dquakeplus/source/view.c

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2022-02-08 21:49:56 +00:00
/*
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.
*/
// view.c -- player eye positioning
#include "quakedef.h"
#include <pspgu.h>
#ifdef PSP_VFPU
#include <pspmath.h>
#endif
sfx_t *cl_sfx_step[4];
/*
The view is allowed to move slightly from it's true position for bobbing,
but if it exceeds 8 pixels linear distance (spherical, not box), the list of
entities sent from the server may not include everything in the pvs, especially
when crossing a water boudnary.
*/
cvar_t lcd_x = {"lcd_x","0"};
cvar_t lcd_yaw = {"lcd_yaw","0"};
cvar_t scr_ofsx = {"scr_ofsx","0", false};
cvar_t scr_ofsy = {"scr_ofsy","0", false};
cvar_t scr_ofsz = {"scr_ofsz","0", false};
cvar_t cl_rollspeed = {"cl_rollspeed", "200"};
cvar_t cl_rollangle = {"cl_rollangle", "2.0"};
cvar_t cl_bob = {"cl_bob","0.02", false};
cvar_t cl_bobcycle = {"cl_bobcycle","0.06", false};
cvar_t cl_bobup = {"cl_bobup","0.02", false};//BLUB changed to 0.02
cvar_t cl_sidebobbing = {"cl_sidebobbing","1"};
cvar_t cl_bobside = {"cl_bobside","0.02"};
cvar_t cl_bobsidecycle = {"cl_bobsidecycle","0.9"};
cvar_t cl_bobsideup = {"cl_bobsideup","0.5"};
cvar_t v_kicktime = {"v_kicktime", "0.5", false};
cvar_t v_kickroll = {"v_kickroll", "0.6", false};
cvar_t v_kickpitch = {"v_kickpitch", "0.6", false};
cvar_t v_iyaw_cycle = {"v_iyaw_cycle", "2", false};
cvar_t v_iroll_cycle = {"v_iroll_cycle", "0.5", false};
cvar_t v_ipitch_cycle = {"v_ipitch_cycle", "1", false};
cvar_t v_iyaw_level = {"v_iyaw_level", "0.3", false};
cvar_t v_iroll_level = {"v_iroll_level", "0.1", false};
cvar_t v_ipitch_level = {"v_ipitch_level", "0.3", false};
cvar_t v_idlescale = {"v_idlescale", "0", false};
cvar_t crosshair = {"crosshair", "0", true};
float v_dmg_time, v_dmg_roll, v_dmg_pitch;
extern int in_forward, in_forward2, in_back;
/*
===============
V_CalcRoll
Used by view and sv_user
===============
*/
vec3_t forward, right, up;
float V_CalcRoll (vec3_t angles, vec3_t velocity)
{
float sign;
float side;
float value;
AngleVectors (angles, forward, right, up);
side = DotProduct (velocity, right);
sign = side < 0 ? -1 : 1;
side = fabsf(side);
value = cl_rollangle.value;
// if (cl.inwater)
// value *= 6;
if (side < cl_rollspeed.value)
side = side * value / cl_rollspeed.value;
else
side = value;
return side*sign;
}
/*
===============
V_CalcBob
===============
*/
// Blub's new V_CalcBob code, both side and pitch are in one, dictated by the (which) parameter
float V_CalcBob (float speed,float which)//0 = regular, 1 = side bobbing
{
float bob = 0;
float sprint = 1;
if(cl.stats[STAT_ZOOM] == 3)
sprint = 1.8;
if(cl.stats[STAT_ZOOM] == 2)
return 0;
//12.048 -> 4.3 = 100 -> 36ish, so replace 100 with 36
#ifdef PSP_VFPU
if(which == 0)
bob = cl_bobup.value * 36 * speed * (sprint * sprint) * vfpu_sinf((cl.time * 12.5 * sprint));//Pitch Bobbing 10
else if(which == 1)
bob = cl_bobside.value * 36 * speed * (sprint * sprint * sprint) * vfpu_sinf((cl.time * 6.25 * sprint) - (M_PI * 0.25));//Yaw Bobbing 5
#else
if(which == 0)
bob = cl_bobup.value * 36 * speed * (sprint * sprint) * sin((cl.time * 12.5 * sprint));//Pitch Bobbing 10
else if(which == 1)
bob = cl_bobside.value * 36 * speed * (sprint * sprint * sprint) * sin((cl.time * 6.25 * sprint) - (M_PI * 0.25));//Yaw Bobbing 5
#endif
return bob;
}
//===================================================== View Bobbing =====================================================
static int lastSound;
float PlayStepSound(void)
{
float num;
int sound = 0;
while(1)
{
num = (rand ()&0x7fff) / ((float)0x7fff);
sound = (int)(num * 4);
sound++;
if(sound != lastSound)
break;
}
if(sound == 1)
S_StartSound (cl.viewentity, 4, cl_sfx_step[0], vec3_origin, 1, 1);
else if(sound == 2)
S_StartSound (cl.viewentity, 4, cl_sfx_step[1], vec3_origin, 1, 1);
else if(sound == 3)
S_StartSound (cl.viewentity, 4, cl_sfx_step[2], vec3_origin, 1, 1);
else if(sound == 4)
S_StartSound (cl.viewentity, 4, cl_sfx_step[3], vec3_origin, 1, 1);
lastSound = sound;
return sound;
}
static int canStep;
float V_CalcVBob(float speed, float which)
{
float bob = 0;
//float speedMulti = (0.2 + sqrt((cl.velocity[0] * cl.velocity[0]) + (cl.velocity[1] * cl.velocity[1])))/97; We're moving this to parent function to save calculations...
