1
0
Fork 0
forked from fte/fteqw
fteqw/engine/client/cl_pred.c
Spoike 8ae45223dc Android: fat presses, vibrator, onscreen keyboard, keep-screen-on, console scaling, touch-based console scrolling, additional bindables.
Some memory leaks fixed.
latency with the nq protocol over loopback is much reduced.
Terrain: now mostly a property of a (q1 for now) bsp map, file format changed, glsl now built in, terrain editor builtin improved/changed, holes supported.

git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@4067 fc73d0e0-1445-4013-8a0c-d673dee63da5
2012-07-14 16:25:18 +00:00

1185 lines
29 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.
*/
#include "quakedef.h"
#include "winquake.h"
cvar_t cl_nopred = SCVAR("cl_nopred","0");
extern cvar_t cl_lerp_players;
cvar_t cl_pushlatency = SCVAR("pushlatency","-999");
extern float pm_airaccelerate;
extern usercmd_t independantphysics[MAX_SPLITS];
#ifdef Q2CLIENT
#define MAX_PARSE_ENTITIES 1024
extern entity_state_t cl_parse_entities[MAX_PARSE_ENTITIES];
char *Get_Q2ConfigString(int i);
#ifdef Q2BSPS
void VARGS Q2_Pmove (q2pmove_t *pmove);
#define Q2PMF_DUCKED 1
#define Q2PMF_JUMP_HELD 2
#define Q2PMF_ON_GROUND 4
#define Q2PMF_TIME_WATERJUMP 8 // pm_time is waterjump
#define Q2PMF_TIME_LAND 16 // pm_time is time before rejump
#define Q2PMF_TIME_TELEPORT 32 // pm_time is non-moving time
#define Q2PMF_NO_PREDICTION 64 // temporarily disables prediction (used for grappling hook)
#endif
vec3_t cl_predicted_origins[UPDATE_BACKUP];
/*
===================
CL_CheckPredictionError
===================
*/
#ifdef Q2BSPS
void CLQ2_CheckPredictionError (void)
{
int frame;
int delta[3];
int i;
int len;
if (cl_nopred.value || (cl.q2frame.playerstate.pmove.pm_flags & Q2PMF_NO_PREDICTION))
return;
// calculate the last usercmd_t we sent that the server has processed
frame = cls.netchan.incoming_acknowledged;
frame &= (UPDATE_MASK);
// compare what the server returned with what we had predicted it to be
VectorSubtract (cl.q2frame.playerstate.pmove.origin, cl_predicted_origins[frame], delta);
// save the prediction error for interpolation
len = abs(delta[0]) + abs(delta[1]) + abs(delta[2]);
if (len > 640) // 80 world units
{ // a teleport or something
VectorClear (cl.prediction_error);
}
else
{
// if (/*cl_showmiss->value && */(delta[0] || delta[1] || delta[2]) )
// Con_Printf ("prediction miss on %i: %i\n", cl.q2frame.serverframe,
// delta[0] + delta[1] + delta[2]);
VectorCopy (cl.q2frame.playerstate.pmove.origin, cl_predicted_origins[frame]);
// save for error itnerpolation
for (i=0 ; i<3 ; i++)
cl.prediction_error[i] = delta[i]*0.125;
}
}
/*
====================
CL_ClipMoveToEntities
====================
*/
void CLQ2_ClipMoveToEntities ( vec3_t start, vec3_t mins, vec3_t maxs, vec3_t end, trace_t *tr )
{
int i, x, zd, zu;
trace_t trace;
float *angles;
entity_state_t *ent;
int num;
model_t *cmodel;
vec3_t bmins, bmaxs;
for (i=0 ; i<cl.q2frame.num_entities ; i++)
{
num = (cl.q2frame.parse_entities + i)&(MAX_PARSE_ENTITIES-1);
ent = &cl_parse_entities[num];
if (!ent->solid)
continue;
if (ent->number == cl.playernum[0]+1)
continue;
if (ent->solid == ES_SOLID_BSP)
{ // special value for bmodel
cmodel = cl.model_precache[ent->modelindex];
if (!cmodel)
continue;
angles = ent->angles;
}
else
{ // encoded bbox
x = 8*(ent->solid & 31);
