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fteqw/engine/server/sv_send.c
Spoike c0841c73ab add net_compress cvar to enable/disable the compression feature. off by default for now.
auto-precache sounds if they were not already precached. also prints a warning (once, obviously). this is for consistency with models
added cmd voicetarg specself, which will send voice only to the people spectating you (and not your team), including into demos.

git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@4647 fc73d0e0-1445-4013-8a0c-d673dee63da5
2014-04-27 23:16:07 +00:00

2843 lines
71 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.
*/
// sv_main.c -- server main program
#include "quakedef.h"
#ifndef CLIENTONLY
#define CHAN_AUTO 0
#define CHAN_WEAPON 1
#define CHAN_VOICE 2
#define CHAN_ITEM 3
#define CHAN_BODY 4
extern cvar_t sv_gravity, sv_friction, sv_waterfriction, sv_gamespeed, sv_stopspeed, sv_spectatormaxspeed, sv_accelerate, sv_airaccelerate, sv_wateraccelerate, sv_edgefriction;
extern cvar_t dpcompat_stats;
/*
=============================================================================
Con_Printf redirection
=============================================================================
*/
char outputbuf[8000];
redirect_t sv_redirected;
int sv_redirectedlang;
extern cvar_t sv_phs;
/*
==================
SV_FlushRedirect
==================
*/
void SV_FlushRedirect (void)
{
int totallen;
char send[8000+6];
if (!*outputbuf)
return;
Log_String(LOG_CONSOLE, va("{\n%s}\n", outputbuf));
if (sv_redirected == RD_PACKET)
{
send[0] = 0xff;
send[1] = 0xff;
send[2] = 0xff;
send[3] = 0xff;
send[4] = A2C_PRINT;
memcpy (send+5, outputbuf, strlen(outputbuf)+1);
NET_SendPacket (NS_SERVER, strlen(send)+1, send, &net_from);
}
#ifdef SUBSERVERS
else if (sv_redirected == RD_MASTER)
{
sizebuf_t s;
memset(&s, 0, sizeof(s));
s.data = send;
s.maxsize = sizeof(send);
s.cursize = 2;
MSG_WriteByte(&s, ccmd_print);
MSG_WriteString(&s, outputbuf);
SSV_InstructMaster(&s);
}
#endif
else if (sv_redirected == RD_CLIENT)
{
int chop;
char spare;
char *s = outputbuf;
totallen = strlen(s)+3;
while (sizeof(host_client->backbuf_data[0])/2 < totallen)
{
chop = sizeof(host_client->backbuf_data[0]) / 2;
spare = s[chop];
s[chop] = '\0';
ClientReliableWrite_Begin (host_client, host_client->protocol==SCP_QUAKE2?svcq2_print:svc_print, chop+3);
ClientReliableWrite_Byte (host_client, PRINT_HIGH);
ClientReliableWrite_String (host_client, s);
s += chop;
totallen -= chop;
s[0] = spare;
}
ClientReliableWrite_Begin (host_client, host_client->protocol==SCP_QUAKE2?svcq2_print:svc_print, strlen(s)+3);
ClientReliableWrite_Byte (host_client, PRINT_HIGH);
ClientReliableWrite_String (host_client, s);
}
// clear it
outputbuf[0] = 0;
}
/*
==================
SV_BeginRedirect
Send Con_Printf data to the remote client
instead of the console
==================
*/
void SV_BeginRedirect (redirect_t rd, int lang)
{
SV_FlushRedirect();
sv_redirected = rd;
sv_redirectedlang = lang;
outputbuf[0] = 0;
}
void SV_EndRedirect (void)
{
SV_FlushRedirect ();
sv_redirectedlang = 0; //clenliness rather than functionality. Shouldn't be needed.
sv_redirected = RD_NONE;
}
/*
================
Con_Printf
Handles cursor positioning, line wrapping, etc
================
*/
#define MAXPRINTMSG 4096
// FIXME: make a buffer size safe vsprintf?
#ifdef SERVERONLY
void VARGS Con_Printf (const char *fmt, ...)
{
va_list argptr;
char msg[MAXPRINTMSG];
va_start (argptr,fmt);
vsnprintf (msg,sizeof(msg)-1, fmt,argptr);
va_end (argptr);
// add to redirected message
if (sv_redirected)
{
if (strlen (msg) + strlen(outputbuf) > sizeof(outputbuf) - 1)
SV_FlushRedirect ();
strcat (outputbuf, msg);
if (sv_redirected != -1)
return;
}
Sys_Printf ("%s", msg); // also echo to debugging console
Con_Log(msg); // log to console
}
void Con_TPrintf (translation_t stringnum, ...)
{
va_list argptr;
char msg[MAXPRINTMSG];
const char *fmt;
// add to redirected message
if (sv_redirected)
{
fmt = langtext(stringnum,sv_redirectedlang);
va_start (argptr,stringnum);
vsnprintf (msg,sizeof(msg)-1, fmt,argptr);
va_end (argptr);
if (strlen (msg) + strlen(outputbuf) > sizeof(outputbuf) - 1)
SV_FlushRedirect ();
strcat (outputbuf, msg);
return;
}
fmt = langtext(stringnum,svs.language);
va_start (argptr,stringnum);
vsnprintf (msg,sizeof(msg)-1, fmt,argptr);
va_end (argptr);
Sys_Printf ("%s", msg); // also echo to debugging console
Con_Log(msg); // log to console
}
/*
================
Con_DPrintf
A Con_Printf that only shows up if the "developer" cvar is set
================
*/
void Con_DPrintf (const char *fmt, ...)
{
va_list argptr;
char msg[MAXPRINTMSG];
extern cvar_t log_developer;
if (!developer.value && !log_developer.value)
return;
va_start (argptr,fmt);
vsnprintf (msg,sizeof(msg)-1, fmt,argptr);
va_end (argptr);
// add to redirected message
if (sv_redirected)
{
if (strlen (msg) + strlen(outputbuf) > sizeof(outputbuf) - 1)
SV_FlushRedirect ();
strcat (outputbuf, msg);
if (sv_redirected != -1)
return;
}
if (developer.value)
Sys_Printf ("%s", msg); // also echo to debugging console
if (log_developer.value)
Con_Log(msg); // log to console
}
#endif
/*
=============================================================================
EVENT MESSAGES
=============================================================================
*/
//Directly print to a client without translating nor printing into an mvd. generally for error messages due to the lack of mvd thing.
void SV_PrintToClient(client_t *cl, int level, const char *string)
{
if (cl->controller)
cl = cl->controller;
switch (cl->protocol)
{
case SCP_BAD: //bot
break;
case SCP_QUAKE2:
#ifdef Q2SERVER
ClientReliableWrite_Begin (cl, svcq2_print, strlen(string)+3);
ClientReliableWrite_Byte (cl, level);
ClientReliableWrite_String (cl, string);
#endif
break;
case SCP_QUAKE3:
break;
case SCP_QUAKEWORLD:
ClientReliableWrite_Begin (cl, svc_print, strlen(string)+3);
ClientReliableWrite_Byte (cl, level);
ClientReliableWrite_String (cl, string);
break;
case SCP_DARKPLACES6:
case SCP_DARKPLACES7:
case SCP_NETQUAKE:
case SCP_PROQUAKE:
case SCP_FITZ666:
#ifdef NQPROT
ClientReliableWrite_Begin (cl, svc_print, strlen(string)+3);
if (level == PRINT_CHAT)
ClientReliableWrite_Byte (cl, 1);
ClientReliableWrite_String (cl, string);
#endif
break;
}
}
//translate it, but avoid 'public' mvd prints.
void SV_TPrintToClient(client_t *cl, int level, const char *string)
{
string = langtext(string, cl->language);
SV_PrintToClient(cl, level, string);
}
void SV_StuffcmdToClient(client_t *cl, char *string)
{
switch (cl->protocol)
{
case SCP_BAD: //bot
break;
case SCP_QUAKE2:
#ifdef Q2SERVER
ClientReliableWrite_Begin (cl, svcq2_stufftext, strlen(string)+3);
ClientReliableWrite_String (cl, string);
#endif
break;
case SCP_QUAKE3:
break;
case SCP_QUAKEWORLD:
case SCP_DARKPLACES6:
case SCP_DARKPLACES7:
case SCP_NETQUAKE:
case SCP_PROQUAKE:
case SCP_FITZ666:
ClientReliableWrite_Begin (cl, svc_stufftext, strlen(string)+3);
ClientReliableWrite_String (cl, string);
break;
}
}
/*
=================
SV_ClientPrintf
Sends text across to be displayed if the level passes
Is included in mvds.
=================
*/
void VARGS SV_ClientPrintf (client_t *cl, int level, char *fmt, ...)
{
va_list argptr;
char string[1024];
if (level < cl->messagelevel)
return;
va_start (argptr,fmt);
vsnprintf (string,sizeof(string)-1, fmt,argptr);
va_end (argptr);
if(strlen(string) >= sizeof(string))
Sys_Error("SV_ClientPrintf: Buffer stomped\n");
if (sv.mvdrecording)
{
sizebuf_t *msg = MVDWrite_Begin (dem_single, cl - svs.clients, strlen(string)+3);
MSG_WriteByte (msg, svc_print);
MSG_WriteByte (msg, level);
MSG_WriteString (msg, string);
}
if (cl->controller)
SV_PrintToClient(cl->controller, level, string);
else
SV_PrintToClient(cl, level, string);
}
void VARGS SV_ClientTPrintf (client_t *cl, int level, translation_t stringnum, ...)
{
va_list argptr;
char string[1024];
const char *fmt = langtext(stringnum, cl->language);
if (level < cl->messagelevel)
return;
va_start (argptr,stringnum);
vsnprintf (string,sizeof(string)-1, fmt,argptr);
va_end (argptr);
if(strlen(string) >= sizeof(string))
Sys_Error("SV_ClientTPrintf: Buffer stomped\n");
if (sv.mvdrecording)
{
sizebuf_t *msg = MVDWrite_Begin (dem_single, cl - svs.clients, strlen(string)+3);
MSG_WriteByte (msg, svc_print);
MSG_WriteByte (msg, level);
MSG_WriteString (msg, string);
}
SV_PrintToClient(cl, level, string);
}
/*
=================
SV_BroadcastPrintf
Sends text to all active clients
=================
*/
void VARGS SV_BroadcastPrintf (int level, char *fmt, ...)