//was going to multiply by speed in the sine function to step faster when you're moving faster... but it skipped around on points of the sine curve too much
//It's be much more efficient to just have a constant step speed, though it would look really weird, it's the only way to have a constant step
float sprint = 1;
if(cl.stats[STAT_ZOOM] == 3)
sprint = 1.8;
if(cl.stats[STAT_ZOOM] == 2)
return 0;
if(sprint == 1)
{
#ifdef PSP_VFPU
if(which == 0)
bob = speed * 8.6 * (1/sprint) * vfpu_sinf((cl.time * 12.5 * sprint));//10
else if(which == 1)
bob = speed * 8.6 * (1/sprint) * vfpu_sinf((cl.time * 6.25 * sprint) - (M_PI * 0.25));//5
else if(which == 2)
bob = speed * 8.6 * (1/sprint) * vfpu_sinf((cl.time * 6.25 * sprint) - (M_PI * 0.25));//5
#else
if(which == 0)
bob = speed * 8.6 * (1/sprint) * sin((cl.time * 12.5 * sprint));//10
else if(which == 1)
bob = speed * 8.6 * (1/sprint) * sin((cl.time * 6.25 * sprint) - (M_PI * 0.25));//5
else if(which == 2)
bob = speed * 8.6 * (1/sprint) * sin((cl.time * 6.25 * sprint) - (M_PI * 0.25));//5
#endif
}
else
{
#ifdef PSP_VFPU
if(which == 0)
bob = speed * 8.6 * (1/sprint) * vfpu_cosf((cl.time * 6.25 * sprint));
else if(which == 1)
bob = speed * 8.6 * (1/sprint) * vfpu_cosf((cl.time * 12.5 * sprint));
else if(which == 2)
bob = speed * 8.6 * (1/sprint) * vfpu_cosf((cl.time * 6.25 * sprint));
#else
if(which == 0)
bob = speed * 8.6 * (1/sprint) * cos((cl.time * 6.25 * sprint));
else if(which == 1)
bob = speed * 8.6 * (1/sprint) * cos((cl.time * 12.5 * sprint));
else if(which == 2)
bob = speed * 8.6 * (1/sprint) * cos((cl.time * 6.25 * sprint));
#endif
}
if(speed > 0.1 && which == 0)
{
#ifdef PSP_VFPU
if(canStep && vfpu_sinf(cl.time * 12.5 * sprint) < -0.8)
#else
if(canStep && sin(cl.time * 12.5 * sprint) < -0.8)
#endif
{
PlayStepSound();
canStep = 0;
}
#ifdef PSP_VFPU
if(vfpu_sinf(cl.time * 12.5 * sprint) > 0.9)
#else
if(sin(cl.time * 12.5 * sprint) > 0.9)
#endif
{
canStep = 1;
}
}
return bob;
}
//=============================================================================
cvar_t v_centermove = {"v_centermove", "0.15", false};
cvar_t v_centerspeed = {"v_centerspeed","500"};
void V_StartPitchDrift (void)
{
#if 1
if (cl.laststop == cl.time)
{
return; // something else is keeping it from drifting
}
#endif
if (cl.nodrift || !cl.pitchvel)
{
cl.pitchvel = v_centerspeed.value;
cl.nodrift = false;
cl.driftmove = 0;
}
}
void V_StopPitchDrift (void)
{
cl.laststop = cl.time;
cl.nodrift = true;
cl.pitchvel = 0;
}
/*
===============
V_DriftPitch
Moves the client pitch angle towards cl.idealpitch sent by the server.
If the user is adjusting pitch manually, either with lookup/lookdown,
mlook and mouse, or klook and keyboard, pitch drifting is constantly stopped.
Drifting is enabled when the center view key is hit, mlook is released and
lookspring is non 0, or when
===============
*/
void V_DriftPitch (void)
{
float delta, move;
if (noclip_anglehack || !cl.onground || cls.demoplayback )
{
cl.driftmove = 0;
cl.pitchvel = 0;
return;
}
// don't count small mouse motion
if (cl.nodrift)
{
if ( fabsf(cl.cmd.forwardmove) < cl_forwardspeed)
cl.driftmove = 0;
else
cl.driftmove += host_frametime;
if ( cl.driftmove > v_centermove.value)
{
V_StartPitchDrift ();
}
return;
}
delta = cl.idealpitch - cl.viewangles[PITCH];
if (!delta)
{
cl.pitchvel = 0;
return;
}
move = host_frametime * cl.pitchvel;
cl.pitchvel += host_frametime * v_centerspeed.value;
//Con_Printf ("move: %f (%f)\n", move, host_frametime);
if (delta > 0)
{
if (move > delta)
{
cl.pitchvel = 0;
move = delta;
}
cl.viewangles[PITCH] += move;
}
else if (delta < 0)
{
if (move > -delta)
{
cl.pitchvel = 0;
move = -delta;
}
cl.viewangles[PITCH] -= move;
}
}
/*
==============================================================================
PALETTE FLASHES
==============================================================================
*/
cshift_t cshift_empty = { {130,80,50}, 0 };
cshift_t cshift_water = { {130,80,50}, 128 };
cshift_t cshift_slime = { {0,25,5}, 150 };
cshift_t cshift_lava = { {255,80,0}, 150 };
cvar_t v_gamma = {"gamma", "1", true};
byte gammatable[256]; // palette is sent through this
byte ramps[3][256];
float v_blend[4]; // rgba 0.0 - 1.0
void BuildGammaTable (float g)
{
int i, inf;
if (g == 1.0)
{
for (i=0 ; i<256 ; i++)
gammatable[i] = i;
return;
}
for (i=0 ; i<256 ; i++)
{
inf = 255 * powf ( (i+0.5f)/255.5f , g ) + 0.5;
if (inf < 0)
inf = 0;
if (inf > 255)
inf = 255;
gammatable[i] = inf;
}
}
/*
=================
V_CheckGamma
=================
*/
static float oldgammavalue;
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qboolean V_CheckGamma (void)
{
if (v_gamma.value == oldgammavalue)
return false;
oldgammavalue = v_gamma.value;
BuildGammaTable (v_gamma.value);
vid.recalc_refdef = 1; // force a surface cache flush
return true;
}
/*
==================
V_cshift_f
==================
*/
void V_cshift_f (void)
{
cshift_empty.destcolor[0] = atoi(Cmd_Argv(1));
cshift_empty.destcolor[1] = atoi(Cmd_Argv(2));
cshift_empty.destcolor[2] = atoi(Cmd_Argv(3));
cshift_empty.percent = atoi(Cmd_Argv(4));
}
/*
==================
