\n", resp);
}
}
#endif
//FIXME: provide some resource->filename mapping that allows various misc files.
if (body)
;
#ifdef _WIN32
else if (!strcmp(name, "favicon.ico"))
{ //we can serve up the icon from the exe. we just have to reformat it a little.
st->dlfile = VFSPIPE_Open(1, false);
if (st->dlfile)
{
struct
{
short reserved;
short type;
short count;
struct
{
qbyte width;
qbyte height;
qbyte colours;
qbyte reserved;
short planes;
short bitcount;
unsigned short bytes[2];
unsigned short fileoffset[2];
} entry[1];
} icohdr;
struct
{
short reserved;
short type;
short count;
struct
{
qbyte width;
qbyte height;
qbyte colours;
qbyte reserved;
short planes;
short bitcount;
unsigned short bytes[2];
unsigned short id;
} entry[1];
} *grphdr = LockResource(LoadResource(NULL, FindResource(NULL, MAKEINTRESOURCE(IDI_ICON1), RT_GROUP_ICON)));
void *blob;
//fixme: scan for the best icon size to use.
icohdr.reserved = 0;
icohdr.type = 1;//type
icohdr.count = countof(icohdr.entry);//count
icohdr.entry[0].width = grphdr->entry[0].width;
icohdr.entry[0].height = grphdr->entry[0].height;
icohdr.entry[0].colours = grphdr->entry[0].colours;
icohdr.entry[0].reserved = grphdr->entry[0].reserved;
icohdr.entry[0].planes = grphdr->entry[0].planes;
icohdr.entry[0].bitcount = grphdr->entry[0].bitcount;
icohdr.entry[0].bytes[0] = grphdr->entry[0].bytes[0];
icohdr.entry[0].bytes[1] = grphdr->entry[0].bytes[1];
icohdr.entry[0].fileoffset[0] = sizeof(icohdr);
icohdr.entry[0].fileoffset[1] = sizeof(icohdr)>>16;
VFS_WRITE(st->dlfile, &icohdr, sizeof(icohdr));
blob = LockResource(LoadResource(NULL, FindResource(NULL, MAKEINTRESOURCE(grphdr->entry[0].id), RT_ICON)));
VFS_WRITE(st->dlfile, blob, grphdr->entry[0].bytes[0] | (grphdr->entry[0].bytes[1]<<16));
resp = NULL;
body = NULL;
}
}
#endif
#if defined(SV_MASTER) && !defined(HAVE_SERVER)
else if ((st->dlfile=SVM_GenerateIndex(arg[WCATTR_HOST], name, &filetype, query)))
;
#endif
#ifdef HAVE_SERVER
/*else if (!strcmp(name, "index.html"))
{
resp = "HTTP/1.1 200 Ok\r\n"
"Content-Type: text/html\r\n";
body = va(
"<html lang='en-us'>"
"<head>"
"<meta charset='utf-8'>"
"<meta http-equiv='Content-Type' content='text/html; charset=utf-8'>"
"<meta name=viewport content='width=device-width, initial-scale=1'>"
"<link rel='icon' type='image/vnd.microsoft.icon' href='/favicon.ico' />"
"<title>%s - %s</title>"
"<style>"
"body { background-color:#000000; color:#808080; height:100%%;width:100%%;margin:0;padding:0;}"
"</style>"
"</head>"
"<body>"
"<iframe name='steve'"
" src='%s/%s?+connect%%20%s%s' allowfullscreen=true"
" frameborder='0' scrolling='no' marginheight='0' marginwidth='0' width='100%%' height='100%%'"
" onerror=\"alert('Failed to load engine')\">"
"</iframe>"
"</body>"
"</html>"
,fs_manifest->formalname, hostname.string, ENGINEWEBSITE, fs_manifest->installation, (st->remoteaddr.prot==NP_TLS)?"wss://":"ws://", arg[WCATTR_HOST]);
}*/
/*else if (!strcmp(name, "default.fmf") && (st->dlfile = FS_OpenVFS("default.fmf", "rb", FS_ROOT)))
{
resp = "HTTP/1.1 200 Ok\r\n"
"Content-Type: application/x-ftemanifest\r\n";
body = NULL;
}*/
#ifdef MVD_RECORDING
else if (!Q_strncasecmp(name, "demolist", 8))
{
filetype = "text/html";
st->dlfile = VFSPIPE_Open(1, false);
if (st->dlfile)
SV_UserCmdMVDList_HTML(st->dlfile);
}
else if (!Q_strncasecmp(name, "demonum/", 8))
{
char *mvdname = SV_MVDNum(arg[WCATTR_METHOD], sizeof(arg[WCATTR_METHOD]), atoi(name+8));
if (mvdname)
{
Con_Printf("Redirect %s to %s (copyrighted)\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
resp = va( "HTTP/1.1 302 Found\r\n"
"Location: /demos/%s\r\n"
"Content-Type: text/html\r\n"
, mvdname);
body = NULL;
}
}
#endif
else if (!SV_AllowDownload(name))
{
Con_Printf("Denied download of %s to %s\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
resp = "HTTP/1.1 403 Forbidden\r\n"
"Content-Type: text/html\r\n";
body = va("File \"%s\" may not be downloaded"
, name);
}
else if (!Q_strncasecmp(name, "package/", 8))
{
if (FS_GetPackageDownloadable(name+8))
st->dlfile = FS_OpenVFS(name+8, "rb", FS_ROOT);
else
{
Con_Printf("Unable to download %s to %s (copyrighted)\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
resp = "HTTP/1.1 403 Forbidden\r\n"
"Content-Type: text/html\r\n";
body = "File is flagged as copyrighted";
}
}
else
{
flocation_t gzloc;
flocation_t rawloc;
#ifdef MVD_RECORDING
if (!Q_strncasecmp(name, "demos/", 6))
name = va("%s/%s", sv_demoDir.string, name+6);
#endif
if (FS_FLocateFile(name, FSLF_IFFOUND, &rawloc))
{
char gzname[MAX_QPATH];
time_t rt;
FS_GetLocMTime(&rawloc, &rt);
Q_snprintfz(gzname, sizeof(gzname), "%s.gz", name);
if (allowgzip && FS_FLocateFile(gzname, FSLF_IFFOUND, &gzloc))
{
time_t gt;
if (rawloc.search == gzloc.search && FS_GetLocMTime(&gzloc, &gt) && gt >= rt)
{ //must be in the same gamedir, and not older
extraheaders = "Content-Encoding: gzip\r\n";
rawloc = gzloc;
rt = gt;
Con_DPrintf("HTTP: Serving %s instead\n", gzname);
}
else
Con_DPrintf("HTTP: Ignoring %s, outdated\n", gzname);
}
modificationtime = rt;
if (rawloc.search->flags & SPF_COPYPROTECTED)
{
Con_Printf("Unable to download %s to %s (copyrighted)\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
resp = "HTTP/1.1 403 Forbidden\r\n"
"Content-Type: text/html\r\n";
body = va("File %s inside a package<br/><a href=\"/package/%s\">Download</a>"
, name, FS_GetPackageDownloadFilename(&rawloc));
}
else
st->dlfile = rawloc.search->handle->OpenVFS(rawloc.search->handle, &rawloc, "rb");
}
else
st->dlfile = NULL;
}
#endif
if (st->dlfile)
{
char etag[64];
if (!filetype)
{
const char *ext;
int i;
static const char *mimes[] =
{
".html", "text/html",
".htm", "text/html",
".png", "image/png",
".jpeg", "image/jpeg",
".jpg", "image/jpeg",
".ico", "image/vnd.microsoft.icon",
".pk3", "application/zip",
".fmf", "application/x-ftemanifest",
".qtv", "application/x-qtv",
".wasm", "application/wasm",
".js", "text/javascript",
".mvd", "application/x-multiviewdemo",
".mvd.gz", "application/x-multiviewdemo",
".qwd", "application/x-multiviewdemo",
".qwd.gz", "application/x-multiviewdemo",
".dem", "application/x-multiviewdemo",
".dem.gz", "application/x-multiviewdemo",
};
ext = COM_GetFileExtension(name, NULL);
if (!strcmp(ext, ".gz")||!strcmp(ext, ".xz"))
ext = COM_GetFileExtension(name, ext);
for (i = 0; i < countof(mimes); i+=2)
{
if (!Q_strcasecmp(ext, mimes[i]))
{
filetype = mimes[i+1];
break;
}
}
}
if (modificationtime)
{
Q_snprintfz(etag, sizeof(etag), "W/\"%0"PRIxQOFS"\"", (qofs_t)modificationtime);
if (!strcmp(arg[WCATTR_IFNONEMATCH], etag))
{
resp = "HTTP/1.1 304 Not Modified \r\n";
body = NULL;
}
Q_snprintfz(etag, sizeof(etag), "ETag: W/\"%0"PRIxQOFS"\"\r\n", (qofs_t)modificationtime);
}
else *etag = 0;
if (resp)
{
VFS_CLOSE(st->dlfile);
st->dlfile = NULL;
}
else
{
Con_Printf("Downloading %s to %s\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
if (filetype)
{
resp = va("HTTP/1.1 200 Ok\r\n"
"Content-Type: %s\r\n"
"%s%s",
filetype,
etag,extraheaders);
}
else
resp = va("HTTP/1.1 200 Ok\r\n"
"%s%s",
etag,extraheaders);
body = NULL;
}
}
else if (!resp)
{
Con_Printf("Unable to download %s to %s\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
resp = "HTTP/1.1 404 File Not Found\r\n"
"Content-Type: text/html\r\n";
body = "File not found";
}
}
if (!resp)
{
Con_Printf("Invalid download request %s to %s\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
resp = "HTTP/1.1 404 File Not Found\r\n"
"Content-Type: text/html\r\n";
body = "This is a Quake WebSocket server, not an http server.<br/>\r\n"
//"<a href='"ENGINEWEBSITE"'>"FULLENGINENAME"</a>"
;
}
st->clienttype = TCPC_HTTPCLIENT;
i = strlen(resp);
if (st->outlen + i > sizeof(st->outbuffer))
return false;
memcpy(st->outbuffer+st->outlen, resp, i);
st->outlen+= i;
resp = "Access-Control-Allow-Origin: *\r\n";
i = strlen(resp);
if (st->outlen + i > sizeof(st->outbuffer))
return false;
memcpy(st->outbuffer+st->outlen, resp, i);
st->outlen+= i;
if (st->httpstate.connection_close)
{
resp = "Connection: Close\r\n";
i = strlen(resp);
if (st->outlen + i > sizeof(st->outbuffer))
return false;
memcpy(st->outbuffer+st->outlen, resp, i);
st->outlen+= i;
}
if (st->dlfile || body)
{
qofs_t size;
if (body)
size = strlen(body);
else
size = VFS_GETLEN(st->dlfile);
resp = adr;
Q_snprintfz(adr, sizeof(adr), "Content-Length: %"PRIuQOFS"\r\n", size);
}
else
resp = "Content-Length: 0\r\n";
i = strlen(resp);
if (st->outlen + i > sizeof(st->outbuffer))
return false;
memcpy(st->outbuffer+st->outlen, resp, i);
st->outlen+= i;
if (st->outlen + 2 > sizeof(st->outbuffer))
return false;
memcpy(st->outbuffer+st->outlen, "\r\n", 2);
st->outlen+= 2;
if (method == 1)
{ //body is not included in HEAD responses
body = NULL;
if (st->dlfile)
VFS_CLOSE(st->dlfile);
st->dlfile = NULL;
}
else if (body)
{
i = strlen(body);
if (st->outlen + i > sizeof(st->outbuffer))
return false;
memcpy(st->outbuffer+st->outlen, body, i);
st->outlen+= i;
}
return true;
}
void FTENET_TCP_WebRTCServerAssigned(ftenet_tcp_stream_t *list, ftenet_tcp_stream_t *client, ftenet_tcp_stream_t *server)
{
qbyte buffer[3];
int trynext = 0;
ftenet_tcp_stream_t *o;
if (client->webrtc.clientnum < 0)
client->webrtc.clientnum = 0;
for(;;)
{
for (o = list; o; o = o->next)
{
if (o != client && o->clienttype == TCPC_WEBRTC_CLIENT && !strcmp(o->webrtc.resource, client->webrtc.resource) && client->webrtc.clientnum == o->webrtc.clientnum)
break;
}
if (!o)
break;
client->webrtc.clientnum = trynext++;
}
if (server)
{ //and tell them both, if the server is actually up
buffer[0] = ICEMSG_NEWPEER;
buffer[1] = (client->webrtc.clientnum>>0)&0xff;
buffer[2] = (client->webrtc.clientnum>>8)&0xff;
// buffer[3] = (client->webrtc.clientnum>>16)&0xff;
// buffer[4] = (client->webrtc.clientnum>>24)&0xff;
FTENET_TCP_WebSocket_Splurge(server, WS_PACKETTYPE_BINARYFRAME, buffer, 3);
buffer[0] = ICEMSG_NEWPEER;
buffer[1] = 0xff;
buffer[2] = 0xff;
// buffer[3] = 0xff;
// buffer[4] = 0xff;
FTENET_TCP_WebSocket_Splurge(client, WS_PACKETTYPE_BINARYFRAME, buffer, 3);
}
}
qboolean FTENET_TCP_ParseHTTPRequest(ftenet_tcp_connection_t *con, ftenet_tcp_stream_t *st)
{
char *resp;
char adr[256];
int i, j;
int attr = 0;
int alen = 0;
qboolean headerscomplete = false;
int contentlen = 0;
int websocketver = 0;
qboolean acceptsgzip = false;
qboolean sendingweirdness = false;
char arg[WCATTR_COUNT][64];
if (!net_enable_http.ival && !net_enable_websockets.ival && !net_enable_rtcbroker.ival)
{
//we need to respond, firefox will create 10 different connections if we just close it
resp = va( "HTTP/1.1 403 Forbidden\r\n"
"Connection: close\r\n" //let the client know that any pipelining it was doing will have been ignored
"\r\n");
VFS_WRITE(st->clientstream, resp, strlen(resp));
return false;
}
for (i = 0; i < WCATTR_COUNT; i++)
arg[i][0] = 0;
for (i = 0; i < st->inlen; i++)
{
if (alen == 63)
{
Con_Printf("http request overflow from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
//we need to respond, firefox will create 10 different connections if we just close it
resp = va( "HTTP/1.1 414 URI Too Long\r\n"
"Connection: close\r\n" //let the client know that any pipelining it was doing will have been ignored
"\r\n");
VFS_WRITE(st->clientstream, resp, strlen(resp));
return false; //overflow...
}
if (st->inbuffer[i] == ' ' || st->inbuffer[i] == '\t' || st->inbuffer[i] == '\r')
{
arg[attr][alen++] = 0;
alen=0;
if (attr++ == WCATTR_HTTP)
break;
for (; i < st->inlen && (st->inbuffer[i] == ' ' || st->inbuffer[i] == '\t' || st->inbuffer[i] == '\r'); i++)
;
if (i == st->inlen)
break;
}
if (st->inbuffer[i] == '\n')
{
arg[attr][alen++] = 0;
alen=0;
break;
}
if (st->inbuffer[i] < ' ' && st->inbuffer[i] != '\t')
{
Con_Printf("http request contained control codes\n");
return false;
}
arg[attr][alen++] = st->inbuffer[i];
}
if (!*arg[WCATTR_URL]) //don't bug out if it was truncated.
strcpy(arg[WCATTR_URL], "/");
if (st->inbuffer[i] == '\r')
i++;
if (st->inbuffer[i] == '\n')
{ //okay, we have at least a line... try scanning the rest of the header for known key:value pairs, and see if we can reach the end
i++;
attr = 0;
j = i;
for (; i < st->inlen; i++)
{
if ((i+1 < st->inlen && st->inbuffer[i] == '\r' && st->inbuffer[i+1] == '\n') ||
(i < st->inlen && st->inbuffer[i] == '\n'))
{
if (st->inbuffer[i] == '\n')
i++;
else
i+=2;
headerscomplete = true;
break;
}
for (; i < st->inlen && (st->inbuffer[i] == ' ' || st->inbuffer[i] == '\t'); i++)
;
if (i == st->inlen)
break;
for (j = i; j < st->inlen; j++)
{
if (st->inbuffer[j] == ':' || st->inbuffer[j] == '\n')
{
/*set j to the end of the word, going back past whitespace*/
while (j > i && (st->inbuffer[j-1] == ' ' || st->inbuffer[i-1] == '\t'))
j--;
break;
}
}
if (j-i == 4 && !strnicmp(&st->inbuffer[i], "Host", 4))
attr = WCATTR_HOST;
else if (j-i == 7 && !strnicmp(&st->inbuffer[i], "Upgrade", 7))
attr = WCATTR_UPGRADE;
else if (j-i == 10 && !strnicmp(&st->inbuffer[i], "Connection", 10))
attr = WCATTR_CONNECTION;
//websocket stuff
else if (j-i == 17 && !strnicmp(&st->inbuffer[i], "Sec-WebSocket-Key", 17))
attr = WCATTR_WSKEY;
else if (j-i == 21 && !strnicmp(&st->inbuffer[i], "Sec-WebSocket-Version", 21))
attr = WCATTR_WSVER;
// else if (j-i == 6 && !strnicmp(&st->inbuffer[i], "Origin", j-i))
// attr = WCATTR_ORIGIN;
else if (j-i == 22 && !strnicmp(&st->inbuffer[i], "Sec-WebSocket-Protocol", 22))
attr = WCATTR_WSPROTO;
// else if (j-i == 24 && !strnicmp(&st->inbuffer[i], "Sec-WebSocket-Extensions", 24))
// attr = WCATTR_WSEXT;
//http stuff
else if (j-i == 14 && !strnicmp(&st->inbuffer[i], "Content-Length", 14))
attr = WCATTR_CONTENT_LENGTH; //in case they're trying to post/put stuff
else if (j-i == 15 && !strnicmp(&st->inbuffer[i], "Accept-Encoding", 15))
attr = WCATTR_ACCEPT_ENCODING; //for gzip
else if (j-i == 17 && !strnicmp(&st->inbuffer[i], "Transfer-Encoding", 17))
attr = WCATTR_TRANSFER_ENCODING;//in case they're trying to post/put complex stuff
else if (j-i == 13 && !strnicmp(&st->inbuffer[i], "If-None-Match", 13))
attr = WCATTR_IFNONEMATCH;//for clientside caches
else
attr = 0;
i = j;
/*skip over the whitespace at the end*/
for (; i < st->inlen && (st->inbuffer[i] == ' ' || st->inbuffer[i] == '\t'); i++)
;
if (i < st->inlen && st->inbuffer[i] == ':')
{
i++;
for (; i < st->inlen && (st->inbuffer[i] == ' ' || st->inbuffer[i] == '\t'); i++)
;
j = i;
//FIXME: check for control codes. although probably not a problem in this part
for (; i < st->inlen && st->inbuffer[i] != '\n'; i++)
;
if (i > j && st->inbuffer[i-1] == '\r')
i--;
if (attr)
{
switch(attr)
{
case WCATTR_CONTENT_LENGTH:
contentlen = atoi(&st->inbuffer[j]);
break;
case WCATTR_ACCEPT_ENCODING:
while (j < i)
{
if (st->inbuffer[j] == ' ' || st->inbuffer[j] == '\t')
{
j++;
continue;
}
else if (j+4 <= i && !strncmp(&st->inbuffer[j], "gzip", 4) && (j+4==i || st->inbuffer[j+4] == ';' || st->inbuffer[j+4] == ','))
acceptsgzip = true;
while (j < i && st->inbuffer[j] != ',')
j++;
if (j < i && st->inbuffer[j] == ',')
j++;
}
break;
case WCATTR_TRANSFER_ENCODING:
sendingweirdness = true; //doesn't matter what it is, we can't handle it.
break;
case WCATTR_WSVER:
websocketver = atoi(&st->inbuffer[j]);
break;
default:
Q_strncpyz(arg[attr], &st->inbuffer[j], (i-j > 63)?64:(i - j + 1));
break;
}
}
if (i < st->inlen && st->inbuffer[i] == '\r')
i++;
}
else
{
/*just a word on the line on its own. that would be invalid in http*/
return false;
}
}
}
if (!headerscomplete)
{
Con_DPrintf("http header parsing failed\n");
return false; //the caller said it was complete! something's fucked if we're here
}
//okay, the above code parsed all the headers that we care about.
if (contentlen && i+contentlen > st->inlen)
{ //request isn't complete yet
if (i+contentlen > sizeof(st->inbuffer)-1)
{
resp = va( "HTTP/1.1 413 Payload Too Large \r\n"
"Connection: close\r\n" //let the client know that any pipelining it was doing will have been ignored
"\r\n");
VFS_WRITE(st->clientstream, resp, strlen(resp));
Con_Printf("http oversize request\n");
return false; //can never be completed.