{
va_list argptr;
char string[1024];
client_t *cl;
int i;
va_start (argptr,fmt);
vsnprintf (string,sizeof(string)-1, fmt,argptr);
va_end (argptr);
if(strlen(string) >= sizeof(string))
Sys_Error("SV_BroadcastPrintf: Buffer stomped\n");
//pretend to print on the server, but not to the client's console
Sys_Printf ("%s", string); // print to the system console
Log_String(LOG_CONSOLE, string); //dump into log
for (i=0, cl = svs.clients ; i<svs.allocated_client_slots ; i++, cl++)
{
if (level < cl->messagelevel)
continue;
if (!cl->state)
continue;
if (cl->protocol == SCP_BAD)
continue;
if (cl == sv.skipbprintclient) //silence bprints about the player in ClientConnect. NQ completely wipes the buffer after clientconnect, which is what traditionally hides it.
continue;
if (cl->controller)
continue;
SV_PrintToClient(cl, level, string);
}
if (sv.mvdrecording)
{
sizebuf_t *msg = MVDWrite_Begin (dem_all, 0, strlen(string)+3);
MSG_WriteByte (msg, svc_print);
MSG_WriteByte (msg, level);
MSG_WriteString (msg, string);
}
}
void VARGS SV_BroadcastTPrintf (int level, translation_t stringnum, ...)
{
va_list argptr;
char string[1024];
client_t *cl;
int i;
int oldlang=-1;
const char *fmt = langtext(stringnum, oldlang=svs.language);
va_start (argptr,stringnum);
vsnprintf (string,sizeof(string)-1, fmt,argptr);
va_end (argptr);
if(strlen(string) >= sizeof(string))
Sys_Error("SV_BroadcastPrintf: Buffer stomped\n");
//pretend to print on the server, but not to the client's console
Sys_Printf ("%s", string); // print to the console
Log_String(LOG_CONSOLE, string); //dump into log
for (i=0, cl = svs.clients ; i<svs.allocated_client_slots ; i++, cl++)
{
if (level < cl->messagelevel)
continue;
if (!cl->state)
continue;
if (cl->controller)
continue;
if (oldlang!=cl->language)
{
fmt = langtext(stringnum, oldlang=cl->language);
va_start (argptr,stringnum);
vsnprintf (string,sizeof(string)-1, fmt,argptr);
va_end (argptr);
if(strlen(string) >= sizeof(string))
Sys_Error("SV_BroadcastPrintf: Buffer stomped\n");
}
SV_PrintToClient(cl, level, string);
}
}
/*
=================
SV_BroadcastCommand
Sends text to all active clients
=================
*/
void VARGS SV_BroadcastCommand (char *fmt, ...)
{
va_list argptr;
char string[1024];
int i;
client_t *cl;
if (!sv.state)
return;
va_start (argptr,fmt);
vsnprintf (string,sizeof(string), fmt,argptr);
va_end (argptr);
for (i=0, cl = svs.clients ; i<svs.allocated_client_slots ; i++, cl++)
{
if (cl->controller)
continue;
if (cl->state>=cs_connected)
{
if (ISQWCLIENT(cl) || ISNQCLIENT(cl))
{
ClientReliableWrite_Begin(cl, svc_stufftext, strlen(string)+2);
ClientReliableWrite_String (cl, string);
}
else if (ISQ2CLIENT(cl))
{
ClientReliableWrite_Begin(cl, svcq2_stufftext, strlen(string)+2);
ClientReliableWrite_String (cl, string);
}
}
}
}
/*
=================
SV_Multicast
Sends the contents of sv.multicast to a subset of the clients,
then clears sv.multicast.
MULTICAST_ALL same as broadcast
MULTICAST_PVS send to clients potentially visible from org
MULTICAST_PHS send to clients potentially hearable from org
MULTICAST_ONE sent to a single client.
MULTICAST_INIT sent to clients when they first connect. for completeness.
=================
*/
void SV_MulticastProtExt(vec3_t origin, multicast_t to, int dimension_mask, int with, int without)
{
client_t *client;
qbyte *mask;
int leafnum;
int j;
qboolean reliable;
int pnum = 0;
if (to == MULTICAST_INIT)
{
//we only have one signon buffer. make sure you don't put non-identical protocols in the buffer
SV_FlushSignon();
SZ_Write (&sv.signon, sv.multicast.data, sv.multicast.cursize);
//and send to players that are already on
to = MULTICAST_ALL_R;
}
// to = MULTICAST_ALL;
//don't let things crash if the world model went away. can happen in broadcasts when reloading video with the map no longer available causing the server to die with the resulting broadcast messages about players dropping or gib effects appearing
if (sv.world.worldmodel->needload)
{
switch(to)
{
case MULTICAST_PHS_R:
case MULTICAST_PVS_R:
to = MULTICAST_ALL_R;
break;
case MULTICAST_PHS:
case MULTICAST_PVS:
to = MULTICAST_ALL;
break;
}
}
#ifdef Q2BSPS
if (sv.world.worldmodel->fromgame == fg_quake2 || sv.world.worldmodel->fromgame == fg_quake3)
{
int area1, area2, cluster;
reliable = false;
if (to != MULTICAST_ALL_R && to != MULTICAST_ALL)
{
leafnum = CM_PointLeafnum (sv.world.worldmodel, origin);
area1 = CM_LeafArea (sv.world.worldmodel, leafnum);
}
else
{
leafnum = 0; // just to avoid compiler warnings
area1 = 0;
}
switch (to)
{
case MULTICAST_ALL_R:
reliable = true; // intentional fallthrough
case MULTICAST_ALL:
leafnum = 0;
mask = NULL;
break;
case MULTICAST_PHS_R:
reliable = true; // intentional fallthrough
case MULTICAST_PHS:
leafnum = CM_PointLeafnum (sv.world.worldmodel, origin);
cluster = CM_LeafCluster (sv.world.worldmodel, leafnum);
mask = CM_ClusterPHS (sv.world.worldmodel, cluster);
break;
case MULTICAST_PVS_R:
reliable = true; // intentional fallthrough
case MULTICAST_PVS:
leafnum = CM_PointLeafnum (sv.world.worldmodel, origin);
cluster = CM_LeafCluster (sv.world.worldmodel, leafnum);
mask = CM_ClusterPVS (sv.world.worldmodel, cluster, NULL, 0);
break;
case MULTICAST_ONE_R:
reliable = true;
case MULTICAST_ONE:
if (svprogfuncs)
{
edict_t *ent = PROG_TO_EDICT(svprogfuncs, pr_global_struct->msg_entity);
pnum = NUM_FOR_EDICT(svprogfuncs, ent) - 1;
}
mask = NULL;
break;
default:
mask = NULL;
SV_Error ("SV_Multicast: bad to:%i", to);
}
// send the data to all relevent clients
for (j = 0, client = svs.clients; j < svs.allocated_client_slots; j++, client++)
{
if (client->state != cs_spawned)
continue;
if (client->protocol == SCP_QUAKEWORLD)
{
if (client->fteprotocolextensions & without)
{
// Con_Printf ("Version supressed multicast - without pext\n");
continue;
}
if (!(~client->fteprotocolextensions & ~with))
{
// Con_Printf ("Version supressed multicast - with pext\n");
continue;
}
}
if (!mask)
{
if (pnum != j)
continue;
}
else
{
#ifdef Q2SERVER
if (ge)
leafnum = CM_PointLeafnum (sv.world.worldmodel, client->q2edict->s.origin);
else
#endif
{
if (svprogfuncs)
{
if (!((int)client->edict->xv->dimension_see & dimension_mask))
continue;
}
leafnum = CM_PointLeafnum (sv.world.worldmodel, client->edict->v->origin);
}
cluster = CM_LeafCluster (sv.world.worldmodel, leafnum);
area2 = CM_LeafArea (sv.world.worldmodel, leafnum);
if (!CM_AreasConnected (sv.world.worldmodel, area1, area2))
continue;
if ( mask && (!(mask[cluster>>3] & (1<<(cluster&7)) ) ) )
continue;
}
switch (client->protocol)
{
case SCP_BAD:
continue; //a bot.
default:
SV_Error("Multicast: Client is using a bad protocl");
case SCP_QUAKE3:
Con_Printf("Skipping multicast for q3 client\n");
break;
#ifdef NQPROT
case SCP_NETQUAKE:
case SCP_PROQUAKE:
case SCP_FITZ666:
case SCP_DARKPLACES6:
case SCP_DARKPLACES7:
if (reliable)
{
ClientReliableCheckBlock(client, sv.nqmulticast.cursize);
ClientReliableWrite_SZ(client, sv.nqmulticast.data, sv.nqmulticast.cursize);
}
else
SZ_Write (&client->datagram, sv.nqmulticast.data, sv.nqmulticast.cursize);
break;
#endif
#ifdef Q2SERVER
case SCP_QUAKE2:
if (reliable)
{
ClientReliableCheckBlock(client, sv.q2multicast.cursize);
ClientReliableWrite_SZ(client, sv.q2multicast.data, sv.q2multicast.cursize);
}
else
SZ_Write (&client->datagram, sv.q2multicast.data, sv.q2multicast.cursize);
break;
#endif
case SCP_QUAKEWORLD:
if (reliable)
{
ClientReliableCheckBlock(client, sv.multicast.cursize);
ClientReliableWrite_SZ(client, sv.multicast.data, sv.multicast.cursize);
}
else
SZ_Write (&client->datagram, sv.multicast.data, sv.multicast.cursize);
break;
}
}
}
else
#endif
{
reliable = false;
switch (to)
{
case MULTICAST_ALL_R:
reliable = true; // intentional fallthrough
case MULTICAST_ALL:
mask = sv.pvs; // leaf 0 is everything;
break;
case MULTICAST_PHS_R:
reliable = true; // intentional fallthrough
case MULTICAST_PHS:
if (!sv.phs) /*broadcast if no pvs*/
mask = sv.pvs;
else
{
leafnum = sv.world.worldmodel->funcs.LeafnumForPoint(sv.world.worldmodel, origin);
mask = sv.phs + leafnum * 4*((sv.world.worldmodel->numleafs+31)>>5);
}
break;
case MULTICAST_PVS_R:
reliable = true; // intentional fallthrough
case MULTICAST_PVS:
leafnum = sv.world.worldmodel->funcs.LeafnumForPoint(sv.world.worldmodel, origin);
mask = sv.pvs + leafnum * 4*((sv.world.worldmodel->numleafs+31)>>5);
break;
case MULTICAST_ONE_R:
reliable = true;
case MULTICAST_ONE:
if (svprogfuncs)
{
edict_t *ent = PROG_TO_EDICT(svprogfuncs, pr_global_struct->msg_entity);
pnum = NUM_FOR_EDICT(svprogfuncs, ent) - 1;
}
mask = NULL;
break;
default:
mask = NULL;
SV_Error ("SV_Multicast: bad to:%i", to);
}
// send the data to all relevent clients
for (j = 0, client = svs.clients; j < sv.allocated_client_slots; j++, client++)
{
if (client->state != cs_spawned)
continue;
if (client->controller)
continue; //FIXME: send if at least one of the players is near enough.