zd = 8*((ent->solid>>5) & 31);
zu = 8*((ent->solid>>10) & 63) - 32;
bmins[0] = bmins[1] = -x;
bmaxs[0] = bmaxs[1] = x;
bmins[2] = -zd;
bmaxs[2] = zu;
cmodel = CM_TempBoxModel (bmins, bmaxs);
angles = vec3_origin; // boxes don't rotate
}
if (tr->allsolid)
return;
trace = CM_TransformedBoxTrace (cmodel, start, end,
mins, maxs, MASK_PLAYERSOLID,
ent->origin, angles);
if (trace.allsolid || trace.startsolid || trace.fraction < tr->fraction)
{
trace.ent = (struct edict_s *)ent;
*tr = trace;
}
}
}
/*
================
CL_PMTrace
================
*/
q2trace_t VARGS CLQ2_PMTrace (vec3_t start, vec3_t mins, vec3_t maxs, vec3_t end)
{
q2trace_t q2t;
trace_t t;
// check against world
t = CM_BoxTrace (cl.worldmodel, start, end, mins, maxs, MASK_PLAYERSOLID);
if (t.fraction < 1.0)
t.ent = (struct edict_s *)1;
// check all other solid models
CLQ2_ClipMoveToEntities (start, mins, maxs, end, &t);
q2t.allsolid = t.allsolid;
q2t.contents = t.contents;
VectorCopy(t.endpos, q2t.endpos);
q2t.ent = t.ent;
q2t.fraction = t.fraction;
q2t.plane = t.plane;
q2t.startsolid = t.startsolid;
q2t.surface = t.surface;
return q2t;
}
int VARGS CLQ2_PMpointcontents (vec3_t point)
{
int i;
entity_state_t *ent;
int num;
model_t *cmodel;
int contents;
contents = CM_PointContents (cl.worldmodel, point);
for (i=0 ; i<cl.q2frame.num_entities ; i++)
{
num = (cl.q2frame.parse_entities + i)&(MAX_PARSE_ENTITIES-1);
ent = &cl_parse_entities[num];
if (ent->solid != 31) // special value for bmodel
continue;
cmodel = cl.model_precache[ent->modelindex];
if (!cmodel)
continue;
contents |= CM_TransformedPointContents (cl.worldmodel, point, cmodel->hulls[0].firstclipnode, ent->origin, ent->angles);
}
return contents;
}
#endif
/*
=================
CL_PredictMovement
Sets cl.predicted_origin and cl.predicted_angles
=================
*/
void CLQ2_PredictMovement (void) //q2 doesn't support split clients.
{
#ifdef Q2BSPS
int ack, current;
int frame;
int oldframe;
q2usercmd_t *cmd;
q2pmove_t pm;
int step;
int oldz;
#endif
int i;
int pnum = 0;
if (cls.state != ca_active)
return;
// if (cl_paused->value)
// return;
#ifdef Q2BSPS
if (cl_nopred.value || (cl.q2frame.playerstate.pmove.pm_flags & Q2PMF_NO_PREDICTION))
#endif
{ // just set angles
for (i=0 ; i<3 ; i++)
{
cl.predicted_angles[i] = cl.playerview[pnum].viewangles[i] + SHORT2ANGLE(cl.q2frame.playerstate.pmove.delta_angles[i]);
}
return;
}
#ifdef Q2BSPS
ack = cls.netchan.incoming_acknowledged;
current = cls.netchan.outgoing_sequence;
// if we are too far out of date, just freeze
if (current - ack >= UPDATE_MASK)
{
// if (cl_showmiss->value)
// Con_Printf ("exceeded CMD_BACKUP\n");
return;
}
// copy current state to pmove
memset (&pm, 0, sizeof(pm));
pm.trace = CLQ2_PMTrace;
pm.pointcontents = CLQ2_PMpointcontents;
pm_airaccelerate = atof(Get_Q2ConfigString(Q2CS_AIRACCEL));
pm.s = cl.q2frame.playerstate.pmove;
// SCR_DebugGraph (current - ack - 1, 0);
frame = 0;
// run frames
while (++ack < current)
{
frame = ack & (UPDATE_MASK);
cmd = (q2usercmd_t*)&cl.frames[frame].cmd[0];
pm.cmd = *cmd;
Q2_Pmove (&pm);
// save for debug checking
VectorCopy (pm.s.origin, cl_predicted_origins[frame]);
}
if (independantphysics[0].msec)
{
cmd = (q2usercmd_t*)&independantphysics[0];
pm.cmd = *cmd;
Q2_Pmove (&pm);
}
oldframe = (ack-2) & (UPDATE_MASK);
oldz = cl_predicted_origins[oldframe][2];