}
return true;
}
//clients uploading chunked stuff is bad/unsupported.
if (sendingweirdness)
{
resp = va( "HTTP/1.1 413 Payload Too Large \r\n"
"Connection: close\r\n" //let the client know that any pipelining it was doing will have been ignored
"\r\n");
VFS_WRITE(st->clientstream, resp, strlen(resp));
Con_Printf("http encoded request\n");
return false; //can't handle the request, so discard the connection
}
memmove(st->inbuffer, st->inbuffer+i, st->inlen - (i));
st->inlen -= i;
//for websocket connections:
//must be a Host, Upgrade=websocket, Connection=Upgrade, Sec-WebSocket-Key=base64(randbytes(16)), Sec-WebSocket-Version=13
//optionally will be Origin=url, Sec-WebSocket-Protocol=FTEWebSocket, Sec-WebSocket-Extensions
//other fields will be ignored.
if (!stricmp(arg[WCATTR_UPGRADE], "websocket") && (!stricmp(arg[WCATTR_CONNECTION], "Upgrade") || !stricmp(arg[WCATTR_CONNECTION], "keep-alive, Upgrade")))
{
int cltype;
//the choice of protocol affects the type of response that we give rather than anything mystic
if (!strcmp(arg[WCATTR_WSPROTO], "quake"))
cltype = TCPC_WEBSOCKETNQ; //raw nq data, all reliable, for compat with webquake
else if (!strcmp(arg[WCATTR_WSPROTO], "rtc_client"))
cltype = TCPC_WEBRTC_CLIENT;//not a real client.
else if (!strcmp(arg[WCATTR_WSPROTO], "rtc_host"))
cltype = TCPC_WEBRTC_HOST;//not a real client, but a competing server! oh noes!
else if (!strcmp(arg[WCATTR_WSPROTO], "binary"))
cltype = TCPC_WEBSOCKETB; //emscripten's networking libraries insists on 'binary', but we stopped using that a while back because its hostname->ip stuff was flawed.
else if (!strcmp(arg[WCATTR_WSPROTO], "fteqw"))
cltype = TCPC_WEBSOCKETB; //specific custom protocol name to avoid ambiguities.
else
cltype = TCPC_WEBSOCKETU; //nacl supports only utf-8 encoded data, at least at the time I implemented it.
if (cltype == TCPC_WEBRTC_CLIENT||cltype==TCPC_WEBRTC_HOST)
{
if (!net_enable_rtcbroker.ival)
return false;
}
else //TCPC_WEBSOCKETNQ, TCPC_WEBSOCKETB, TCPC_WEBSOCKETU
{
if (!net_enable_websockets.ival)
return false;
}
if (websocketver != 13)
{
Con_DPrintf("Outdated websocket request for \"%s\" from \"%s\". got version %i, expected version 13\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr), websocketver);
resp = va( "HTTP/1.1 426 Upgrade Required\r\n"
"Sec-WebSocket-Version: 13\r\n"
"Connection: close\r\n" //let the client know that any pipelining it was doing will have been ignored
"\r\n");
VFS_WRITE(st->clientstream, resp, strlen(resp));
return false;
}
else
{
const char *failreason = NULL;
char acceptkey[20*2];
unsigned char sha1digest[20];
char *blurgh;
char *protoname = "";
blurgh = va("%s258EAFA5-E914-47DA-95CA-C5AB0DC85B11", arg[WCATTR_WSKEY]);
tobase64(acceptkey, sizeof(acceptkey), sha1digest, CalcHash(&hash_sha1, sha1digest, sizeof(sha1digest), blurgh, strlen(blurgh)));
if (st->remoteaddr.prot == NP_TLS)
st->remoteaddr.prot = NP_WSS;
else
st->remoteaddr.prot = NP_WS;
protoname = (cltype==TCPC_WEBSOCKETU)?"":va("Sec-WebSocket-Protocol: %s\r\n", arg[WCATTR_WSPROTO]);
st->clienttype = cltype;
switch(st->clienttype)
{
case TCPC_WEBSOCKETNQ:
case TCPC_WEBSOCKETU:
case TCPC_WEBSOCKETB:
if (!net_enable_websockets.ival)
failreason = "blocked by net_enable_websockets";
break;
case TCPC_WEBRTC_HOST:
case TCPC_WEBRTC_CLIENT:
if (!net_enable_rtcbroker.ival)
failreason = "blocked by net_enable_rtcbroker";
break;
default:
failreason = "unsupported protocol type";
break;
}
if (*arg[WCATTR_URL] == '/')
Q_strncpyz(st->webrtc.resource, arg[WCATTR_URL]+1, sizeof(st->webrtc.resource));
else
Q_strncpyz(st->webrtc.resource, arg[WCATTR_URL], sizeof(st->webrtc.resource));
st->webrtc.clientnum = -1;
#ifndef SUPPORT_RTC_ICE
if (st->clienttype == TCPC_WEBRTC_CLIENT && !*st->webrtc.resource)
failreason = "client did not specify resource type";
#endif
if (failreason)
{
Con_DPrintf("Websocket(%s) request for %s from %s - %s\n", arg[WCATTR_WSPROTO], arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr), failreason);
return false;
}
Con_DPrintf("Websocket request for %s from %s (%s)\n", arg[WCATTR_URL], NET_AdrToString (adr, sizeof(adr), &st->remoteaddr), arg[WCATTR_WSPROTO]);
resp = va( "HTTP/1.1 101 WebSocket Protocol Handshake\r\n"
"Upgrade: websocket\r\n"
"Connection: Upgrade\r\n"
"Access-Control-Allow-Origin: *\r\n" //allow cross-origin requests. this means you can use any domain to play on any public server.
"Sec-WebSocket-Accept: %s\r\n"
"%s"
"\r\n", acceptkey, protoname);
//send the websocket handshake response.
VFS_WRITE(st->clientstream, resp, strlen(resp));
if (st->clienttype == TCPC_WEBRTC_CLIENT && !*st->webrtc.resource)
{ //client should be connected to us rather than any impostors. tell it to start its ICE handshake.
net_message_buffer[0] = ICEMSG_NEWPEER;
net_message_buffer[1] = 0xff;
net_message_buffer[2] = 0xff;
FTENET_TCP_WebSocket_Splurge(st, WS_PACKETTYPE_BINARYFRAME, net_message_buffer, 3);
}
else if (st->clienttype == TCPC_WEBRTC_HOST || st->clienttype == TCPC_WEBRTC_CLIENT)
{
ftenet_tcp_stream_t *o;
if (st->clienttype == TCPC_WEBRTC_HOST)
{ //if its a server, then let it know its final resource name
char *idstart = strchr(st->webrtc.resource, '/');
if (!idstart++)
{ //MUST have a protocol name
return false;
}
if (!*idstart)
{ //webrtc servers need some unique resource address. lets use their ip+port for now. we should probably be randomising this
static unsigned int g;
int ofs = strlen(st->webrtc.resource);
Q_snprintfz(st->webrtc.resource+ofs, sizeof(st->webrtc.resource)-ofs, "%u", ++g);
}
for (o = con->tcpstreams; o; o = o->next)
{
if (o != st && o->clienttype == TCPC_WEBRTC_HOST && !strcmp(st->webrtc.resource, o->webrtc.resource))
{
net_message_buffer[0] = ICEMSG_NAMEINUSE;
strcpy(net_message_buffer+1, st->webrtc.resource);
FTENET_TCP_WebSocket_Splurge(st, WS_PACKETTYPE_BINARYFRAME, net_message_buffer, strlen(net_message_buffer));
*st->webrtc.resource = 0; //don't trigger shutdown broadcasts to valid clients.
return false; //conflict! can't have two servers listening on the same url
}
}
net_message_buffer[0] = ICEMSG_GREETING;
net_message_buffer[1] = 0xff;
net_message_buffer[2] = 0xff;
strcpy(net_message_buffer+3, st->webrtc.resource);
FTENET_TCP_WebSocket_Splurge(st, WS_PACKETTYPE_BINARYFRAME, net_message_buffer, strlen(net_message_buffer));
//if we have (inactive) clients connected, assign them (and let them know that they need to start handshaking)
for (o = con->tcpstreams; o; o = o->next)
{
if (o->clienttype == TCPC_WEBRTC_CLIENT && !strcmp(st->webrtc.resource, o->webrtc.resource))
FTENET_TCP_WebRTCServerAssigned(con->tcpstreams, o, st);
}
#ifdef SV_MASTER
SVM_AddBrokerGame(st->webrtc.resource, "");
#endif
}
else
{ //find its server, if we can
for (o = con->tcpstreams; o; o = o->next)
{
if (o->clienttype == TCPC_WEBRTC_HOST && !strcmp(st->webrtc.resource, o->webrtc.resource))
break;
}
//and assign it to this client
FTENET_TCP_WebRTCServerAssigned(con->tcpstreams, st, o);
}
}
//and the connection is okay
if (st->clienttype == TCPC_WEBSOCKETNQ)
{
//inject a connection request so that our server actually accepts them...
net_message.cursize = 0;
net_message.packing = SZ_RAWBYTES;
net_message.currentbit = 0;
net_from = st->remoteaddr;
net_from.connum = con->generic.connum;
net_from_connection = &con->generic;
MSG_WriteLong(&net_message, LongSwap(NETFLAG_CTL | (strlen(NQ_NETCHAN_GAMENAME)+7)));
MSG_WriteByte(&net_message, CCREQ_CONNECT);
MSG_WriteString(&net_message, NQ_NETCHAN_GAMENAME);
MSG_WriteByte(&net_message, NQ_NETCHAN_VERSION);
con->generic.owner->ReadGamePacket();
}
return true;
}
}
else
{
if (!net_enable_http.ival)
return false;
return FTENET_TCP_HTTPResponse(st, arg, acceptsgzip);
}
}
#endif
#if defined(HAVE_SSL) && (defined(HAVE_SERVER) || defined(HAVE_HTTPSV))
static int QDECL TLSPromoteRead (struct vfsfile_s *file, void *buffer, int bytestoread)
{
if (bytestoread > net_message.cursize)
bytestoread = net_message.cursize;
memcpy(buffer, net_message_buffer, bytestoread);
net_message.cursize -= bytestoread;
memmove(net_message_buffer, net_message_buffer+bytestoread, net_message.cursize);
return bytestoread;
}
#endif
void FTENET_TCP_PrintStatus(ftenet_generic_connection_t *gcon)
{
ftenet_tcp_connection_t *con = (ftenet_tcp_connection_t*)gcon;
ftenet_tcp_stream_t *st;
char adr[MAX_QPATH];
if (!con->tcpstreams)
return;
for (st = con->tcpstreams; st; st = st->next)
{
NET_AdrToString(adr, sizeof(adr), &st->remoteaddr);
switch(st->clienttype)
{
case TCPC_UNKNOWN: //note: this is often a pending http client that's waiting on the off-chance of having more requests to send
Con_Printf("handshaking %s\n", adr);
break;
case TCPC_QIZMO:
Con_Printf("qizmo %s\n", adr);
break;
#ifdef HAVE_HTTPSV
case TCPC_WEBSOCKETU:
case TCPC_WEBSOCKETB:
case TCPC_WEBSOCKETNQ:
Con_Printf("websocket %s\n", adr);
break;
case TCPC_HTTPCLIENT:
Con_Printf("http %s\n", adr);
break;
case TCPC_WEBRTC_CLIENT:
Con_Printf("webrtc client %s/%s\n", adr, st->webrtc.resource);
break;
case TCPC_WEBRTC_HOST:
Con_Printf("webrtc host %s/%s\n", adr, st->webrtc.resource);
break;
#endif
}
}
}
static qboolean FTENET_TCP_KillStream(ftenet_tcp_connection_t *con, ftenet_tcp_stream_t *st)
{ //some sort of error. kill the connection info (will be cleaned up later)
#ifdef HAVE_EPOLL
if (st->socketnum != INVALID_SOCKET)
epoll_ctl(epoll_fd, EPOLL_CTL_DEL, st->socketnum, NULL);
#endif
if (st->clientstream)
VFS_CLOSE(st->clientstream);
st->clientstream = NULL;
if (st->dlfile)
VFS_CLOSE(st->dlfile);
#ifdef HAVE_HTTPSV
if (st->clienttype == TCPC_WEBRTC_CLIENT)
{ //notify its server
ftenet_tcp_stream_t *o;
for (o = con->tcpstreams; o; o = o->next)
{
if (o->clienttype == TCPC_WEBRTC_HOST && !strcmp(o->webrtc.resource, st->webrtc.resource))
{
qbyte msg[3];
msg[0] = ICEMSG_PEERLOST;
msg[1] = (st->webrtc.clientnum>>0)&0xff;
msg[2] = (st->webrtc.clientnum>>8)&0xff;
FTENET_TCP_WebSocket_Splurge(o, WS_PACKETTYPE_BINARYFRAME, msg, 3);
break; //should only be one.
}
}
}
else if (st->clienttype == TCPC_WEBRTC_HOST)
{ //we're brokering a client+server. all messages should be unicasts between a client and its host, matched by resource.
ftenet_tcp_stream_t *o;
for (o = con->tcpstreams; o; o = o->next)
{
if (o->clienttype == TCPC_WEBRTC_CLIENT && !strcmp(o->webrtc.resource, st->webrtc.resource))
{
qbyte msg[3];
msg[0] = ICEMSG_PEERLOST;
msg[1] = (st->webrtc.clientnum>>0)&0xff;
msg[2] = (st->webrtc.clientnum>>8)&0xff;
FTENET_TCP_WebSocket_Splurge(o, WS_PACKETTYPE_BINARYFRAME, msg, 3);
}
}
#ifdef SV_MASTER
SVM_RemoveBrokerGame(st->webrtc.resource);
#endif
}
#endif
return false;
}
static void FTENET_TCP_Flush(ftenet_tcp_connection_t *con, ftenet_tcp_stream_t *st)
{
//write after the reads, for slightly faster pings
if (st->outlen && st->clientstream)
{ /*try and flush any old outgoing data*/
int done;
done = VFS_WRITE(st->clientstream, st->outbuffer, st->outlen);
if (done > 0)
{
memmove(st->outbuffer, st->outbuffer + done, st->outlen - done);
st->outlen -= done;
st->timeouttime = Sys_DoubleTime() + 30;
}
/*else if (done == 0)
{
Con_DPrintf ("tcp peer %s closed connection\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
st->outlen = 0;
}*/
}
}
//returns true if we read a game packet (should re-call in this case.
static enum{
FTETCP_DONE, FTETCP_KILL, FTETCP_RETRY
} FTENET_TCP_ReadStream(ftenet_tcp_connection_t *con, ftenet_tcp_stream_t *st)
{
char adr[MAX_ADR_SIZE];
if (st->inlen < sizeof(st->inbuffer)-1)
{
int ret = VFS_READ(st->clientstream, st->inbuffer+st->inlen, sizeof(st->inbuffer)-1-st->inlen);
if (ret < 0)
{
st->outlen = 0; //don't flush, no point.
Con_DPrintf ("tcp peer %s closed connection\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
st->inlen += ret;
}
switch(st->clienttype)
{
case TCPC_UNKNOWN:
if (st->inlen < 6)
return FTETCP_DONE;
//so TLS apparently uses a first byte that is always < 64. which is handy to know.
if (con->generic.islisten && st->remoteaddr.prot == NP_STREAM && st->clientstream && !((st->inbuffer[0] >= 'a' && st->inbuffer[0] <= 'z') || (st->inbuffer[0] >= 'A' && st->inbuffer[0] <= 'Z')))
{
#if defined(HAVE_SSL) && (defined(HAVE_SERVER) || defined(HAVE_HTTPSV)) //if its non-ascii, then try and upgrade the connection to tls
if (net_enable_tls.ival)
{
//copy off our buffer so we can read it into the tls stream's buffer instead.
char tmpbuf[256];
vfsfile_t *stream = st->clientstream;
int (QDECL *realread) (struct vfsfile_s *file, void *buffer, int bytestoread);
if (st->inlen > sizeof(net_message_buffer))
return FTETCP_KILL; //would cause data loss...
realread = stream->ReadBytes;
stream->ReadBytes = TLSPromoteRead;
memcpy(net_message_buffer, st->inbuffer, st->inlen);
net_message.cursize = st->inlen;
//wrap the stream now
st->clientstream = FS_OpenSSL(NULL, st->clientstream, true);
st->remoteaddr.prot = NP_TLS;
if (st->clientstream)
{
//try and reclaim it all
st->inlen = VFS_READ(st->clientstream, st->inbuffer, sizeof(st->inbuffer)-1);
if (st->inlen < 0)
{ //okay, something failed...
st->inlen = 0;
return FTETCP_KILL;
}
else
{
//make sure we actually read from the proper stream again
stream->ReadBytes = realread;
}
}
if (!st->clientstream || net_message.cursize)
return FTETCP_KILL; //failure, or it didn't read all the data that we buffered for it (error instead of forgetting it).
if (developer.ival)
Con_Printf("promoted peer to tls: %s\n", NET_AdrToString(tmpbuf, sizeof(tmpbuf), &st->remoteaddr));
return FTETCP_RETRY; //might be a usable packet in there that we now need to make sense of.
}
#endif
return FTETCP_KILL;
}
//check if its a qizmo connection (or rather a general qw-over-tcp connection)
if (st->inlen >= 6 && !strncmp(st->inbuffer, "qizmo\n", 6))
{
if (
#ifdef HAVE_SERVER
net_enable_qizmo.ival ||
#endif
!con->generic.islisten)
{
memmove(st->inbuffer, st->inbuffer+6, st->inlen - (6));
st->inlen -= 6;
st->clienttype = TCPC_QIZMO;
if (con->generic.islisten)
{
//send the qizmo handshake response.
if (VFS_WRITE(st->clientstream, "qizmo\n", 6) != 6)
return FTETCP_KILL; //unable to write for some reason.
}
return FTETCP_DONE;
}
return FTETCP_KILL; //not enabled.
}
//check if we have some http-like protocol with a header that ends with two trailing new lines (carrage returns optional, at least here)
//(must have a full request header, meaning double-lineendings somewhere)
if (con->generic.islisten)// && !strncmp(st->inbuffer, "GET ", 4))
{
//qtv or http request header. these terminate with a blank line.
int i = 0;
qboolean headerscomplete = false;
for (; i < st->inlen; i++)
{
//we're at the start of a line, so if its a \r\n or a \n then its a blank line, and the headers are complete
if ((i+1 < st->inlen && st->inbuffer[i] == '\r' && st->inbuffer[i+1] == '\n') ||
(i < st->inlen && st->inbuffer[i] == '\n'))
{
if (st->inbuffer[i] == '\n')
i++;
else
i+=2;
headerscomplete = true;
break;
}
for (; i < st->inlen && st->inbuffer[i] != '\n'; i++)
;
}
if (headerscomplete)
{
#if defined(SUBSERVERS) && defined(HAVE_SERVER)
//this is a new subserver node...
if (!Q_strncasecmp(st->inbuffer, "NODE", 4))
{
char tmpbuf[256];
#ifdef HAVE_EPOLL
//the tcp connection will be handled elsewhere.
//make sure we don't get tcp-handler wakeups from this connection.
epoll_ctl(epoll_fd, EPOLL_CTL_DEL, st->socketnum, NULL);
st->socketnum = INVALID_SOCKET;
st->epoll.Polled = NULL;
#endif
//now try to pass it over
MSV_NewNetworkedNode(st->clientstream, st->inbuffer, st->inbuffer+i, st->inlen-i, NET_AdrToString(tmpbuf, sizeof(tmpbuf), &st->remoteaddr));
st->clientstream = NULL; //qtv code took it.
return FTETCP_KILL;
}
else
#endif
#ifdef MVD_RECORDING
//for QTV connections, we just need the method and a blank line. our qtv parser will parse the actual headers.
if (!Q_strncasecmp(st->inbuffer, "QTV", 3))
{ //FIXME: make sure its removed from epoll and not killed prematurely
int r = -2;
const char *desc;
if (net_enable_qtv.ival == 2 && NET_ClassifyAddress(&st->remoteaddr, &desc) > ASCOPE_HOST)
;
else if (net_enable_qtv.ival)
r = SV_MVD_GotQTVRequest(st->clientstream, st->inbuffer, st->inbuffer+st->inlen, &st->qtvstate);
i = st->inlen;
memmove(st->inbuffer, st->inbuffer+i, st->inlen - (i));
st->inlen -= i;
switch(r)
{
case -2:
VFS_PUTS(st->clientstream, "QTVSV 1\n" "PERROR: net_enable_qtv is disabled on this server\n\n");
return FTETCP_KILL;
case -1: //error
return FTETCP_KILL;
case 0: //retry
return FTETCP_DONE;
case 1: //accepted
#ifdef HAVE_EPOLL
//the tcp connection will now be handled by the dedicated qtv code rather than us.