if (client->protocol == SCP_QUAKEWORLD)
{
if (client->fteprotocolextensions & without)
{
// Con_Printf ("Version supressed multicast - without pext\n");
continue;
}
if (!(client->fteprotocolextensions & with) && with)
{
// Con_Printf ("Version supressed multicast - with pext\n");
continue;
}
}
if (!mask)
{
if (pnum != j)
continue;
}
else if (svprogfuncs)
{
if (!((int)client->edict->xv->dimension_see & dimension_mask))
continue;
if (to == MULTICAST_PHS_R || to == MULTICAST_PHS)
{
vec3_t delta;
VectorSubtract(origin, client->edict->v->origin, delta);
if (Length(delta) <= 1024)
goto inrange;
}
// -1 is because pvs rows are 1 based, not 0 based like leafs
if (mask != sv.pvs)
{
vec3_t pos;
VectorAdd(client->edict->v->origin, client->edict->v->view_ofs, pos);
leafnum = sv.world.worldmodel->funcs.LeafnumForPoint (sv.world.worldmodel, pos)-1;
if ( !(mask[leafnum>>3] & (1<<(leafnum&7)) ) )
{
// Con_Printf ("PVS supressed multicast\n");
continue;
}
}
}
inrange:
switch (client->protocol)
{
case SCP_BAD:
continue; //a bot.
default:
SV_Error("multicast: Client is using a bad protocol");
case SCP_QUAKE3:
Con_Printf("Skipping multicast for q3 client\n");
break;
#ifdef NQPROT
case SCP_NETQUAKE:
case SCP_PROQUAKE:
case SCP_FITZ666:
case SCP_DARKPLACES6:
case SCP_DARKPLACES7: //extra prediction stuff
if (reliable)
{
ClientReliableCheckBlock(client, sv.nqmulticast.cursize);
ClientReliableWrite_SZ(client, sv.nqmulticast.data, sv.nqmulticast.cursize);
}
else
SZ_Write (&client->datagram, sv.nqmulticast.data, sv.nqmulticast.cursize);
break;
#endif
#ifdef Q2SERVER
case SCP_QUAKE2:
if (reliable)
{
ClientReliableCheckBlock(client, sv.q2multicast.cursize);
ClientReliableWrite_SZ(client, sv.q2multicast.data, sv.q2multicast.cursize);
}
else
SZ_Write (&client->datagram, sv.q2multicast.data, sv.q2multicast.cursize);
break;
#endif
case SCP_QUAKEWORLD:
if (reliable)
{
ClientReliableCheckBlock(client, sv.multicast.cursize);
ClientReliableWrite_SZ(client, sv.multicast.data, sv.multicast.cursize);
}
else
SZ_Write (&client->datagram, sv.multicast.data, sv.multicast.cursize);
break;
}
}
}
if (sv.mvdrecording && ((demo.recorder.fteprotocolextensions & with) == with) && !(demo.recorder.fteprotocolextensions & without))
{
sizebuf_t *msg;
if (!mask)
{
/*no distinction between reliable or not*/
msg = MVDWrite_Begin(dem_single, pnum, sv.multicast.cursize);
}
else
{
if (reliable)
{
msg = MVDWrite_Begin(dem_all, 0, sv.multicast.cursize);
}
else
msg = &demo.datagram;
}
SZ_Write(msg, sv.multicast.data, sv.multicast.cursize);
}
#ifdef NQPROT
SZ_Clear (&sv.nqmulticast);
#endif
#ifdef Q2SERVER
SZ_Clear (&sv.q2multicast);
#endif
SZ_Clear (&sv.multicast);
}
//version does all the work now
void VARGS SV_Multicast (vec3_t origin, multicast_t to)
{
SV_MulticastProtExt(origin, to, FULLDIMENSIONMASK, 0, 0);
}
/*
==================
SV_StartSound
Each entity can have eight independant sound sources, like voice,
weapon, feet, etc.
Channel 0 is an auto-allocate channel, the others override anything
already running on that entity/channel pair.
An attenuation of 0 will play full volume everywhere in the level.
Larger attenuations will drop off. (max 4 attenuation)
==================
*/
void SV_StartSound (int ent, vec3_t origin, int seenmask, int channel, const char *sample, int volume, float attenuation, int pitchadj)
{
int sound_num;
int extfield_mask;
int qwflags;
int i;
qboolean use_phs;
qboolean reliable;
int requiredextensions = 0;
if (channel & 256)
{
channel &= ~256;
reliable = true;
}
else
reliable = false;
if (volume < 0 || volume > 255)
{
Con_Printf ("SV_StartSound: volume = %i", volume);
return;
}
if (attenuation < 0 || attenuation > 4)
{
Con_Printf ("SV_StartSound: attenuation = %f", attenuation);
return;
}
if (channel < 0 || channel > 255)
{
Con_Printf ("SV_StartSound: channel = %i", channel);
return;
}
// find precache number for sound
if (!*sample)
sound_num = 0;
else
{
for (sound_num=1 ; sound_num<MAX_SOUNDS
&& *sv.strings.sound_precache[sound_num] ; sound_num++)
if (!strcmp(sample, sv.strings.sound_precache[sound_num]))
break;
}
if ( sound_num == MAX_SOUNDS || !*sv.strings.sound_precache[sound_num] )
{
if (sound_num < MAX_SOUNDS)
{
Con_Printf("WARNING: SV_StartSound: sound %s not precached\n", sample);
//late precache it. use multicast to ensure that its sent NOW (and to all). normal reliables would mean it would arrive after the svc_sound
Q_strncpyz(sv.strings.sound_precache[sound_num], sample, sizeof(sv.strings.sound_precache[sound_num]));
Con_DPrintf("Delayed sound precache: %s\n", sample);
MSG_WriteByte(&sv.multicast, svcfte_precache);
MSG_WriteShort(&sv.multicast, sound_num+PC_SOUND);
MSG_WriteString(&sv.multicast, sample);
#ifdef NQPROT
MSG_WriteByte(&sv.nqmulticast, svcdp_precache);
MSG_WriteShort(&sv.nqmulticast, sound_num+PC_SOUND);
MSG_WriteString(&sv.nqmulticast, sample);
#endif
SV_MulticastProtExt(NULL, MULTICAST_ALL_R, FULLDIMENSIONMASK, PEXT_CSQC, 0);
reliable = true; //try to make sure it doesn't arrive before the precache!
}
else
{
Con_DPrintf ("SV_StartSound: %s not precached\n", sample);
return;
}
}
if (reliable || !sv_phs.value) // no PHS flag
use_phs = false;
else
use_phs = attenuation!=0;
// if (channel == CHAN_BODY || channel == CHAN_VOICE)
// reliable = true;
extfield_mask = 0;
if (volume != DEFAULT_SOUND_PACKET_VOLUME)
extfield_mask |= NQSND_VOLUME;
if (attenuation != DEFAULT_SOUND_PACKET_ATTENUATION)
extfield_mask |= NQSND_ATTENUATION;
if (ent >= 8192 || channel >= 8)
extfield_mask |= DPSND_LARGEENTITY;
if (sound_num > 0xff)
extfield_mask |= DPSND_LARGESOUND;
if (pitchadj && (pitchadj != 100))
extfield_mask |= FTESND_PITCHADJ;
#ifdef PEXT_SOUNDDBL
if (channel >= 8 || ent >= 2048 || sound_num > 0xff || pitchadj)
{
//if any of the above conditions evaluates to true, then we can't use standard qw protocols
MSG_WriteByte (&sv.multicast, svcfte_soundextended);
MSG_WriteByte (&sv.multicast, extfield_mask);
if (extfield_mask & NQSND_VOLUME)
MSG_WriteByte (&sv.multicast, volume);
if (extfield_mask & NQSND_ATTENUATION)
MSG_WriteByte (&sv.multicast, bound(0, attenuation*64, 255));
if (extfield_mask & FTESND_PITCHADJ)
MSG_WriteByte (&sv.multicast, pitchadj);
if (extfield_mask & DPSND_LARGEENTITY)
{
MSG_WriteEntity (&sv.multicast, ent);
MSG_WriteByte (&sv.multicast, channel);
}
else
MSG_WriteShort (&sv.multicast, (ent<<3) | channel);
if (extfield_mask & DPSND_LARGESOUND)
MSG_WriteShort (&sv.multicast, sound_num);
else
MSG_WriteByte (&sv.multicast, sound_num);
for (i=0 ; i<3 ; i++)
MSG_WriteCoord (&sv.multicast, origin[i]);
requiredextensions |= PEXT_SOUNDDBL;
if (ent > 512)
requiredextensions |= PEXT_ENTITYDBL;
if (ent > 1024)
requiredextensions |= PEXT_ENTITYDBL2;
}
else
#endif
{
qwflags = (ent<<3) | channel;
if (volume != DEFAULT_SOUND_PACKET_VOLUME)
qwflags |= SND_VOLUME;
if (attenuation != DEFAULT_SOUND_PACKET_ATTENUATION)
qwflags |= SND_ATTENUATION;
MSG_WriteByte (&sv.multicast, svc_sound);
MSG_WriteShort (&sv.multicast, qwflags);
if (qwflags & SND_VOLUME)
MSG_WriteByte (&sv.multicast, volume);
if (qwflags & SND_ATTENUATION)
MSG_WriteByte (&sv.multicast, bound(0, attenuation*64, 255));
MSG_WriteByte (&sv.multicast, sound_num);
for (i=0 ; i<3 ; i++)
MSG_WriteCoord (&sv.multicast, origin[i]);
if (ent > 512)
requiredextensions |= PEXT_ENTITYDBL;
if (ent > 1024)
requiredextensions |= PEXT_ENTITYDBL2;
}
#ifdef NQPROT
MSG_WriteByte (&sv.nqmulticast, svc_sound);
MSG_WriteByte (&sv.nqmulticast, extfield_mask);
if (extfield_mask & NQSND_VOLUME)
MSG_WriteByte (&sv.nqmulticast, volume);
if (extfield_mask & NQSND_ATTENUATION)
MSG_WriteByte (&sv.nqmulticast, bound(0, attenuation*64, 255));
if (extfield_mask & FTESND_PITCHADJ)
MSG_WriteByte (&sv.nqmulticast, pitchadj);
if (extfield_mask & DPSND_LARGEENTITY)
{
MSG_WriteEntity (&sv.nqmulticast, ent);
MSG_WriteByte (&sv.nqmulticast, channel);
}
else
MSG_WriteShort (&sv.nqmulticast, (ent<<3) | channel);
if (extfield_mask & DPSND_LARGESOUND)
MSG_WriteShort (&sv.nqmulticast, sound_num);
else
MSG_WriteByte (&sv.nqmulticast, sound_num);
for (i=0 ; i<3 ; i++)
MSG_WriteCoord (&sv.nqmulticast, origin[i]);
#endif
if (use_phs)
SV_MulticastProtExt(origin, reliable ? MULTICAST_PHS_R : MULTICAST_PHS, seenmask, requiredextensions, 0);
else
SV_MulticastProtExt(origin, reliable ? MULTICAST_ALL_R : MULTICAST_ALL, seenmask, requiredextensions, 0);
}
void SVQ1_StartSound (float *origin, wedict_t *wentity, int channel, const char *sample, int volume, float attenuation, int pitchadj)
{
edict_t *entity = (edict_t*)wentity;
int i;
vec3_t originbuf;
if (!origin)
{
origin = originbuf;
if (entity->v->solid == SOLID_BSP)
{
for (i=0 ; i<3 ; i++)
origin[i] = entity->v->origin[i]+0.5*(entity->v->mins[i]+entity->v->maxs[i]);
//add the reliable flag for bsp objects.