step = pm.s.origin[2] - oldz;
if (step > 63 && step < 160 && (pm.s.pm_flags & Q2PMF_ON_GROUND) )
{
cl.predicted_step = step * 0.125;
cl.predicted_step_time = realtime - host_frametime * 0.5;
}
cl.onground[0] = !!(pm.s.pm_flags & Q2PMF_ON_GROUND);
// copy results out for rendering
cl.predicted_origin[0] = pm.s.origin[0]*0.125;
cl.predicted_origin[1] = pm.s.origin[1]*0.125;
cl.predicted_origin[2] = pm.s.origin[2]*0.125;
VectorCopy (pm.viewangles, cl.predicted_angles);
#endif
}
/*
=================
CL_NudgePosition
If pmove.origin is in a solid position,
try nudging slightly on all axis to
allow for the cut precision of the net coordinates
=================
*/
void CL_NudgePosition (void)
{
vec3_t base;
int x, y;
if (cl.worldmodel->funcs.PointContents (cl.worldmodel, NULL, pmove.origin) == FTECONTENTS_EMPTY)
return;
VectorCopy (pmove.origin, base);
for (x=-1 ; x<=1 ; x++)
{
for (y=-1 ; y<=1 ; y++)
{
pmove.origin[0] = base[0] + x * 1.0/8;
pmove.origin[1] = base[1] + y * 1.0/8;
if (cl.worldmodel->funcs.PointContents (cl.worldmodel, NULL, pmove.origin) == FTECONTENTS_EMPTY)
return;
}
}
Con_DPrintf ("CL_NudgePosition: stuck\n");
}
#endif
/*
==============
CL_PredictUsercmd
==============
*/
void CL_PredictUsercmd (int pnum, int entnum, player_state_t *from, player_state_t *to, usercmd_t *u)
{
extern vec3_t player_mins;
extern vec3_t player_maxs;
// split up very long moves
if (u->msec > 50)
{
player_state_t temp;
usercmd_t split;
split = *u;
split.msec /= 2;
CL_PredictUsercmd (pnum, entnum, from, &temp, &split);
CL_PredictUsercmd (pnum, entnum, &temp, to, &split);
return;
}
VectorCopy (from->origin, pmove.origin);
VectorCopy (u->angles, pmove.angles);
VectorCopy (from->velocity, pmove.velocity);
VectorCopy (from->gravitydir, pmove.gravitydir);
if (!(pmove.velocity[0] == 0) && !(pmove.velocity[0] != 0))
{
Con_Printf("nan velocity!\n");
pmove.velocity[0] = 0;
pmove.velocity[1] = 0;
pmove.velocity[2] = 0;
}
pmove.jump_msec = (cls.z_ext & Z_EXT_PM_TYPE) ? 0 : from->jump_msec;
pmove.jump_held = from->jump_held;
pmove.waterjumptime = from->waterjumptime;
pmove.pm_type = from->pm_type;
pmove.cmd = *u;
pmove.skipent = entnum;
movevars.entgravity = cl.entgravity[pnum];
movevars.maxspeed = cl.maxspeed[pnum];
movevars.bunnyspeedcap = cl.bunnyspeedcap;
pmove.onladder = false;
VectorCopy(from->szmins, player_mins);
VectorCopy(from->szmaxs, player_maxs);
PM_PlayerMove (cl.gamespeed);
to->waterjumptime = pmove.waterjumptime;
to->jump_held = pmove.jump_held;
to->jump_msec = pmove.jump_msec;
pmove.jump_msec = 0;
VectorCopy (pmove.origin, to->origin);
VectorCopy (pmove.angles, to->viewangles);
VectorCopy (pmove.velocity, to->velocity);
VectorCopy (pmove.gravitydir, to->gravitydir);
to->onground = pmove.onground;
to->weaponframe = from->weaponframe;
to->pm_type = from->pm_type;
VectorCopy(player_mins, to->szmins);
VectorCopy(player_maxs, to->szmaxs);
}
//Used when cl_nopred is 1 to determine whether we are on ground, otherwise stepup smoothing code produces ugly jump physics
void CL_CatagorizePosition (int pnum)
{
if (cl.spectator)
{
cl.onground[pnum] = false; // in air
return;
}
VectorClear (pmove.velocity);
VectorCopy (cl.playerview[pnum].simorg, pmove.origin);
pmove.numtouch = 0;
PM_CategorizePosition ();
cl.onground[pnum] = pmove.onground;
}
//Smooth out stair step ups.