V_BonusFlash_f
When you run over an item, the server sends this command
==================
*/
void V_BonusFlash_f (void)
{
cl.cshifts[CSHIFT_BONUS].destcolor[0] = 215;
cl.cshifts[CSHIFT_BONUS].destcolor[1] = 186;
cl.cshifts[CSHIFT_BONUS].destcolor[2] = 69;
cl.cshifts[CSHIFT_BONUS].percent = 50;
}
/*
=============
V_SetContentsColor
Underwater, lava, etc each has a color shift
=============
*/
void V_SetContentsColor (int contents)
{
//int s, e, r, g, b, a;
switch (contents)
{
case CONTENTS_EMPTY:
case CONTENTS_SOLID:
cl.cshifts[CSHIFT_CONTENTS] = cshift_empty;
break;
case CONTENTS_LAVA:
cl.cshifts[CSHIFT_CONTENTS] = cshift_lava;
break;
case CONTENTS_SLIME:
cl.cshifts[CSHIFT_CONTENTS] = cshift_slime;
break;
default:
cl.cshifts[CSHIFT_CONTENTS] = cshift_water;
break;
}
/*
s = 0;
e = 400;
r = 130;
g = 80;
b = 50;
a = r_wateralpha.value * 255.0f;
if (contents!=CONTENTS_EMPTY||contents!=CONTENTS_SOLID)
{
sceGuEnable(GU_FOG);
sceGuFog (s, e, GU_COLOR( r * 0.01f, g * 0.01f, b * 0.01f, a * 0.01f));
}
*/
}
/*
=============
V_HealthCshift
=============
*/
void V_HealthCshift (void)
{
int pulse_value, pulseadd;
float tempi1, tempi2, tempi3, tempi4;
if (cl.stats[STAT_HEALTH] < 100 && cl.stats[STAT_HEALTH])
{
cl.cshifts[CSHIFT_DAMAGE].destcolor[0] = 255;
cl.cshifts[CSHIFT_DAMAGE].destcolor[1] = 0;
cl.cshifts[CSHIFT_DAMAGE].destcolor[2] = 0;
if (cl.stats[STAT_HEALTH] < 50)
{
pulse_value = abs(((int)(realtime*100)&100) - 50);
pulseadd = 50;
}
else
{
pulse_value = abs(((int)(realtime*50)&20) - 10);
pulseadd = 10;
}
tempi1 = cl.stats[STAT_HEALTH] + pulse_value;
tempi2 = 100 + pulseadd;
tempi3 = tempi1/tempi2;
tempi4 = 200 - (tempi3*255);
if (tempi4 < 0)
tempi4 = 0;
cl.cshifts[CSHIFT_DAMAGE].percent = (int)tempi4;
}
else
cl.cshifts[CSHIFT_DAMAGE].percent = 0;
}
/*
=============
V_CalcBlend
=============
*/
void V_CalcBlend (void)
{
float r, g, b, a, a2;
int j;
r = 0;
g = 0;
b = 0;
a = 0;
for (j=0 ; j<NUM_CSHIFTS ; j++)
{
if (!r_polyblend.value)
continue;
a2 = cl.cshifts[j].percent / 255.0;
// a2 = cl.cshifts[j].percent/255.0;
if (!a2)
continue;
a = a + a2*(1-a);
//Con_Printf ("j:%i a:%f\n", j, a);
a2 = a2/a;
r = r*(1-a2) + cl.cshifts[j].destcolor[0]*a2;
g = g*(1-a2) + cl.cshifts[j].destcolor[1]*a2;
b = b*(1-a2) + cl.cshifts[j].destcolor[2]*a2;
}
v_blend[0] = r/255.0;
v_blend[1] = g/255.0;
v_blend[2] = b/255.0;
v_blend[3] = a;
if (v_blend[3] > 1)
v_blend[3] = 1;
if (v_blend[3] < 0)
v_blend[3] = 0;
}
/*
=============
V_UpdatePalette
=============
*/
void V_UpdatePalette (void)
{
int i, j;
qboolean new;
byte *basepal, *newpal;
byte pal[768];
float r,g,b,a;
int ir, ig, ib;
qboolean force;
//V_HealthCshift ();
new = false;
for (i=0 ; i<NUM_CSHIFTS ; i++)
{
if (cl.cshifts[i].percent != cl.prev_cshifts[i].percent)
{
new = true;
cl.prev_cshifts[i].percent = cl.cshifts[i].percent;
}
for (j=0 ; j<3 ; j++)
if (cl.cshifts[i].destcolor[j] != cl.prev_cshifts[i].destcolor[j])
{
new = true;
cl.prev_cshifts[i].destcolor[j] = cl.cshifts[i].destcolor[j];
}
}
// drop the bonus value
cl.cshifts[CSHIFT_BONUS].percent -= host_frametime*100;
if (cl.cshifts[CSHIFT_BONUS].percent <= 0)
cl.cshifts[CSHIFT_BONUS].percent = 0;
force = V_CheckGamma ();
if (!new && !force)
return;
V_CalcBlend ();
a = v_blend[3];
r = 255*v_blend[0]*a;
g = 255*v_blend[1]*a;
b = 255*v_blend[2]*a;
a = 1-a;
for (i=0 ; i<256 ; i++)
{
ir = i*a + r;
ig = i*a + g;
ib = i*a + b;
if (ir > 255)
ir = 255;
if (ig > 255)
ig = 255;
if (ib > 255)
ib = 255;
ramps[0][i] = gammatable[ir];
ramps[1][i] = gammatable[ig];
ramps[2][i] = gammatable[ib];
}
basepal = host_basepal;
newpal = pal;
for (i=0 ; i<256 ; i++)
{
ir = basepal[0];
ig = basepal[1];
ib = basepal[2];
basepal += 3;
newpal[0] = ramps[0][ir];
newpal[1] = ramps[1][ig];
newpal[2] = ramps[2][ib];
newpal += 3;
}
VID_ShiftPalette (pal);
}
/*
==============================================================================
VIEW RENDERING
==============================================================================
*/
float angledelta (float a)
{
a = anglemod(a);
if (a > 180)
a -= 360;
return a;
}
/*
==================
CalcGunAngle
==================
*/
static float OldYawTheta;
static float OldPitchTheta;
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static vec3_t cADSOfs;
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void CalcGunAngle (void)
{
float yaw, pitch, move;
static float oldyaw = 0;
static float oldpitch = 0;
yaw = r_refdef.viewangles[YAW];
pitch = -r_refdef.viewangles[PITCH];
yaw = angledelta(yaw - r_refdef.viewangles[YAW]) * 0.4;
if (yaw > 10)
yaw = 10;
if (yaw < -10)
yaw = -10;
pitch = angledelta(-pitch - r_refdef.viewangles[PITCH]) * 0.4;
if (pitch > 10)
pitch = 10;
if (pitch < -10)
pitch = -10;
move = host_frametime*20;
if (yaw > oldyaw)
{
if (oldyaw + move < yaw)
yaw = oldyaw + move;
}
else
{
if (oldyaw - move > yaw)
yaw = oldyaw - move;
}
if (pitch > oldpitch)
{
if (oldpitch + move < pitch)
pitch = oldpitch + move;
}
else
{
if (oldpitch - move > pitch)
pitch = oldpitch - move;
}
oldyaw = yaw;
oldpitch = pitch;
//=========Strafe-Roll=========
//Creating backup
