/*
=================
R_SetupEntityLightingGrid
=================
*/
static void R_SetupEntityLightingGrid( trRefEntity_t *ent ) {
vec3_t lightOrigin;
int pos[3];
int i, j;
float frac[3];
int gridStep[3];
vec3_t direction;
float totalFactor;
unsigned short *startGridPos;
if (r_fullbright->integer || tr.refdef.doFullbright )
{
ent->ambientLight[0] = ent->ambientLight[1] = ent->ambientLight[2] = 255.0;
ent->directedLight[0] = ent->directedLight[1] = ent->directedLight[2] = 255.0;
VectorCopy( tr.sunDirection, ent->lightDir );
return;
}
if ( ent->e.renderfx & RF_LIGHTING_ORIGIN ) {
// seperate lightOrigins are needed so an object that is
// sinking into the ground can still be lit, and so
// multi-part models can be lit identically
VectorCopy( ent->e.lightingOrigin, lightOrigin );
} else {
VectorCopy( ent->e.origin, lightOrigin );
}
#define ACCURATE_LIGHTGRID_SAMPLING 1
#if ACCURATE_LIGHTGRID_SAMPLING
vec3_t startLightOrigin;
VectorCopy( lightOrigin, startLightOrigin );
#endif
VectorSubtract( lightOrigin, tr.world->lightGridOrigin, lightOrigin );
for ( i = 0 ; i < 3 ; i++ ) {
float v;
v = lightOrigin[i]*tr.world->lightGridInverseSize[i];
pos[i] = floor( v );
frac[i] = v - pos[i];
if ( pos[i] < 0 ) {
pos[i] = 0;
} else if ( pos[i] >= tr.world->lightGridBounds[i] - 1 ) {
pos[i] = tr.world->lightGridBounds[i] - 1;
}
}
VectorClear( ent->ambientLight );
VectorClear( ent->directedLight );
VectorClear( direction );
// trilerp the light value
gridStep[0] = 1;
gridStep[1] = tr.world->lightGridBounds[0];
gridStep[2] = tr.world->lightGridBounds[0] * tr.world->lightGridBounds[1];
startGridPos = tr.world->lightGridArray + pos[0] * gridStep[0]
+ pos[1] * gridStep[1] + pos[2] * gridStep[2];
#if ACCURATE_LIGHTGRID_SAMPLING
vec3_t startGridOrg;
VectorCopy( tr.world->lightGridOrigin, startGridOrg );
startGridOrg[0] += pos[0] * tr.world->lightGridSize[0];
startGridOrg[1] += pos[1] * tr.world->lightGridSize[1];
startGridOrg[2] += pos[2] * tr.world->lightGridSize[2];
#endif
totalFactor = 0;
for ( i = 0 ; i < 8 ; i++ ) {
float factor;
mgrid_t *data;
unsigned short *gridPos;
int lat, lng;
vec3_t normal;
#if ACCURATE_LIGHTGRID_SAMPLING
vec3_t gridOrg;
VectorCopy( startGridOrg, gridOrg );
#endif
factor = 1.0;
gridPos = startGridPos;
for ( j = 0 ; j < 3 ; j++ ) {
if ( i & (1<<j) ) {
factor *= frac[j];
gridPos += gridStep[j];
#if ACCURATE_LIGHTGRID_SAMPLING
gridOrg[j] += tr.world->lightGridSize[j];
#endif
} else {
factor *= (1.0 - frac[j]);
}
}
if (gridPos >= tr.world->lightGridArray + tr.world->numGridArrayElements)
{//we've gone off the array somehow
continue;
}
data = tr.world->lightGridData + *gridPos;
if ( data->styles[0] == LS_NONE )
{
continue; // ignore samples in walls
}
#if 0
if ( !SV_inPVS( startLightOrigin, gridOrg ) )