//Called before CL_EmitEntities so that the player's lightning model origin is updated properly
void CL_CalcCrouch (int pnum, float stepchange)
{
qboolean teleported;
static vec3_t oldorigin[MAX_SPLITS];
static float oldz[MAX_SPLITS] = {0}, extracrouch[MAX_SPLITS] = {0}, crouchspeed[MAX_SPLITS] = {100,100};
vec3_t delta;
VectorSubtract(cl.playerview[pnum].simorg, oldorigin[pnum], delta);
teleported = Length(delta)>48;
VectorCopy (cl.playerview[pnum].simorg, oldorigin[pnum]);
if (teleported)
{
// possibly teleported or respawned
oldz[pnum] = cl.playerview[pnum].simorg[2];
extracrouch[pnum] = 0;
crouchspeed[pnum] = 100;
cl.crouch[pnum] = 0;
VectorCopy (cl.playerview[pnum].simorg, oldorigin[pnum]);
return;
}
if (cl.onground[pnum] && cl.playerview[pnum].simorg[2] - oldz[pnum] > 0)
{
if (cl.playerview[pnum].simorg[2] - oldz[pnum] > movevars.stepheight+2)
{
// if on steep stairs, increase speed
if (crouchspeed[pnum] < 160)
{
extracrouch[pnum] = cl.playerview[pnum].simorg[2] - oldz[pnum] - host_frametime * 200 - 15;
extracrouch[pnum] = min(extracrouch[pnum], 5);
}
crouchspeed[pnum] = 160;
}
oldz[pnum] += host_frametime * crouchspeed[pnum];
if (oldz[pnum] > cl.playerview[pnum].simorg[2])
oldz[pnum] = cl.playerview[pnum].simorg[2];
if (cl.playerview[pnum].simorg[2] - oldz[pnum] > 15 + extracrouch[pnum])
oldz[pnum] = cl.playerview[pnum].simorg[2] - 15 - extracrouch[pnum];
extracrouch[pnum] -= host_frametime * 200;
extracrouch[pnum] = max(extracrouch[pnum], 0);
cl.crouch[pnum] = oldz[pnum] - cl.playerview[pnum].simorg[2];
}
else
{
// in air or moving down
oldz[pnum] = cl.playerview[pnum].simorg[2];
cl.crouch[pnum] += host_frametime * 150;
if (cl.crouch[pnum] > 0)
cl.crouch[pnum] = 0;
crouchspeed[pnum] = 100;
extracrouch[pnum] = 0;
}
}
float LerpAngles360(float to, float from, float frac)
{
int delta;
delta = (from-to);
if (delta > 180)
delta -= 360;
if (delta < -180)
delta += 360;
return to + frac*delta;
}
//shamelessly ripped from zquake
extern cvar_t cl_nolerp;
static void CL_LerpMove (int pnum, float msgtime)
{
static int lastsequence = 0;
static vec3_t lerp_angles[3];
static vec3_t lerp_origin[3];
static float lerp_times[3];
static qboolean nolerp[2];
static float demo_latency = 0.01;
float frac;
float simtime;
int i;
int from, to;
if (!CL_MayLerp() || cls.demoplayback == DPB_MVD || cls.demoplayback == DPB_EZTV)
return;
#ifdef NQPROT
if (cls.demoplayback == DPB_NETQUAKE)
return;
#endif
if (cls.netchan.outgoing_sequence < lastsequence)
{
// reset
lastsequence = -1;
lerp_times[0] = -1;
demo_latency = 0.01;
}
if (cls.netchan.outgoing_sequence > lastsequence)
{
lastsequence = cls.netchan.outgoing_sequence;
// move along
lerp_times[2] = lerp_times[1];
lerp_times[1] = lerp_times[0];
lerp_times[0] = msgtime;
VectorCopy (lerp_origin[1], lerp_origin[2]);
VectorCopy (lerp_origin[0], lerp_origin[1]);
VectorCopy (cl.playerview[pnum].simorg, lerp_origin[0]);
VectorCopy (lerp_angles[1], lerp_angles[2]);
VectorCopy (lerp_angles[0], lerp_angles[1]);
VectorCopy (cl.playerview[pnum].simangles, lerp_angles[0]);
nolerp[1] = nolerp[0];
nolerp[0] = false;
for (i = 0; i < 3; i++)
if (fabs(lerp_origin[0][i] - lerp_origin[1][i]) > 40)
break;
if (i < 3)
nolerp[0] = true; // a teleport or something
}
simtime = realtime - demo_latency;
// adjust latency
if (simtime > lerp_times[0])
{
// Com_DPrintf ("HIGH clamp\n");
demo_latency = realtime - lerp_times[0];
}
else if (simtime < lerp_times[2])
{
// Com_DPrintf (" low clamp\n");
demo_latency = realtime - lerp_times[2];
}
else
{
// drift towards ideal latency
float ideal_latency = (lerp_times[0] - lerp_times[2]) * 0.6;
if (demo_latency > ideal_latency)
demo_latency = max(demo_latency - host_frametime * 0.1, ideal_latency);