CWeaponRot[PITCH] = cl.viewent.angles[PITCH] * -1;
CWeaponRot[YAW] = cl.viewent.angles[YAW] * -1;
CWeaponRot[ROLL] = cl.viewent.angles[ROLL] * -1;
float side;
side = V_CalcRoll (cl_entities[cl.viewentity].angles, cl.velocity);
cl.viewent.angles[ROLL] = angledelta(cl.viewent.angles[ROLL] - ((cl.viewent.angles[ROLL] - (side * 5)) * 0.5));
//^^^ Model swaying
if(cl.stats[STAT_ZOOM] == 1)
{
cl.viewent.angles[YAW] = (r_refdef.viewangles[YAW] + yaw) - (angledelta((r_refdef.viewangles[YAW] + yaw) - OldYawTheta ) * 0.3);//0.6
}
else
{
cl.viewent.angles[YAW] = (r_refdef.viewangles[YAW] + yaw) - (angledelta((r_refdef.viewangles[YAW] + yaw) - OldYawTheta ) * 0.6);//0.6
}
cl.viewent.angles[PITCH] = -1 * ((r_refdef.viewangles[PITCH] + pitch) - (angledelta((r_refdef.viewangles[PITCH] + pitch) + OldPitchTheta ) * 0.2));
//cl.viewent.angles[PITCH] = - (r_refdef.viewangles[PITCH] + pitch);
//BLUBS STOPS HERE
OldYawTheta = cl.viewent.angles[YAW];
OldPitchTheta = cl.viewent.angles[PITCH];
//readd this
cl.viewent2.angles[ROLL] = cl.viewent.angles[ROLL] -= v_idlescale.value * sinf(cl.time*v_iroll_cycle.value * 2) * v_iroll_level.value;
cl.viewent2.angles[PITCH] = cl.viewent.angles[PITCH] -= v_idlescale.value * sinf(cl.time*v_ipitch_cycle.value * 2) * v_ipitch_level.value;
cl.viewent2.angles[YAW] = cl.viewent.angles[YAW] -= v_idlescale.value * sinf(cl.time*v_iyaw_cycle.value * 2) * v_iyaw_level.value;
//Evaluating total offset
CWeaponRot[PITCH] -= cl.viewent.angles[PITCH];
CWeaponRot[YAW] += cl.viewent.angles[YAW];
CWeaponRot[ROLL] += cl.viewent.angles[ROLL];
}
/*
==============
V_BoundOffsets
==============
*/
void V_BoundOffsets (void)
{
entity_t *ent;
ent = &cl_entities[cl.viewentity];
// absolutely bound refresh reletive to entity clipping hull
// so the view can never be inside a solid wall
if (r_refdef.vieworg[0] < ent->origin[0] - 14)
r_refdef.vieworg[0] = ent->origin[0] - 14;
else if (r_refdef.vieworg[0] > ent->origin[0] + 14)
r_refdef.vieworg[0] = ent->origin[0] + 14;
if (r_refdef.vieworg[1] < ent->origin[1] - 14)
r_refdef.vieworg[1] = ent->origin[1] - 14;
else if (r_refdef.vieworg[1] > ent->origin[1] + 14)
r_refdef.vieworg[1] = ent->origin[1] + 14;
if (r_refdef.vieworg[2] < ent->origin[2] - 22)
r_refdef.vieworg[2] = ent->origin[2] - 22;
else if (r_refdef.vieworg[2] > ent->origin[2] + 32)
r_refdef.vieworg[2] = ent->origin[2] + 32;
}
/*
==============
V_AddIdle
Idle swaying
==============
*/
void V_AddIdle (void)
{
r_refdef.viewangles[ROLL] += v_idlescale.value * sinf(cl.time*v_iroll_cycle.value) * v_iroll_level.value;
r_refdef.viewangles[PITCH] += v_idlescale.value * sinf(cl.time*v_ipitch_cycle.value) * v_ipitch_level.value;
r_refdef.viewangles[YAW] += v_idlescale.value * sinf(cl.time*v_iyaw_cycle.value) * v_iyaw_level.value;
}
/*
==============
V_CalcViewRoll
Roll is induced by movement and damage
==============
*/
void V_CalcViewRoll (void)
{
float side;
side = V_CalcRoll (cl_entities[cl.viewentity].angles, cl.velocity);
r_refdef.viewangles[ROLL] += side;
if (v_dmg_time > 0)
{
r_refdef.viewangles[ROLL] += v_dmg_time/v_kicktime.value*v_dmg_roll;
r_refdef.viewangles[PITCH] += v_dmg_time/v_kicktime.value*v_dmg_pitch;
v_dmg_time -= host_frametime;
}
}
/*
==================
V_CalcIntermissionRefdef
==================
*/
void V_CalcIntermissionRefdef (void)
{
entity_t *ent, *view, *view2;
float old;
// ent is the player model (visible when out of body)
ent = &cl_entities[cl.viewentity];
// view is the weapon model (only visible from inside body)
view = &cl.viewent;
view2 = &cl.viewent2;
VectorCopy (ent->origin, r_refdef.vieworg);
VectorCopy (ent->angles, r_refdef.viewangles);
view->model = NULL;
view2->model = NULL;
// allways idle in intermission
old = v_idlescale.value;
v_idlescale.value = 1;
V_AddIdle ();
v_idlescale.value = old;
}
float ApproxEqual(float A, float B)
{
if((A-B) < -0.001)
return 0;
if(A-B > 0.001)
return 0;
//Con_Printf ("%f",sinf(M_PI));
return 1;
};
/*
==================
Weapon ADS Declarations
==================
*/
void GetWeaponADSOfs(vec2_t out)
{
switch(cl.stats[STAT_ACTIVEWEAPON])
{
case W_COLT:
{
//out[0] = -15.281;
//out[1] = 5.0677;
out[0] = -5.4792;
out[1] = 1.6500;
return;
}
case W_KAR:
{
//out[0] = -15.4472;
//out[1] = 8.75790;
out[0] = -5.4959;
out[1] = 3.1869;
return;
}
case W_KAR_SCOPE:
{
//out[0] = -15.4472;
//out[1] = 1.8985;
out[0] = -5.2860;
out[1] = 0.7061;
return;
}
case W_THOMPSON:
{
//out[0] = -14.0936;
//out[1] = 6.7265;
out[0] = -6.0693;
out[1] = 3.0076;
return;
}
case W_TRENCH:
{
//out[0] = -20.5952;
//out[1] = 10.1903;
out[0] = -5.5271;
out[1] = 2.8803;
return;
}
case W_357:
{
//out[0] = -15.3425;
//out[1] = 3.7888;
out[0] = -8.3065;
out[1] = 0.8792;
return;
}
case W_MG:
{
out[0] = -6.6437;
out[1] = 3.5092;
return;
}
case W_DB:
{
out[0] = -5.8017;
out[1] = 2.9121;
return;
}
case W_SAWNOFF:
{
out[0] = -5.8017;
out[1] = 2.9121;
return;
}
case W_M1A1:
{
out[0] = -5.3878;
out[1] = 3.6719;
return;
}
case W_BAR:
{
out[0] = -3.8833;
//out[1] = 2.3745;
out[1] = 2.6745;
return;
}
default:
{
//Large values > 20ish cause weapon to flicker, scale model down if we encounter!