//these sounds are often looped, and if the start is in the phs and the end isn't/gets dropped, then you end up with an annoying infinitely looping sample.
//making them all reliable avoids packetloss and phs issues.
//this applies only to pushers. you won't get extra latency on player actions because of this.
//be warned that it does mean you might be able to hear people triggering stuff on the other side of the map however.
channel |= 256;
}
else
{
VectorCopy (entity->v->origin, origin);
}
}
SV_StartSound(NUM_FOR_EDICT(svprogfuncs, entity), origin, entity->xv->dimension_seen, channel, sample, volume, attenuation, pitchadj);
}
/*
===============================================================================
FRAME UPDATES
===============================================================================
*/
int sv_nailmodel, sv_supernailmodel, sv_playermodel;
void SV_FindModelNumbers (void)
{
int i;
sv_nailmodel = -1;
sv_supernailmodel = -1;
sv_playermodel = -1;
for (i=0 ; i<MAX_MODELS ; i++)
{
if (!sv.strings.model_precache[i])
break;
if (!strcmp(sv.strings.model_precache[i],"progs/spike.mdl") && sv.multicast.prim.coordsize == 2)
sv_nailmodel = i;
if (!strcmp(sv.strings.model_precache[i],"progs/s_spike.mdl") && sv.multicast.prim.coordsize == 2)
sv_supernailmodel = i;
if (!strcmp(sv.strings.model_precache[i],"progs/player.mdl"))
sv_playermodel = i;
}
}
void SV_WriteEntityDataToMessage (client_t *client, sizebuf_t *msg, int pnum)
{
edict_t *other;
edict_t *ent;
int i;
float newa;
ent = client->edict;
if (!ent)
return;
// send a damage message if the player got hit this frame
if (ent->v->dmg_take || ent->v->dmg_save)
{
other = PROG_TO_EDICT(svprogfuncs, ent->v->dmg_inflictor);
if (pnum)
{
MSG_WriteByte(msg, svcfte_choosesplitclient);
MSG_WriteByte(msg, pnum);
}
MSG_WriteByte (msg, svc_damage);
MSG_WriteByte (msg, min(255, ent->v->dmg_save));
MSG_WriteByte (msg, min(255, ent->v->dmg_take));
for (i=0 ; i<3 ; i++)
MSG_WriteCoord (msg, other->v->origin[i] + 0.5*(other->v->mins[i] + other->v->maxs[i]));
ent->v->dmg_take = 0;
ent->v->dmg_save = 0;
}
// a fixangle might get lost in a dropped packet. Oh well.
if (ent->v->fixangle)
{
if (pnum)
{
MSG_WriteByte(msg, svcfte_choosesplitclient);
MSG_WriteByte(msg, pnum);
}
if (!client->lockangles && (client->fteprotocolextensions2 & PEXT2_SETANGLEDELTA) && client->delta_sequence != -1 && !client->viewent)
{
MSG_WriteByte (msg, svcfte_setangledelta);
for (i=0 ; i < 3 ; i++)
{
newa = ent->v->angles[i] - SHORT2ANGLE(client->lastcmd.angles[i]);
MSG_WriteAngle16 (msg, newa);
client->lastcmd.angles[i] = ANGLE2SHORT(ent->v->angles[i]);
}
}
else
{
MSG_WriteByte (msg, svc_setangle);
for (i=0 ; i < 3 ; i++)
MSG_WriteAngle (msg, ent->v->angles[i]);
}
ent->v->fixangle = 0;
client->lockangles = true;
}
else
client->lockangles = false;
}
/*sends the a centerprint string directly to the client*/
void SV_WriteCenterPrint(client_t *cl, char *s)
{
if (cl->controller)
{ //this is a slave client.
//find the right number and send.
int pnum = 0;
client_t *sp;
for (sp = cl->controller; sp; sp = sp->controlled)
{
if (sp == cl)
break;
pnum++;
}
cl = cl->controller;
ClientReliableWrite_Begin (cl, svcfte_choosesplitclient, 4 + strlen(s));
ClientReliableWrite_Byte (cl, pnum);
ClientReliableWrite_Byte (cl, svc_centerprint);
}
else
{
ClientReliableWrite_Begin (cl, svc_centerprint, 2 + strlen(s));
}
ClientReliableWrite_String (cl, s);
if (sv.mvdrecording)
{
sizebuf_t *msg = MVDWrite_Begin (dem_single, cl - svs.clients, 2 + strlen(s));
MSG_WriteByte (msg, svc_centerprint);
MSG_WriteString (msg, s);
}
}
/*
==================
SV_WriteClientdataToMessage
==================
*/
void SV_WriteClientdataToMessage (client_t *client, sizebuf_t *msg)
{
#ifdef NQPROT
int i;
int bits, items;
edict_t *ent;
#endif
client_t *split;
int pnum=0;
int weaponmodelindex = 0;
qboolean nqjunk = true;
// send the chokecount for r_netgraph
if (ISQWCLIENT(client))
if (client->chokecount)
{
MSG_WriteByte (msg, svc_chokecount);
MSG_WriteByte (msg, client->chokecount);
client->chokecount = 0;
}
for (split = client; split; split=split->controlled, pnum++)
{
SV_WriteEntityDataToMessage(split, msg, pnum);
if (split->centerprintstring && ! client->num_backbuf)
{
SV_WriteCenterPrint(split, split->centerprintstring);
Z_Free(split->centerprintstring);
split->centerprintstring = NULL;
}
}
/*
MSG_WriteByte (msg, svc_time);
MSG_WriteFloat(msg, sv.physicstime);
client->nextservertimeupdate = sv.physicstime;
*/
ent = client->edict;
#ifdef NQPROT
if (progstype != PROG_QW)
{
if (ISQWCLIENT(client))
{
//quakeworld clients drop the punch angle themselves.
while (ent->xv->punchangle[0] < -3)
{
ent->xv->punchangle[0] += 4;
MSG_WriteByte (msg, svc_bigkick);
}
while (ent->xv->punchangle[0] < -1)
{
ent->xv->punchangle[0] += 2;
MSG_WriteByte (msg, svc_smallkick);
}
ent->xv->punchangle[1] = 0;
ent->xv->punchangle[2] = 0;
}
else
{
for (i = 0; i < 3; i++)
{
//nq clients require the server to do it (interpolating, if its a decent client).
if (ent->xv->punchangle[i] < 0)
{
ent->xv->punchangle[i] += 10 * (1/77.0);
if (ent->xv->punchangle[i] > 0)
ent->xv->punchangle[i] = 0;
}
if (ent->xv->punchangle[i] < 0)
{
ent->xv->punchangle[i] -= 10 * (1/77.0);
if (ent->xv->punchangle[i] < 0)
ent->xv->punchangle[i] = 0;
}
}
}
}
if (ISQWCLIENT(client))
return;
if (!(client->fteprotocolextensions2 & PEXT2_REPLACEMENTDELTAS))
{
MSG_WriteByte (msg, svc_time);
MSG_WriteFloat(msg, sv.world.physicstime);
if (client->fteprotocolextensions2 & PEXT2_PREDINFO)
MSG_WriteLong(msg, client->last_sequence);
// Con_Printf("%f\n", sv.world.physicstime);
}
//predinfo extension reworks stats, making svc_clientdata redundant.