}
// decide where to lerp from
if (simtime > lerp_times[1])
{
from = 1;
to = 0;
}
else
{
from = 2;
to = 1;
}
if (nolerp[to])
return;
frac = (simtime - lerp_times[from]) / (lerp_times[to] - lerp_times[from]);
frac = bound (0, frac, 1);
for (i=0 ; i<3 ; i++)
{
cl.playerview[pnum].simorg[i] = lerp_origin[from][i] +
frac * (lerp_origin[to][i] - lerp_origin[from][i]);
cl.playerview[pnum].simangles[i] = LerpAngles360(lerp_angles[from][i], lerp_angles[to][i], frac);
}
// LerpVector (lerp_origin[from], lerp_origin[to], frac, cl.simorg);
// LerpAngles (lerp_angles[from], lerp_angles[to], frac, cl.simangles);
}
short LerpAngles16(short to, short from, float frac)
{
int delta;
delta = (from-to);
if (delta > 32767)
delta -= 65535;
if (delta < -32767)
delta += 65535;
return to + frac*delta;
}
void CL_CalcClientTime(void)
{
{
float oldst = realtime;
if (cls.protocol == CP_QUAKEWORLD && cls.demoplayback == DPB_MVD)
{
extern float nextdemotime, olddemotime, demtime;
float f;
f = (demtime - olddemotime) / (nextdemotime - olddemotime);
f = bound(0, f, 1);
cl.servertime = cl.gametime*f + cl.oldgametime*(1-f);
}
else if (0)
{
float f;
f = cl.gametime - cl.oldgametime;
if (f > 0.1)
f = 0.1;
f = (realtime - cl.gametimemark) / (f);
f = bound(0, f, 1);
cl.servertime = cl.gametime*f + cl.oldgametime*(1-f);
}
else
{
float min, max;
oldst = cl.servertime;
max = cl.gametime;// - 5;
min = cl.oldgametime;// - 5;
cl.servertime += host_frametime;
if (cl.servertime > max)
{
if (cl.servertime > cl.gametime)
{
cl.servertime = cl.gametime;
// Con_Printf("clamped to new time\n");
}
else
{
cl.servertime -= 0.02*(cl.gametime - cl.servertime);
}
}
if (cl.servertime < min)
{
if (cl.servertime < min-0.5)
{
cl.servertime = min-0.5;
// Con_Printf("clamped to old time\n");
}
else if (cl.servertime < min-0.3)
{
cl.servertime += 0.02*(min - cl.servertime);
// Con_Printf("running really slow\n");
}
else
{
cl.servertime += 0.01*(min - cl.servertime);
// Con_Printf("running slow\n");
}
}
}
cl.time = cl.servertime;
if (oldst == 0)
{
int i;
for (i = 0; i < MAX_CLIENTS; i++)
{
cl.players[i].entertime += cl.servertime;
}
}
return;
}
if (cls.protocol == CP_NETQUAKE || (cls.demoplayback && cls.demoplayback != DPB_MVD && cls.demoplayback != DPB_EZTV))
{
float want;
// float off;
want = cl.oldgametime + realtime - cl.gametimemark;
// off = (want - cl.time);
if (want>cl.time) //don't decrease
cl.time = want;
// Con_Printf("Drifted to %f off by %f\n", cl.time, off);
// Con_Printf("\n");
if (cl.time > cl.gametime)
{
cl.time = cl.gametime;
// Con_Printf("max TimeClamp\n");
}
if (cl.time < cl.oldgametime)
{
cl.time = cl.oldgametime;
// Con_Printf("old TimeClamp\n");
}
}
else
{
cl.time = realtime - cls.latency - cl_pushlatency.value*0.001;
if (cl.time > realtime)
cl.time = realtime;
}
}
static void CL_DecodeStateSize(unsigned short solid, int modelindex, vec3_t mins, vec3_t maxs)
{
if (solid == ES_SOLID_BSP)
{
if (modelindex < MAX_MODELS && cl.model_precache[modelindex] && !cl.model_precache[modelindex]->needload)
{
VectorCopy(cl.model_precache[modelindex]->mins, mins);
VectorCopy(cl.model_precache[modelindex]->maxs, maxs);
}
else
{
VectorClear(mins);
VectorClear(maxs);
}
}
else if (solid)
{
mins[0] = -8*(solid&31);
mins[1] = -8*(solid&31);
mins[2] = -8*((solid>>5)&31);
maxs[0] = 8*(solid&31);
maxs[1] = 8*(solid&31);
maxs[2] = 8*((solid>>10)&63) - 32;
}
else
{
VectorClear(mins);
VectorClear(maxs);
}
}
/*called on packet reception*/
#include "pr_common.h"
void CL_PlayerFrameUpdated(player_state_t *plstate, entity_state_t *state, int sequence)
{
/*update the prediction info*/
vec3_t a;
int pmtype, i;
switch(state->u.q1.pmovetype)
{
case MOVETYPE_NOCLIP:
if (cls.z_ext & Z_EXT_PM_TYPE_NEW)