//Scale better be 4.3, or else viewbobbing is going to be inaccurate.
out[0] = -5.4792;
out[1] = 1.6500;
return;
}
}
};
/*
==================
V_CalcRefdef
==================
*/
static float lastUpVelocity;
static float VerticalOffset;
static float cVerticalOffset;
vec3_t CWeaponOffset;//blubs declared this
vec3_t CWeaponRot;
extern double crosshair_spread_time;
void DropRecoilKick (void)
{
float len;
if (crosshair_spread_time > sv.time)
return;
len = VectorNormalize (cl.gun_kick);
//Con_Printf ("len = %f\n",len);
len = len - 5*host_frametime;
if (len < 0)
len = 0;
VectorScale (cl.gun_kick, len, cl.gun_kick);
//Con_Printf ("len final = %f\n",len);
}
vec3_t lastPunchAngle;
void V_CalcRefdef (void)
{
entity_t *ent, *view, *view2;
int i;
vec3_t forward, right, up;
vec3_t angles;
static float oldz = 0;
V_DriftPitch ();
DropRecoilKick();
// ent is the player model (visible when out of body)
ent = &cl_entities[cl.viewentity];
// view is the weapon model (only visible from inside body)
view = &cl.viewent;
view2 = &cl.viewent2;
// transform the view offset by the model's matrix to get the offset from
// model origin for the view
ent->angles[YAW] = cl.viewangles[YAW]; // the model should face
// the view dir
ent->angles[PITCH] = -cl.viewangles[PITCH]; // the model should face
// the view dir
//Blubs Bobbing calculations were here, moved them down to be right above bob code block
// refresh position
VectorCopy (ent->origin, r_refdef.vieworg);
r_refdef.vieworg[2] += cl.viewheight;//blubs removed "+ bob", it's added again below actually...
// never let it sit exactly on a node line, because a water plane can
// dissapear when viewed with the eye exactly on it.
// the server protocol only specifies to 1/16 pixel, so add 1/32 in each axis
r_refdef.vieworg[0] += 1.0/32;
r_refdef.vieworg[1] += 1.0/32;
r_refdef.vieworg[2] += 1.0/32;
VectorCopy (cl.viewangles, r_refdef.viewangles);
V_CalcViewRoll ();
V_AddIdle ();
// offsets
angles[PITCH] = -ent->angles[PITCH]; // because entity pitches are actually backwards
angles[YAW] = ent->angles[YAW];
angles[ROLL] = ent->angles[ROLL];
AngleVectors (angles, forward, right, up);
for (i=0 ; i<3 ; i++)
r_refdef.vieworg[i] += scr_ofsx.value*forward[i]
+ scr_ofsy.value*right[i]
+ scr_ofsz.value*up[i];
V_BoundOffsets ();
// set up gun position
VectorCopy (cl.viewangles, view->angles);
//cl.oldviewangles = cl.viewangles;
CalcGunAngle ();
view->angles[PITCH] = view->angles[PITCH] - cl.gun_kick[PITCH];
view->angles[YAW] = view->angles[YAW] + cl.gun_kick[YAW];
VectorCopy (ent->origin, view->origin);
view->origin[2] += cl.viewheight;
//Storing base location, later to calculate total offset
CWeaponOffset[0]= view->origin[0] * -1;
CWeaponOffset[1]= view->origin[1] * -1;
CWeaponOffset[2]= view->origin[2] * -1;
//Angle Vectors used by landing and iron sights, so do it here
vec3_t temp_up,temp_right,temp_forward;
AngleVectors (r_refdef.viewangles,temp_forward, temp_right, temp_up);
//============================================================ Fall Landing Buffering ============================================================
if(lastUpVelocity < cl.velocity[2] - 5)//We've had a dramatic change in velocity
{
VerticalOffset = (lastUpVelocity - cl.velocity[2])/25;
if(VerticalOffset < -15)
{
VerticalOffset = -15;
}
}
cVerticalOffset += (VerticalOffset - cVerticalOffset) * 0.3;
temp_up[0] *= cVerticalOffset;
temp_up[1] *= cVerticalOffset;
temp_up[2] *= cVerticalOffset;
view->origin[0] +=(temp_up[0]);
view->origin[1] +=(temp_up[1]);
view->origin[2] +=(temp_up[2]);
if(cVerticalOffset > VerticalOffset - 2 && cVerticalOffset < VerticalOffset + 2)//Close enough to goal
{
VerticalOffset = 0;
}
lastUpVelocity = cl.velocity[2];
//============================================================ Engine-Side Iron Sights ============================================================
AngleVectors (r_refdef.viewangles, temp_forward, temp_right, temp_up);
2023-02-04 01:25:41 +00:00
vec3_t ADSOffset;
2022-02-08 21:49:56 +00:00
if(cl.stats[STAT_ZOOM] == 1 || cl.stats[STAT_ZOOM] == 2)
{
ADSOffset[0] = sv_player->v.ADS_Offset[0];
ADSOffset[1] = sv_player->v.ADS_Offset[1];
ADSOffset[2] = sv_player->v.ADS_Offset[2];
ADSOffset[0] = ADSOffset[0]/1000;
ADSOffset[1] = ADSOffset[1]/1000;
ADSOffset[2] = ADSOffset[2]/1000;
}
else
{
ADSOffset[0] = 0;
ADSOffset[1] = 0;
2023-01-21 00:04:49 +00:00
ADSOffset[2] = 0;
2022-02-08 21:49:56 +00:00
}
//Side offset
cADSOfs [0] += (ADSOffset[0] - cADSOfs[0]) * 0.25;
cADSOfs [1] += (ADSOffset[1] - cADSOfs[1]) * 0.25;
cADSOfs [2] += (ADSOffset[2] - cADSOfs[2]) * 0.25;
2022-02-08 21:49:56 +00:00
temp_right[0] *= cADSOfs[0];
temp_right[1] *= cADSOfs[0];
temp_right[2] *= cADSOfs[0];
temp_up[0] *= cADSOfs[1];
temp_up[1] *= cADSOfs[1];
temp_up[2] *= cADSOfs[1];
temp_forward[0] *= cADSOfs[2];
temp_forward[1] *= cADSOfs[2];
temp_forward[2] *= cADSOfs[2];
2023-01-20 23:56:24 +00:00
view->origin[0] +=(temp_forward[0] + temp_right[0] + temp_up[0]);
view->origin[1] +=(temp_forward[1] + temp_right[1] + temp_up[1]);
view->origin[2] +=(temp_forward[2] + temp_right[2] + temp_up[2]);
2022-02-08 21:49:56 +00:00
float speed = (0.2 + sqrt((cl.velocity[0] * cl.velocity[0]) + (cl.velocity[1] * cl.velocity[1])));
speed = speed/190;
float bob, bobside = 0;
if (cl_sidebobbing.value)
bobside = V_CalcBob(speed,1);
bob = V_CalcBob (speed,0);
//============================ Weapon Bobbing Code Block=================================
for (i=0 ; i<3 ; i++)
{
if (cl_sidebobbing.value)
{
view->origin[i] += right[i]*bobside*0.4;