{
continue;
}
#endif
totalFactor += factor;
for(j=0;j<MAXLIGHTMAPS;j++)
{
if (data->styles[j] != LS_NONE)
{
const byte style= data->styles[j];
ent->ambientLight[0] += factor * data->ambientLight[j][0] * styleColors[style][0] / 255.0f;
ent->ambientLight[1] += factor * data->ambientLight[j][1] * styleColors[style][1] / 255.0f;
ent->ambientLight[2] += factor * data->ambientLight[j][2] * styleColors[style][2] / 255.0f;
ent->directedLight[0] += factor * data->directLight[j][0] * styleColors[style][0] / 255.0f;
ent->directedLight[1] += factor * data->directLight[j][1] * styleColors[style][1] / 255.0f;
ent->directedLight[2] += factor * data->directLight[j][2] * styleColors[style][2] / 255.0f;
}
else
{
break;
}
}
lat = data->latLong[1];
lng = data->latLong[0];
lat *= (FUNCTABLE_SIZE/256);
lng *= (FUNCTABLE_SIZE/256);
// decode X as cos( lat ) * sin( long )
// decode Y as sin( lat ) * sin( long )
// decode Z as cos( long )
normal[0] = tr.sinTable[(lat+(FUNCTABLE_SIZE/4))&FUNCTABLE_MASK] * tr.sinTable[lng];
normal[1] = tr.sinTable[lat] * tr.sinTable[lng];
normal[2] = tr.sinTable[(lng+(FUNCTABLE_SIZE/4))&FUNCTABLE_MASK];
VectorMA( direction, factor, normal, direction );
#if ACCURATE_LIGHTGRID_SAMPLING
if ( r_debugLight->integer && ent->e.hModel == -1 )
{
//draw
refEntity_t refEnt;
refEnt.hModel = 0;
refEnt.ghoul2 = NULL;
refEnt.renderfx = 0;
VectorCopy( gridOrg, refEnt.origin );
vectoangles( normal, refEnt.angles );
AnglesToAxis( refEnt.angles, refEnt.axis );
refEnt.reType = RT_MODEL;
RE_AddRefEntityToScene( &refEnt );
refEnt.renderfx = RF_DEPTHHACK;
refEnt.reType = RT_SPRITE;
refEnt.customShader = RE_RegisterShader( "gfx/misc/debugAmbient" );
refEnt.shaderRGBA[0] = data->ambientLight[0][0];
refEnt.shaderRGBA[1] = data->ambientLight[0][1];
refEnt.shaderRGBA[2] = data->ambientLight[0][2];
refEnt.shaderRGBA[3] = 255;
refEnt.radius = factor*50+2.0f; // maybe always give it a minimum size?
refEnt.rotation = 0; // don't let the sprite wobble around
RE_AddRefEntityToScene( &refEnt );
refEnt.reType = RT_LINE;
refEnt.customShader = RE_RegisterShader( "gfx/misc/debugArrow" );
refEnt.shaderRGBA[0] = data->directLight[0][0];
refEnt.shaderRGBA[1] = data->directLight[0][1];
refEnt.shaderRGBA[2] = data->directLight[0][2];
refEnt.shaderRGBA[3] = 255;
VectorCopy( refEnt.origin, refEnt.oldorigin );
VectorMA( gridOrg, (factor*-255) - 2.0f, normal, refEnt.origin ); // maybe always give it a minimum length
refEnt.radius = 1.5f;
RE_AddRefEntityToScene( &refEnt );
}
#endif
}
if ( totalFactor > 0 && totalFactor < 0.99 )
{
totalFactor = 1.0 / totalFactor;
VectorScale( ent->ambientLight, totalFactor, ent->ambientLight );
VectorScale( ent->directedLight, totalFactor, ent->directedLight );
}
VectorScale( ent->ambientLight, r_ambientScale->value, ent->ambientLight );