//make sure we don't get tcp-handler wakeups from this connection.
epoll_ctl(epoll_fd, EPOLL_CTL_DEL, st->socketnum, NULL);
st->socketnum = INVALID_SOCKET;
st->epoll.Polled = NULL;
#endif
st->clientstream = NULL; //qtv code took it.
return FTETCP_KILL;
}
}
else
#endif
{
#ifdef HAVE_HTTPSV
if (FTENET_TCP_ParseHTTPRequest(con, st))
return FTETCP_RETRY;
#else
Con_DPrintf ("Unknown TCP handshake from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
#endif
return FTETCP_KILL;
}
}
else
{
//they splurged too much data and we don't even know what they were
//either way we're expecting a request header in our buffer that can never be completed
if (st->inlen >= sizeof(st->inbuffer)-1)
return FTETCP_KILL;
}
}
return FTETCP_DONE;
#ifdef HAVE_HTTPSV
case TCPC_HTTPCLIENT:
/*try and keep it flushed*/
FTENET_TCP_Flush(con, st);
if (!st->outlen)
{
if (st->dlfile)
st->outlen = VFS_READ(st->dlfile, st->outbuffer, sizeof(st->outbuffer));
else
st->outlen = 0;
if (st->outlen <= 0)
{
st->outlen = 0;
if (st->dlfile)
VFS_CLOSE(st->dlfile);
st->dlfile = NULL;
st->clienttype = TCPC_UNKNOWN; //wait for the next request (could potentially be a websocket connection)
Con_DPrintf ("Outgoing file transfer complete\n");
if (st->httpstate.connection_close)
return FTETCP_KILL;
}
FTENET_TCP_Flush(con, st);
}
return FTETCP_DONE;
#endif
case TCPC_QIZMO:
if (st->inlen < 2)
return FTETCP_DONE;
net_message.cursize = BigShort(*(short*)st->inbuffer);
if (net_message.cursize >= sizeof(net_message_buffer) )
{
Con_TPrintf ("Warning: Oversize packet from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
if (net_message.cursize+2 > st->inlen)
{ //not enough buffered to read a packet out of it.
return FTETCP_DONE;
}
memcpy(net_message_buffer, st->inbuffer+2, net_message.cursize);
memmove(st->inbuffer, st->inbuffer+net_message.cursize+2, st->inlen - (net_message.cursize+2));
st->inlen -= net_message.cursize+2;
net_message.packing = SZ_RAWBYTES;
net_message.currentbit = 0;
net_from = st->remoteaddr;
net_from.connum = con->generic.connum;
net_from_connection = &con->generic;
con->generic.owner->ReadGamePacket();
return FTETCP_RETRY;
#ifdef HAVE_HTTPSV
case TCPC_WEBSOCKETU:
case TCPC_WEBSOCKETB:
case TCPC_WEBSOCKETNQ:
case TCPC_WEBRTC_HOST:
case TCPC_WEBRTC_CLIENT:
while (st->inlen >= 2)
{
unsigned short ctrl = ((unsigned char*)st->inbuffer)[0]<<8 | ((unsigned char*)st->inbuffer)[1];
unsigned long paylen;
unsigned int payoffs = 2;
unsigned int mask = 0;
// st->inbuffer[st->inlen]=0;
if (ctrl & 0x7000)
{
Con_Printf ("%s: reserved bits set\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
if ((ctrl & 0x7f) == 127)
{
quint64_t ullpaylen;
//as a payload is not allowed to be encoded as too large a type, and quakeworld never used packets larger than 1450 bytes anyway, this code isn't needed (65k is the max even without this)
if (sizeof(ullpaylen) < 8)
{
Con_Printf ("%s: payload frame too large\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
else
{
if (payoffs + 8 > st->inlen)
break;
ullpaylen =
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+0]<<56u |
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+1]<<48u |
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+2]<<40u |
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+3]<<32u |
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+4]<<24u |
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+5]<<16u |
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+6]<< 8u |
(quint64_t)((unsigned char*)st->inbuffer)[payoffs+7]<< 0u;
if (ullpaylen < 0x10000)
{
Con_Printf ("%s: payload size (%"PRIu64") encoded badly\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr), ullpaylen);
return FTETCP_KILL;
}
if (ullpaylen > 0x40000)
{
Con_Printf ("%s: payload size (%"PRIu64") is abusive\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr), ullpaylen);
return FTETCP_KILL;
}
paylen = ullpaylen;
payoffs += 8;
}
}
else if ((ctrl & 0x7f) == 126)
{
if (payoffs + 2 > st->inlen)
break;
paylen =
((unsigned char*)st->inbuffer)[payoffs+0]<<8 |
((unsigned char*)st->inbuffer)[payoffs+1]<<0;
if (paylen < 126)
{
Con_Printf ("%s: payload size encoded badly\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
payoffs += 2;
}
else
{
paylen = ctrl & 0x7f;
}
if (ctrl & 0x80)
{
if (payoffs + 4 > st->inlen)
break;
/*this might read data that isn't set yet, but should be safe*/
((unsigned char*)&mask)[0] = ((unsigned char*)st->inbuffer)[payoffs+0];
((unsigned char*)&mask)[1] = ((unsigned char*)st->inbuffer)[payoffs+1];
((unsigned char*)&mask)[2] = ((unsigned char*)st->inbuffer)[payoffs+2];
((unsigned char*)&mask)[3] = ((unsigned char*)st->inbuffer)[payoffs+3];
payoffs += 4;
}
/*if there isn't space, try again next time around*/
if (payoffs + paylen > st->inlen)
{
if (payoffs + paylen >= sizeof(st->inbuffer)-1)
{
Con_TPrintf ("Warning: Oversize packet from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
break;
}
if (mask)
{
int i;
for (i = 0; i < paylen; i++)
{
((unsigned char*)st->inbuffer)[i + payoffs] ^= ((unsigned char*)&mask)[i&3];
}
}
net_message.cursize = 0;
switch((ctrl>>8) & 0xf)
{
case WS_PACKETTYPE_CONTINUATION: /*continuation*/
Con_Printf ("websocket continuation frame from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL; //can't handle these.
case WS_PACKETTYPE_TEXTFRAME: /*text frame*/
// Con_Printf ("websocket text frame from %s\n", NET_AdrToString (adr, sizeof(adr), st->remoteaddr));
{
/*text frames are pure utf-8 chars, no dodgy encodings or anything, all pre-checked...
except we're trying to send binary data.
so we need to unmask things (char 0 is encoded as 0x100 - truncate it)
*/
unsigned char *in = st->inbuffer+payoffs, *out = net_message_buffer;
int len = paylen;
while(len && out < net_message_buffer + sizeof(net_message_buffer))
{
if ((*in & 0xe0)==0xc0 && len > 1)
{
*out = ((in[0] & 0x1f)<<6) | ((in[1] & 0x3f)<<0);
in+=2;
len -= 2;
}
else if (*in & 0x80)
{
*out = '?';
in++;
len -= 1;
}
else
{
*out = in[0];
in++;
len -= 1;
}
out++;
}
net_message.cursize = out - net_message_buffer;
}
break;
case WS_PACKETTYPE_BINARYFRAME: /*binary frame*/
// Con_Printf ("websocket binary frame from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
net_message.cursize = paylen;
if (net_message.cursize+8 >= sizeof(net_message_buffer) )
{
Con_TPrintf ("Warning: Oversize packet from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
#ifdef SUPPORT_RTC_ICE
if (st->clienttype == TCPC_WEBRTC_CLIENT && !*st->webrtc.resource)
{ //this is a client that's connected directly to us via webrtc.
//FIXME: we don't support dtls, so browers will bitch about our sdp.
if (paylen+1 < sizeof(net_message_buffer))
{
net_message_buffer[paylen] = 0;
memcpy(net_message_buffer, st->inbuffer+payoffs, paylen);
if (!st->webrtc.ice) //if the ice state isn't established yet, do that now.
st->webrtc.ice = iceapi.ICE_Create(NULL, "test", "rtc://foo", ICEM_ICE, ICEP_QWSERVER);
iceapi.ICE_Set(st->webrtc.ice, "sdp", net_message_buffer);
if (iceapi.ICE_Get(st->webrtc.ice, "sdp", net_message_buffer, sizeof(net_message_buffer)))
FTENET_TCP_WebSocket_Splurge(st, WS_PACKETTYPE_BINARYFRAME, net_message_buffer, strlen(net_message_buffer));
}
net_message.cursize = 0;
}
else
#endif
if (st->clienttype == TCPC_WEBRTC_HOST && st->inbuffer[payoffs+0] == ICEMSG_SERVERINFO)
{
#ifdef SV_MASTER
qbyte old = st->inbuffer[payoffs+paylen];
st->inbuffer[payoffs+paylen] = 0; //make sure its null terminated...
SVM_AddBrokerGame(st->webrtc.resource, st->inbuffer+payoffs+3);
st->inbuffer[payoffs+paylen] = old;
#endif
}
else if ((st->clienttype == TCPC_WEBRTC_CLIENT || st->clienttype == TCPC_WEBRTC_HOST) && paylen >= 3)
{ //we're brokering a client+server. all messages should be unicasts between a client and its host, matched by resource.
ftenet_tcp_stream_t *o;
short clnum = (st->inbuffer[payoffs+1]<<0)|(st->inbuffer[payoffs+2]<<8);
int type = (st->clienttype != TCPC_WEBRTC_CLIENT)?TCPC_WEBRTC_CLIENT:TCPC_WEBRTC_HOST;
for (o = con->tcpstreams; o; o = o->next)
{
if (o->clienttype == type && clnum == o->webrtc.clientnum && !strcmp(o->webrtc.resource, st->webrtc.resource))
{
st->inbuffer[payoffs+1] = (st->webrtc.clientnum>>0)&0xff;
st->inbuffer[payoffs+2] = (st->webrtc.clientnum>>8)&0xff;
FTENET_TCP_WebSocket_Splurge(o, WS_PACKETTYPE_BINARYFRAME, st->inbuffer+payoffs, paylen);
break;
}
}
if (!o)
Con_DPrintf("Unable to relay\n");
net_message.cursize = 0;
}
else
#ifdef NQPROT
if (st->clienttype == TCPC_WEBSOCKETNQ)
{ //hack in an 8-byte header
payoffs+=1;
paylen-=1;
memcpy(net_message_buffer+8, st->inbuffer+payoffs, paylen);
net_message.cursize=paylen+8;
((int*)net_message_buffer)[0] = BigLong(NETFLAG_UNRELIABLE | net_message.cursize);
((int*)net_message_buffer)[1] = LongSwap(++st->fakesequence);
}
else
#endif
memcpy(net_message_buffer, st->inbuffer+payoffs, paylen);
break;
case WS_PACKETTYPE_CLOSE: /*connection close*/
Con_Printf ("websocket closure %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
case WS_PACKETTYPE_PING: /*ping*/
// Con_Printf ("websocket ping from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
if (FTENET_TCP_WebSocket_Splurge(st, WS_PACKETTYPE_PONG, st->inbuffer+payoffs, paylen) != NETERR_SENT)
return FTETCP_KILL;
break;
case WS_PACKETTYPE_PONG: /*pong*/
st->timeouttime = Sys_DoubleTime() + 30;
st->pinging = false;
// Con_Printf ("websocket pong from %s\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
break;
default:
Con_Printf ("Unsupported websocket opcode (%i) from %s\n", (ctrl>>8) & 0xf, NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
return FTETCP_KILL;
}
memmove(st->inbuffer, st->inbuffer+payoffs + paylen, st->inlen - (payoffs + paylen));
st->inlen -= payoffs + paylen;
if (net_message.cursize)
{
net_message.packing = SZ_RAWBYTES;
net_message.currentbit = 0;
net_from = st->remoteaddr;
net_from.connum = con->generic.connum;
net_from_connection = &con->generic;
con->generic.owner->ReadGamePacket();
return FTETCP_RETRY;
}
}
return FTETCP_DONE;
#endif
}
return FTETCP_DONE;
}
#ifdef HAVE_EPOLL
static void FTENET_TCP_Polled(epollctx_t *ctx, unsigned int events)
{
ftenet_tcp_stream_t *st = NULL;
st = (ftenet_tcp_stream_t *)((qbyte*)ctx - ((qbyte*)&st->epoll-(qbyte*)st));
for(;st->clientstream;)
{
switch(FTENET_TCP_ReadStream(st->con, st))
{
case FTETCP_RETRY:
continue;
case FTETCP_KILL:
FTENET_TCP_KillStream(st->con, st);
return;
case FTETCP_DONE:
FTENET_TCP_Flush(st->con, st);
return;
}
}
}
#endif
qboolean FTENET_TCP_GetPacket(ftenet_generic_connection_t *gcon)
{
ftenet_tcp_connection_t *con = (ftenet_tcp_connection_t*)gcon;
int ret;
char adr[MAX_ADR_SIZE];
struct sockaddr_qstorage from;
int fromlen;
float timeval = Sys_DoubleTime();
ftenet_tcp_stream_t *st;
st = con->tcpstreams;
while (con->tcpstreams && con->tcpstreams->clientstream == NULL)
{ //remove initial stale ones
st = con->tcpstreams;
con->tcpstreams = con->tcpstreams->next;
#ifdef HAVE_EPOLL
st->epoll.Polled = NULL; //to cause segfaults if we failed somehow.
#endif
BZ_Free(st);
con->active--;
}
for (st = con->tcpstreams; st; st = st->next)
{//client receiving only via tcp
while (st->next && st->next->clientstream == NULL)
{ //remove following stale ones
ftenet_tcp_stream_t *temp;
temp = st->next;
st->next = st->next->next;
#ifdef HAVE_EPOLL
temp->epoll.Polled = NULL; //to cause segfaults if we failed somehow.
#endif
BZ_Free(temp);
con->active--;
}
//due to the above checks about invalid sockets, the socket is always open for st below.
if (st->timeouttime < timeval)
{
#ifdef HAVE_HTTPSV
if (!st->pinging && (st->clienttype==TCPC_WEBRTC_CLIENT||st->clienttype==TCPC_WEBRTC_HOST) && *st->webrtc.resource)
{ //ping broker clients. there usually shouldn't be any data flow to keep it active otherwise.
st->timeouttime = timeval + 30;
st->pinging = true;
FTENET_TCP_WebSocket_Splurge(st, WS_PACKETTYPE_PING, "ping", 4);
}
else
#endif
{
Con_DPrintf ("tcp peer %s timed out\n", NET_AdrToString (adr, sizeof(adr), &st->remoteaddr));
FTENET_TCP_KillStream(con, st);
continue;
}
}
for(;st->clientstream;)
{
ret = FTENET_TCP_ReadStream(con, st);
if (ret == FTETCP_RETRY)
continue;
else if (ret == FTETCP_KILL)
FTENET_TCP_KillStream(con, st);
break;
}
FTENET_TCP_Flush(con, st);
}
if (con->generic.thesocket != INVALID_SOCKET && con->active < 256)
{
int newsock;
fromlen = sizeof(from);
newsock = accept(con->generic.thesocket, (struct sockaddr*)&from, &fromlen);
if (newsock != INVALID_SOCKET)
{
char tmpbuf[256];
int _true = true;
ioctlsocket(newsock, FIONBIO, (u_long *)&_true);
setsockopt(newsock, IPPROTO_TCP, TCP_NODELAY, (char *)&_true, sizeof(_true));
con->active++;
st = Z_Malloc(sizeof(*con->tcpstreams));
/*grab the net address*/
SockadrToNetadr(&from, fromlen, &st->remoteaddr);
if (developer.ival)
Con_Printf("new TCP connection from %s\n", NET_AdrToString(tmpbuf, sizeof(tmpbuf), &st->remoteaddr));
st->clienttype = TCPC_UNKNOWN;
st->next = con->tcpstreams;
con->tcpstreams = st;
st->socketnum = newsock;
st->clientstream = FS_WrapTCPSocket(newsock, false, NET_AdrToString(tmpbuf, sizeof(tmpbuf), &st->remoteaddr));
st->inlen = 0;
#ifdef HAVE_EPOLL
{
struct epoll_event event = {EPOLLIN|EPOLLOUT|EPOLLET, {&st->epoll}};
st->con = con;
st->epoll.Polled = FTENET_TCP_Polled;
epoll_ctl(epoll_fd, EPOLL_CTL_ADD, newsock, &event);
}
#endif
#ifdef HAVE_SSL
if (con->tls && st->clientstream) //if we're meant to be using tls, wrap the stream in a tls connection
{
st->clientstream = FS_OpenSSL(NULL, st->clientstream, true);
/*sockadr doesn't contain transport info, so fix that up here*/
st->remoteaddr.prot = NP_TLS;
}
else
#endif
{
/*sockadr doesn't contain transport info, so fix that up here*/
st->remoteaddr.prot = NP_STREAM;
}
st->timeouttime = timeval + 30;
}
}
return false;
}
neterr_t FTENET_TCP_SendPacket(ftenet_generic_connection_t *gcon, int length, const void *data, netadr_t *to)
{
ftenet_tcp_connection_t *con = (ftenet_tcp_connection_t*)gcon;
ftenet_tcp_stream_t *st;
for (st = con->tcpstreams; st; st = st->next)
{
if (st->clientstream == NULL)
continue;
if (NET_CompareAdr(to, &st->remoteaddr))
{
if (!st->outlen)
{
switch(st->clienttype)
{
case TCPC_QIZMO:
{
unsigned short slen = BigShort((unsigned short)length);
if (length > 0xffff)
return NETERR_MTU;
if (st->outlen + sizeof(slen) + length > sizeof(st->outbuffer))
{
if (length+sizeof(slen) > sizeof(st->outbuffer))
return NETERR_MTU;
Con_DPrintf("FTENET_TCP_SendPacket: outgoing overflow\n");
return NETERR_CLOGGED;
}
else
{
memcpy(st->outbuffer + st->outlen, &slen, sizeof(slen));
memcpy(st->outbuffer + st->outlen + sizeof(slen), data, length);
st->outlen += sizeof(slen) + length;
}
}
break;
#ifdef HAVE_HTTPSV
case TCPC_WEBSOCKETNQ:
if (length < 8 || ((char*)data)[0] & 0x80)
break;
// length = 2;
// data = "\1\1";
length-=7;
data=(char*)data + 7;
*(char*)data = 1; //for compat with webquake, we add an extra byte at the start. 1 for reliable, 2 for unreliable.
//fallthrough
case TCPC_WEBSOCKETU:
case TCPC_WEBSOCKETB:
{
neterr_t e = FTENET_TCP_WebSocket_Splurge(st, (st->clienttype==TCPC_WEBSOCKETU)?WS_PACKETTYPE_TEXTFRAME:WS_PACKETTYPE_BINARYFRAME, data, length);
if (e != NETERR_SENT)
return e;
}
break;
#endif
default:
break;
}
}
if (st->outlen)
{ /*try and flush the old data*/
int done;
done = VFS_WRITE(st->clientstream, st->outbuffer, st->outlen);
if (done > 0)
{
memmove(st->outbuffer, st->outbuffer + done, st->outlen - done);
st->outlen -= done;
}
}
st->timeouttime = Sys_DoubleTime() + 20;
return NETERR_SENT;
}
}
return NETERR_NOROUTE;
}
static int FTENET_TCP_GetLocalAddresses(struct ftenet_generic_connection_s *gcon, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
ftenet_tcp_connection_t *con = (ftenet_tcp_connection_t*)gcon;
netproto_t prot = con->tls?NP_TLS:NP_STREAM;
int i, r = FTENET_Generic_GetLocalAddresses(gcon, adrflags, addresses, adrparams, maxaddresses);
for (i = 0; i < r; i++)
{
addresses[i].prot = prot;
}
return r;
}
static qboolean FTENET_TCP_ChangeLocalAddress(struct ftenet_generic_connection_s *con, const char *addressstring, netadr_t *adr)
{
//if we're a server, we want to try switching listening tcp port without shutting down all other connections.
//yes, this might mean we leave a connection active on the old port, but oh well.
int addrsize, addrsize2;
int family;
struct sockaddr_qstorage qs;
struct sockaddr_qstorage cur;
netadr_t n;
SOCKET newsocket = INVALID_SOCKET;
unsigned long _true = true;
int sysprot;
addrsize = NetadrToSockadr(adr, &qs);
family = ((struct sockaddr*)&qs)->sa_family;
switch(adr->type)
{
#if defined(HAVE_IPV4) || defined(HAVE_IPV6)
case NA_IP:
case NA_IPV6:
sysprot = IPPROTO_TCP;
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
sysprot = NSPROTO_IPX;
break;
#endif
default:
sysprot = 0;
break;
}
if (con->thesocket != INVALID_SOCKET)
{
addrsize2 = sizeof(cur);
getsockname(con->thesocket, (struct sockaddr *)&cur, &addrsize2);
if (addrsize == addrsize2)
{
SockadrToNetadr(&cur, addrsize2, &n);
if (NET_CompareAdr(adr, &n)) //the address+port we're trying is already current, apparently.
return true;
}
closesocket(con->thesocket);
con->thesocket = INVALID_SOCKET;
}
#if defined(HAVE_IPV6) && defined(IPV6_V6ONLY)
if (newsocket == INVALID_SOCKET)
if (family == AF_INET && net_hybriddualstack.ival && !((struct sockaddr_in*)&qs)->sin_addr.s_addr)
{ //hybrid sockets pathway takes over when INADDR_ANY
unsigned long _false = false;
if ((newsocket = socket (AF_INET6, SOCK_STREAM, sysprot)) != INVALID_SOCKET)
{
#ifdef __linux__ //note: windows blindly allows dupes, whereas linux prevents exact matches
setsockopt(newsocket, SOL_SOCKET, SO_REUSEADDR, (const char *)&_true, sizeof(_true)); //try to avoid 'address in use' problems when killing+restarting.
#elif defined(_WIN32)
setsockopt(newsocket, SOL_SOCKET, SO_REUSEADDR, (const char *)&_true, sizeof(_true)); //try to avoid 'address in use' problems when killing+restarting.
#endif
if (0 == setsockopt(newsocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_false, sizeof(_false)))
{
memset(&n, 0, sizeof(n));
n.type = NA_IPV6;
n.port = adr->port;
n.scopeid = adr->scopeid;
addrsize2 = NetadrToSockadr(&n, &cur);
if ((bind(newsocket, (struct sockaddr *)&cur, addrsize2) != INVALID_SOCKET) &&
(listen(newsocket, 2) != INVALID_SOCKET) &&
ioctlsocket (newsocket, FIONBIO, &_true) != -1)
{
con->addrtype[0] = NA_IP;
con->addrtype[1] = NA_IPV6;
}
else
{
closesocket(newsocket);
newsocket = INVALID_SOCKET;
}
}
else
{
closesocket(newsocket);
newsocket = INVALID_SOCKET;
}
}
}
#endif
if (newsocket == INVALID_SOCKET)
{
if ((newsocket = socket (family, SOCK_STREAM, sysprot)) != INVALID_SOCKET)
{
#ifdef UNIXSOCKETS
if (family == AF_UNIX)
{
struct sockaddr_un *un = (struct sockaddr_un *)&qs;
struct stat s;
if (*un->sun_path)
{ //non-abstract sockets don't clean up the filesystem when the socket is closed
//and we can't re-bind to it while it still exists.