pmtype = PM_SPECTATOR;
else
pmtype = PM_OLD_SPECTATOR;
break;
case MOVETYPE_FLY:
pmtype = PM_FLY;
break;
case MOVETYPE_NONE:
pmtype = PM_NONE;
break;
case MOVETYPE_BOUNCE:
case MOVETYPE_TOSS:
pmtype = PM_DEAD;
break;
case MOVETYPE_WALLWALK:
pmtype = PM_WALLWALK;
break;
default:
pmtype = PM_NORMAL;
break;
}
plstate->pm_type = pmtype;
VectorCopy(state->origin, plstate->origin);
plstate->command.angles[0] = state->angles[0] * -3 *65536/360.0;
plstate->command.angles[1] = state->angles[1] * 65536/360.0;
plstate->command.angles[2] = state->angles[2] * 65536/360.0;
VectorScale(state->u.q1.velocity, 1/8.0, plstate->velocity);
plstate->messagenum = sequence;
a[0] = ((-192-state->u.q1.gravitydir[0])/256.0f) * 360;
a[1] = (state->u.q1.gravitydir[1]/256.0f) * 360;
a[2] = 0;
AngleVectors(a, plstate->gravitydir, NULL, NULL);
cl.players[state->number-1].stats[STAT_WEAPONFRAME] = state->u.q1.weaponframe;
cl.players[state->number-1].statsf[STAT_WEAPONFRAME] = state->u.q1.weaponframe;
for (i = 0; i < cl.splitclients; i++)
{
if (cl.playernum[i] == state->number-1)
{
cl.playerview[i].stats[STAT_WEAPONFRAME] = state->u.q1.weaponframe;
cl.playerview[i].statsf[STAT_WEAPONFRAME] = state->u.q1.weaponframe;
}
}
CL_DecodeStateSize(state->solid, state->modelindex, plstate->szmins, plstate->szmaxs);
}
/*called once every rendered frame*/
qboolean CL_PredictPlayer(lerpents_t *le, entity_state_t *state, int sequence)
{
int msec, oldphysent;
usercmd_t cmd;
player_state_t start, exact;
int pnum;
if (state->number-1 > cl.allocated_client_slots || cl.intermission)
return false;
/*local players just interpolate for now. the prediction code will move it to the right place afterwards*/
for (pnum = 0; pnum < cl.splitclients; pnum++)
{
if (state->number-1 == cl.playernum[pnum])
return false;
}
memset(&cmd, 0, sizeof(cmd));
memset(&start, 0, sizeof(start));
CL_PlayerFrameUpdated(&start, state, sequence);
msec = 500*(realtime - cls.latency + 0.02 - cl.frames[sequence & UPDATE_MASK].receivedtime);
cmd.msec = bound(0, msec, 255);
cmd.forwardmove = state->u.q1.movement[0];
cmd.sidemove = state->u.q1.movement[1];
cmd.upmove = state->u.q1.movement[2];
oldphysent = pmove.numphysent;
CL_PredictUsercmd (0, state->number, &start, &exact, &cmd); //uses player 0's maxspeed/grav...
pmove.numphysent = oldphysent;
/*need to update the entity's angles and origin so the linkentities function puts it in the correct predicted place*/
le->angles[0] = state->angles[0];
le->angles[1] = state->angles[1];
le->angles[2] = state->angles[2];
VectorCopy (exact.origin, le->origin);
return true;
}
/*
==============
CL_PredictMove
==============
*/
void CL_PredictMovePNum (int pnum)
{
frame_t ind;
int i;
float f;
frame_t *from, *to = NULL;
int oldphysent;
vec3_t lrp, lrpv;
//these are to make svc_viewentity work better
float *vel;
float *org;
float stepheight = 0;
cl.nolocalplayer[pnum] = !!(cls.fteprotocolextensions2 & PEXT2_REPLACEMENTDELTAS);
#ifdef Q2CLIENT
if (cls.protocol == CP_QUAKE2)
{
if (!cl.worldmodel || cl.worldmodel->needload)
return;
cl.crouch[pnum] = 0;
CLQ2_PredictMovement();
return;
}
#endif
if (cl_pushlatency.value > 0)
Cvar_Set (&cl_pushlatency, "0");
if (cl.paused && !(cls.demoplayback!=DPB_MVD && cls.demoplayback!=DPB_EZTV) && (!cl.spectator || !autocam[pnum]))
return;
if (cl.intermission==1 && cls.protocol == CP_QUAKEWORLD)
{
cl.crouch[pnum] = 0;
return;
}
#ifdef NQPROT
if (cls.protocol == CP_NETQUAKE)
{
cl.ackedinputsequence = cls.netchan.outgoing_sequence;
}
#endif
if (!cl.ackedinputsequence)
{
return;
}
if (cls.netchan.outgoing_sequence - cl.ackedinputsequence >= UPDATE_BACKUP-1)
{ //lagging like poo.
if (!cl.intermission) //keep the angles working though.