if (client->fteprotocolextensions2 & PEXT2_PREDINFO)
return;
bits = 0;
if (ent->v->view_ofs[2] != DEFAULT_VIEWHEIGHT)
bits |= SU_VIEWHEIGHT;
// if (ent->v->idealpitch)
// bits |= SU_IDEALPITCH;
// stuff the sigil bits into the high bits of items for sbar, or else
// mix in items2
// val = GetEdictFieldValue(ent, "items2", &items2cache);
// if (val)
// items = (int)ent->v->items | ((int)val->_float << 23);
// else
items = (int)ent->v->items | ((int)pr_global_struct->serverflags << 28);
bits |= SU_ITEMS;
if ( (int)ent->v->flags & FL_ONGROUND)
bits |= SU_ONGROUND;
if ( ent->v->waterlevel >= 2)
bits |= SU_INWATER;
for (i=0 ; i<3 ; i++)
{
if (ent->xv->punchangle[i])
bits |= (SU_PUNCH1<<i);
if (ent->v->velocity[i])
bits |= (SU_VELOCITY1<<i);
}
if (client->protocol == SCP_DARKPLACES6 || client->protocol == SCP_DARKPLACES7)
{
//bits &= ~SU_ITEMS;
nqjunk = false;
}
else
{
nqjunk = true;
if (ent->v->weaponframe)
bits |= SU_WEAPONFRAME;
if (ent->v->armorvalue)
bits |= SU_ARMOR;
weaponmodelindex = SV_ModelIndex(ent->v->weaponmodel + svprogfuncs->stringtable);
if (weaponmodelindex)
bits |= SU_WEAPONMODEL;
if (client->protocol == SCP_FITZ666)
{
if (weaponmodelindex & 0xff00)
bits |= FITZSU_WEAPONMODEL2;
if ((int)ent->v->armorvalue & 0xff00)
bits |= FITZSU_ARMOR2;
if ((int)ent->v->currentammo & 0xff00)
bits |= FITZSU_AMMO2;
if ((int)ent->v->ammo_shells & 0xff00)
bits |= FITZSU_SHELLS2;
if ((int)ent->v->ammo_nails & 0xff00)
bits |= FITZSU_NAILS2;
if ((int)ent->v->ammo_rockets & 0xff00)
bits |= FITZSU_ROCKETS2;
if ((int)ent->v->ammo_cells & 0xff00)
bits |= FITZSU_CELLS2;
if ((int)ent->v->weaponframe & 0xff00)
bits |= FITZSU_WEAPONFRAME2;
if (ent->xv->alpha && ent->xv->alpha < 1)
bits |= FITZSU_WEAPONALPHA;
}
}
if (bits >= (1u<<16))
bits |= SU_EXTEND1;
if (bits >= (1u<<24))
bits |= SU_EXTEND2;
if (bits >= (1ull<<32))
bits |= SU_EXTEND3;
// send the data
MSG_WriteByte (msg, svcnq_clientdata);
MSG_WriteShort (msg, bits);
if (bits & SU_EXTEND1)
MSG_WriteByte(msg, bits>>16);
if (bits & SU_EXTEND2)
MSG_WriteByte(msg, bits>>24);
if (bits & SU_VIEWHEIGHT)
MSG_WriteChar (msg, ent->v->view_ofs[2]);
// if (bits & SU_IDEALPITCH)
// MSG_WriteChar (msg, ent->v->idealpitch);
for (i=0 ; i<3 ; i++)
{
if (bits & (SU_PUNCH1<<i))
{
if (client->protocol == SCP_DARKPLACES6 || client->protocol == SCP_DARKPLACES7)
MSG_WriteAngle16 (msg, ent->xv->punchangle[i]);
else
MSG_WriteChar (msg, ent->xv->punchangle[i]);
}
if (bits & (SU_VELOCITY1<<i))
{
if (client->protocol == SCP_DARKPLACES6 || client->protocol == SCP_DARKPLACES7)
MSG_WriteCoord(msg, ent->v->velocity[i]);
else
MSG_WriteChar (msg, ent->v->velocity[i]/16);
}
}
if (bits & SU_ITEMS)
MSG_WriteLong (msg, items);
if (bits & SU_WEAPONFRAME)
MSG_WriteByte (msg, ent->v->weaponframe);
if (bits & SU_ARMOR)
{
if (ent->v->armorvalue>255 && !(bits & FITZSU_ARMOR2))
MSG_WriteByte (msg, 255);
else
MSG_WriteByte (msg, ent->v->armorvalue);
}
if (bits & SU_WEAPONMODEL)
MSG_WriteByte (msg, weaponmodelindex);
if (nqjunk)
{
MSG_WriteShort (msg, ent->v->health);
MSG_WriteByte (msg, ent->v->currentammo);
MSG_WriteByte (msg, ent->v->ammo_shells);
MSG_WriteByte (msg, ent->v->ammo_nails);
MSG_WriteByte (msg, ent->v->ammo_rockets);
MSG_WriteByte (msg, ent->v->ammo_cells);
if (standard_quake)
{
MSG_WriteByte (msg, ent->v->weapon);
}
else
{
for(i=0;i<32;i++)
{
if ( ((int)ent->v->weapon) & (1<<i) )
{
MSG_WriteByte (msg, i);
break;
}
}
}
}
if (bits & FITZSU_WEAPONMODEL2) MSG_WriteByte (msg, weaponmodelindex >> 8);
if (bits & FITZSU_ARMOR2) MSG_WriteByte (msg, (int)ent->v->armorvalue >> 8);
if (bits & FITZSU_AMMO2) MSG_WriteByte (msg, (int)ent->v->currentammo >> 8);
if (bits & FITZSU_SHELLS2) MSG_WriteByte (msg, (int)ent->v->ammo_shells >> 8);
if (bits & FITZSU_NAILS2) MSG_WriteByte (msg, (int)ent->v->ammo_nails >> 8);
if (bits & FITZSU_ROCKETS2) MSG_WriteByte (msg, (int)ent->v->ammo_rockets >> 8);
if (bits & FITZSU_CELLS2) MSG_WriteByte (msg, (int)ent->v->ammo_cells >> 8);
if (bits & FITZSU_WEAPONFRAME2) MSG_WriteByte (msg, (int)ent->v->weaponframe >> 8);
if (bits & FITZSU_WEAPONALPHA) MSG_WriteByte (msg, ent->xv->alpha*255);
// }
#endif
}
typedef struct {
int type; //negative means a global.
char name[64];
union {
evalc_t c;
eval_t *g; //just store a pointer to it.
} eval;
int statnum;
} qcstat_t;
qcstat_t qcstats[MAX_CL_STATS-32];
int numqcstats;
void SV_QCStatEval(int type, char *name, evalc_t *field, eval_t *global, int statnum)
{
int i;
if (numqcstats == sizeof(qcstats)/sizeof(qcstats[0]))
{
Con_Printf("Too many stat types\n");
return;
}
for (i = 0; i < numqcstats; i++)
{
if (qcstats[i].statnum == statnum)
break;
}
if (i == numqcstats)
{
if (i == sizeof(qcstats)/sizeof(qcstats[0]))
{
Con_Printf("Too many stats specified for csqc\n");
return;
}
numqcstats++;
}
qcstats[i].type = type;
qcstats[i].statnum = statnum;
Q_strncpyz(qcstats[i].name, name, sizeof(qcstats[i].name));
if (type < 0)
qcstats[i].eval.g = global;
else
memcpy(&qcstats[i].eval.c, field, sizeof(evalc_t));
}
void SV_QCStatGlobal(int type, char *globalname, int statnum)
{
eval_t *glob;
if (type < 0)
return;
glob = svprogfuncs->FindGlobal(svprogfuncs, globalname, PR_ANY, NULL);
if (!glob)
{
Con_Printf("couldn't find named global for csqc stat (%s)\n", globalname);
return;
}
SV_QCStatEval(-type, globalname, NULL, glob, statnum);
}
void SV_QCStatPtr(int type, void *ptr, int statnum)
{
SV_QCStatEval(-type, "", NULL, ptr, statnum);
}
void SV_QCStatName(int type, char *name, int statnum)
{
evalc_t cache;
if (type < 0)
return;
memset(&cache, 0, sizeof(cache));
if (!svprogfuncs->GetEdictFieldValue(svprogfuncs, NULL, name, &cache))
return;
SV_QCStatEval(type, name, &cache, NULL, statnum);
}
void SV_QCStatFieldIdx(int type, unsigned int fieldindex, int statnum)
{
evalc_t cache;
char *name;
etype_t ftype;
if (type < 0)
return;
if (!svprogfuncs->QueryField(svprogfuncs, fieldindex, &ftype, &name, &cache))
{
Con_Printf("invalid field for csqc stat\n");
return;
}
SV_QCStatEval(type, name, &cache, NULL, statnum);
}
void SV_ClearQCStats(void)
{
numqcstats = 0;
}
extern cvar_t dpcompat_stats;
void SV_UpdateQCStats(edict_t *ent, int *statsi, const char **statss, float *statsf)
{
const char *s;
int i;
int t;
for (i = 0; i < numqcstats; i++)
{
eval_t *eval;
t = qcstats[i].type;
if (t < 0)
{
t = -t;
eval = qcstats[i].eval.g;
}
else
{
eval = svprogfuncs->GetEdictFieldValue(svprogfuncs, ent, qcstats[i].name, &qcstats[i].eval.c);
}
if (!eval)
continue;
switch(t)
{
case ev_float:
statsf[qcstats[i].statnum] = eval->_float;
break;
case ev_vector:
statsf[qcstats[i].statnum+0] = eval->_vector[0];
statsf[qcstats[i].statnum+1] = eval->_vector[1];
statsf[qcstats[i].statnum+2] = eval->_vector[2];
break;
case ev_integer:
statsi[qcstats[i].statnum] = eval->_int;
break;
case ev_entity:
statsi[qcstats[i].statnum] = NUM_FOR_EDICT(svprogfuncs, PROG_TO_EDICT(svprogfuncs, eval->edict));
break;
case ev_string:
s = PR_GetString(svprogfuncs, eval->string);
statss[qcstats[i].statnum] = s;
// statsi[qcstats[i].statnum+0] = LittleLong(((int*)s)[0]); //so the network is sent out correctly as a string.
// statsi[qcstats[i].statnum+1] = LittleLong(((int*)s)[1]);
// statsi[qcstats[i].statnum+2] = LittleLong(((int*)s)[2]);
// statsi[qcstats[i].statnum+3] = LittleLong(((int*)s)[3]);
break;
}
}
}
/*this function calculates the current stat values for the given client*/
void SV_CalcClientStats(client_t *client, int statsi[MAX_CL_STATS], float statsf[MAX_CL_STATS], char *statss[MAX_CL_STATS])
{
edict_t *ent;
ent = client->edict;
memset (statsi, 0, sizeof(int)*MAX_CL_STATS);
memset (statsf, 0, sizeof(float)*MAX_CL_STATS);
memset (statss, 0, sizeof(char*)*MAX_CL_STATS);
// if we are a spectator and we are tracking a player, we get his stats
// so our status bar reflects his
if (client->spectator && client->spec_track > 0)
ent = EDICT_NUM(svprogfuncs, client->spec_track);
#ifdef HLSERVER
if (svs.gametype == GT_HALFLIFE)
{
SVHL_BuildStats(client, statsi, statsf, statss);
}
else
#endif
{
statsf[STAT_HEALTH] = ent->v->health; //sorry, but mneh
statsi[STAT_WEAPON] = SV_ModelIndex(PR_GetString(svprogfuncs, ent->v->weaponmodel));
if (client->fteprotocolextensions & PEXT_MODELDBL)
{
if ((unsigned)statsi[STAT_WEAPON] >= MAX_MODELS)
statsi[STAT_WEAPON] = 0;
}
else
{
if ((unsigned)statsi[STAT_WEAPON] >= 256)
statsi[STAT_WEAPON] = 0;
}
statsf[STAT_AMMO] = ent->v->currentammo;
statsf[STAT_ARMOR] = ent->v->armorvalue;
statsf[STAT_SHELLS] = ent->v->ammo_shells;
statsf[STAT_NAILS] = ent->v->ammo_nails;
statsf[STAT_ROCKETS] = ent->v->ammo_rockets;
statsf[STAT_CELLS] = ent->v->ammo_cells;
if (!client->spectator)
{
statsf[STAT_ACTIVEWEAPON] = ent->v->weapon;
if ((client->csqcactive && !(client->fteprotocolextensions2 & PEXT2_REPLACEMENTDELTAS)) || client->protocol != SCP_QUAKEWORLD)
statsf[STAT_WEAPONFRAME] = ent->v->weaponframe;
}
// stuff the sigil bits into the high bits of items for sbar
if (sv.haveitems2)
statsi[STAT_ITEMS] = (int)ent->v->items | ((int)ent->xv->items2 << 23);
else
statsi[STAT_ITEMS] = (int)ent->v->items | ((int)pr_global_struct->serverflags << 28);
statsf[STAT_VIEWHEIGHT] = ent->v->view_ofs[2];
#ifdef PEXT_VIEW2
if (ent->xv->view2)
statsi[STAT_VIEW2] = NUM_FOR_EDICT(svprogfuncs, PROG_TO_EDICT(svprogfuncs, ent->xv->view2));
else
statsi[STAT_VIEW2] = 0;
#endif
if (!ent->xv->viewzoom)
statsi[STAT_VIEWZOOM] = 255;
else
statsi[STAT_VIEWZOOM] = ent->xv->viewzoom*255;
if (client->protocol == SCP_DARKPLACES7 || (client->fteprotocolextensions2 & PEXT2_PREDINFO))
{
float *statsfi;
if (client->fteprotocolextensions2 & PEXT2_PREDINFO)
statsfi = statsf;
else
statsfi = (float*)statsi; /*dp requires a union of ints and floats, which is rather hideous...*/
// statsfi[STAT_MOVEVARS_WALLFRICTION] = sv_wall
statsfi[STAT_MOVEVARS_FRICTION] = sv_friction.value;
statsfi[STAT_MOVEVARS_WATERFRICTION] = sv_waterfriction.value;
statsfi[STAT_MOVEVARS_TICRATE] = 72;
statsfi[STAT_MOVEVARS_TIMESCALE] = sv_gamespeed.value;
statsfi[STAT_MOVEVARS_GRAVITY] = sv_gravity.value;
statsfi[STAT_MOVEVARS_STOPSPEED] = sv_stopspeed.value;
statsfi[STAT_MOVEVARS_MAXSPEED] = host_client->maxspeed;
statsfi[STAT_MOVEVARS_SPECTATORMAXSPEED] = sv_spectatormaxspeed.value;
statsfi[STAT_MOVEVARS_ACCELERATE] = sv_accelerate.value;
statsfi[STAT_MOVEVARS_AIRACCELERATE] = sv_airaccelerate.value;
statsfi[STAT_MOVEVARS_WATERACCELERATE] = sv_wateraccelerate.value;
statsfi[STAT_MOVEVARS_ENTGRAVITY] = host_client->entgravity/sv_gravity.value;
statsfi[STAT_MOVEVARS_JUMPVELOCITY] = 270;//sv_jumpvelocity.value; //bah
statsfi[STAT_MOVEVARS_EDGEFRICTION] = sv_edgefriction.value;
statsfi[STAT_MOVEVARS_MAXAIRSPEED] = host_client->maxspeed;
statsfi[STAT_MOVEVARS_STEPHEIGHT] = 18;
statsfi[STAT_MOVEVARS_AIRACCEL_QW] = 1;
statsfi[STAT_MOVEVARS_AIRACCEL_SIDEWAYS_FRICTION] = sv_gravity.value;
}
SV_UpdateQCStats(ent, statsi, statss, statsf);
}
}
/*
=======================
SV_UpdateClientStats
Performs a delta update of the stats array. This should only be performed
when a reliable message can be delivered this frame.