//so standard practise is to delete it before the bind.
//we do want to make sure the file is actually a socket before we remove it (so people can't abuse stuffcmds)
if (stat(un->sun_path, &s)!=-1)
{
if ((s.st_mode & S_IFMT) == S_IFSOCK)
unlink(un->sun_path);
}
}
}
#endif
if ((bind(newsocket, (struct sockaddr *)&qs, addrsize) != INVALID_SOCKET) &&
(listen(newsocket, 2) != INVALID_SOCKET) &&
ioctlsocket (newsocket, FIONBIO, &_true) != -1)
;
else
{
closesocket(newsocket);
newsocket = INVALID_SOCKET;
}
}
}
if (newsocket != INVALID_SOCKET)
{
#ifdef UNIXSOCKETS
if (family != NA_UNIX)
#endif
setsockopt(newsocket, IPPROTO_TCP, TCP_NODELAY, (char *)&_true, sizeof(_true));
con->thesocket = newsocket;
#ifdef HAVE_EPOLL
{
struct epoll_event event = {EPOLLIN|EPOLLET, {NULL}};//&newcon->generic.epoll}};
//newcon->generic.epoll.Polled = FTENET_TCP_AcceptPolled;
epoll_ctl(epoll_fd, EPOLL_CTL_ADD, newsocket, &event);
}
#endif
return true;
}
return false;
}
static void FTENET_TCP_Close(ftenet_generic_connection_t *gcon)
{
ftenet_tcp_connection_t *con = (ftenet_tcp_connection_t*)gcon;
ftenet_tcp_stream_t *st;
st = con->tcpstreams;
while (con->tcpstreams)
{
st = con->tcpstreams;
con->tcpstreams = st->next;
if (st->clientstream != NULL)
VFS_CLOSE(st->clientstream);
BZ_Free(st);
}
FTENET_Datagram_Close(gcon);
}
#if defined(HAVE_PACKET) && !defined(HAVE_EPOLL)
static int FTENET_TCP_SetFDSets(ftenet_generic_connection_t *gcon, fd_set *readfdset, fd_set *writefdset)
{
int maxfd = -1;
ftenet_tcp_connection_t *con = (ftenet_tcp_connection_t*)gcon;
ftenet_tcp_stream_t *st;
for (st = con->tcpstreams; st; st = st->next)
{
#ifdef SUPPORT_RTC_ICE
if (st->webrtc.ice)
{
while(iceapi.ICE_GetLCandidateSDP(st->webrtc.ice, net_message_buffer, sizeof(net_message_buffer)))
{
FTENET_TCP_WebSocket_Splurge(st, WS_PACKETTYPE_BINARYFRAME, net_message_buffer, strlen(net_message_buffer));
}
continue;
}
#endif
if (st->clientstream == NULL || st->socketnum == INVALID_SOCKET)
continue;
#ifdef HAVE_HTTPSV
if (st->clienttype == TCPC_HTTPCLIENT && st->outlen)
FD_SET(st->socketnum, writefdset); // network socket
#endif
FD_SET(st->socketnum, readfdset); // network socket
if (maxfd < st->socketnum)
maxfd = st->socketnum;
}
if (con->generic.thesocket != INVALID_SOCKET)
{
FD_SET(con->generic.thesocket, readfdset); // network socket
if (maxfd < con->generic.thesocket)
maxfd = con->generic.thesocket;
}
return maxfd;
}
#endif
ftenet_generic_connection_t *FTENET_TCP_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr)
{
//this is written to support either ipv4 or ipv6, depending on the remote addr.
ftenet_tcp_connection_t *newcon;
qboolean isserver = col->islisten;
unsigned long _true = true;
SOCKET newsocket;
qboolean tls = (adr.prot == NP_TLS || adr.prot == NP_WSS);
#ifndef HAVE_SSL
if (tls)
{
Con_Printf("tls not supported in this build\n");
return NULL;
}
#endif
newcon = Z_Malloc(sizeof(*newcon));
newcon->generic.thesocket = newsocket = INVALID_SOCKET;
newcon->generic.addrtype[0] = adr.type;
newcon->generic.addrtype[1] = NA_INVALID;
if (isserver)
{
#ifdef HAVE_PACKET //unable to listen on tcp if we have no packet interface
if (!FTENET_TCP_ChangeLocalAddress(&newcon->generic, address, &adr))
{
Z_Free(newcon);
return NULL;
}
#endif
}
else
{
newsocket = TCP_OpenStream(&adr, address);
if (newsocket == INVALID_SOCKET)
{
Z_Free(newcon);
return NULL;
}
#ifdef UNIXSOCKETS
if (adr.type != NA_UNIX)
#endif
{
//this isn't fatal
setsockopt(newsocket, IPPROTO_TCP, TCP_NODELAY, (char *)&_true, sizeof(_true));
}
}
if (newcon)
{
newcon->tls = tls;
if (isserver)
{
newcon->generic.GetLocalAddresses = FTENET_TCP_GetLocalAddresses;
newcon->generic.ChangeLocalAddress = FTENET_TCP_ChangeLocalAddress;
}
newcon->generic.GetPacket = FTENET_TCP_GetPacket;
newcon->generic.SendPacket = FTENET_TCP_SendPacket;
newcon->generic.Close = FTENET_TCP_Close;
#if defined(HAVE_PACKET) && !defined(HAVE_EPOLL)
newcon->generic.SetFDSets = FTENET_TCP_SetFDSets;
#endif
newcon->generic.PrintStatus = FTENET_TCP_PrintStatus;
newcon->generic.owner = col;
newcon->generic.islisten = isserver;
newcon->active = 0;
if (!isserver)
{
newcon->active++;
newcon->tcpstreams = Z_Malloc(sizeof(*newcon->tcpstreams));
newcon->tcpstreams->next = NULL;
newcon->tcpstreams->socketnum = newsocket;
newcon->tcpstreams->clientstream = FS_WrapTCPSocket(newsocket, true, address);
newcon->tcpstreams->inlen = 0;
newcon->tcpstreams->remoteaddr = adr;
#ifdef HAVE_SSL
if (newcon->tls) //if we're meant to be using tls, wrap the stream in a tls connection
{ //remove any markup junk, get just the hostname out of it.
char hostonly[MAX_QPATH];
const char *host = strstr(address, "://");
const char *port;
host = host?host+3:address;
port = strchr(host, ':');
if (!port)
port = host+strlen(host);
if (port-host >= sizeof(hostonly))
{
VFS_CLOSE(&newcon->generic);
return NULL;
}
memcpy(hostonly, host, port-host);
hostonly[port-host] = 0;
newcon->tcpstreams->clientstream = FS_OpenSSL(hostonly, newcon->tcpstreams->clientstream, false);
if (!newcon->tcpstreams->clientstream)
return NULL;
}
#endif
//send the qizmo greeting. any actual data is just <ushort len><byte data[len]> otherwise consistent with qw/udp, including challenges.
newcon->tcpstreams->clienttype = TCPC_UNKNOWN;
memcpy(newcon->tcpstreams->outbuffer, "qizmo\n", newcon->tcpstreams->outlen = 6);
newcon->tcpstreams->timeouttime = Sys_DoubleTime() + 30;
}
else
{
newcon->tcpstreams = NULL;
}
return &newcon->generic;
}
else
{
closesocket(newsocket);
return NULL;
}
}
#endif
#ifdef IRCCONNECT
typedef struct ftenet_ircconnect_stream_s {
char theiruser[16];
int inlen;
char inbuffer[1500];
float timeouttime;
netadr_t remoteaddr;
struct ftenet_ircconnect_stream_s *next;
} ftenet_ircconnect_stream_t;
typedef struct {
ftenet_generic_connection_t generic;
netadr_t ircserver;
char incoming[512+1];
int income;
char ourusername[16];
char usechannel[16];
char outbuf[8192];
unsigned int outbufcount;
ftenet_ircconnect_stream_t *streams;
} ftenet_ircconnect_connection_t;
qboolean FTENET_IRCConnect_GetPacket(ftenet_generic_connection_t *gcon)
{
unsigned char *s, *start, *end, *endl;
int read;
unsigned char *from;
int fromlen;
int code;
char adr[128];
ftenet_ircconnect_connection_t *con = (ftenet_ircconnect_connection_t*)gcon;
if (con->generic.thesocket == INVALID_SOCKET)
{
if (con->income == 0)
{
netadr_t ip;
cvar_t *ircuser = Cvar_Get("ircuser", "none", 0, "IRC Connect");
cvar_t *ircnick = Cvar_Get("ircnick", "", 0, "IRC Connect");
cvar_t *ircsomething = Cvar_Get("ircsomething", "moo", 0, "IRC Connect");
cvar_t *ircclientaddr = Cvar_Get("ircclientaddr", "127.0.0.1", 0, "IRC Connect");
if (!NET_StringToAdr(con->ircserver.address.irc.host, 6667, &ip))
return false;
con->generic.thesocket = TCP_OpenStream(&ip);
//when hosting, the specified nick is the name we're using.
//when connecting, the specified nick is the name we're trying to send to, and our own name is inconsequential.
if (con->generic.islisten && *con->ircserver.address.irc.user)
Q_strncpyz(con->ourusername, con->ircserver.address.irc.user, sizeof(con->ourusername));
else
Q_strncpyz(con->ourusername, ircnick->string, sizeof(con->ourusername));
if (!*con->ourusername)
{
Q_snprintfz(con->ourusername, sizeof(con->ourusername), "fte%x\n", rand());
}
send(con->generic.thesocket, "USER ", 5, 0);
send(con->generic.thesocket, ircuser->string, strlen(ircuser->string), 0);
send(con->generic.thesocket, " ", 1, 0);
send(con->generic.thesocket, con->ircserver.address.irc.host, strlen(con->ircserver.address.irc.host), 0);
send(con->generic.thesocket, " ", 1, 0);
send(con->generic.thesocket, ircclientaddr->string, strlen(ircclientaddr->string), 0);
send(con->generic.thesocket, " :", 2, 0);
send(con->generic.thesocket, ircsomething->string, strlen(ircsomething->string), 0);
send(con->generic.thesocket, "\r\n", 2, 0);
send(con->generic.thesocket, "NICK ", 5, 0);
send(con->generic.thesocket, con->ourusername, strlen(con->ourusername), 0);
send(con->generic.thesocket, "\r\n", 2, 0);
}
}
else
{
read = recv(con->generic.thesocket, con->incoming+con->income, sizeof(con->incoming)-1 - con->income, 0);
if (read < 0)
{
read = neterrno();
switch(read)
{
case NET_ECONNABORTED:
case NET_ECONNRESET:
closesocket(con->generic.thesocket);
con->generic.thesocket = INVALID_SOCKET;
break;
default:
break;
}
read = 0;//return false;
}
else if (read == 0) //they disconnected.
{
closesocket(con->generic.thesocket);
con->generic.thesocket = INVALID_SOCKET;
}
con->income += read;
con->incoming[con->income] = 0;
}
start = con->incoming;
end = start+con->income;
while (start < end)
{
endl = NULL;
for (s = start; s < end; s++)
{
if (*s == '\n')
{
endl = s;
break;
}
}
if (endl == NULL)
//not got a complete command.
break;
s = start;
while(*s == ' ')
s++;
if (*s == ':')
{
s++;
from = s;
while(s<endl && *s != ' ' && *s != '\n')
{
s++;
}
fromlen = s - from;
}
else
{
from = NULL;
fromlen = 0;
}
while(*s == ' ')
s++;
if (!strncmp(s, "PRIVMSG ", 8))
{
unsigned char *dest;
s+=8;
while(*s == ' ')
s++;
//cap the length
if (fromlen > sizeof(net_from.address.irc.user)-1)
fromlen = sizeof(net_from.address.irc.user)-1;
for (code = 0; code < fromlen; code++)
if (from[code] == '!')
{
fromlen = code;
break;
}
net_from.type = NA_IRC;
memcpy(net_from.address.irc.user, from, fromlen);
net_from.address.irc.user[fromlen] = 0;
dest = s;
//discard the destination name
while(s<endl && *s != ' ' && *s != '\n')
{
s++;
}
if (s-dest >= sizeof(net_from.address.irc.channel))
{ //no space, just pretend it was direct.
net_from.address.irc.channel[0] = 0;
}
else
{
memcpy(net_from.address.irc.channel, dest, s-dest);
net_from.address.irc.channel[s-dest] = 0;
if (!strcmp(net_from.address.irc.channel, con->ourusername))
{ //this was aimed at us. clear the channel.
net_from.address.irc.channel[0] = 0;
}
}
while(*s == ' ')
s++;
if (*s == ':')
{
s++;
if (*s == '!')
{
s++;
/*interpret as a connectionless packet*/
net_message.cursize = 4 + endl - s;
if (net_message.cursize >= sizeof(net_message_buffer) )
{
Con_TPrintf ("Warning: Oversize packet from %s\n", NET_AdrToString (adr, sizeof(adr), &net_from));
break;
}
*(unsigned int*)net_message_buffer = ~0;
memcpy(net_message_buffer+4, s, net_message.cursize);
net_message.packing = SZ_RAWBYTES;
net_message.currentbit = 0;
//clean up the incoming data
memmove(con->incoming, start, end - (endl+1));
con->income = end - (endl+1);
con->incoming[con->income] = 0;
return true;
}
if (*s == '$')
{
unsigned char *nstart = s;
while (*s != '\r' && *s != '\n' && *s != '#' && *s != ' ' && *s != ':')
s++;
if (*s == '#')
{
if (strncmp(nstart, con->ourusername, strlen(con->ourusername)) || strlen(con->ourusername) != s - nstart)
while(*s == '#')
s++;
}
}
if (*s == '#')
{
ftenet_ircconnect_stream_t *st;
int psize;
for (st = con->streams; st; st = st->next)
{
if (!strncmp(st->remoteaddr.address.irc.user, from, fromlen) && st->remoteaddr.address.irc.user[fromlen] == 0)
break;
}
if (!st)
{
st = Z_Malloc(sizeof(*st));
st->remoteaddr = net_from;
st->next = con->streams;
con->streams = st;
}
//skip over the hash
s++;
psize = 0;
if (*s >= 'a' && *s <= 'f')
psize += *s - 'a' + 10;
else if (*s >= '0' && *s <= '9')
psize += *s - '0';
s++;
psize*=16;
if (*s >= 'a' && *s <= 'f')
psize += *s - 'a' + 10;
else if (*s >= '0' && *s <= '9')
psize += *s - '0';
s++;
psize*=16;
if (*s >= 'a' && *s <= 'f')
psize += *s - 'a' + 10;
else if (*s >= '0' && *s <= '9')
psize += *s - '0';
s++;
while (s < endl && st->inlen < sizeof(st->inbuffer))
{
switch (*s)
{
//handle markup
case '\\':
s++;
if (s < endl)
{
switch(*s)
{
case '\\':
st->inbuffer[st->inlen++] = *s;
break;
case 'n':
st->inbuffer[st->inlen++] = '\n';
break;
case 'r':
st->inbuffer[st->inlen++] = '\r';
break;
case '0':
st->inbuffer[st->inlen++] = 0;
break;
default:
st->inbuffer[st->inlen++] = '?';
break;
}
}
break;
//ignore these
case '\n':
case '\r':
case '\0': //this one doesn't have to be ignored.
break;
//handle normal char
default:
st->inbuffer[st->inlen++] = *s;
break;
}
s++;
}
if (st->inlen > psize || psize >= sizeof(net_message_buffer) )
{
st->inlen = 0;
Con_Printf ("Corrupt packet from %s\n", NET_AdrToString (adr, sizeof(adr), &net_from));
}
else if (st->inlen == psize)
{
/*interpret as a connectionless packet*/
net_message.cursize = st->inlen;
if (net_message.cursize >= sizeof(net_message_buffer) )
{
Con_TPrintf ("Warning: Oversize packet from %s\n", NET_AdrToString (adr, sizeof(adr), &net_from));
break;
}
memcpy(net_message_buffer, st->inbuffer, net_message.cursize);
net_message.packing = SZ_RAWBYTES;
net_message.currentbit = 0;
st->inlen = 0;
//clean up the incoming data
memmove(con->incoming, start, end - (endl+1));
con->income = end - (endl+1);
con->incoming[con->income] = 0;
return true;
}
}
}
}
else if (!strncmp(s, "PING ", 5))
{
send(con->generic.thesocket, "PONG ", 5, 0);
send(con->generic.thesocket, s+5, endl - s - 5, 0);
send(con->generic.thesocket, "\r\n", 2, 0);
}
else
{
code = strtoul(s, (char **)&s, 10);
switch (code)
{
case 1:
{
if (con->ircserver.address.irc.channel)
{
send(con->generic.thesocket, "JOIN ", 5, 0);
send(con->generic.thesocket, con->ircserver.address.irc.channel, strlen(con->ircserver.address.irc.channel), 0);
send(con->generic.thesocket, "\r\n", 2, 0);
}
}
break;
case 433:
//nick already in use
send(con->generic.thesocket, "NICK ", 5, 0);
{
cvar_t *ircnick2 = Cvar_Get("ircnick2", "YIBBLE", 0, "IRC Connect");
Q_strncpyz(con->ourusername, ircnick2->string, sizeof(con->ourusername));
send(con->generic.thesocket, con->ourusername, strlen(con->ourusername), 0);
}
send(con->generic.thesocket, "\r\n", 2, 0);
break;
case 0:
//non-numerical event.
break;
}
}
while(*s == ' ')
s++;
start = s = endl+1;
}
memmove(con->incoming, start, end - start);
con->income = end - start;
con->incoming[con->income] = 0;
if (con->generic.thesocket == INVALID_SOCKET)
con->income = 0;
return false;
}
neterr_t FTENET_IRCConnect_SendPacket(ftenet_generic_connection_t *gcon, int length, const void *data, netadr_t *to)
{
ftenet_ircconnect_connection_t *con = (ftenet_ircconnect_connection_t*)gcon;
unsigned char *buffer;
unsigned char *lenofs;
int packed;
int fulllen = length;
int newoutcount;
for (packed = 0; packed < FTENET_ADDRTYPES; packed++)
if (to->type == con->generic.addrtype[packed])
break;
if (packed == FTENET_ADDRTYPES)
return NETERR_NOROUTE;
packed = 0;
if (con->generic.thesocket == INVALID_SOCKET)
return NETERR_DISCONNECTED;
/*
if (*(unsigned int *)data == ~0 && !strchr(data, '\n') && !strchr(data, '\r') && strlen(data) == length)
{
if (send(con->generic.thesocket, va("PRIVMSG %s :!", to.address.irc.user), 15, 0) != 15)
Con_Printf("bad send\n");
else if (send(con->generic.thesocket, (char*)data+4, length - 4, 0) != length-4)
Con_Printf("bad send\n");
else if (send(con->generic.thesocket, "\r\n", 2, 0) != 2)
Con_Printf("bad send\n");
return true;
}
*/
newoutcount = con->outbufcount;
if (!con->outbufcount)
while(length)
{
buffer = con->outbuf + newoutcount;
if (*to->address.irc.channel)
{
int unamelen;
int chanlen;
unamelen = strlen(to->address.irc.user);
chanlen = strlen(to->address.irc.channel);
packed = 8+chanlen+3+unamelen+1 + 3;
if (packed+1 + newoutcount > sizeof(con->outbuf))
break;
memcpy(buffer, "PRIVMSG ", 8);
memcpy(buffer+8, to->address.irc.channel, chanlen);
memcpy(buffer+8+chanlen, " :$", 3);
memcpy(buffer+8+chanlen+3, to->address.irc.user, unamelen);
memcpy(buffer+8+chanlen+3+unamelen, "#", 1);
lenofs = buffer+8+chanlen+3+unamelen+1;
sprintf(lenofs, "%03x", fulllen);
}
else
{
int unamelen;
unamelen = strlen(to->address.irc.user);
packed = 8 + unamelen + 3 + 3;
if (packed+1 + newoutcount > sizeof(con->outbuf))
break;
memcpy(buffer, "PRIVMSG ", 8);
memcpy(buffer+8, to->address.irc.user, unamelen);
memcpy(buffer+8+unamelen, " :#", 3);
lenofs = buffer+8+unamelen+3;
sprintf(lenofs, "%03x", fulllen);
}
while(length && packed < 400 && packed+newoutcount < sizeof(con->outbuf)-2) //make sure there's always space
{
switch(*(unsigned char*)data)
{
case '\\':
buffer[packed++] = '\\';
buffer[packed++] = '\\';
break;
case '\n':
buffer[packed++] = '\\';
buffer[packed++] = 'n';
break;
case '\r':
buffer[packed++] = '\\';
buffer[packed++] = 'r';
break;
case '\0':
buffer[packed++] = '\\';
buffer[packed++] = '0';
break;
default:
buffer[packed++] = *(unsigned char*)data;
break;
}
length--;
data = (char*)data + 1;
}
buffer[packed++] = '\r';
buffer[packed++] = '\n';
newoutcount += packed;
packed = 0;
}
if (!length)
{
//only if we flushed all
con->outbufcount = newoutcount;
}
//try and flush it
length = send(con->generic.thesocket, con->outbuf, con->outbufcount, 0);
if (length > 0)
{
memmove(con->outbuf, con->outbuf+length, con->outbufcount-length);
con->outbufcount -= length;
}
return NETERR_SENT;
}
void FTENET_IRCConnect_Close(ftenet_generic_connection_t *gcon)
{
ftenet_ircconnect_connection_t *con = (ftenet_ircconnect_connection_t *)gcon;
ftenet_ircconnect_stream_t *st;
while(con->streams)
{
st = con->streams;
con->streams = st->next;
Z_Free(st);
}
FTENET_Generic_Close(gcon);
}
struct ftenet_generic_connection_s *FTENET_IRCConnect_EstablishConnection(qboolean isserver, const char *address, netadr_t adr)
{
//this is written to support either ipv4 or ipv6, depending on the remote addr.