VectorCopy (cl.playerview[pnum].viewangles, cl.playerview[pnum].simangles);
return;
}
// this is the last frame received from the server
from = &cl.frames[cl.ackedinputsequence & UPDATE_MASK];
if (!cl.intermission)
{
VectorCopy (cl.playerview[pnum].viewangles, cl.playerview[pnum].simangles);
}
vel = from->playerstate[cl.playernum[pnum]].velocity;
org = from->playerstate[cl.playernum[pnum]].origin;
#ifdef PEXT_SETVIEW
if (cl.viewentity[pnum])
{
if (cl.viewentity[pnum] < cl.maxlerpents)
{
cl.nolocalplayer[pnum] = true;
// Con_Printf("Using lerped pos\n");
org = cl.lerpents[cl.viewentity[pnum]].origin;
vel = vec3_origin;
goto fixedorg;
}
}
#endif
if (!from->playerstate[cl.playernum[pnum]].messagenum)
{
//no player states?? put the view on an ent
if (cl.playernum[pnum] < cl.maxlerpents)
{
cl.nolocalplayer[pnum] = true;
// Con_Printf("Using lerped pos\n");
org = cl.lerpents[cl.playernum[pnum]+1].origin;
vel = vec3_origin;
goto fixedorg;
}
}
if (((cl_nopred.value && cls.demoplayback!=DPB_MVD && cls.demoplayback != DPB_EZTV)|| cl.playerview[pnum].fixangle || cl.paused))
{
if (cl_lerp_players.ival && !cls.demoplayback)
{
lerpents_t *le;
if (cls.fteprotocolextensions2 & PEXT2_REPLACEMENTDELTAS)
le = &cl.lerpents[spec_track[pnum]+1];
else
le = &cl.lerpplayers[spec_track[pnum]];
org = le->origin;
vel = vec3_origin;
}
fixedorg:
VectorCopy (vel, cl.playerview[pnum].simvel);
VectorCopy (org, cl.playerview[pnum].simorg);
to = &cl.frames[cl.ackedinputsequence & UPDATE_MASK];
CL_CatagorizePosition(pnum);
goto out;
}
// predict forward until cl.time <= to->senttime
oldphysent = pmove.numphysent;
CL_SetSolidPlayers();
pmove.skipent = cl.playernum[pnum]+1;
to = &cl.frames[cl.ackedinputsequence & UPDATE_MASK];
if (Cam_TrackNum(pnum)>=0 && CL_MayLerp())
{
float f;
if (cl_lerp_players.ival && (cls.demoplayback==DPB_MVD || cls.demoplayback == DPB_EZTV))
{
lerpents_t *le = &cl.lerpplayers[spec_track[pnum]];
org = le->origin;
vel = vec3_origin;
VectorCopy(le->angles, cl.playerview[pnum].simangles);
goto fixedorg;
}
to = &cl.frames[cl.validsequence & UPDATE_MASK];
from = &cl.frames[cl.oldvalidsequence & UPDATE_MASK];
//figure out the lerp factor
if (cl.gametime == cl.servertime)
f = 0;
else
f = (cl.gametime-cl.servertime)/(cl.gametime-cl.oldgametime);//f = (cl.time-cl.lerpents[state->number].lerptime)/cl.lerpents[state->number].lerprate;
if (f<0)
f=0;
if (f>1)
f=1;
// f = 1-f;
// calculate origin
for (i=0 ; i<3 ; i++)
{
lrp[i] = to->playerstate[cl.playernum[pnum]].origin[i] +
f * (from->playerstate[cl.playernum[pnum]].origin[i] - to->playerstate[cl.playernum[pnum]].origin[i]);
lrpv[i] = to->playerstate[spec_track[pnum]].velocity[i] +
f * (from->playerstate[spec_track[pnum]].velocity[i] - to->playerstate[spec_track[pnum]].velocity[i]);
cl.playerview[pnum].simangles[i] = LerpAngles16(to->playerstate[spec_track[pnum]].command.angles[i], from->playerstate[spec_track[pnum]].command.angles[i], f)*360.0f/65535;
}
org = lrp;
vel = lrpv;
cl.pmovetype[pnum] = PM_NONE;
goto fixedorg;
}
else
{
if (cls.demoplayback==DPB_MVD || cls.demoplayback==DPB_EZTV)
{
to = &cl.frames[(cls.netchan.outgoing_sequence-1) & UPDATE_MASK];
to->playerstate->pm_type = PM_SPECTATOR;
VectorCopy (cl.playerview[pnum].simvel, from->playerstate[cl.playernum[pnum]].velocity);