=======================
*/
void SV_UpdateClientStats (client_t *client, int pnum)
{
int statsi[MAX_CL_STATS];
float statsf[MAX_CL_STATS];
char *statss[MAX_CL_STATS];
int i, m;
/*figure out what the stat values should be*/
SV_CalcClientStats(client, statsi, statsf, statss);
m = MAX_QW_STATS;
if (client->fteprotocolextensions & (PEXT_HEXEN2|PEXT_CSQC))
m = MAX_CL_STATS;
for (i=0 ; i<m ; i++)
{
#ifdef SERVER_DEMO_PLAYBACK
if (sv.demofile)
{
if (!client->spec_track)
{
statsf[i] = 0;
if (i == STAT_HEALTH)
statsf[i] = 100;
}
else
{
statsf[i] = sv.recordedplayer[client->spec_track - 1].stats[i];
statsi[i] = sv.recordedplayer[client->spec_track - 1].stats[i];
}
}
#endif
if (!ISQWCLIENT(client))
{
if (!statsi[i])
statsi[i] = statsf[i];
if (statsi[i] != client->statsi[i])
{
client->statsi[i] = statsi[i];
ClientReliableWrite_Begin(client, svcnq_updatestatlong, 6);
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_Long(client, statsi[i]);
}
}
else
{
#ifdef PEXT_CSQC
if (client->fteprotocolextensions & PEXT_CSQC)
{
if (statss[i] || client->statss[i])
if (strcmp(statss[i]?statss[i]:"", client->statss[i]?client->statss[i]:""))
{
client->statss[i] = statss[i];
if (pnum)
{
ClientReliableWrite_Begin(client->controller, svcfte_choosesplitclient, 5+strlen(statss[i]));
ClientReliableWrite_Byte(client->controller, pnum);
ClientReliableWrite_Byte(client->controller, svcfte_updatestatstring);
ClientReliableWrite_Byte(client->controller, i);
ClientReliableWrite_String(client->controller, statss[i]);
}
else
{
ClientReliableWrite_Begin(client, svcfte_updatestatstring, 3+strlen(statss[i]));
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_String(client, statss[i]);
}
}
}
if (dpcompat_stats.ival)
{
if (statsf[i])
{
statsi[i] = statsf[i];
statsf[i] = 0;
}
}
#endif
if (statsf[i])
{
if (client->fteprotocolextensions & PEXT_CSQC)
{
if (statsf[i] != client->statsf[i])
{
if (statsf[i] - (float)(int)statsf[i] == 0 && statsf[i] >= 0 && statsf[i] <= 255)
{
if (pnum)
{
ClientReliableWrite_Begin(client->controller, svcfte_choosesplitclient, 5);
ClientReliableWrite_Byte(client->controller, pnum);
ClientReliableWrite_Byte(client->controller, svcqw_updatestatbyte);
ClientReliableWrite_Byte(client->controller, i);
ClientReliableWrite_Byte(client->controller, statsf[i]);
}
else
{
ClientReliableWrite_Begin(client, svcqw_updatestatbyte, 3);
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_Byte(client, statsf[i]);
}
}
else
{
if (pnum)
{
ClientReliableWrite_Begin(client->controller, svcfte_choosesplitclient, 8);
ClientReliableWrite_Byte(client->controller, pnum);
ClientReliableWrite_Byte(client->controller, svcfte_updatestatfloat);
ClientReliableWrite_Byte(client->controller, i);
ClientReliableWrite_Float(client->controller, statsf[i]);
}
else
{
ClientReliableWrite_Begin(client, svcfte_updatestatfloat, 6);
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_Float(client, statsf[i]);
}
}
client->statsf[i] = statsf[i];
/*make sure statsf is correct*/
client->statsi[i] = statsf[i];
}
continue;
}
else
{
statsi[i] = statsf[i];
}
}
if (statsi[i] != client->statsi[i])
{
client->statsi[i] = statsi[i];
client->statsf[i] = statsi[i];
if (statsi[i] >=0 && statsi[i] <= 255)
{
if (pnum)
{
ClientReliableWrite_Begin(client->controller, svcfte_choosesplitclient, 5);
ClientReliableWrite_Byte(client->controller, pnum);
ClientReliableWrite_Byte(client->controller, svcqw_updatestatbyte);
ClientReliableWrite_Byte(client->controller, i);
ClientReliableWrite_Byte(client->controller, statsi[i]);
}
else
{
ClientReliableWrite_Begin(client, svcqw_updatestatbyte, 3);
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_Byte(client, statsi[i]);
}
}
else
{
if (pnum)
{
ClientReliableWrite_Begin(client->controller, svcfte_choosesplitclient, 8);
ClientReliableWrite_Byte(client->controller, pnum);
ClientReliableWrite_Byte(client->controller, svcqw_updatestatlong);
ClientReliableWrite_Byte(client->controller, i);
ClientReliableWrite_Long(client->controller, statsi[i]);
}
else
{
ClientReliableWrite_Begin(client, svcqw_updatestatlong, 6);
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_Long(client, statsi[i]);
}
}
}
}
}
}
qboolean SV_CanTrack(client_t *client, int entity)
{
if (entity < 0 || entity > sv.allocated_client_slots || svs.clients[entity-1].state != cs_spawned || svs.clients[entity-1].spectator)
return false;
return true;
}
/*
=======================
SV_SendClientDatagram
=======================
*/
qboolean SV_SendClientDatagram (client_t *client)
{
qbyte buf[MAX_OVERALLMSGLEN];
sizebuf_t msg;
unsigned int sentbytes, fnum;
msg.data = buf;
msg.maxsize = sizeof(buf);
msg.cursize = 0;
msg.allowoverflow = true;
msg.overflowed = false;
msg.prim = client->datagram.prim;
if (client->spec_track && !SV_CanTrack(client, client->spec_track))
{
client->spec_track = 0;
client->edict->v->goalentity = 0;
}
if (client->protocol != SCP_FITZ666 && !client->netchan.fragmentsize)
msg.maxsize = MAX_DATAGRAM;
if (sv.world.worldmodel && !client->controller)
{
#ifdef Q2SERVER
if (ISQ2CLIENT(client))
{
SVQ2_BuildClientFrame (client);
// send over all the relevant entity_state_t
// and the player_state_t
SVQ2_WriteFrameToClient (client, &msg);
}
else
#endif
{
// add the client specific data to the datagram
SV_WriteClientdataToMessage (client, &msg);
// send over all the objects that are in the PVS
// this will include clients, a packetentities, and
// possibly a nails update
SV_WriteEntitiesToClient (client, &msg, false);
}
#ifdef VOICECHAT
SV_VoiceSendPacket(client, &msg);
#endif
}
// copy the accumulated multicast datagram
// for this client out to the message
if (client->datagram.overflowed || msg.cursize + client->datagram.cursize > msg.maxsize)
Con_Printf ("WARNING: datagram overflowed for %s\n", client->name);
else
SZ_Write (&msg, client->datagram.data, client->datagram.cursize);
SZ_Clear (&client->datagram);
// send deltas over reliable stream
if (sv.world.worldmodel)
if (!ISQ2CLIENT(client) && Netchan_CanReliable (&client->netchan, SV_RateForClient(client)))
{
int pnum=1;
client_t *c;
SV_UpdateClientStats (client, 0);
for (c = client->controlled; c; c = c->controlled,pnum++)
SV_UpdateClientStats(c, pnum);
}
if (msg.overflowed)
{
Con_Printf ("WARNING: msg overflowed for %s\n", client->name);
SZ_Clear (&msg);
}
SV_DarkPlacesDownloadChunk(client, &msg);
// send the datagram
fnum = client->netchan.outgoing_sequence;
sentbytes = Netchan_Transmit (&client->netchan, msg.cursize, buf, SV_RateForClient(client));
if (ISQWCLIENT(client) || ISNQCLIENT(client))
client->frameunion.frames[fnum & UPDATE_MASK].packetsizeout += sentbytes;
return true;
}
client_t *SV_SplitClientDest(client_t *client, qbyte first, int size)
{
client_t *sp;
if (client->controller)
{ //this is a slave client.