VectorScale( ent->directedLight, r_directedScale->value, ent->directedLight );
VectorNormalize2( direction, ent->lightDir );
}
/*
================
CG_AddFragment
================
*/
void CG_AddFragment( localEntity_t *le ) {
vec3_t newOrigin;
trace_t trace;
if (le->forceAlpha)
{
le->refEntity.renderfx |= RF_FORCE_ENT_ALPHA;
le->refEntity.shaderRGBA[3] = le->forceAlpha;
}
if ( le->pos.trType == TR_STATIONARY ) {
// sink into the ground if near the removal time
int t;
float t_e;
t = le->endTime - cg.time;
if ( t < (SINK_TIME*2) ) {
le->refEntity.renderfx |= RF_FORCE_ENT_ALPHA;
t_e = (float)((float)(le->endTime - cg.time)/(SINK_TIME*2));
t_e = (int)((t_e)*255);
if (t_e > 255)
{
t_e = 255;
}
if (t_e < 1)
{
t_e = 1;
}
if (le->refEntity.shaderRGBA[3] && t_e > le->refEntity.shaderRGBA[3])
{
t_e = le->refEntity.shaderRGBA[3];
}
le->refEntity.shaderRGBA[3] = t_e;
trap_R_AddRefEntityToScene( &le->refEntity );
} else {
trap_R_AddRefEntityToScene( &le->refEntity );
}
return;
}
// calculate new position
BG_EvaluateTrajectory( &le->pos, cg.time, newOrigin );
// trace a line from previous position to new position
CG_Trace( &trace, le->refEntity.origin, NULL, NULL, newOrigin, -1, CONTENTS_SOLID );
if ( trace.fraction == 1.0 ) {
// still in free fall
VectorCopy( newOrigin, le->refEntity.origin );
if ( le->leFlags & LEF_TUMBLE ) {
vec3_t angles;
BG_EvaluateTrajectory( &le->angles, cg.time, angles );
AnglesToAxis( angles, le->refEntity.axis );
}
trap_R_AddRefEntityToScene( &le->refEntity );
// add a blood trail
if ( le->leBounceSoundType == LEBS_BLOOD ) {
CG_BloodTrail( le );
}
return;
}
// if it is in a nodrop zone, remove it
// this keeps gibs from waiting at the bottom of pits of death
// and floating levels
if ( trap_CM_PointContents( trace.endpos, 0 ) & CONTENTS_NODROP ) {
CG_FreeLocalEntity( le );
return;
}
if (!trace.startsolid)
{
// leave a mark
CG_FragmentBounceMark( le, &trace );
// do a bouncy sound
CG_FragmentBounceSound( le, &trace );
if (le->bounceSound)
{ //specified bounce sound (debris)
trap_S_StartSound(le->pos.trBase, ENTITYNUM_WORLD, CHAN_AUTO, le->bounceSound);
}
// reflect the velocity on the trace plane
CG_ReflectVelocity( le, &trace );
trap_R_AddRefEntityToScene( &le->refEntity );
}
}
/*
====================
CG_AddKamikaze
====================
*/
void CG_AddKamikaze( localEntity_t *le ) {
refEntity_t *re;
refEntity_t shockwave;
float c;
vec3_t test, axis[3];
int t;
re = &le->refEntity;
t = cg.time - le->startTime;
VectorClear( test );
AnglesToAxis( test, axis );
if (t > KAMI_SHOCKWAVE_STARTTIME && t < KAMI_SHOCKWAVE_ENDTIME) {
if (!(le->leFlags & LEF_SOUND1)) {
// trap_S_StartSound (re->origin, ENTITYNUM_WORLD, CHAN_AUTO, cgs.media.kamikazeExplodeSound );