ftenet_ircconnect_connection_t *newcon;
if (!NET_StringToAdr(address, 6667, &adr))
return NULL; //couldn't resolve the name
newcon = Z_Malloc(sizeof(*newcon));
if (newcon)
{
newcon->generic.GetPacket = FTENET_IRCConnect_GetPacket;
newcon->generic.SendPacket = FTENET_IRCConnect_SendPacket;
newcon->generic.Close = FTENET_IRCConnect_Close;
newcon->generic.islisten = isserver;
newcon->generic.addrtype[0] = NA_IRC;
newcon->generic.addrtype[1] = NA_INVALID;
newcon->generic.thesocket = INVALID_SOCKET;
newcon->ircserver = adr;
return &newcon->generic;
}
else
{
return NULL;
}
}
#endif
#ifdef FTE_TARGET_WEB
cvar_t net_ice_servers = CVAR("net_ice_servers", "");
cvar_t net_ice_relayonly = CVAR("net_ice_relayonly", "0");
#include "web/ftejslib.h"
typedef struct
{
ftenet_generic_connection_t generic;
int brokersock; //only if rtc
netadr_t remoteadr;
qboolean failed;
int datasock; //only if we're a client
double heartbeat; //timestamp of next heartbeat.
size_t numclients;
struct
{
netadr_t remoteadr;
int datasock;
} *clients;
} ftenet_websocket_connection_t;
static void FTENET_WebSocket_Close(ftenet_generic_connection_t *gcon)
{
ftenet_websocket_connection_t *wsc = (void*)gcon;
size_t i;
if (wsc->brokersock != INVALID_SOCKET)
emscriptenfte_ws_close(wsc->brokersock);
if (wsc->datasock != INVALID_SOCKET)
emscriptenfte_ws_close(wsc->datasock);
for (i = 0; i < wsc->numclients; i++)
{
if (wsc->clients[i].datasock != INVALID_SOCKET)
emscriptenfte_ws_close(wsc->clients[i].datasock);
}
free(wsc->clients);
}
static qboolean FTENET_WebSocket_GetPacket(ftenet_generic_connection_t *gcon)
{
ftenet_websocket_connection_t *wsc = (void*)gcon;
net_message.cursize = emscriptenfte_ws_recv(wsc->datasock, net_message_buffer, sizeof(net_message_buffer));
if (net_message.cursize > 0)
{
net_from = wsc->remoteadr;
return true;
}
if ((int)net_message.cursize < 0)
wsc->failed = true;
net_message.cursize = 0;//just incase
return false;
}
static neterr_t FTENET_WebSocket_SendPacket(ftenet_generic_connection_t *gcon, int length, const void *data, netadr_t *to)
{
ftenet_websocket_connection_t *wsc = (void*)gcon;
if (wsc->failed)
return NETERR_DISCONNECTED;
if (NET_CompareAdr(to, &wsc->remoteadr))
{
if (emscriptenfte_ws_send(wsc->datasock, data, length) < 0)
return NETERR_CLOGGED;
return NETERR_SENT;
}
return NETERR_NOROUTE;
}
static void FTENET_WebRTC_Heartbeat(ftenet_websocket_connection_t *b)
{
#ifdef HAVE_SERVER
if (b->generic.islisten)
{
extern cvar_t maxclients;
char info[2048];
int i;
client_t *cl;
int numclients = 0;
for (i=0 ; i<svs.allocated_client_slots ; i++)
{
cl = &svs.clients[i];
if ((cl->state == cs_connected || cl->state == cs_spawned || cl->name[0]) && !cl->spectator)
numclients++;
}
info[0] = ICEMSG_SERVERINFO;
info[1] =
info[2] = 0xff; //to the broker rather than any actual client
info[3] = 0;
Info_SetValueForKey(info+3, "protocol", SV_GetProtocolVersionString(), sizeof(info)-3);
Info_SetValueForKey(info+3, "maxclients", maxclients.string, sizeof(info)-3);
Info_SetValueForKey(info+3, "clients", va("%i", numclients), sizeof(info)-3);
Info_SetValueForKey(info+3, "hostname", hostname.string, sizeof(info)-3);
Info_SetValueForKey(info+3, "modname", FS_GetGamedir(true), sizeof(info)-3);
Info_SetValueForKey(info+3, "mapname", InfoBuf_ValueForKey(&svs.info, "map"), sizeof(info)-3);
Info_SetValueForKey(info+3, "needpass", InfoBuf_ValueForKey(&svs.info, "needpass"), sizeof(info)-3);
if (emscriptenfte_ws_send(b->brokersock, info, 3+strlen(info+3)) < 0)
return;
}
#endif
b->heartbeat = realtime+30;
}
//called from the javascript when there was some ice event. just forwards over the broker connection.
static void FTENET_WebRTC_Callback(void *ctxp, int ctxi, int/*enum icemsgtype_s*/ evtype, const char *data)
{
ftenet_websocket_connection_t *wcs = ctxp;
size_t dl = strlen(data);
qbyte *o = net_message_buffer;
*o++ = evtype;
*o++ = (ctxi>>0)&0xff;
*o++ = (ctxi>>8)&0xff;
memcpy(o, data, dl);
o+=dl;
//Con_Printf("To Broker: %i %i %s\n", evtype, ctxi, data);
emscriptenfte_ws_send(wcs->brokersock, net_message_buffer, o-net_message_buffer);
}
static int FTENET_WebRTC_Create(qboolean initiator, ftenet_websocket_connection_t *wsc, int clid)
{
char config[4096], tmp[256];
qboolean first = true;
const char *servers;
*config = 0;
Q_strncatz(config, "{\"iceServers\":[", sizeof(config));
{
/*
rtc://broker/id
rtc:///id
/id
*/
char *c;
int i;
const char *brokeraddress = wsc->remoteadr.address.websocketurl;
char *pre[] = { "wss://", "ices://", "rtcs://", "tls://",
"ws://", "ice://", "rtc://", "tcp://"};
//try and clean up the prefix, if specified
for (i = countof(pre); i --> 0; )
{
if (!strncmp(brokeraddress, pre[i], strlen(pre[i])))
{
brokeraddress += strlen(pre[i]);
break;
}
}
if (*brokeraddress == '/')
{
brokeraddress = fs_manifest->rtcbroker;
for (i = countof(pre); i --> 0; )
{
if (!strncmp(brokeraddress, pre[i], strlen(pre[i])))
{
brokeraddress += strlen(pre[i]);
break;
}
}
}
Q_strncpyz(com_token, brokeraddress, sizeof(com_token));
c = strchr(com_token, '/');
if (c) *c = 0;
first = false;
Q_strncatz(config, va("\n{\"urls\":[\"stun:%s\"]}", COM_QuotedString(com_token, tmp,sizeof(tmp), true)), sizeof(config));
}
for(servers = net_ice_servers.string; (servers=COM_Parse(servers)); )
{
//we don't do the ?foo stuff properly (RFCs say only ?transport= and only for stun)
char *s = strchr(com_token, '?'), *next;
const char *transport = NULL;
const char *user = NULL;
const char *auth = NULL;
for (;s;s=next)
{
*s++ = 0;
next = strchr(s, '?');
if (next)
*next = 0;
if (!strncmp(s, "transport=", 10))
transport = s+10;
else if (!strncmp(s, "user=", 5))
user = s+5;
else if (!strncmp(s, "auth=", 5))
auth = s+5;
else if (!strncmp(s, "fam=", 4))
;
}
if (!strncmp(com_token, "turn:", 5) || !strncmp(com_token, "turns:", 6))
if (!user || !auth)
continue;
if (first)
first = false;
else
Q_strncatz(config, ",", sizeof(config));
if (transport)
Q_strncatz(config, va("\n{\"urls\":[\"%s?transport=%s\"]", COM_QuotedString(com_token, tmp,sizeof(tmp), true), transport), sizeof(config));
else
Q_strncatz(config, va("\n{\"urls\":[\"%s\"]", COM_QuotedString(com_token, tmp,sizeof(tmp), true)), sizeof(config));
if (user)
Q_strncatz(config, va(",\"username\":\"%s\"", COM_QuotedString(user, tmp,sizeof(tmp), true)), sizeof(config));
if (auth)
Q_strncatz(config, va(",\"credential\":\"%s\"", COM_QuotedString(auth, tmp,sizeof(tmp), true)), sizeof(config));
Q_strncatz(config, "}", sizeof(config));
}
Q_strncatz(config, va("]"
// ",\"bundlePolicy\":\"max-bundle\""
",\"iceTransportPolicy\":\"%s\""
"}",net_ice_relayonly.ival?"relay":"all"), sizeof(config));
return emscriptenfte_rtc_create(initiator, wsc, clid, FTENET_WebRTC_Callback, config);
}
static qboolean FTENET_WebRTC_GetPacket(ftenet_generic_connection_t *gcon)
{
ftenet_websocket_connection_t *wsc = (void*)gcon;
size_t i;
if (wsc->heartbeat < realtime)
FTENET_WebRTC_Heartbeat(wsc);
if (!wsc->generic.islisten)
{
if (wsc->datasock != INVALID_SOCKET && FTENET_WebSocket_GetPacket(gcon))
return true;
}
else
{
for (i = 0; i < wsc->numclients; i++)
{
net_message.cursize = emscriptenfte_ws_recv(wsc->clients[i].datasock, net_message_buffer, sizeof(net_message_buffer));
if (net_message.cursize > 0)
{
net_from = wsc->clients[i].remoteadr;
return true;
}
}
}
net_message.cursize = emscriptenfte_ws_recv(wsc->brokersock, net_message_buffer, sizeof(net_message_buffer));
if (net_message.cursize > 0)
{
int cmd;
short cl;
const char *s;
char *p;
MSG_BeginReading(&net_message, msg_nullnetprim);
cmd = MSG_ReadByte();
cl = MSG_ReadShort();
//Con_Printf("From Broker: %i %i\n", cmd, cl);
switch(cmd)
{
case ICEMSG_PEERLOST: //connection closing...
if (cl == -1)
{
wsc->failed = true;
// Con_Printf("Broker closing connection: %s\n", MSG_ReadString());
}
else if (cl >= 0 && cl < wsc->numclients)
{
wsc->clients[cl].remoteadr.type = NA_INVALID;
if (wsc->clients[cl].datasock != INVALID_SOCKET)
emscriptenfte_ws_close(wsc->clients[cl].datasock);
wsc->clients[cl].datasock = INVALID_SOCKET;
// Con_Printf("Broker closing connection: %s\n", MSG_ReadString());
}
break;
case ICEMSG_GREETING: //reports the trailing url we're 'listening' on. anyone else using that url will connect to us.
s = MSG_ReadString();
if (*s == '/')
s++;
p = wsc->remoteadr.address.websocketurl;
while (*p)
{
if (p[0] == ':' && p[1] == '/' && p[2] == '/')
p+=3;
else if (p[0] == '/')
{
*p = 0;
break;
}
else
p++;
}
Q_strncatz(wsc->remoteadr.address.websocketurl, "/", sizeof(wsc->remoteadr.address.websocketurl));
Q_strncatz(wsc->remoteadr.address.websocketurl, s, sizeof(wsc->remoteadr.address.websocketurl));
Con_Printf("Listening on %s\n", wsc->remoteadr.address.websocketurl);
break;
case ICEMSG_NEWPEER: //connection established with a new peer
if (wsc->generic.islisten)
{
if (cl < 1024 && cl >= wsc->numclients)
{ //looks like a new one... but don't waste memory
size_t nm;
nm = cl+1;
wsc->clients = realloc(wsc->clients, sizeof(*wsc->clients)*nm);
while(wsc->numclients < nm)
{
memset(&wsc->clients[i].remoteadr, 0, sizeof(wsc->clients[i].remoteadr));
wsc->clients[wsc->numclients++].datasock = INVALID_SOCKET;
}
}
if (cl < wsc->numclients)
{
char id[256];
Q_snprintfz(id, sizeof(id), "/%i_%x", cl+1, rand());
if (wsc->clients[cl].datasock != INVALID_SOCKET)
emscriptenfte_ws_close(wsc->clients[cl].datasock);
memcpy(&wsc->clients[cl].remoteadr, &wsc->remoteadr, sizeof(netadr_t));
Q_strncatz(wsc->clients[cl].remoteadr.address.websocketurl, id, sizeof(wsc->clients[cl].remoteadr.address.websocketurl));
wsc->clients[cl].remoteadr.port = htons(cl+1);
wsc->clients[cl].datasock = FTENET_WebRTC_Create(false, wsc, cl);
}
}
else
{
if (wsc->datasock != INVALID_SOCKET)
emscriptenfte_ws_close(wsc->datasock);
wsc->datasock = FTENET_WebRTC_Create(true, wsc, cl);
}
break;
case ICEMSG_OFFER: //we received an offer from a client
s = MSG_ReadString();
if (wsc->generic.islisten)
{
if (cl < wsc->numclients && wsc->clients[cl].datasock != INVALID_SOCKET)
emscriptenfte_rtc_offer(wsc->clients[cl].datasock, s, "offer");
}
else
{
if (wsc->datasock != INVALID_SOCKET)
emscriptenfte_rtc_offer(wsc->datasock, s, "answer");
}
break;
case ICEMSG_CANDIDATE:
s = MSG_ReadString();
if (wsc->generic.islisten)
{
if (cl < wsc->numclients && wsc->clients[cl].datasock != INVALID_SOCKET)
emscriptenfte_rtc_candidate(wsc->clients[cl].datasock, s);
}
else
{
if (wsc->datasock != INVALID_SOCKET)
emscriptenfte_rtc_candidate(wsc->datasock, s);
}
break;
}
}
net_message.cursize = 0;//just incase
return false;
}
static neterr_t FTENET_WebRTC_SendPacket(ftenet_generic_connection_t *gcon, int length, const void *data, netadr_t *to)
{
ftenet_websocket_connection_t *wsc = (void*)gcon;
size_t i;
if (!wsc->generic.islisten)
{
// if (wsc->failed)
// return NETERR_DISCONNECTED;
if (NET_CompareAdr(to, &wsc->remoteadr))
{
if (wsc->datasock == INVALID_SOCKET)
return NETERR_CLOGGED; //we're still waiting for the broker to give us a server... or for a server to become available.
else
{
if (emscriptenfte_ws_send(wsc->datasock, data, length) <= 0)
return NETERR_CLOGGED;
return NETERR_SENT;
}
}
}
else
{
for (i = 0; i < wsc->numclients; i++)
{
if (NET_CompareAdr(to, &wsc->clients[i].remoteadr))
{
if (emscriptenfte_ws_send(wsc->clients[i].datasock, data, length) <= 0)
return NETERR_CLOGGED;
return NETERR_SENT;
}
}
}
return NETERR_NOROUTE;
}
static int FTENET_WebRTC_GetAddresses(struct ftenet_generic_connection_s *con, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
ftenet_websocket_connection_t *wsc = (void*)con;
if (maxaddresses)
{
*addresses = wsc->remoteadr;
*adrflags = 0;
return 1;
}
return 0;
}
static int FTENET_WebRTC_Establish(const char *address, const char *type)
{
/*
rtc://broker/id
rtc:///id
/id
*/
const char *path, *host;
char *c;
int i;
char url[512];
char cleanaddress[512];
char *pre[] = { "wss://", "ices://", "rtcs://", "tls://",
"ws://", "ice://", "rtc://", "tcp://"};
//try and clean up the prefix, if specified
for (i = countof(pre); i --> 0; )
{
if (!strncmp(address, pre[i], strlen(pre[i])))
{
address += strlen(pre[i]);
i -= i%(countof(pre)/2);
break;
}
}
host = address;
if (*address == '/')
{
path = address+1;
address = fs_manifest->rtcbroker;
for (i = countof(pre); i --> 0; )
{
if (!strncmp(address, pre[i], strlen(pre[i])))
{
address += strlen(pre[i]);
i -= i%(countof(pre)/2);
break;
}
}
}
else
{
path = strchr(address, '/');
if (!path)
path = "";
}
Q_strncpyz(cleanaddress, address, sizeof(cleanaddress));
c = strchr(cleanaddress, '/');
if (c) *c = 0;
COM_Parse(com_protocolname.string);
Q_snprintfz(url, sizeof(url), "%s%s/%s/%s", pre[i], cleanaddress, com_token, path);
return emscriptenfte_ws_connect(url, type);
}
static qboolean FTENET_WebRTC_ChangeLocalAddress(struct ftenet_generic_connection_s *con, const char *addressstring, netadr_t *adr)
{
//ftenet_websocket_connection_t *wsc = (void*)con;
return true; //pretend we changed it, because needed to change in the first place.
//doesn't match how its currently bound, so I guess we need to rebind then.
// return false;
}
static ftenet_generic_connection_t *FTENET_WebSocket_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr)
{
qboolean isserver = col->islisten;
ftenet_websocket_connection_t *newcon;
int brokersocket = INVALID_SOCKET;
int datasocket = INVALID_SOCKET;
newcon = Z_Malloc(sizeof(*newcon));
if (isserver)
{
Con_Printf("Browsers are unable to host regular servers. Please use an rtc://broker:port/serverid scheme instead.\n");
datasocket = INVALID_SOCKET;
}
else
datasocket = emscriptenfte_ws_connect(adr.address.websocketurl, "fteqw");
newcon->generic.GetPacket = FTENET_WebSocket_GetPacket;
newcon->generic.SendPacket = FTENET_WebSocket_SendPacket;
if (brokersocket == INVALID_SOCKET && datasocket == INVALID_SOCKET)
{
Con_Printf("Unable to create rtc/ws connection\n");
Z_Free(newcon);
}
else
{
Q_strncpyz(newcon->generic.name, "WebSocket", sizeof(newcon->generic.name));
newcon->generic.Close = FTENET_WebSocket_Close;
newcon->generic.islisten = isserver;
newcon->generic.addrtype[0] = NA_WEBSOCKET;
newcon->generic.addrtype[1] = NA_INVALID;
newcon->generic.thesocket = INVALID_SOCKET;
newcon->brokersock = brokersocket;
newcon->datasock = datasocket;
newcon->heartbeat = realtime-1;
adr.port = 0;
newcon->remoteadr = adr;
return &newcon->generic;
}
return NULL;
}
static ftenet_generic_connection_t *FTENET_WebRTC_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr)
{
qboolean isserver = col->islisten;
ftenet_websocket_connection_t *newcon;
int brokersocket = INVALID_SOCKET;
int datasocket = INVALID_SOCKET;
newcon = Z_Malloc(sizeof(*newcon));
if (adr.type == NA_INVALID)
{ //if its using our broker, flip it over to a real address type, if we can.
adr.type = NA_WEBSOCKET;
Q_strncpyz(adr.address.websocketurl, fs_manifest->rtcbroker, sizeof(adr.address.websocketurl));
}
brokersocket = FTENET_WebRTC_Establish(address, isserver?"rtc_host":"rtc_client");
newcon->generic.GetPacket = FTENET_WebRTC_GetPacket;
newcon->generic.SendPacket = FTENET_WebRTC_SendPacket;
newcon->generic.GetLocalAddresses = FTENET_WebRTC_GetAddresses;
newcon->generic.ChangeLocalAddress = FTENET_WebRTC_ChangeLocalAddress;
if (brokersocket == INVALID_SOCKET && datasocket == INVALID_SOCKET)
{
Con_Printf("Unable to create rtc/ws connection\n");
Z_Free(newcon);
}
else
{
Q_strncpyz(newcon->generic.name, "WebSocket", sizeof(newcon->generic.name));
newcon->generic.Close = FTENET_WebSocket_Close;
newcon->generic.islisten = isserver;
newcon->generic.addrtype[0] = NA_WEBSOCKET;
newcon->generic.addrtype[1] = NA_INVALID;
newcon->generic.thesocket = INVALID_SOCKET;
newcon->brokersock = brokersocket;
newcon->datasock = datasocket;
newcon->heartbeat = realtime-1;
adr.port = 0;
newcon->remoteadr = adr;
return &newcon->generic;
}
return NULL;
}
#endif
#ifdef NACL
#include <ppapi/c/pp_errors.h>
#include <ppapi/c/pp_resource.h>
#include <ppapi/c/ppb_core.h>
#include <ppapi/c/ppb_websocket.h>
#include <ppapi/c/ppb_var.h>
#include <ppapi/c/ppb_var_array_buffer.h>
#include <ppapi/c/ppb_instance.h>
extern PPB_Core *ppb_core;
extern PPB_WebSocket *ppb_websocket_interface;
extern PPB_Var *ppb_var_interface;
extern PPB_VarArrayBuffer *ppb_vararraybuffer_interface;
extern PP_Instance pp_instance;
typedef struct
{
ftenet_generic_connection_t generic;
PP_Resource sock;
netadr_t remoteadr;
struct PP_Var incomingpacket;
qboolean havepacket;
qboolean failed;
int showerror;
} ftenet_websocket_connection_t;
static void websocketgot(void *user_data, int32_t result)
{
ftenet_websocket_connection_t *wsc = user_data;
if (result == PP_OK)
{
wsc->havepacket = true;
}
else
{
Sys_Printf("%s: %i\n", __func__, result);
wsc->failed = true;
wsc->showerror = result;
}
}
static void websocketconnected(void *user_data, int32_t result)
{
ftenet_websocket_connection_t *wsc = user_data;
if (result == PP_OK)
{
int res;
//we got a successful connection, enable reception.