//find the right number and send.
int pnum = 0;
for (sp = client->controller; sp; sp = sp->controlled)
{
if (sp == client)
break;
pnum++;
}
sp = client->controller;
ClientReliableWrite_Begin (sp, svcfte_choosesplitclient, size+2);
ClientReliableWrite_Byte (sp, pnum);
ClientReliableWrite_Byte (sp, first);
return sp;
}
else
{
ClientReliableWrite_Begin (client, first, size);
return client;
}
}
void SV_FlushBroadcasts (void)
{
client_t *client;
int j;
// append the broadcast messages to each client messages
for (j=0, client = svs.clients ; j<svs.allocated_client_slots ; j++, client++)
{
if (client->state < cs_connected)
continue; // reliables go to all connected or spawned
if (client->controller)
continue; //splitscreen
if (client->protocol == SCP_BAD)
continue; //botclient
#ifdef Q2SERVER
if (ISQ2CLIENT(client))
{
ClientReliableCheckBlock(client, sv.q2reliable_datagram.cursize);
ClientReliableWrite_SZ(client, sv.q2reliable_datagram.data, sv.q2reliable_datagram.cursize);
if (client->state != cs_spawned)
continue; // datagrams only go to spawned
SZ_Write (&client->datagram
, sv.q2datagram.data
, sv.q2datagram.cursize);
}
else
#endif
#ifdef NQPROT
if (!ISQWCLIENT(client))
{
if (client->pextknown)
{
ClientReliableCheckBlock(client, sv.nqreliable_datagram.cursize);
ClientReliableWrite_SZ(client, sv.nqreliable_datagram.data, sv.nqreliable_datagram.cursize);
}
if (client->state != cs_spawned)
continue; // datagrams only go to spawned
SZ_Write (&client->datagram
, sv.nqdatagram.data
, sv.nqdatagram.cursize);
}
else
#endif
{
ClientReliableCheckBlock(client, sv.reliable_datagram.cursize);
ClientReliableWrite_SZ(client, sv.reliable_datagram.data, sv.reliable_datagram.cursize);
if (client->state != cs_spawned)
continue; // datagrams only go to spawned
SZ_Write (&client->datagram
, sv.datagram.data
, sv.datagram.cursize);
}
}
SV_MVD_WriteReliables();
SZ_Clear (&sv.reliable_datagram);
SZ_Clear (&sv.datagram);
#ifdef NQPROT
SZ_Clear (&sv.nqreliable_datagram);
SZ_Clear (&sv.nqdatagram);
#endif
SZ_Clear (&sv.q2reliable_datagram);
SZ_Clear (&sv.q2datagram);
}
/*
=======================
SV_UpdateToReliableMessages
=======================
*/
void SV_UpdateToReliableMessages (void)
{
int i, j;
client_t *client, *sp;
edict_t *ent;
const char *name;
float curgrav;
float curspeed;
int curfrags;
// check for changes to be sent over the reliable streams to all clients
for (i=0, host_client = svs.clients ; i<svs.allocated_client_slots ; i++, host_client++)
{
if ((svs.gametype == GT_Q1QVM || svs.gametype == GT_PROGS) && host_client->state == cs_spawned)
{
//DP_SV_CLIENTCOLORS
if (host_client->edict->xv->clientcolors != host_client->playercolor)
{
Info_SetValueForKey(host_client->userinfo, "topcolor", va("%i", (int)host_client->edict->xv->clientcolors/16), sizeof(host_client->userinfo));
Info_SetValueForKey(host_client->userinfo, "bottomcolor", va("%i", (int)host_client->edict->xv->clientcolors&15), sizeof(host_client->userinfo));
{
SV_ExtractFromUserinfo (host_client, true); //this will take care of nq for us anyway.
MSG_WriteByte (&sv.reliable_datagram, svc_setinfo);
MSG_WriteByte (&sv.reliable_datagram, i);
MSG_WriteString (&sv.reliable_datagram, "topcolor");
MSG_WriteString (&sv.reliable_datagram, Info_ValueForKey(host_client->userinfo, "topcolor"));
MSG_WriteByte (&sv.reliable_datagram, svc_setinfo);
MSG_WriteByte (&sv.reliable_datagram, i);
MSG_WriteString (&sv.reliable_datagram, "bottomcolor");
MSG_WriteString (&sv.reliable_datagram, Info_ValueForKey(host_client->userinfo, "bottomcolor"));
}
}
name = PR_GetString(svprogfuncs, host_client->edict->v->netname);
if (name != host_client->name)
{
if (strcmp(host_client->name, name))
{
char oname[80];
Q_strncpyz(oname, host_client->name, sizeof(oname));
Con_DPrintf("Client %s programatically renamed to %s\n", host_client->name, name);
Info_SetValueForKey(host_client->userinfo, "name", name, sizeof(host_client->userinfo));
SV_ExtractFromUserinfo (host_client, true);
if (strcmp(oname, host_client->name))
{
MSG_WriteByte (&sv.reliable_datagram, svc_setinfo);
MSG_WriteByte (&sv.reliable_datagram, i);
MSG_WriteString (&sv.reliable_datagram, "name");
MSG_WriteString (&sv.reliable_datagram, host_client->name);
}
}
host_client->edict->v->netname = PR_SetString(svprogfuncs, host_client->name);
}
}
if (host_client->state != cs_spawned)
{
if (!host_client->state && host_client->name && host_client->name[0]) //if this is a writebyte bot
{
if (host_client->old_frags != (int)host_client->edict->v->frags)
{
for (j=0, client = svs.clients ; j<svs.allocated_client_slots ; j++, client++)
{
if (client->state < cs_connected)
continue;
ClientReliableWrite_Begin(client, svc_updatefrags, 4);
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_Short(client, host_client->edict->v->frags);
}
if (sv.mvdrecording)
{
sizebuf_t *msg = MVDWrite_Begin(dem_all, 0, 4);
MSG_WriteByte(msg, svc_updatefrags);
MSG_WriteByte(msg, i);
MSG_WriteShort(msg, host_client->edict->v->frags);
}
host_client->old_frags = host_client->edict->v->frags;
}
}
continue;
}
if (svs.gametype == GT_PROGS || svs.gametype == GT_Q1QVM)
{
ent = host_client->edict;
curfrags = host_client->edict->v->frags;
curgrav = ent->xv->gravity*sv_gravity.value;
curspeed = ent->xv->maxspeed;
if (progstype != PROG_QW)
{
if (!curgrav)
curgrav = sv_gravity.value;
if (!curspeed)
curspeed = sv_maxspeed.value;
}
if (ent->xv->hasted)
curspeed*=ent->xv->hasted;
}
else
{
curgrav = sv_gravity.value;
curspeed = sv_maxspeed.value;
curfrags = 0;
}
#ifdef SVCHAT //enforce a no moving time when chatting. Prevent client prediction going mad.
if (host_client->chat.active)
curspeed = 0;
#endif
if (!ISQ2CLIENT(host_client))
{
if (host_client->sendinfo)
{
host_client->sendinfo = false;
SV_FullClientUpdate (host_client, NULL);
}
if (host_client->old_frags != curfrags)
{
for (j=0, client = svs.clients ; j<sv.allocated_client_slots ; j++, client++)
{
if (client->state < cs_connected)
continue;
if (client->controller)
continue;
ClientReliableWrite_Begin(client, svc_updatefrags, 4);
ClientReliableWrite_Byte(client, i);
ClientReliableWrite_Short(client, curfrags);
}
if (sv.mvdrecording)
{
sizebuf_t *msg = MVDWrite_Begin(dem_all, 0, 4);
MSG_WriteByte(msg, svc_updatefrags);
MSG_WriteByte(msg, i);
MSG_WriteShort(msg, curfrags);
}
host_client->old_frags = curfrags;
}
{
if (host_client->entgravity != curgrav)
{
if (ISQWCLIENT(host_client))
{
sp = SV_SplitClientDest(host_client, svc_entgravity, 5);
ClientReliableWrite_Float(sp, curgrav/movevars.gravity); //lie to the client in a cunning way
}
host_client->entgravity = curgrav;
}
if (host_client->maxspeed != curspeed)
{ //MSVC can really suck at times (optimiser bug)
if (ISQWCLIENT(host_client))
{
if (host_client->controller)
{ //this is a slave client.
//find the right number and send.
int pnum = 0;
client_t *sp;
for (sp = host_client->controller; sp; sp = sp->controlled)
{
if (sp == host_client)
break;
pnum++;
}
sp = host_client->controller;
ClientReliableWrite_Begin (sp, svcfte_choosesplitclient, 7);
ClientReliableWrite_Byte (sp, pnum);
ClientReliableWrite_Byte (sp, svc_maxspeed);
ClientReliableWrite_Float(sp, curspeed);
}
else
{
ClientReliableWrite_Begin(host_client, svc_maxspeed, 5);
ClientReliableWrite_Float(host_client, curspeed);
}
}
host_client->maxspeed = curspeed;
}
}
}
}
if (sv.reliable_datagram.overflowed)
{
Con_Printf("WARNING: Reliable datagram overflowed\n");
SZ_Clear (&sv.reliable_datagram);
}
if (sv.datagram.overflowed)
SZ_Clear (&sv.datagram);
#ifdef NQPROT
if (sv.nqdatagram.overflowed)
SZ_Clear (&sv.nqdatagram);
#endif
#ifdef Q2SERVER
if (sv.q2datagram.overflowed)
SZ_Clear (&sv.q2datagram);
#endif
SV_FlushBroadcasts();
}
#ifdef _MSC_VER
#pragma optimize( "", off )
#endif
/*
=======================
SV_SendClientMessages
=======================
*/
void SV_SendClientMessages (void)
{
int i, j;
client_t *c;
int sentbytes, fnum;
float pt = sv.paused?realtime:sv.world.physicstime;
#ifdef Q3SERVER
if (svs.gametype == GT_QUAKE3)
{
for (i=0, c = svs.clients ; i<svs.allocated_client_slots ; i++, c++)
{
if (c->state < cs_connected)
continue;
if (c->drop)
{
SV_DropClient(c);
c->drop = false;
continue;
}
if (c->protocol == SCP_BAD) //this is a bot.