view->origin[i] += up[i]*bob*0.5;
// view2->origin[i] += right[i]*bobside*0.2;
// view2->origin[i] += up[i]*bob*0.2;
// mz->origin[i] += right[i]*bobside*0.2;
// mz->origin[i] += up[i]*bob*0.2;
}
else
{
view->origin[i] += forward[i]*bob*0.4;
// view2->origin[i] += forward[i]*bob*0.4;
// mz->origin[i] += forward[i]*bob*0.4;
}
}
//view->origin[2] += bob * 2;//Removed because it added bobbing 2 times, we need to have more control than that, removed all multipliers but
// view2->origin[2] += bob;
// mz->origin[2] += bob;
//=============================== Added View Bobbing Code Block (Blubs wuz here)=======================
vec3_t vbob;
vbob[0] = V_CalcVBob(speed,0) * cl_bob.value * 50;//cl_bob * 50 undo each other, but we want to give some control to people to limit view bobbing
vbob[1] = V_CalcVBob(speed,1) * cl_bob.value * 50;
vbob[2] = V_CalcVBob(speed,2) * cl_bob.value * 50;
r_refdef.viewangles[YAW] = angledelta(r_refdef.viewangles[YAW] + (vbob[0] * 0.1));
r_refdef.viewangles[PITCH] = angledelta(r_refdef.viewangles[PITCH] + (vbob[1] * 0.1));
r_refdef.viewangles[ROLL] = anglemod(r_refdef.viewangles[ROLL] + (vbob[2] * 0.05));
//Here we finally set CWeaponOffset by the total weapon model offset, used for mzfl which uses CWeaponOffset variable.
CWeaponOffset[0] += view->origin[0];
CWeaponOffset[1] += view->origin[1];
CWeaponOffset[2] += view->origin[2];
//I don't know what the comments below this are, but blubs didn't add them...
// fudge position around to keep amount of weapon visible
// roughly equal with different FOV
view->model = cl.model_precache[cl.stats[STAT_WEAPON]];
view->frame = cl.stats[STAT_WEAPONFRAME];
view->skinnum = cl.stats[STAT_WEAPONSKIN];
view->colormap = vid.colormap;
view2->model = cl.model_precache[cl.stats[STAT_WEAPON2]];
view2->frame = cl.stats[STAT_WEAPON2FRAME];
view2->skinnum = cl.stats[STAT_WEAPON2SKIN];
view2->colormap = vid.colormap;
// set up the refresh position
//blubs's punchangle interpolation
lastPunchAngle[0] += (cl.punchangle[0] - lastPunchAngle[0]) * 0.5;
lastPunchAngle[1] += (cl.punchangle[1] - lastPunchAngle[1]) * 0.5;
lastPunchAngle[2] += (cl.punchangle[2] - lastPunchAngle[2]) * 0.5;
//VectorCopy(cl.punchangle,lastPunchAngle);
VectorAdd (r_refdef.viewangles, lastPunchAngle, r_refdef.viewangles);
//VectorCopy(cl.punchangle,lastPunchAngle);
VectorAdd (r_refdef.viewangles, cl.gun_kick, r_refdef.viewangles);
// smooth out stair step ups
if (cl.onground && ent->origin[2] - oldz > 0)
{
float steptime;
steptime = cl.time - cl.oldtime;
if (steptime < 0)
//FIXME I_Error ("steptime < 0");
steptime = 0;
oldz += steptime * 80;
if (oldz > ent->origin[2])
oldz = ent->origin[2];
if (ent->origin[2] - oldz > 12)
oldz = ent->origin[2] - 12;
r_refdef.vieworg[2] += oldz - ent->origin[2];
view->origin[2] += oldz - ent->origin[2];
}
else
oldz = ent->origin[2];
if (chase_active.value)
Chase_Update ();
view2->origin[0] = view->origin[0];
view2->origin[1] = view->origin[1];
view2->origin[2] = view->origin[2];
view2->angles[0] = view->angles[0];
view2->angles[1] = view->angles[1];
view2->angles[2] = view->angles[2];
}
//================
// Blub's magical debug tracemove, begin debug functions here
//================
/*
int EN_Find(int num,char *string);
void drawbbox (vec3_t start,vec3_t mins,vec3_t maxs,vec3_t end,int color)
{
vec3_t colorVec;
if(color == 1)
{
colorVec[0] = 0; colorVec[1] = 1; colorVec[2] = 1;
}
if(color == 0)
{
colorVec[0] = 1; colorVec[1] = 0; colorVec[2] = 0;
}
if(color == -1)
{
colorVec[0] = 1; colorVec[1] = 0.5; colorVec[2] = 0.5;
}
//Goal Tracebox
if(color >= 6 && color < 7)
{
colorVec[0] = 1; colorVec[1] = 1; colorVec[2] = 0;
}
if(color == 7)
{
colorVec[0] = 0; colorVec[1] = 1; colorVec[2] = 0;
}
//Down Tracebox
if(color == 2)
{
colorVec[0] = 0.25; colorVec[1] = 0.2; colorVec[2] = 0.2;
}
if(color > 2 && color <= 3)
{
colorVec[0] = 1; colorVec[1] = 0.5; colorVec[2] = 0.25;
}
//Up Tracebox
if(color >= 4 && color < 5)
{
colorVec[0] = 1; colorVec[1] = 0; colorVec[2] = 1;
}
if(color == 5)
{
colorVec[0] = 0; colorVec[1] = 0; colorVec[2] = 1;
}
vec3_t boxmins,boxmaxs;
int i;
if(start[0] == end[0] && start[1] == end[1] && start[2] == end[2])
{
for(i = 0; i < 3; i++)
{
boxmins[i] = start[i] + mins[i];
boxmaxs[i] = start[i] + maxs[i];
}
}
else
{
for (i=0 ; i<3 ; i++)
{
if (end[i] > start[i])
{
boxmins[i] = start[i] + mins[i] - 1;
boxmaxs[i] = end[i] + maxs[i] + 1;
}
else
{
boxmins[i] = end[i] + mins[i] - 1;
boxmaxs[i] = start[i] + maxs[i] + 1;
}
}
}
vec3_t start1,end1;
//Drawing resultant box
//Bottom Square
start1[0] = boxmins[0]; start1[1] = boxmins[1]; start1[2] = boxmins[2];
end1[0] = boxmins[0]; end1[1] = boxmaxs[1]; end1[2] = boxmins[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmins[0]; start1[1] = boxmaxs[1]; start1[2] = boxmins[2];
end1[0] = boxmaxs[0]; end1[1] = boxmaxs[1]; end1[2] = boxmins[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmaxs[0]; start1[1] = boxmaxs[1]; start1[2] = boxmins[2];
end1[0] = boxmaxs[0]; end1[1] = boxmins[1]; end1[2] = boxmins[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmaxs[0]; start1[1] = boxmins[1]; start1[2] = boxmins[2];
end1[0] = boxmins[0]; end1[1] = boxmins[1]; end1[2] = boxmins[2];
R_DrawLine(start1,end1,colorVec);
//Top square
start1[0] = boxmins[0]; start1[1] = boxmins[1]; start1[2] = boxmaxs[2];
end1[0] = boxmins[0]; end1[1] = boxmaxs[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmins[0]; start1[1] = boxmaxs[1]; start1[2] = boxmaxs[2];