VectorCopy (cl.playerview[pnum].simorg, from->playerstate[cl.playernum[pnum]].origin);
CL_PredictUsercmd (pnum, cl.playernum[pnum]+1, &from->playerstate[cl.playernum[pnum]], &to->playerstate[cl.playernum[pnum]], &to->cmd[pnum]);
}
else
{
for (i=1 ; i<UPDATE_BACKUP-1 && cl.ackedinputsequence+i <
cls.netchan.outgoing_sequence; i++)
{
to = &cl.frames[(cl.ackedinputsequence+i) & UPDATE_MASK];
CL_PredictUsercmd (pnum, cl.playernum[pnum]+1, &from->playerstate[cl.playernum[pnum]]
, &to->playerstate[cl.playernum[pnum]], &to->cmd[pnum]);
if (to->senttime >= realtime)
break;
from = to;
}
}
if (independantphysics[pnum].msec)
{
from = to;
to = &ind;
to->cmd[pnum] = independantphysics[pnum];
to->senttime = realtime;
CL_PredictUsercmd (pnum, cl.playernum[pnum]+1, &from->playerstate[cl.playernum[pnum]]
, &to->playerstate[cl.playernum[pnum]], &to->cmd[pnum]);
}
cl.onground[pnum] = pmove.onground;
cl.pmovetype[pnum] = to->playerstate[cl.playernum[pnum]].pm_type;
stepheight = to->playerstate[cl.playernum[pnum]].origin[2] - from->playerstate[cl.playernum[pnum]].origin[2];
if (cl.nolocalplayer[pnum])
{
//keep the entity tracking the prediction position, so mirrors don't go all weird
VectorCopy(to->playerstate[cl.playernum[pnum]].origin, cl.lerpents[cl.playernum[pnum]+1].origin);
VectorScale(to->cmd[pnum].angles, 360.0f / 0xffff, cl.lerpents[cl.playernum[pnum]+1].angles);
cl.lerpents[cl.playernum[pnum]+1].angles[0] *= -0.333;
}
}
pmove.numphysent = oldphysent;
if (1)//!independantphysics.msec)
{
VectorCopy (to->playerstate[cl.playernum[pnum]].velocity, cl.playerview[pnum].simvel);
VectorCopy (to->playerstate[cl.playernum[pnum]].origin, cl.playerview[pnum].simorg);
}
else
{
// now interpolate some fraction of the final frame
if (to->senttime == from->senttime)
f = 0;
else
{
f = (realtime - from->senttime) / (to->senttime - from->senttime);
if (f < 0)
f = 0;
if (f > 1)
f = 1;
}
for (i=0 ; i<3 ; i++)
if ( fabs(org[i] - to->playerstate[cl.playernum[pnum]].origin[i]) > 128)
{ // teleported, so don't lerp
VectorCopy (to->playerstate[cl.playernum[pnum]].velocity, cl.playerview[pnum].simvel);
VectorCopy (to->playerstate[cl.playernum[pnum]].origin, cl.playerview[pnum].simorg);
goto out;
}
for (i=0 ; i<3 ; i++)
{
cl.playerview[pnum].simorg[i] = org[i]
+ f*(to->playerstate[cl.playernum[pnum]].origin[i] - org[i]);
cl.playerview[pnum].simvel[i] = vel[i]
+ f*(to->playerstate[cl.playernum[pnum]].velocity[i] - vel[i]);
}
CL_CatagorizePosition(pnum);
}
if (cls.demoplayback)
CL_LerpMove (pnum, to->senttime);
out:
CL_CalcCrouch (pnum, stepheight);
cl.waterlevel[pnum] = pmove.waterlevel;
VectorCopy(pmove.gravitydir, cl.playerview[pnum].gravitydir);
}
void CL_PredictMove (void)
{
int i;
//work out which packet entities are solid
CL_SetSolidEntities ();
// Set up prediction for other players
CL_SetUpPlayerPrediction(false);
// do client side motion prediction
for (i = 0; i < cl.splitclients; i++)
CL_PredictMovePNum(i);
// Set up prediction for other players
CL_SetUpPlayerPrediction(true);
}
/*
==============
CL_InitPrediction
==============
*/
void CL_InitPrediction (void)
{
extern char cl_predictiongroup[];
Cvar_Register (&cl_pushlatency, cl_predictiongroup);
Cvar_Register (&cl_nopred, cl_predictiongroup);
}