{
SZ_Clear (&c->netchan.message);
SZ_Clear (&c->datagram);
continue;
}
SVQ3_SendMessage(c);
}
return;
}
#endif
// update frags, names, etc
SV_UpdateToReliableMessages ();
// build individual updates
for (i=0, c = svs.clients ; i<svs.allocated_client_slots ; i++, c++)
{
if (c->state < cs_loadzombie)
continue;
if (c->drop)
{
SV_DropClient(c);
c->drop = false;
continue;
}
if (c->state == cs_loadzombie)
{ //not yet present.
c->netchan.message.cursize = 0;
c->datagram.cursize = 0;
continue;
}
#ifdef SVCHAT
SV_ChatThink(c);
#endif
if (c->wasrecorded)
{
c->netchan.message.cursize = 0;
c->datagram.cursize = 0;
continue;
}
#ifdef Q3SERVER
if (ISQ3CLIENT(c))
{ //q3 protocols bypass backbuffering and pretty much everything else
SVQ3_SendMessage(c);
continue;
}
#endif
// check to see if we have a backbuf to stick in the reliable
if (c->num_backbuf)
{
// will it fit?
if (c->netchan.message.cursize + c->backbuf_size[0] <
c->netchan.message.maxsize)
{
Con_DPrintf("%s: backbuf %d bytes\n",
c->name, c->backbuf_size[0]);
// it'll fit
SZ_Write(&c->netchan.message, c->backbuf_data[0],
c->backbuf_size[0]);
//move along, move along
for (j = 1; j < c->num_backbuf; j++)
{
memcpy(c->backbuf_data[j - 1], c->backbuf_data[j],
c->backbuf_size[j]);
c->backbuf_size[j - 1] = c->backbuf_size[j];
}
c->num_backbuf--;
if (c->num_backbuf)
{
memset(&c->backbuf, 0, sizeof(c->backbuf));
c->backbuf.data = c->backbuf_data[c->num_backbuf - 1];
c->backbuf.cursize = c->backbuf_size[c->num_backbuf - 1];
c->backbuf.maxsize = sizeof(c->backbuf_data[c->num_backbuf - 1]);
}
}
}
if (c->protocol == SCP_BAD)
{
SZ_Clear (&c->netchan.message);
SZ_Clear (&c->datagram);
c->num_backbuf = 0;
continue;
}
// if the reliable message overflowed,
// drop the client
if (c->netchan.message.overflowed)
{
SZ_Clear (&c->netchan.message);
SZ_Clear (&c->datagram);
SV_BroadcastPrintf (PRINT_HIGH, "%s overflowed\n", c->name);
Con_Printf ("WARNING: reliable overflow for %s\n",c->name);
c->send_message = true;
c->netchan.cleartime = 0; // don't choke this message
SV_DropClient (c);
continue;
}
#ifdef NQPROT
// only send messages if the client has sent one
// and the bandwidth is not choked
if (ISNQCLIENT(c))
{
//tread carefully with NQ:
//while loading models etc, NQ will error out if it receives anything that it wasn't expecting.
//we should still send unreliable nops whenever we want as a keepalive (and we may need to in order to wake up the client).
//other unreliables are disallowed when connecting, due to sync issues.
//reliables may be sent only if some other code has said that its okay (to avoid stray name changes killing clients).
if (c->state == cs_connected)
{
if (c->nextservertimeupdate > pt + 6)
c->nextservertimeupdate = 0;
c->netchan.nqunreliableonly = !c->send_message;
c->datagram.cursize = 0;
if (!c->send_message && c->nextservertimeupdate < pt)
{
if (c->nextservertimeupdate)
MSG_WriteByte(&c->datagram, svc_nop);
c->nextservertimeupdate = pt+5;
}
c->send_message = true;
//we can still send an outgoing packet if something set send_message. This should really only be svnq_new_f and friends.
}
else
{
if (c->nextservertimeupdate > pt + 0.1)
c->nextservertimeupdate = 0;
c->netchan.nqunreliableonly = false;
c->send_message = false;
//nq sends one packet only for each server physics frame
if (c->nextservertimeupdate < pt && c->state >= ca_connected)
{
c->send_message = true;
c->nextservertimeupdate = pt + 1.0/77;
}
}
}
//qw servers will set send_message on packet reception.
#endif
if (!c->send_message)
continue;
c->send_message = false; // try putting this after choke?
if (c->controller)
continue; /*shouldn't have been set*/
if (!sv.paused && !Netchan_CanPacket (&c->netchan, SV_RateForClient(c)))
{
c->chokecount++;
c->waschoked = true;
continue; // bandwidth choke
}
c->waschoked = false;
if (sv.time > c->ratetime + 1)
{
c->inrate = c->netchan.bytesin / (sv.time - c->ratetime);
c->outrate = c->netchan.bytesout / (sv.time - c->ratetime);
c->netchan.bytesin = 0;
c->netchan.bytesout = 0;
c->ratetime = sv.time;
}
if (c->state == cs_spawned)
SV_SendClientDatagram (c);
else
{
SV_SendClientPrespawnInfo(c);
SV_DarkPlacesDownloadChunk(c, &c->datagram);
fnum = c->netchan.outgoing_sequence;
sentbytes = Netchan_Transmit (&c->netchan, c->datagram.cursize, c->datagram.data, SV_RateForClient(c)); // just update reliable
if (ISQWCLIENT(c) || ISNQCLIENT(c))
c->frameunion.frames[fnum & UPDATE_MASK].packetsizeout += sentbytes;
c->datagram.cursize = 0;
}
}
SV_CleanupEnts();
}
#ifdef _MSC_VER
#pragma optimize( "", on )
#endif
void SV_WriteMVDMessage (sizebuf_t *msg, int type, int to, float time);
void DemoWriteQTVTimePad(int msecs);
#define Max(a, b) ((a>b)?a:b)
void SV_SendMVDMessage(void)
{
int i, j, m, cls = 0;
client_t *c;
qbyte buf[MAX_DATAGRAM];
sizebuf_t msg;
int statsi[MAX_CL_STATS];
float statsf[MAX_CL_STATS];
char *statss[MAX_CL_STATS];
float min_fps;
extern cvar_t sv_demofps;
extern cvar_t sv_demoPings;
// extern cvar_t sv_demoMaxSize;
sizebuf_t *dmsg;
SV_MVD_RunPendingConnections();
if (!sv.mvdrecording)
return;
if (sv_demoPings.value)
{
if (sv.time - demo.pingtime > sv_demoPings.value)
{
SV_MVDPings();
demo.pingtime = sv.time;
}
}
if (sv_demofps.value <= 1)
min_fps = 30.0;
else
min_fps = sv_demofps.value;
min_fps = Max(4, min_fps);
if (sv.time - demo.time < 1.0/min_fps)
return;
for (i=0, c = svs.clients ; i<svs.allocated_client_slots && i < 32; i++, c++)
{
if (c->state != cs_spawned)
continue; // datagrams only go to spawned
cls |= 1 << i;
}
if (!cls)
{
SZ_Clear (&demo.datagram);
DemoWriteQTVTimePad((int)((sv.time - demo.time)*1000));
DestFlush(false);
demo.time = sv.time;
return;
}
msg.data = buf;
msg.maxsize = sizeof(buf);
msg.cursize = 0;
msg.allowoverflow = true;
msg.overflowed = false;
m = MAX_QW_STATS;
if (demo.recorder.fteprotocolextensions & (PEXT_HEXEN2|PEXT_CSQC))
m = MAX_CL_STATS;
for (i=0, c = svs.clients ; i<svs.allocated_client_slots && i < 32; i++, c++)
{
if (c->state != cs_spawned)
continue; // datagrams only go to spawned
if (c->spectator)
continue;
/*figure out what the stat values should be*/
SV_CalcClientStats(c, statsi, statsf, statss);
//FIXME we should do something about the packet overhead here. each MVDWrite_Begin is a separate packet!
for (j=0 ; j<m ; j++)
{
if (demo.recorder.fteprotocolextensions & PEXT_CSQC)
{
if (statss[j] || demo.statss[i][j])
if (strcmp(statss[j]?statss[j]:"", demo.statss[i][j]?demo.statss[i][j]:""))
{
sizebuf_t *msg = MVDWrite_Begin(dem_stats, i, 3+strlen(statss[j]));
demo.statss[i][j] = statss[j];
MSG_WriteByte(msg, svcfte_updatestatstring);
MSG_WriteByte(msg, j);
MSG_WriteString(msg, statss[j]);
}
}
if (statsf[j])
{
if (demo.recorder.fteprotocolextensions & PEXT_CSQC)
{
if (statsf[j] != demo.statsf[i][j])
{
if (statsf[j] - (float)(int)statsf[j] == 0 && statsf[j] >= 0 && statsf[j] <= 255)
{
dmsg = MVDWrite_Begin(dem_stats, i, 3);
MSG_WriteByte(dmsg, svcqw_updatestatbyte);
MSG_WriteByte(dmsg, j);
MSG_WriteByte(dmsg, statsf[j]);
}
else
{
dmsg = MVDWrite_Begin(dem_stats, i, 6);
MSG_WriteByte(dmsg, svcfte_updatestatfloat);
MSG_WriteByte(dmsg, j);
MSG_WriteFloat(dmsg, statsf[j]);
}
demo.statsf[i][j] = statsf[j];
/*make sure statsf is correct*/
demo.statsi[i][j] = statsf[j];
}
continue;
}
else
statsi[j] = statsf[j];
}
if (statsi[j] != demo.statsi[i][j])
{
demo.statsi[i][j] = statsi[j];
demo.statsf[i][j] = statsi[j];
if (statsi[j] >=0 && statsi[j] <= 255)
{
dmsg = MVDWrite_Begin(dem_stats, i, 3);
MSG_WriteByte(dmsg, svcqw_updatestatbyte);
MSG_WriteByte(dmsg, j);
MSG_WriteByte(dmsg, statsi[j]);
}
else
{
dmsg = MVDWrite_Begin(dem_stats, i, 6);
MSG_WriteByte(dmsg, svcqw_updatestatlong);
MSG_WriteByte(dmsg, j);
MSG_WriteLong(dmsg, statsi[j]);
}
}
}
}
// send over all the objects that are in the PVS
// this will include clients, a packetentities, and
// possibly a nails update
msg.cursize = 0;
msg.prim = demo.recorder.netchan.netprim;
if (!demo.recorder.delta_sequence)
demo.recorder.delta_sequence = -1;
// copy the accumulated multicast datagram
// for this client out to the message
if (demo.datagram.cursize && sv.mvdrecording)
{
dmsg = MVDWrite_Begin(dem_all, 0, demo.datagram.cursize);
SZ_Write (dmsg, demo.datagram.data, demo.datagram.cursize);
SZ_Clear (&demo.datagram);
}
while (demo.lastwritten < demo.parsecount-1 && sv.mvdrecording)
{
SV_MVDWritePackets(1);
}
demo.recorder.delta_sequence = demo.recorder.netchan.incoming_sequence&255;
demo.recorder.netchan.incoming_sequence++;
demo.frames[demo.parsecount&DEMO_FRAMES_MASK].time = demo.time = sv.time;
if (sv.mvdrecording)
{
SV_WriteEntitiesToClient (&demo.recorder, &msg, true);
SV_WriteMVDMessage(&msg, dem_all, 0, sv.time);
// dmsg = MVDWrite_Begin(dem_all, 0, msg.cursize);
// SZ_Write (dmsg, msg.data, msg.cursize);
}
demo.parsecount++;
// MVDSetMsgBuf(demo.dbuf,&demo.frames[demo.parsecount&DEMO_FRAMES_MASK].buf);
}
/*
=======================
SV_SendMessagesToAll
FIXME: does this sequence right?
=======================
*/
void SV_SendMessagesToAll (void)
{
int i;
client_t *c;
for (i=0, c = svs.clients ; i<svs.allocated_client_slots ; i++, c++)
if (c->state) // FIXME: should this only send to active?
c->send_message = true;
SV_SendClientMessages ();
}
#endif