struct PP_CompletionCallback ccb = {websocketgot, wsc, PP_COMPLETIONCALLBACK_FLAG_OPTIONAL};
res = ppb_websocket_interface->ReceiveMessage(wsc->sock, &wsc->incomingpacket, ccb);
if (res != PP_OK_COMPLETIONPENDING)
websocketgot(wsc, res);
}
else
{
Sys_Printf("%s: %i\n", __func__, result);
//some sort of error connecting, make it timeout now
wsc->failed = true;
wsc->showerror = result;
}
}
static void websocketclosed(void *user_data, int32_t result)
{
ftenet_websocket_connection_t *wsc = user_data;
if (wsc->havepacket)
{
wsc->havepacket = false;
ppb_var_interface->Release(wsc->incomingpacket);
}
ppb_core->ReleaseResource(wsc->sock);
// Z_Free(wsc);
}
static void FTENET_NaClWebSocket_Close(ftenet_generic_connection_t *gcon)
{
int res;
/*meant to free the memory too, in this case we get the callback to do it*/
ftenet_websocket_connection_t *wsc = (void*)gcon;
struct PP_CompletionCallback ccb = {websocketclosed, wsc, PP_COMPLETIONCALLBACK_FLAG_NONE};
ppb_websocket_interface->Close(wsc->sock, PP_WEBSOCKETSTATUSCODE_NORMAL_CLOSURE, PP_MakeUndefined(), ccb);
}
static qboolean FTENET_NaClWebSocket_GetPacket(ftenet_generic_connection_t *gcon)
{
ftenet_websocket_connection_t *wsc = (void*)gcon;
int res;
int len = 0;
if (wsc->havepacket)
{
if (wsc->incomingpacket.type == PP_VARTYPE_ARRAY_BUFFER)
{
uint32_t length;
void *buf = ppb_vararraybuffer_interface->Map(wsc->incomingpacket);
if (buf && ppb_vararraybuffer_interface->ByteLength(wsc->incomingpacket, &length))
{
net_message.cursize = length;
memcpy(net_message_buffer, buf, length);
ppb_vararraybuffer_interface->Unmap(wsc->incomingpacket);
}
else
net_message.cursize = 0;
}
else
{
unsigned char *utf8 = (unsigned char *)ppb_var_interface->VarToUtf8(wsc->incomingpacket, &len);
unsigned char *out = (unsigned char *)net_message_buffer;
while(len && out < net_message_buffer + sizeof(net_message_buffer))
{
if ((*utf8 & 0xe0)==0xc0 && len > 1)
{
*out = ((utf8[0] & 0x1f)<<6) | ((utf8[1] & 0x3f)<<0);
utf8+=2;
len -= 2;
}
else if (*utf8 & 0x80)
{
*out = '?';
utf8++;
len -= 1;
}
else
{
*out = utf8[0];
utf8++;
len -= 1;
}
out++;
}
net_message.cursize = out - net_message_buffer;
}
memcpy(&net_from, &wsc->remoteadr, sizeof(net_from));
wsc->havepacket = false;
ppb_var_interface->Release(wsc->incomingpacket);
if (!wsc->failed)
{
//get the next one
struct PP_CompletionCallback ccb = {websocketgot, wsc, PP_COMPLETIONCALLBACK_FLAG_OPTIONAL};
res = ppb_websocket_interface->ReceiveMessage(wsc->sock, &wsc->incomingpacket, ccb);
if (res != PP_OK_COMPLETIONPENDING)
websocketgot(wsc, res);
}
if (len)
{
char adr[64];
Con_TPrintf ("Warning: Oversize packet from %s\n", NET_AdrToString (adr, sizeof(adr), &net_from));
return false;
}
return true;
}
if (wsc->showerror != PP_OK)
{
switch(wsc->showerror)
{
case PP_ERROR_FAILED:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_FAILED\n");
break;
case PP_ERROR_ABORTED:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_ABORTED\n");
break;
case PP_ERROR_NOTSUPPORTED:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_NOTSUPPORTED\n");
break;
case PP_ERROR_CONNECTION_CLOSED:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_CONNECTION_CLOSED\n");
break;
case PP_ERROR_CONNECTION_RESET:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_CONNECTION_RESET\n");
break;
case PP_ERROR_CONNECTION_REFUSED:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_CONNECTION_REFUSED\n");
break;
case PP_ERROR_CONNECTION_ABORTED:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_CONNECTION_ABORTED\n");
break;
case PP_ERROR_CONNECTION_FAILED:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_CONNECTION_FAILED\n");
break;
case PP_ERROR_CONNECTION_TIMEDOUT:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_CONNECTION_TIMEDOUT\n");
break;
case PP_ERROR_ADDRESS_INVALID:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_ADDRESS_INVALID\n");
break;
case PP_ERROR_ADDRESS_UNREACHABLE:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_ADDRESS_UNREACHABLE\n");
break;
case PP_ERROR_ADDRESS_IN_USE:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: PP_ERROR_ADDRESS_IN_USE\n");
break;
default:
Con_TPrintf ("FTENET_NaClWebSocket_GetPacket: error %i\n", wsc->showerror);
break;
}
wsc->showerror = PP_OK;
}
return false;
}
static neterr_t FTENET_NaClWebSocket_SendPacket(ftenet_generic_connection_t *gcon, int length, void *data, netadr_t *to)
{
ftenet_websocket_connection_t *wsc = (void*)gcon;
int res;
if (wsc->failed)
return NETERR_DISCONNECTED;
#if 1
struct PP_Var str = ppb_vararraybuffer_interface->Create(length);
void *out = ppb_vararraybuffer_interface->Map(str);
if (!out)
return NETERR_MTU;
memcpy(out, data, length);
ppb_vararraybuffer_interface->Unmap(str);
#else
int outchars = 0;
unsigned char outdata[length*2+1];
unsigned char *out=outdata, *in=data;
while(length-->0)
{
if (!*in)
{
//sends 256 instead of 0
*out++ = 0xc0 | (0x100 >> 6);
*out++ = 0x80 | (0x100 & 0x3f);
}
else if (*in >= 0x80)
{
*out++ = 0xc0 | (*in >> 6);
*out++ = 0x80 | (*in & 0x3f);
}
else
*out++ = *in;
in++;
outchars++;
}
*out = 0;
struct PP_Var str = ppb_var_interface->VarFromUtf8(outdata, out - outdata);
#endif
res = ppb_websocket_interface->SendMessage(wsc->sock, str);
// Sys_Printf("FTENET_WebSocket_SendPacket: result %i\n", res);
ppb_var_interface->Release(str);
return NETERR_SENT;
}
/*nacl websockets implementation...*/
static ftenet_generic_connection_t *FTENET_WebSocket_EstablishConnection(ftenet_connections_t *col, const char *address, netadr_t adr)
{
qboolean isserver = col->islisten;
ftenet_websocket_connection_t *newcon;
PP_Resource newsocket;
if (isserver || !ppb_websocket_interface)
{
return NULL;
}
newcon = Z_Malloc(sizeof(*newcon));
if (newcon)
{
#define WEBSOCKETPROTOCOL "fteqw"
struct PP_CompletionCallback ccb = {websocketconnected, newcon, PP_COMPLETIONCALLBACK_FLAG_NONE};
newsocket = ppb_websocket_interface->Create(pp_instance);
struct PP_Var str = ppb_var_interface->VarFromUtf8(adr.address.websocketurl, strlen(adr.address.websocketurl));
struct PP_Var protocols[1] = {ppb_var_interface->VarFromUtf8(WEBSOCKETPROTOCOL, strlen(WEBSOCKETPROTOCOL))};
ppb_websocket_interface->Connect(newsocket, str, protocols, countof(protocols), ccb);
ppb_var_interface->Release(str);
ppb_var_interface->Release(protocols[0]);
Q_strncpyz(newcon->generic.name, "WebSocket", sizeof(newcon->generic.name));
newcon->generic.GetPacket = FTENET_NaClWebSocket_GetPacket;
newcon->generic.SendPacket = FTENET_NaClWebSocket_SendPacket;
newcon->generic.Close = FTENET_NaClWebSocket_Close;
newcon->generic.islisten = isserver;
newcon->generic.addrtype[0] = NA_WEBSOCKET;
newcon->generic.addrtype[1] = NA_INVALID;
newcon->generic.thesocket = INVALID_SOCKET;
newcon->sock = newsocket;
newcon->remoteadr = adr;
return &newcon->generic;
}
return NULL;
}
#endif
qboolean NET_GetRates(ftenet_connections_t *collection, float *pi, float *po, float *bi, float *bo)
{
int ctime;
if (!collection)
return false;
ctime = Sys_Milliseconds();
if ((ctime - collection->timemark) > 1000)
{
float secs = (ctime - collection->timemark) / 1000.0f;
collection->packetsinrate = collection->packetsin * secs;
collection->packetsoutrate = collection->packetsout * secs;
collection->bytesinrate = collection->bytesin * secs;
collection->bytesoutrate = collection->bytesout * secs;
collection->packetsin = 0;
collection->packetsout = 0;
collection->bytesin = 0;
collection->bytesout = 0;
collection->timemark = ctime;
}
*pi = collection->packetsinrate;
*po = collection->packetsoutrate;
*bi = collection->bytesinrate;
*bo = collection->bytesoutrate;
return true;
}
#ifdef HAVE_CLIENT
//for demo playback
qboolean NET_UpdateRates(ftenet_connections_t *collection, qboolean inbound, size_t size)
{
int ctime;
if (!collection)
return false;
if (inbound)
{
cls.sockets->bytesin += size;
cls.sockets->packetsin += 1;
}
else
{
cls.sockets->bytesout += size;
cls.sockets->packetsout += 1;
}
ctime = Sys_Milliseconds();
if ((ctime - collection->timemark) > 1000)
{
float secs = (ctime - collection->timemark) / 1000.0f;
collection->packetsinrate = collection->packetsin * secs;
collection->packetsoutrate = collection->packetsout * secs;
collection->bytesinrate = collection->bytesin * secs;
collection->bytesoutrate = collection->bytesout * secs;
collection->packetsin = 0;
collection->packetsout = 0;
collection->bytesin = 0;
collection->bytesout = 0;
collection->timemark = ctime;
}
return true;
}
#endif
void NET_ReadPackets (ftenet_connections_t *collection)
{
struct ftenet_delayed_packet_s *p;
unsigned int ctime;
size_t c = 0;
if (!collection)
return;
while ((p = collection->delayed_packets) && (int)(Sys_Milliseconds()-p->sendtime) > 0)
{
collection->delayed_packets = p->next;
#ifdef SUPPORT_ICE
if (p->dest.type == NA_ICE)
NET_SendPacketCol (collection, p->cursize, p->data, &p->dest);
else
#endif
#ifdef HAVE_DTLS
if (p->dest.prot == NP_DTLS)
FTENET_DTLS_SendPacket(collection, p->cursize, p->data, &p->dest);
else
#endif
NET_SendPacketCol (collection, p->cursize, p->data, &p->dest);
Z_Free(p);
}
for (c = 0; c < MAX_CONNECTIONS; c++)
{
if (collection->conn[c])
{
while (collection->conn[c]->GetPacket(collection->conn[c]))
{
if (net_fakeloss.value)
{
if (frandom () < net_fakeloss.value)
continue;
}
collection->bytesin += net_message.cursize;
collection->packetsin += 1;
net_from.connum = c+1;
net_from_connection = collection->conn[c];
collection->ReadGamePacket();
}
}
}
ctime = Sys_Milliseconds();
if ((ctime - collection->timemark) > 1000)
{
float secs = (ctime - collection->timemark) / 1000.0f;
collection->packetsinrate = collection->packetsin * secs;
collection->packetsoutrate = collection->packetsout * secs;
collection->bytesinrate = collection->bytesin * secs;
collection->bytesoutrate = collection->bytesout * secs;
collection->packetsin = 0;
collection->packetsout = 0;
collection->bytesin = 0;
collection->bytesout = 0;
collection->timemark = ctime;
}
}
int NET_LocalAddressForRemote(ftenet_connections_t *collection, netadr_t *remote, netadr_t *local, int idx)
{
int adrflags;
const char *adrparams;
if (!remote->connum)
return 0;
if (!collection->conn[remote->connum-1])
return 0;
if (!collection->conn[remote->connum-1]->GetLocalAddresses)
return 0;
return collection->conn[remote->connum-1]->GetLocalAddresses(collection->conn[remote->connum-1], &adrflags, local, &adrparams, 1);
}
static neterr_t NET_SendPacketCol (ftenet_connections_t *collection, int length, const void *data, netadr_t *to)
{
neterr_t err;
int i;
if (!collection)
return NETERR_NOROUTE;
if (net_fakeloss.value && data)
{
if (frandom () < net_fakeloss.value)
{
collection->bytesout += length;
collection->packetsout += 1;
return NETERR_SENT;
}
}
if (to->connum)
{
i = to->connum-1;
if (i < MAX_CONNECTIONS && collection->conn[i])
{
err = collection->conn[i]->SendPacket(collection->conn[i], length, data, to);
if (err != NETERR_NOROUTE)
{
/*if (err == NETERR_DISCONNECTED)
{
collection->conn[i]->Close(collection->conn[i]);
collection->conn[i] = NULL;
continue;
}*/
collection->bytesout += length;
collection->packetsout += 1;
return err;
}
}
return NETERR_NOROUTE;
}
for (i = 0; i < MAX_CONNECTIONS; i++)
{
if (!collection->conn[i])
continue;
err = collection->conn[i]->SendPacket(collection->conn[i], length, data, to);
if (err != NETERR_NOROUTE)
{
/*if (err == NETERR_DISCONNECTED)
{
collection->conn[i]->Close(collection->conn[i]);
collection->conn[i] = NULL;
continue;
}*/
collection->bytesout += length;
collection->packetsout += 1;
return err;
}
}
// Con_Printf("No route to %s - try reconnecting\n", NET_AdrToString(buffer, sizeof(buffer), to));
return NETERR_NOROUTE;
}
neterr_t NET_SendPacket (ftenet_connections_t *collection, int length, const void *data, netadr_t *to)
{
if (!collection)
return NETERR_NOROUTE;
#ifdef HAVE_CLIENT
if (collection == cls.sockets && cl_delay_packets.ival >= 1 && !(cl.fpd & FPD_NO_FAKE_LAG))
{
struct ftenet_delayed_packet_s *p, **l;
if (!collection)
return NETERR_NOROUTE; //erk...
p = BZ_Malloc(sizeof(*p) - sizeof(p->data) + length);
p->sendtime = Sys_Milliseconds() + cl_delay_packets.ival;
p->next = NULL;
p->cursize = length;
p->dest = *to;
memcpy(p->data, data, length);
for (l = &collection->delayed_packets; *l; l = &((*l)->next))
;
*l = p;
return NETERR_SENT; //fixme: mtu, noroute, etc... panic? only allow if udp dest?
}
#endif
#ifdef SUPPORT_ICE
if (to->type == NA_ICE)
return ICE_SendPacket(length, data, to);
#endif
#ifdef HAVE_DTLS
if (to->prot == NP_DTLS)
return FTENET_DTLS_SendPacket(collection, length, data, to);
#endif
return NET_SendPacketCol (collection, length, data, to);
}
qboolean NET_EnsureRoute(ftenet_connections_t *collection, char *routename, char *host, netadr_t *adr)
{
switch(adr->prot)
{
case NP_DGRAM:
if (NET_SendPacketCol(collection, 0, NULL, adr) != NETERR_NOROUTE)
return true;
if (!FTENET_AddToCollection(collection, routename, "0", adr->type, adr->prot))
return false;
break;
case NP_DTLS:
#ifdef HAVE_DTLS
adr->prot = NP_DGRAM;
if (NET_EnsureRoute(collection, routename, host, adr))
{
dtlscred_t cred;
memset(&cred, 0, sizeof(cred));
cred.peer.name = host;
if (NET_DTLS_Create(collection, adr, &cred))
{
adr->prot = NP_DTLS;
return true;
}
}
adr->prot = NP_DTLS;
#endif
return false;
case NP_WS:
case NP_WSS:
case NP_TLS:
case NP_STREAM:
if (!FTENET_AddToCollection(collection, routename, host, adr->type, adr->prot))
return false;
Con_Printf("Establishing connection to %s\n", host);
break;
#if defined(SUPPORT_ICE) || defined(FTE_TARGET_WEB)
case NP_RTC_TCP:
case NP_RTC_TLS:
if (!FTENET_AddToCollection(collection, routename, host, adr->type, adr->prot))
return false;
break;
#endif
default:
//not recognised, or not needed
break;
}
return true;
}
void NET_TerminateRoute(ftenet_connections_t *collection, netadr_t *adr)
{
switch(adr->prot)
{
case NP_DTLS:
#ifdef HAVE_DTLS
NET_DTLS_Disconnect(collection, adr);
#endif
break;
default:
break;
}
#ifdef SUPPORT_ICE
if (adr->type == NA_ICE)
ICE_Terminate(adr);
#endif
}
int NET_EnumerateAddresses(ftenet_connections_t *collection, struct ftenet_generic_connection_s **con, unsigned int *adrflags, netadr_t *addresses, const char **adrparams, int maxaddresses)
{
unsigned int found = 0, c, i, j;
for (i = 0; i < MAX_CONNECTIONS; i++)
{
if (!collection->conn[i])
continue;
if (collection->conn[i]->GetLocalAddresses)
c = collection->conn[i]->GetLocalAddresses(collection->conn[i], adrflags+found, addresses+found, adrparams+found, maxaddresses-found);
else
c = 0;
if (maxaddresses>found && !c)
{
adrflags[found] = 0;
adrparams[found] = NULL;
addresses[found].type = NA_INVALID;
addresses[found].prot = NP_INVALID;
c = 1;
}
//fill in connection info
for (j = 0; j < c; j++)
{
con[found+j] = collection->conn[i];
addresses[found+j].connum = i+1;
}
found += c;
}
return found;
}
static enum addressscope_e NET_ClassifyAddressipv4(int ip, const char **outdesc)
{
int scope = ASCOPE_NET;
const char *desc = NULL;
if ((ip&BigLong(0xffff0000)) == BigLong(0xA9FE0000)) //169.254.x.x/16
scope = ASCOPE_LINK, desc = localtext("link-local");
else if ((ip&BigLong(0xff000000)) == BigLong(0x0a000000)) //10.x.x.x/8
scope = ASCOPE_LAN, desc = localtext("private");
else if ((ip&BigLong(0xff000000)) == BigLong(0x7f000000)) //127.x.x.x/8
scope = ASCOPE_HOST, desc = "localhost";
else if ((ip&BigLong(0xfff00000)) == BigLong(0xac100000)) //172.16.x.x/12
scope = ASCOPE_LAN, desc = localtext("private");
else if ((ip&BigLong(0xffff0000)) == BigLong(0xc0a80000)) //192.168.x.x/16
scope = ASCOPE_LAN, desc = localtext("private");
else if ((ip&BigLong(0xffc00000)) == BigLong(0x64400000)) //100.64.x.x/10
scope = ASCOPE_LAN, desc = localtext("CGNAT");
else if (ip == BigLong(0x00000000)) //0.0.0.0/32
scope = ASCOPE_HOST, desc = "any";
*outdesc = desc;
return scope;
}
enum addressscope_e NET_ClassifyAddress(netadr_t *adr, const char **outdesc)
{
int scope = ASCOPE_NET;
const char *desc = NULL;
if (adr->type == NA_LOOPBACK)
{
//we don't list 127.0.0.1 or ::1, so don't bother with this either. its not interesting.
scope = ASCOPE_PROCESS, desc = localtext("internal");
}
else if (adr->type == NA_IPV6)
{
if ((*(int*)adr->address.ip6&BigLong(0xffc00000)) == BigLong(0xfe800000)) //fe80::/10
scope = ASCOPE_LINK, desc = localtext("link-local");
else if ((*(int*)adr->address.ip6&BigLong(0xfe000000)) == BigLong(0xfc00000)) //fc::/7
scope = ASCOPE_LAN, desc = localtext("ULA/private");
else if (*(int*)adr->address.ip6 == BigLong(0x20010000)) //2001::/32
scope = ASCOPE_NET, desc = "toredo";
else if ((*(int*)adr->address.ip6&BigLong(0xffff0000)) == BigLong(0x20020000)) //2002::/16
scope = ASCOPE_NET, desc = "6to4";
else if (memcmp(adr->address.ip6, "\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\1", 16) == 0) //::1
scope = ASCOPE_HOST, desc = "localhost";
else if (memcmp(adr->address.ip6, "\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0\0", 16) == 0) //::
scope = ASCOPE_HOST, desc = "any";
else if (memcmp(adr->address.ip6, "\0\0\0\0\0\0\0\0\0\0\xff\xff", 12) == 0) //::ffff:x.y.z.w
{
scope = NET_ClassifyAddressipv4(*(int*)(adr->address.ip6+12), &desc);
if (!desc)
desc = localtext("v4-mapped");
}
}
#ifdef UNIXSOCKETS
else if (adr->type == NA_UNIX)
{
scope = ASCOPE_HOST, desc = "unix";
}
#endif
else if (adr->type == NA_IP)
scope = NET_ClassifyAddressipv4(*(int*)adr->address.ip, &desc);
if (outdesc)
*outdesc = desc;
return scope;
}
#define MAXADDRESSES 64
void NET_PrintAddresses(ftenet_connections_t *collection)
{
int i;
char adrbuf[MAX_ADR_SIZE];
int m;
qboolean shown = false;
netadr_t addr[64];
struct ftenet_generic_connection_s *con[sizeof(addr)/sizeof(addr[0])], *nc;
int flags[sizeof(addr)/sizeof(addr[0])];
const char *params[sizeof(addr)/sizeof(addr[0])];
qboolean warn = true;
static const char *scopes[] = {"process", "local", "link", "lan", "net"};
const char *desc;
if (!collection)
return;
m = NET_EnumerateAddresses(collection, con, flags, addr, params, sizeof(addr)/sizeof(addr[0]));
for (i = 0; i < m; i++)
{
if (addr[i].type != NA_INVALID)
{
enum addressscope_e scope = NET_ClassifyAddress(&addr[i], &desc);
if (i+1 < m)
nc = con[i+1];
else
nc = NULL;
if (nc != con[i])
{ //next is a different family.