end1[0] = boxmaxs[0]; end1[1] = boxmaxs[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmaxs[0]; start1[1] = boxmaxs[1]; start1[2] = boxmaxs[2];
end1[0] = boxmaxs[0]; end1[1] = boxmins[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmaxs[0]; start1[1] = boxmins[1]; start1[2] = boxmaxs[2];
end1[0] = boxmins[0]; end1[1] = boxmins[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
//Side Lines
start1[0] = boxmins[0]; start1[1] = boxmins[1]; start1[2] = boxmins[2];
end1[0] = boxmins[0]; end1[1] = boxmins[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmins[0]; start1[1] = boxmaxs[1]; start1[2] = boxmins[2];
end1[0] = boxmins[0]; end1[1] = boxmaxs[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmaxs[0]; start1[1] = boxmaxs[1]; start1[2] = boxmins[2];
end1[0] = boxmaxs[0]; end1[1] = boxmaxs[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
start1[0] = boxmaxs[0]; start1[1] = boxmins[1]; start1[2] = boxmins[2];
end1[0] = boxmaxs[0]; end1[1] = boxmins[1]; end1[2] = boxmaxs[2];
R_DrawLine(start1,end1,colorVec);
}
/////////////////////////////////////////////
int DebugTraceMove(vec3_t start, vec3_t mins, vec3_t maxs, vec3_t end, int type, edict_t *ent)
{
if(start[0] == end[0] && start[1] == end[1] && start[2] == end[2])
{
return 1;
}
vec3_t forward, up;
float HorDist;
vec3_t HorGoal;
vec3_t tempHorGoal;
up[0] = 0;
up[1] = 0;
up[2] = 1;
HorGoal[0] = end[0];
HorGoal[1] = end[1];
HorGoal[2] = start[2];
VectorSubtract(HorGoal,start,forward);
HorDist = VectorLength(forward);
VectorNormalize(forward);
vec3_t CurrentPos;
VectorCopy(start,CurrentPos);
VectorCopy(HorGoal,tempHorGoal);
float CurrentDist = 0;//2d distance from initial 3d positionvector
trace_t trace1, trace2;
float tempDist;
vec3_t tempVec;
vec3_t tempVec2;
float i;
int STEPSIZEB = 18;//other declaration isn't declared yet
float SLOPELEN = 10.4;//18/tan(60) = 10.4, the the length of the triangle formed by the max walkable slope of 60 degrees.
int skip = 0;
int LoopBreak = 0;
while(CurrentDist < HorDist)
{
if(LoopBreak > 50)
{
Con_Printf("AI Warning: There is a ledge that is greater than 650 meters.\n");
return -1;
}
trace1 = SV_Move(CurrentPos, mins, maxs, tempHorGoal, MOVE_NOMONSTERS, ent);
//Goal
//drawbbox(CurrentPos,mins,maxs,tempHorGoal,trace1.fraction + 6);
VectorSubtract(tempHorGoal,CurrentPos,tempVec);
tempDist = trace1.fraction * VectorLength(tempVec);
//Check if we fell along the path
for(i = (maxs[0] * 1); i < tempDist; i += (maxs[0] * 1))
{
VectorScale(forward,i,tempVec);
VectorAdd(tempVec,CurrentPos,tempVec);
VectorScale(up,-500,tempVec2);//500 inches is about 13 meters
VectorAdd(tempVec,tempVec2,tempVec2);
trace2 = SV_Move(tempVec, mins, maxs, tempVec2, MOVE_NOMONSTERS, ent);
//Down
if(trace2.fraction > 0)
{
vec3_t tVec;
VectorScale(up,-500,tVec);
VectorScale(tVec,trace2.fraction,tVec);
VectorAdd(tempVec,tVec,tVec);
drawbbox(tempVec,mins,maxs,tVec,3);
//drawbbox(tempVec,mins,maxs,tempVec2,3);
}
if(trace2.fraction > 0)
{
VectorScale(up,trace2.fraction * -500,tempVec2);
VectorAdd(tempVec,tempVec2,CurrentPos);
VectorAdd(tempHorGoal,tempVec2,tempHorGoal);
skip = 1;
CurrentDist += i;
if(trace2.fraction == 1)
{
//We fell the full 13 meters!, we need to be careful here,
//because if we're checking over the void, then we could be stuck in an infinite loop and crash the game
//So we're going to keep track of how many times we fall 13 meters
LoopBreak++;
}
else
{
LoopBreak = 0;
}
break;
}
}
//If we fell at any location along path, then we don't try to step up
if(skip == 1)
{
trace2.fraction = 0;
skip = 0;
continue;
}
//We need to advance it as much as possible along path before step up
if(trace1.fraction > 0 && trace1.fraction < 1)
{
VectorCopy(trace1.endpos,CurrentPos);
trace1.fraction = 0;
}
//Check step up
if(trace1.fraction < 1)
{
VectorScale(up,STEPSIZEB,tempVec2);
VectorAdd(CurrentPos,tempVec2,tempVec);
VectorAdd(tempHorGoal,tempVec2,tempVec2);
trace2 = SV_Move(tempVec, mins, maxs, tempVec2, MOVE_NOMONSTERS, ent);
//up
//=============================== Debug ==============================================================
vec3_t debugVec;//temp, we need to do the conditional for success step up but we copy vector after this, so we need to do a temp version of the copy to test in color assignment
VectorSubtract(tempVec2,tempVec,debugVec);
if(trace2.fraction <= (trace1.fraction + (SLOPELEN/VectorLength(debugVec))) && trace2.fraction != 1)
{
drawbbox(tempVec,mins,maxs,tempVec,4);
}
drawbbox(CurrentPos,mins,maxs,CurrentPos,5);
//=============================== / Debug ==============================================================
//10.4 is minimum length for a slope of 60 degrees, we need to at least advance this much to know the surface is walkable
VectorSubtract(tempVec2,tempVec,tempVec2);
if(trace2.fraction > (trace1.fraction + (SLOPELEN/VectorLength(tempVec2))) || trace2.fraction == 1)
{
//we check for slope above
//This is for advancing within the step up
//VectorCopy(trace2.endpos,CurrentPos);
//tempHorGoal[2] = CurrentPos[2];
//VectorSubtract(trace2.endpos,tempVec,tempVec2);
//CurrentDist += VectorLength(tempVec2);
//this is for continuing the search with the step up
VectorCopy(tempVec,CurrentPos);
tempHorGoal[2] = CurrentPos[2];
continue;
}
else
{
//Con_Printf("t2:%f,t1:%f, delta: %f",trace2.fraction,trace1.fraction,trace1.fraction + (SLOPELEN/VectorLength(tempVec2)));
//Con_Printf("hitwall ");
return 0;//stepping up didn't advance so we've hit a wall, we failed
}
}
if(trace1.fraction == 1)//we've made it horizontally to our goal... so check if we've made it vertically...