if (!shown && (scope == ASCOPE_LINK || scope == ASCOPE_HOST))
scope = ASCOPE_LAN; //force it visible.
shown = false;
}
if (developer.ival || scope >= ASCOPE_LAN)
{
shown = true;
warn = false;
if ((addr[i].prot == NP_RTC_TCP || addr[i].prot == NP_RTC_TLS) && params[i])
{
if (addr[i].type == NA_INVALID)
Con_TPrintf("%s address (%s): /%s\n", scopes[scope], con[i]->name, params[i]);
else
Con_TPrintf("%s address (%s): %s/%s\n", scopes[scope], con[i]->name, NET_AdrToString(adrbuf, sizeof(adrbuf), &addr[i]), params[i]);
}
else if (desc)
Con_TPrintf("%s address (%s): %s (%s)\n", scopes[scope], con[i]->name, NET_AdrToString(adrbuf, sizeof(adrbuf), &addr[i]), desc);
else
Con_TPrintf("%s address (%s): %s\n", scopes[scope], con[i]->name, NET_AdrToString(adrbuf, sizeof(adrbuf), &addr[i]));
}
}
}
if (warn)
Con_TPrintf("net address: no public addresses\n");
}
void NET_PrintConnectionsStatus(ftenet_connections_t *collection)
{
unsigned int i;
if (!collection)
return;
for (i = 0; i < MAX_CONNECTIONS; i++)
{
if (!collection->conn[i])
continue;
if (collection->conn[i]->PrintStatus)
collection->conn[i]->PrintStatus(collection->conn[i]);
}
#ifdef HAVE_DTLS
if (developer.ival)
{
struct dtlspeer_s *dtls;
char adr[64];
for (dtls = collection->dtls; dtls; dtls = dtls->next)
Con_Printf("dtls: %s\n", NET_AdrToString(adr, sizeof(adr), &dtls->addr));
}
else
{
struct dtlspeer_s *dtls;
int c = 0;
for (dtls = collection->dtls; dtls; dtls = dtls->next)
c++;
if (c)
Con_Printf("dtls connections : %i\n", c);
}
#endif
}
//=============================================================================
int TCP_OpenStream (netadr_t *remoteaddr, const char *remotename)
{
#ifndef HAVE_TCP
return (int)INVALID_SOCKET;
#else
unsigned long _true = true;
int newsocket;
int temp;
struct sockaddr_qstorage qs;
// struct sockaddr_qstorage loc;
int recvbufsize = (1<<19);//512kb
int sysprot;
switch(remoteaddr->type)
{
#if defined(HAVE_IPV4) || defined(HAVE_IPV6)
case NA_IP:
case NA_IPV6:
sysprot = IPPROTO_TCP;
break;
#endif
#ifdef HAVE_IPX
case NA_IPX:
sysprot = NSPROTO_IPX;
break;
#endif
//case NA_UNIX:
default:
sysprot = 0; //'auto'
break;
}
temp = NetadrToSockadr(remoteaddr, &qs);
if ((newsocket = socket (((struct sockaddr_in*)&qs)->sin_family, SOCK_CLOEXEC|SOCK_STREAM, sysprot)) == INVALID_SOCKET)
return (int)INVALID_SOCKET;
setsockopt(newsocket, SOL_SOCKET, SO_RCVBUF, (void*)&recvbufsize, sizeof(recvbufsize));
if (ioctlsocket (newsocket, FIONBIO, &_true) == -1)
Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(neterrno()));
#ifdef UNIXSOCKETS
if (remoteaddr->type == AF_UNIX)
{ //if its a unix socket, attempt to bind it to an unnamed address. linux should generate an ephemerial abstract address (otherwise the server will see an empty address).
struct sockaddr_un un;
memset(&un, 0, offsetof(struct sockaddr_un, sun_path));
bind(newsocket, (struct sockaddr*)&un, offsetof(struct sockaddr_un, sun_path));
}
else
#endif
{
// memset(&loc, 0, sizeof(loc));
// ((struct sockaddr*)&loc)->sa_family = ((struct sockaddr*)&loc)->sa_family;
// bind(newsocket, (struct sockaddr *)&loc, ((struct sockaddr_in*)&qs)->sin_family == AF_INET?sizeof(struct sockaddr_in):sizeof(struct sockaddr_in6));
}
if (connect(newsocket, (struct sockaddr *)&qs, temp) == INVALID_SOCKET)
{
int err = neterrno();
if (err != NET_EWOULDBLOCK && err != NET_EINPROGRESS)
{
if (err == NET_EADDRNOTAVAIL)
{
if (remoteaddr->port == 0 && (remoteaddr->type == NA_IP || remoteaddr->type == NA_IPV6))
Con_Printf ("TCP_OpenStream: no port specified (%s)\n", remotename);
else
Con_Printf ("TCP_OpenStream: invalid address trying to connect to %s\n", remotename);
}
else if (err == NET_ECONNREFUSED)
Con_Printf ("TCP_OpenStream: connection refused (%s)\n", remotename);
else if (err == NET_EACCES)
Con_Printf ("TCP_OpenStream: access denied: check firewall (%s)\n", remotename);
else if (err == NET_ENETUNREACH)
Con_Printf ("TCP_OpenStream: unreachable (%s)\n", remotename);
else
Con_Printf ("TCP_OpenStream: connect: error %i (%s)\n", err, remotename);
closesocket(newsocket);
return (int)INVALID_SOCKET;
}
}
return newsocket;
#endif
}
#if defined(SV_MASTER) || defined(CL_MASTER)
#ifdef HAVE_IPV4
int UDP_OpenSocket (int port)
{
SOCKET newsocket;
struct sockaddr_in address;
unsigned long _true = true;
int i;
int maxport = port + 100;
if ((newsocket = socket (PF_INET, SOCK_CLOEXEC|SOCK_DGRAM, IPPROTO_UDP)) == INVALID_SOCKET)
return (int)INVALID_SOCKET;
if (ioctlsocket (newsocket, FIONBIO, &_true) == -1)
Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(neterrno()));
address.sin_family = AF_INET;
//ZOID -- check for interface binding option
if ((i = COM_CheckParm("-ip")) != 0 && i < com_argc) {
address.sin_addr.s_addr = inet_addr(com_argv[i+1]);
Con_TPrintf("Binding to IP Interface Address of %s\n",
inet_ntoa(address.sin_addr));
} else
address.sin_addr.s_addr = INADDR_ANY;
for(;;)
{
if (port == PORT_ANY)
address.sin_port = 0;
else
address.sin_port = htons((short)port);
if( bind (newsocket, (void *)&address, sizeof(address)) == -1)
{
if (!port)
Sys_Error ("UDP_OpenSocket: bind: %s", strerror(neterrno()));
port++;
if (port > maxport)
Sys_Error ("UDP_OpenSocket: bind: %s", strerror(neterrno()));
}
else
break;
}
return newsocket;
}
void UDP_CloseSocket (int socket)
{
closesocket(socket);
}
#endif
#ifdef HAVE_IPV6
int UDP6_OpenSocket (int port)
{
int err;
SOCKET newsocket;
struct sockaddr_in6 address;
unsigned long _true = true;
// int i;
int maxport = port + 100;
memset(&address, 0, sizeof(address));
if ((newsocket = socket (PF_INET6, SOCK_CLOEXEC|SOCK_DGRAM, 0)) == INVALID_SOCKET)
{
Con_Printf("IPV6 is not supported: %s\n", strerror(neterrno()));
return (int)INVALID_SOCKET;
}
if (ioctlsocket (newsocket, FIONBIO, &_true) == -1)
Sys_Error ("UDP_OpenSocket: ioctl FIONBIO: %s", strerror(neterrno()));
#ifdef IPV6_V6ONLY
setsockopt(newsocket, IPPROTO_IPV6, IPV6_V6ONLY, (char *)&_true, sizeof(_true));
#endif
address.sin6_family = AF_INET6;
//ZOID -- check for interface binding option
// if ((i = COM_CheckParm("-ip6")) != 0 && i < com_argc) {
// address.sin6_addr = inet_addr(com_argv[i+1]);
/// Con_TPrintf("Binding to IP Interface Address of %s\n",
// inet_ntoa(address.sin6_addr));
// } else
memset(&address.sin6_addr, 0, sizeof(struct in6_addr));
for(;;)
{
if (port == PORT_ANY)
address.sin6_port = 0;
else
address.sin6_port = htons((short)port);
if( bind (newsocket, (void *)&address, sizeof(address)) == -1)
{
if (!port)
{
err = neterrno();
Con_Printf ("UDP6_OpenSocket: bind: (%i) %s", err, strerror(err));
closesocket(newsocket);
return (int)INVALID_SOCKET;
}
port++;
if (port > maxport)
{
err = neterrno();
Con_Printf ("UDP6_OpenSocket: bind: (%i) %s", err, strerror(err));
closesocket(newsocket);
return (int)INVALID_SOCKET;
}
}
else
break;
}
return newsocket;
}
void UDP6_CloseSocket (int socket)
{
closesocket(socket);
}
#endif
#ifdef HAVE_IPX
int IPX_OpenSocket (int port)
{
SOCKET newsocket;
struct sockaddr_ipx address;
u_long _true = 1;
if ((newsocket = socket (PF_IPX, SOCK_CLOEXEC|SOCK_DGRAM, NSPROTO_IPX)) == INVALID_SOCKET)
{
int e = neterrno();
if (e != NET_EAFNOSUPPORT)
Con_Printf ("WARNING: IPX_Socket: socket: %i\n", e);
return INVALID_SOCKET;
}
// make it non-blocking
if (ioctlsocket (newsocket, FIONBIO, &_true) == -1)
{
Con_Printf ("WARNING: IPX_Socket: ioctl FIONBIO: %i\n", neterrno());
return INVALID_SOCKET;
}
address.sa_family = AF_IPX;
memset (address.sa_netnum, 0, 4);
memset (address.sa_nodenum, 0, 6);
if (port == PORT_ANY)
address.sa_socket = 0;
else
address.sa_socket = htons((short)port);
if( bind (newsocket, (void *)&address, sizeof(address)) == -1)
{
Con_Printf ("WARNING: IPX_Socket: bind: %i\n", neterrno());
closesocket (newsocket);
return INVALID_SOCKET;
}
return newsocket;
}
void IPX_CloseSocket (int socket)
{
closesocket(socket);
}
#endif
#endif
#ifdef HAVE_EPOLL
static qboolean stdin_ready;
static qboolean stdin_epolling;
static void StdIn_Now_Ready (struct epollctx_s *ctx, unsigned int events)
{
stdin_ready = true;
}
qboolean NET_Sleep(float seconds, qboolean stdinissocket)
{
int waitms;
struct epoll_event waitevents[256];
int n, i;
if (epoll_fd < 0)
return false; // o.O
if (stdin_epolling != stdinissocket)
{
static epollctx_t stdinctx = {StdIn_Now_Ready};
struct epoll_event event = {EPOLLIN, {&stdinctx}};
stdin_epolling = stdinissocket;
if (stdinissocket)
epoll_ctl(epoll_fd, EPOLL_CTL_ADD, STDIN_FILENO, &event);
else
epoll_ctl(epoll_fd, EPOLL_CTL_DEL, STDIN_FILENO, &event);
}
waitms = bound(0, (int)(seconds*1000), 4*1000);
n = epoll_wait(epoll_fd, waitevents, countof(waitevents), waitms);
if (n < 0)
{
int err = errno;
switch(err)
{
case EINTR:
break;
default:
Con_Printf("EPoll error: %s\n", strerror(err));
break;
}
}
for (i = 0; i < n; i++)
{
struct epoll_event *ev = &waitevents[i];
struct epollctx_s *ctx = ev->data.ptr;
if (ctx)
ctx->Polled(ctx, ev->events);
//else edge-triggered events can be processed as part of the main loop
}
return stdin_ready;
}
#else
// sleeps msec or until net socket is ready
//stdin can sometimes be a socket. As a result,
//we give the option to select it for nice console imput with timeouts.
qboolean NET_Sleep(float seconds, qboolean stdinissocket)
{
#ifdef HAVE_PACKET
struct timeval timeout;
fd_set readfdset;
fd_set writefdset;
qintptr_t maxfd = -1;
int con, sock;
unsigned int usec;
FD_ZERO(&readfdset);
FD_ZERO(&writefdset);
#ifndef _WIN32
if (stdinissocket)
{
sock = STDIN_FILENO; //stdin tends to be socket/filehandle 0 in unix
FD_SET(sock, &readfdset);
maxfd = sock;
}
#endif
#ifdef SV_MASTER
{
extern ftenet_connections_t *svm_sockets;
if (svm_sockets)
for (con = 0; con < MAX_CONNECTIONS; con++)
{
if (!svm_sockets->conn[con])
continue;
if (svm_sockets->conn[con]->SetFDSets)
{
sock = svm_sockets->conn[con]->SetFDSets(svm_sockets->conn[con], &readfdset, &writefdset);
if (sock > maxfd)
maxfd = sock;
}
else
{
sock = svm_sockets->conn[con]->thesocket;
if (sock != INVALID_SOCKET)
{
FD_SET(sock, &readfdset); // network socket
if (sock > maxfd)
maxfd = sock;
}
}
}
}
#endif
#ifdef HAVE_SERVER
if (svs.sockets)
for (con = 0; con < MAX_CONNECTIONS; con++)
{
if (!svs.sockets->conn[con])
continue;
if (svs.sockets->conn[con]->SetFDSets)
{
sock = svs.sockets->conn[con]->SetFDSets(svs.sockets->conn[con], &readfdset, &writefdset);
if (sock > maxfd)
maxfd = sock;
}
else
{
sock = svs.sockets->conn[con]->thesocket;
if (sock != INVALID_SOCKET)
{
FD_SET(sock, &readfdset); // network socket
if (sock > maxfd)
maxfd = sock;
}
}
}
#endif
seconds = bound(0.0, seconds, 4.0); //realy? oh well.
if (maxfd == -1)
Sys_Sleep(seconds);
else
{
usec = seconds*1000*1000;
usec += 1000; //slight extra delay, to ensure we don't wake up with nothing to do.
timeout.tv_sec = usec/(1000*1000);
timeout.tv_usec = usec;
select(maxfd+1, &readfdset, &writefdset, NULL, &timeout);
}
#ifndef _WIN32
if (stdinissocket)
return FD_ISSET(STDIN_FILENO, &readfdset);
#endif
#endif
return true;
}
#endif
//this function is used to determine the 'default' local address.
//this is used for compat with gamespy which insists on sending us a packet via that interface and not something more sensible like 127.0.0.1
//thus its only needed on windows and with ipv4.
void NET_GetLocalAddress (int socket, netadr_t *out)
{
#if defined(_WIN32) && defined(HAVE_PACKET)
char buff[512];
struct sockaddr_qstorage address;
int namelen;
netadr_t adr = {0};
qboolean notvalid = false;
strcpy(buff, "localhost");
gethostname(buff, 512);
buff[512-1] = 0;
if (!NET_StringToAdr (buff, 0, &adr)) //urm
if (!NET_StringToAdr ("127.0.0.1", 0, &adr))
return;
namelen = sizeof(address);
if (getsockname (socket, (struct sockaddr *)&address, &namelen) == -1)
{
notvalid = true;
NET_StringToSockaddr2("0.0.0.0", 0, NA_INVALID, (struct sockaddr_qstorage *)&address, NULL, NULL, 1);
// Sys_Error ("NET_Init: getsockname:", strerror(qerrno));
}
SockadrToNetadr(&address, namelen, out);
if (out->type == NA_IP)
{
if (!*(int*)out->address.ip) //socket was set to auto
{
if (adr.type == NA_IP)
*(int *)out->address.ip = *(int *)adr.address.ip; //change it to what the machine says it is, rather than the socket.
}
}
if (out->type == NA_IPV6)
{
if (!((int*)out->address.ip6)[0] &&
!((int*)out->address.ip6)[1] &&
!((short*)out->address.ip6)[4] &&
(!((short*)out->address.ip6)[5] || ((unsigned short*)out->address.ip6)[5]==0xffffu)
&& !((int*)out->address.ip6)[3]) //ipv6 any or ipv4-mapped any.
{
if (adr.type == NA_IP)
{
memset(out->address.ip6, 0, sizeof(out->address.ip6));
((short *)out->address.ip6)[5] = 0xffff;
((int *)out->address.ip6)[3] = *(int *)adr.address.ip;
}
else if (adr.type == NA_IPV6)
memcpy(out->address.ip6, adr.address.ip6, sizeof(out->address.ip6));
}
}
if (!notvalid)
{
// char adrbuf[MAX_ADR_SIZE];
// Con_TPrintf("Client IP address %s\n", NET_AdrToString (adrbuf, sizeof(adrbuf), out) );
return;
}
// Con_Printf("Couldn't detect local ip\n");
#endif
out->type = NA_INVALID;
}
#ifdef HAVE_SERVER
void SVNET_AddPort_f(void)
{
char *s = Cmd_Argv(1);
char *conname = Cmd_Argv(2);
if (!*s && !*conname)
{
Con_Printf("Active Server ports:\n");
NET_PrintAddresses(svs.sockets);
Con_Printf("end of list\n");
return;
}
if (!*conname)
conname = NULL;
//just in case
if (!svs.sockets)
{
svs.sockets = FTENET_CreateCollection(true, SV_ReadPacket);
#ifdef HAVE_CLIENT
FTENET_AddToCollection(svs.sockets, "SVLoopback", STRINGIFY(PORT_DEFAULTSERVER), NA_LOOPBACK, NP_DGRAM);
#endif
}
FTENET_AddToCollection(svs.sockets, conname, *s?s:NULL, *s?NA_IP:NA_INVALID, NP_DGRAM);
}
#endif
#ifdef HAVE_CLIENT
void NET_ClientPort_f(void)
{
Con_Printf("Active Client ports:\n");
NET_PrintAddresses(cls.sockets);
Con_Printf("end of list\n");
}
#endif
qboolean NET_WasSpecialPacket(ftenet_connections_t *collection)
{
#ifdef HAVE_NATPMP
if (NET_Was_NATPMP(collection))
return true;
#endif
#if defined(SUPPORT_ICE) || defined(MASTERONLY)
if (ICE_WasStun(collection))
return true;
#endif
#if defined(HAVE_DTLS) && defined(HAVE_SERVER)
if (collection->islisten && NET_DTLS_CheckInbound(collection))
return true;
#endif
return false;
}
//static void QDECL NET_UPNPIGP_Callback(cvar_t *var, char *oldval)
//{
//}
//cvar_t net_upnpigp = CVARCD("net_upnpigp", "0", NET_UPNPIGP_Callback, "If set, enables the use of the upnp-igd protocol to punch holes in your local NAT box.");
void SSL_Init(void);
/*
====================
NET_Init
====================
*/
void NET_Init (void)
{
#ifdef HAVE_EPOLL
epoll_fd = epoll_create1(EPOLL_CLOEXEC);
#endif
Cvar_Register(&net_enabled, "networking");
Cvar_Register(&net_dns_ipv4, "networking");
Cvar_Register(&net_dns_ipv6, "networking");
if (net_enabled.ival)
{
#if defined(_WIN32) && defined(HAVE_PACKET)
int r;
#ifdef HAVE_IPV6
dllfunction_t fncs[] =
{
{(void**)&pgetaddrinfo, "getaddrinfo"},
{(void**)&pfreeaddrinfo, "freeaddrinfo"},
{(void**)&pgetnameinfo, "getnameinfo"},
{NULL, NULL}
};
Sys_LoadLibrary("ws2_32.dll", fncs);
#endif
r = WSAStartup (MAKEWORD(2, 2), &winsockdata);
if (r)
Sys_Error ("Winsock initialization failed.");
#endif
}
Cvar_Register(&timeout, "networking");
Cvar_Register(&net_hybriddualstack, "networking");
Cvar_Register(&net_fakeloss, "networking");
#if defined(HAVE_SSL)
Cvar_Register(&tls_provider, "networking");
Cvar_Register(&tls_ignorecertificateerrors, "networking");
#endif
#if defined(TCPCONNECT) && (defined(HAVE_SERVER) || defined(HAVE_HTTPSV))
#ifdef HAVE_SERVER
Cvar_Register(&net_enable_qizmo, "networking");
#endif
#ifdef MVD_RECORDING
Cvar_Register(&net_enable_qtv, "networking");
#endif
#if defined(HAVE_SSL)
Cvar_Register(&net_enable_tls, "networking");
#endif
#ifdef HAVE_HTTPSV
Cvar_Register(&net_enable_http, "networking");
Cvar_Register(&net_enable_websockets, "networking");
Cvar_Register(&net_enable_rtcbroker, "networking");
#endif
#endif
#ifdef HAVE_SERVER
Cmd_AddCommand("sv_addport", SVNET_AddPort_f);
#endif
#ifdef HAVE_CLIENT
Cvar_Register(&cl_delay_packets, "networking");
Cmd_AddCommand("cl_addport", NET_ClientPort_f);
#endif
// Cvar_Register (&net_upnpigp, "networking");
// net_upnpigp.restriction = RESTRICT_MAX;
//
// init the message buffer
//
net_message.maxsize = sizeof(net_message_buffer);
net_message.data = net_message_buffer;
#if defined(HAVE_WINSSPI)
SSL_Init();
#endif
#ifdef SUPPORT_ICE
ICE_Init();
#endif
#if defined(HAVE_CLIENT)||defined(HAVE_SERVER)
Net_Master_Init();
#endif
#if defined(SUBSERVERS) && defined(HAVE_SERVER)
if (isDedicated && !SSV_IsSubServer())
{ //-clusterhost address:port password
//connects this server to a remote control/gateway server.
int i = COM_CheckParm("-clusterhost");
if (i && i+2 < com_argc)
{
vfsfile_t *f = FS_OpenTCP(com_argv[i+1], PORT_DEFAULTSERVER, true);
if (!f)
Sys_Error("Unable to resolve/connect to cluster host address \"%s\"\n", com_argv[i+1]);
VFS_PRINTF(f, "NODE\r\nPassword: \"%s\"\r\n", com_argv[i+2]);
SSV_SetupControlPipe(f);
return;
}
}
#endif
}
#ifdef HAVE_CLIENT
void NET_CloseClient(void)
{ //called by disconnect console command
FTENET_CloseCollection(cls.sockets);
cls.sockets = NULL;
}
void NET_InitClient(qboolean loopbackonly)
{
const char *port;
int p;
#ifdef QUAKESPYAPI
port = STRINGIFY(PORT_QWCLIENT);
#else
port = "0";
#endif
p = COM_CheckParm ("-clport");
if (p && p < com_argc)
{
port = com_argv[p+1];
}
if (!cls.sockets)
cls.sockets = FTENET_CreateCollection(false, CL_ReadPacket);
#ifdef HAVE_SERVER
FTENET_AddToCollection(cls.sockets, "CLLoopback", "1", NA_LOOPBACK, NP_DGRAM);
#endif
if (loopbackonly)
port = "";
#if defined(HAVE_IPV4) && defined(HAVE_IPV6)
if (net_hybriddualstack.ival)
{
FTENET_AddToCollection(cls.sockets, "CLUDP", port, NA_IP, NP_DGRAM);
}
else
#endif
{
#ifdef HAVE_IPV4
FTENET_AddToCollection(cls.sockets, "CLUDP4", port, NA_IP, NP_DGRAM);
#endif
#ifdef HAVE_IPV6
FTENET_AddToCollection(cls.sockets, "CLUDP6", port, NA_IPV6, NP_DGRAM);
#endif
}
#ifdef HAVE_IPX
FTENET_AddToCollection(cls.sockets, "CLIPX", port, NA_IPX, NP_DGRAM);
#endif
// Con_TPrintf("Client port Initialized\n");
}
#endif
#ifdef HAVE_SERVER
#ifdef HAVE_IPV4
static void QDECL SV_Tcpport_Callback(struct cvar_s *var, char *oldvalue)
{
if (!strcmp(var->string, "0")) //qtv_streamport had an old default value of 0. make sure we don't end up listening on random ports.
FTENET_AddToCollection(svs.sockets, var->name, "", NA_IP, NP_STREAM);
else
FTENET_AddToCollection(svs.sockets, var->name, var->string, NA_IP, NP_STREAM);
}
cvar_t sv_port_tcp = CVARFC("sv_port_tcp", "", CVAR_SERVERINFO, SV_Tcpport_Callback);
#ifdef HAVE_LEGACY
cvar_t qtv_streamport = CVARAFCD( "qtv_streamport", "",
"mvd_streamport", 0, SV_Tcpport_Callback, "Legacy cvar. Use sv_port_tcp instead.");
#endif
#endif
#ifdef HAVE_IPV6
static void QDECL SV_Tcpport6_Callback(struct cvar_s *var, char *oldvalue)
{
FTENET_AddToCollection(svs.sockets, var->name, var->string, NA_IPV6, NP_STREAM);
}
cvar_t sv_port_tcp6 = CVARC("sv_port_tcp6", "", SV_Tcpport6_Callback);
#endif
#ifdef HAVE_IPV4
static void QDECL SV_Port_Callback(struct cvar_s *var, char *oldvalue)
{
FTENET_AddToCollection(svs.sockets, var->name, var->string, NA_IP, NP_DGRAM);
}
cvar_t sv_port_ipv4 = CVARC("sv_port", STRINGIFY(PORT_DEFAULTSERVER), SV_Port_Callback);
#endif
#ifdef HAVE_IPV6
static void QDECL SV_PortIPv6_Callback(struct cvar_s *var, char *oldvalue)
{
FTENET_AddToCollection(svs.sockets, var->name, var->string, NA_IPV6, NP_DGRAM);
}
cvar_t sv_port_ipv6 = CVARCD("sv_port_ipv6", "", SV_PortIPv6_Callback, "Port to use for incoming ipv6 udp connections. Due to hybrid sockets this might not be needed. You can specify an ipv4 address:port for a second ipv4 port if you want.");
#endif
#ifdef HAVE_IPX
void QDECL SV_PortIPX_Callback(struct cvar_s *var, char *oldvalue)
{
FTENET_AddToCollection(svs.sockets, var->name, var->string, NA_IPX, NP_DGRAM);
}
cvar_t sv_port_ipx = CVARC("sv_port_ipx", "", SV_PortIPX_Callback);
#endif
#ifdef UNIXSOCKETS
void QDECL SV_PortUNIX_Callback(struct cvar_s *var, char *oldvalue)
{
FTENET_AddToCollection(svs.sockets, var->name, var->string, NA_UNIX, NP_DGRAM);
}
#ifdef __linux //linux adds abstract sockets, which require no filesystem cleanup.
cvar_t sv_port_unix = CVARC("sv_port_unix", "@qsock.fte", SV_PortUNIX_Callback);
#else
cvar_t sv_port_unix = CVARC("sv_port_unix", "/tmp/qsock.fte", SV_PortUNIX_Callback);
#endif
#endif
#ifdef HAVE_NATPMP
static void QDECL SV_Port_NatPMP_Callback(struct cvar_s *var, char *oldvalue)
{
FTENET_AddToCollection(svs.sockets, var->name, va("natpmp://%s", var->string), NA_IP, NP_NATPMP);
}
#if 1//def SERVERONLY
#define NATPMP_DEFAULT_PORT "" //don't fuck with dedicated servers
#else
#define NATPMP_DEFAULT_PORT "5351" //home users, yay, lucky people.
#endif
cvar_t sv_port_natpmp = CVARCD("sv_port_natpmp", NATPMP_DEFAULT_PORT, SV_Port_NatPMP_Callback, "If set (typically to 5351), automatically configures your router's port forwarding. You can instead specify the full ip address of your router (192.168.1.1:5351 for example). Your router must have NAT-PMP supported and enabled.");
#endif
#ifdef FTE_TARGET_WEB
void QDECL SV_PortRTC_Callback(struct cvar_s *var, char *oldvalue)
{
FTENET_AddToCollection(svs.sockets, var->name, var->string, NA_WEBSOCKET, NP_DTLS);
}
cvar_t sv_port_rtc = CVARCD("sv_port_rtc", "/", SV_PortRTC_Callback, "This specifies the broker url to use to obtain clients from. If the hostname is ommitted, it'll come from the manifest. If omitted, the broker service will randomize the resource part, so be sure to tell your friends the path reported by eg status rather than just this cvar value. Or just set it to 'rtc:///example' and tell clients to connect to the same sservevalue.");
#endif
void SVNET_RegisterCvars(void)
{
#ifdef FTE_TARGET_WEB
Cvar_Register (&net_ice_relayonly, "networking");
Cvar_Register (&net_ice_servers, "networking");
Cvar_Register (&sv_port_rtc, "networking");
// sv_port_rtc.restriction = RESTRICT_MAX;
#endif
#if defined(TCPCONNECT) && defined(HAVE_IPV4)
Cvar_Register (&sv_port_tcp, "networking");
sv_port_tcp.restriction = RESTRICT_MAX;
#ifdef HAVE_LEGACY
Cvar_Register (&qtv_streamport, "networking");
qtv_streamport.restriction = RESTRICT_MAX;
#endif
#endif
#if defined(TCPCONNECT) && defined(HAVE_IPV6)
Cvar_Register (&sv_port_tcp6, "networking");
sv_port_tcp6.restriction = RESTRICT_MAX;
#endif
#ifdef HAVE_IPV6
Cvar_Register (&sv_port_ipv6, "networking");
sv_port_ipv6.restriction = RESTRICT_MAX;
#endif
#ifdef HAVE_IPX
Cvar_Register (&sv_port_ipx, "networking");
sv_port_ipx.restriction = RESTRICT_MAX;
#endif
#ifdef HAVE_IPV4
Cvar_Register (&sv_port_ipv4, "networking");
sv_port_ipv4.restriction = RESTRICT_MAX;
#endif
#ifdef HAVE_NATPMP
Cvar_Register (&sv_port_natpmp, "networking");
sv_port_natpmp.restriction = RESTRICT_MAX;
#endif
#ifdef UNIXSOCKETS
// Cvar_Register (&sv_port_unix, "networking");
#endif
#if defined(HAVE_DTLS) && defined(HAVE_SERVER)
Cvar_Register (&net_enable_dtls, "networking");
#endif
#ifdef HAVE_DTLS
Cvar_Register (&dtls_psk_hint, "networking");
Cvar_Register (&dtls_psk_user, "networking");
Cvar_Register (&dtls_psk_key, "networking");
#endif
}
void NET_CloseServer(void)
{
FTENET_CloseCollection(svs.sockets);
svs.sockets = NULL;
}
void NET_InitServer(void)
{
qboolean singleplayer = (sv.allocated_client_slots == 1) && !isDedicated;
#ifdef HAVE_EPOLL
if (epoll_fd < 0)
epoll_fd = epoll_create1(EPOLL_CLOEXEC);
#endif
if ((sv_listen_nq.value || sv_listen_dp.value || sv_listen_qw.value
#ifdef QWOVERQ3
|| sv_listen_q3.ival
#endif
) && !singleplayer)
{
if (!svs.sockets)
{
svs.sockets = FTENET_CreateCollection(true, SV_ReadPacket);
#ifdef HAVE_CLIENT
FTENET_AddToCollection(svs.sockets, "SVLoopback", STRINGIFY(PORT_DEFAULTSERVER), NA_LOOPBACK, NP_DGRAM);
#endif
}
#ifdef FTE_TARGET_WEB
Cvar_ForceCallback(&sv_port_rtc);
#endif
#ifdef HAVE_IPV4
Cvar_ForceCallback(&sv_port_ipv4);
#endif
#ifdef HAVE_IPV6
Cvar_ForceCallback(&sv_port_ipv6);
#endif
#ifdef HAVE_IPX
Cvar_ForceCallback(&sv_port_ipx);
#endif
#if defined(TCPCONNECT) && defined(HAVE_TCP)
Cvar_ForceCallback(&sv_port_tcp);
#ifdef HAVE_LEGACY
Cvar_ForceCallback(&qtv_streamport);
#endif
#ifdef HAVE_IPV6
Cvar_ForceCallback(&sv_port_tcp6);
#endif
#endif
#ifdef HAVE_NATPMP
Cvar_ForceCallback(&sv_port_natpmp);
#endif
#ifdef UNIXSOCKETS
// Cvar_ForceCallback(&sv_port_unix);
#endif
#ifdef HAVE_DTLS
Cvar_ForceCallback(&net_enable_dtls);
#endif
#if defined(SUPPORT_ICE) || defined(FTE_TARGET_WEB)
Cvar_ForceCallback(&sv_public);
#endif
}
else
{
NET_CloseServer();
#ifdef HAVE_CLIENT
svs.sockets = FTENET_CreateCollection(true, SV_ReadPacket);
FTENET_AddToCollection(svs.sockets, "SVLoopback", STRINGIFY(PORT_DEFAULTSERVER), NA_LOOPBACK, NP_DGRAM);
#endif
}
}
#endif
void NET_Tick(void)
{
#ifdef SUPPORT_ICE
ICE_Tick();
#endif
}
/*
====================
NET_Shutdown
====================
*/
void NET_Shutdown (void)
{
#ifdef HAVE_SERVER
NET_CloseServer();
#endif
#ifdef HAVE_CLIENT
FTENET_CloseCollection(cls.sockets);
cls.sockets = NULL;
#endif
#ifdef HAVE_EPOLL
if (epoll_fd >= 0)
close(epoll_fd);
epoll_fd = -1;
stdin_epolling = false;
#endif
#if defined(_WIN32) && defined(HAVE_PACKET)
#ifdef SERVERTONLY
if (!serverthreadID) //running as subsystem of client. Don't close all of it's sockets too.
#endif
WSACleanup ();
#endif
}
#ifdef HAVE_TCP
#ifdef HAVE_EPOLL
#include <poll.h>
#endif
static int VFSTCP_IsStillConnecting(SOCKET sock)
{
#ifdef HAVE_EPOLL
//poll has no arbitrary fd limit. use it instead of select where possible.
struct pollfd ourfd[1];
ourfd[0].fd = sock;
ourfd[0].events = POLLOUT;
ourfd[0].revents = 0;
if (!poll(ourfd, countof(ourfd), 0))
{
if (ourfd[0].revents & POLLERR)
return VFS_ERROR_UNSPECIFIED;
if (ourfd[0].revents & POLLHUP)
return VFS_ERROR_REFUSED;
return true; //no events yet.
}
#else
//okay on windows where sock+1 is ignored, has issues when lots of other fds are already open (for any reason).
fd_set fdw, fdx;
struct timeval timeout;
timeout.tv_sec = 0;
timeout.tv_usec = 0;
FD_ZERO(&fdw);
FD_SET(sock, &fdw);
FD_ZERO(&fdx);
FD_SET(sock, &fdx);
//check if we can actually write to it yet, without generating weird errors...
if (!select((int)sock+1, NULL, &fdw, &fdx, &timeout))
return true;
#endif
//if we get here then its writable(read: connected) or failed.
// int error = NET_ENOTCONN;
// socklen_t sz = sizeof(error);
// if (getsockopt(sock, SOL_SOCKET, SO_ERROR, &error, &sz))
// error = NET_ENOTCONN;
return false;
}
typedef struct {
vfsfile_t funcs;
SOCKET sock;
qboolean conpending;
int readaborted; //some kind of error. don't spam
int writeaborted; //some kind of error. don't spam
char readbuffer[65536];
int readbuffered;
char peer[1];
} tcpfile_t;
int QDECL VFSTCP_ReadBytes (struct vfsfile_s *file, void *buffer, int bytestoread)
{
tcpfile_t *tf = (tcpfile_t*)file;
int len;
int trying;
if (tf->conpending)
{
trying = VFSTCP_IsStillConnecting(tf->sock);
if (trying < 0)
tf->readaborted = trying;
else if (trying)
return 0;
tf->conpending = false;
}
if (!tf->readaborted)
{
trying = sizeof(tf->readbuffer) - tf->readbuffered;
if (bytestoread > 1500)
{
if (trying > bytestoread)
trying = bytestoread;
}
else
{
if (trying > 1500)
trying = 1500;
}
len = recv(tf->sock, tf->readbuffer + tf->readbuffered, trying, 0);
if (len == -1)
{
int e = neterrno();
if (e != NET_EWOULDBLOCK && e != NET_EINTR)
{
tf->readaborted = VFS_ERROR_UNSPECIFIED;
switch(e)
{
case NET_ENOTCONN:
Con_Printf("connection to \"%s\" failed\n", tf->peer);
tf->readaborted = VFS_ERROR_NORESPONSE;
break;
case NET_ECONNABORTED:
Con_DPrintf("connection to \"%s\" aborted\n", tf->peer);
tf->readaborted = VFS_ERROR_NORESPONSE;
break;
case NET_ETIMEDOUT:
Con_Printf("connection to \"%s\" timed out\n", tf->peer);
tf->readaborted = VFS_ERROR_NORESPONSE;
break;
case NET_ECONNREFUSED:
Con_DPrintf("connection to \"%s\" refused\n", tf->peer);
tf->readaborted = VFS_ERROR_REFUSED;
break;
case NET_ECONNRESET:
Con_DPrintf("connection to \"%s\" reset\n", tf->peer);
break;
default:
Con_Printf("tcp socket error %i (%s)\n", e, tf->peer);
}
}
//fixme: figure out wouldblock or error
}
else if (len == 0 && trying != 0)
{
//peer disconnected
tf->readaborted = VFS_ERROR_EOF;
}
else
{
tf->readbuffered += len;
}
}
//return a partially filled buffer.
if (bytestoread > tf->readbuffered)
bytestoread = tf->readbuffered;
if (bytestoread < 0)
return VFS_ERROR_UNSPECIFIED; //caller error...
if (bytestoread > 0)
{
memcpy(buffer, tf->readbuffer, bytestoread);
tf->readbuffered -= bytestoread;
memmove(tf->readbuffer, tf->readbuffer+bytestoread, tf->readbuffered);
return bytestoread;
}
else return tf->readaborted;
}
int QDECL VFSTCP_WriteBytes (struct vfsfile_s *file, const void *buffer, int bytestoread)
{
tcpfile_t *tf = (tcpfile_t*)file;
int len;
if (tf->writeaborted)
return VFS_ERROR_UNSPECIFIED; //a previous write failed.
if (tf->conpending)
{
len = VFSTCP_IsStillConnecting(tf->sock);
if (len < 0)
{
tf->writeaborted = true;
tf->conpending = false;
return len;
}
if (len)
return 0;
tf->conpending = false;
}
len = send(tf->sock, buffer, bytestoread, 0);
if (len == -1 || len == 0)
{
int reason = VFS_ERROR_UNSPECIFIED;
int e = (len==0)?NET_ECONNABORTED:neterrno();
switch(e)
{
case NET_EINTR:
case NET_EWOULDBLOCK:
return 0; //nothing available yet.
case NET_ETIMEDOUT:
Con_Printf("connection to \"%s\" timed out\n", tf->peer);
return VFS_ERROR_NORESPONSE; //don't bother trying to read if we never connected.
case NET_ECONNREFUSED: //peer sent a reset instead of accepting a new connection
Con_DPrintf("connection to \"%s\" refused\n", tf->peer);
return VFS_ERROR_REFUSED; //don't bother trying to read if we never connected.
case NET_ECONNABORTED: //peer closed its socket
Con_Printf("connection to \"%s\" aborted\n", tf->peer);
reason = len?VFS_ERROR_NORESPONSE:VFS_ERROR_EOF;
break;
case NET_ECONNRESET: //'peer' claims no knowledge (rebooted?) or forcefully closed
Con_DPrintf("connection to \"%s\" reset\n", tf->peer);
reason = VFS_ERROR_EOF;
break;
case NET_ENOTCONN:
#ifdef __unix__
case EPIPE:
#endif
Con_Printf("connection to \"%s\" failed\n", tf->peer);
return VFS_ERROR_NORESPONSE; //don't bother trying to read if we never connected.
default:
Sys_Printf("tcp socket error %i (%s)\n", e, tf->peer);
break;
}
// don't destroy it on write errors, because that prevents us from reading anything that was sent to us afterwards.
// instead let the read handling kill it if there's nothing new to be read
VFSTCP_ReadBytes(file, NULL, 0);
tf->writeaborted = true;
return reason;
}
return len;
}
qboolean QDECL VFSTCP_Seek (struct vfsfile_s *file, qofs_t pos)
{
return false;
}
static qofs_t QDECL VFSTCP_Tell (struct vfsfile_s *file)
{
return 0;
}
static qofs_t QDECL VFSTCP_GetLen (struct vfsfile_s *file)
{
return 0;
}
static qboolean QDECL VFSTCP_Close (struct vfsfile_s *file)
{
tcpfile_t *f = (tcpfile_t *)file;
qboolean success = f->sock != INVALID_SOCKET;
if (f->sock != INVALID_SOCKET)
{
closesocket(f->sock);
f->sock = INVALID_SOCKET;
}
Z_Free(f);
return success;
}
vfsfile_t *FS_WrapTCPSocket(SOCKET sock, qboolean conpending, const char *peername)
{
tcpfile_t *newf;
if (sock == INVALID_SOCKET)
return NULL;
newf = Z_Malloc(sizeof(*newf) + strlen(peername));
strcpy(newf->peer, peername);
newf->conpending = conpending;
newf->sock = sock;
newf->funcs.Close = VFSTCP_Close;
newf->funcs.Flush = NULL;
newf->funcs.GetLen = VFSTCP_GetLen;
newf->funcs.ReadBytes = VFSTCP_ReadBytes;
newf->funcs.Seek = VFSTCP_Seek;
newf->funcs.Tell = VFSTCP_Tell;
newf->funcs.WriteBytes = VFSTCP_WriteBytes;
newf->funcs.seekstyle = SS_UNSEEKABLE;
return &newf->funcs;
}
vfsfile_t *FS_OpenTCP(const char *name, int defaultport, qboolean assumetls)
{
netadr_t adr = {0};
if (NET_StringToAdr(name, defaultport, &adr))
{
qboolean wanttls = (adr.prot == NP_TLS || (adr.prot != NP_STREAM && assumetls));
vfsfile_t *f;
#ifndef HAVE_SSL
if (wanttls)
return NULL; //don't even make the connection if we can't satisfy it.
#endif
f = FS_WrapTCPSocket(TCP_OpenStream(&adr, name), true, name);
#ifdef HAVE_SSL
if (f && wanttls)
f = FS_OpenSSL(name, f, false);
#endif
return f;
}
else
return NULL;
}
#else
vfsfile_t *FS_OpenTCP(const char *name, int defaultport, qboolean assumetls)
{
return NULL;
}
#endif