{
if((end[2] - tempHorGoal[2] < STEPSIZEB) && (end[2] - tempHorGoal[2]) > -1 * STEPSIZEB)
return 1;
else
{
Con_Printf("vert ");
return 0;
}
}
}
Con_Printf("end ");
return 0;
}
void tryLine()
{
edict_t *p;
int pnum;
pnum = EN_Find(0,"player");
p = EDICT_NUM(pnum);
vec3_t cv;
int result;
result = DebugTraceMove(p->v.origin,p->v.mins,p->v.maxs,PROG_TO_EDICT(p->v.enemy)->v.origin ,0,p);
cv[0] = 1; cv[1] = 0; cv[2] = 0;
if(result == 1)
{
cv[0] = 0; cv[1] = 1; cv[2] = 0;
}
R_DrawLine(p->v.origin,PROG_TO_EDICT(p->v.enemy)->v.origin,cv);
//drawbbox(p->v.origin,p->v.mins,p->v.maxs,PROG_TO_EDICT(p->v.enemy)->v.origin,result);
drawbbox(PROG_TO_EDICT(p->v.enemy)->v.origin,p->v.mins,p->v.maxs,PROG_TO_EDICT(p->v.enemy)->v.origin,1);
drawbbox(p->v.origin,p->v.mins,p->v.maxs,p->v.origin,1);
}*/
//End blubs debug functions
/*
==================
V_RenderView
The player's clipping box goes from (-16 -16 -24) to (16 16 32) from
the entity origin, so any view position inside that will be valid
==================
*/
extern vrect_t scr_vrect;
void V_RenderView (void)
{
if (con_forcedup)
return;
// don't allow cheats in multiplayer
if (cl.maxclients > 1)
{
Cvar_Set ("scr_ofsx", "0");
Cvar_Set ("scr_ofsy", "0");
Cvar_Set ("scr_ofsz", "0");
}
if (cl.intermission)
{ // intermission / finale rendering
V_CalcIntermissionRefdef ();
}
else
{
if (!cl.paused && (cl.maxclients > 1 || key_dest == key_game) )
{
V_CalcRefdef ();
}
}
R_PushDlights ();
if (lcd_x.value)//blubs: psp doesn't appear to use these
{
//
// render two interleaved views
//
int i;
vid.rowbytes <<= 1;
vid.aspect *= 0.5;
r_refdef.viewangles[YAW] -= lcd_yaw.value;
for (i=0 ; i<3 ; i++)
r_refdef.vieworg[i] -= right[i]*lcd_x.value;
R_RenderView ();
vid.buffer += vid.rowbytes>>1;
R_PushDlights ();
r_refdef.viewangles[YAW] += lcd_yaw.value*2;
for (i=0 ; i<3 ; i++)
r_refdef.vieworg[i] += 2*right[i]*lcd_x.value;
R_RenderView ();
vid.buffer -= vid.rowbytes>>1;
r_refdef.vrect.height <<= 1;
vid.rowbytes >>= 1;
vid.aspect *= 2;
}
else
{
R_RenderView ();
}
//Blub's debug tracemove: to use: uncomment this, go above and uncomment the functions used above this one, and go in qc and make the player spawn an entity of .enemy
//tryLine();
}
//============================================================================
/*
=============
V_Init
=============
*/
void V_Init (void)
{
Cmd_AddCommand ("v_cshift", V_cshift_f);
Cmd_AddCommand ("bf", V_BonusFlash_f);
Cmd_AddCommand ("centerview", V_StartPitchDrift);
Cvar_RegisterVariable (&lcd_x);
Cvar_RegisterVariable (&lcd_yaw);
Cvar_RegisterVariable (&v_centermove);
Cvar_RegisterVariable (&v_centerspeed);
Cvar_RegisterVariable (&v_iyaw_cycle);
Cvar_RegisterVariable (&v_iroll_cycle);
Cvar_RegisterVariable (&v_ipitch_cycle);
Cvar_RegisterVariable (&v_iyaw_level);
Cvar_RegisterVariable (&v_iroll_level);
Cvar_RegisterVariable (&v_ipitch_level);
Cvar_RegisterVariable (&v_idlescale);
Cvar_RegisterVariable (&crosshair);
Cvar_RegisterVariable (&scr_ofsx);
Cvar_RegisterVariable (&scr_ofsy);
Cvar_RegisterVariable (&scr_ofsz);
Cvar_RegisterVariable (&cl_rollspeed);
Cvar_RegisterVariable (&cl_rollangle);
Cvar_RegisterVariable (&cl_bob);
Cvar_RegisterVariable (&cl_bobcycle);
Cvar_RegisterVariable (&cl_bobup);
Cvar_RegisterVariable (&cl_sidebobbing);
Cvar_RegisterVariable (&cl_bobside);
Cvar_RegisterVariable (&cl_bobsidecycle);
Cvar_RegisterVariable (&cl_bobsideup);
Cvar_RegisterVariable (&v_kicktime);
Cvar_RegisterVariable (&v_kickroll);
Cvar_RegisterVariable (&v_kickpitch);
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BuildGammaTable (1.0); // no gamma yet
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Cvar_RegisterVariable (&v_gamma);
}