trap_S_StartLocalSound(cgs.media.kamikazeExplodeSound, CHAN_AUTO);
le->leFlags |= LEF_SOUND1;
}
// 1st kamikaze shockwave
memset(&shockwave, 0, sizeof(shockwave));
shockwave.hModel = cgs.media.kamikazeShockWave;
shockwave.reType = RT_MODEL;
shockwave.shaderTime = re->shaderTime;
VectorCopy(re->origin, shockwave.origin);
c = (float)(t - KAMI_SHOCKWAVE_STARTTIME) / (float)(KAMI_SHOCKWAVE_ENDTIME - KAMI_SHOCKWAVE_STARTTIME);
VectorScale( axis[0], c * KAMI_SHOCKWAVE_MAXRADIUS / KAMI_SHOCKWAVEMODEL_RADIUS, shockwave.axis[0] );
VectorScale( axis[1], c * KAMI_SHOCKWAVE_MAXRADIUS / KAMI_SHOCKWAVEMODEL_RADIUS, shockwave.axis[1] );
VectorScale( axis[2], c * KAMI_SHOCKWAVE_MAXRADIUS / KAMI_SHOCKWAVEMODEL_RADIUS, shockwave.axis[2] );
shockwave.nonNormalizedAxes = qtrue;
if (t > KAMI_SHOCKWAVEFADE_STARTTIME) {
c = (float)(t - KAMI_SHOCKWAVEFADE_STARTTIME) / (float)(KAMI_SHOCKWAVE_ENDTIME - KAMI_SHOCKWAVEFADE_STARTTIME);
}
else {
c = 0;
}
c *= 0xff;
shockwave.shaderRGBA[0] = 0xff - c;
shockwave.shaderRGBA[1] = 0xff - c;
shockwave.shaderRGBA[2] = 0xff - c;
shockwave.shaderRGBA[3] = 0xff - c;
trap_R_AddRefEntityToScene( &shockwave );
}
if (t > KAMI_EXPLODE_STARTTIME && t < KAMI_IMPLODE_ENDTIME) {
// explosion and implosion
c = ( le->endTime - cg.time ) * le->lifeRate;
c *= 0xff;
re->shaderRGBA[0] = le->color[0] * c;
re->shaderRGBA[1] = le->color[1] * c;
re->shaderRGBA[2] = le->color[2] * c;
re->shaderRGBA[3] = le->color[3] * c;
if( t < KAMI_IMPLODE_STARTTIME ) {
c = (float)(t - KAMI_EXPLODE_STARTTIME) / (float)(KAMI_IMPLODE_STARTTIME - KAMI_EXPLODE_STARTTIME);
}
else {
if (!(le->leFlags & LEF_SOUND2)) {
// trap_S_StartSound (re->origin, ENTITYNUM_WORLD, CHAN_AUTO, cgs.media.kamikazeImplodeSound );
trap_S_StartLocalSound(cgs.media.kamikazeImplodeSound, CHAN_AUTO);
le->leFlags |= LEF_SOUND2;
}
c = (float)(KAMI_IMPLODE_ENDTIME - t) / (float) (KAMI_IMPLODE_ENDTIME - KAMI_IMPLODE_STARTTIME);
}
VectorScale( axis[0], c * KAMI_BOOMSPHERE_MAXRADIUS / KAMI_BOOMSPHEREMODEL_RADIUS, re->axis[0] );
VectorScale( axis[1], c * KAMI_BOOMSPHERE_MAXRADIUS / KAMI_BOOMSPHEREMODEL_RADIUS, re->axis[1] );
VectorScale( axis[2], c * KAMI_BOOMSPHERE_MAXRADIUS / KAMI_BOOMSPHEREMODEL_RADIUS, re->axis[2] );
re->nonNormalizedAxes = qtrue;
trap_R_AddRefEntityToScene( re );
// add the dlight
trap_R_AddLightToScene( re->origin, c * 1000.0, 1.0, 1.0, c );
}
if (t > KAMI_SHOCKWAVE2_STARTTIME && t < KAMI_SHOCKWAVE2_ENDTIME) {
// 2nd kamikaze shockwave
if (le->angles.trBase[0] == 0 &&
le->angles.trBase[1] == 0 &&
le->angles.trBase[2] == 0) {
le->angles.trBase[0] = random() * 360;
le->angles.trBase[1] = random() * 360;
le->angles.trBase[2] = random() * 360;
}
else {
c = 0;
}
memset(&shockwave, 0, sizeof(shockwave));
shockwave.hModel = cgs.media.kamikazeShockWave;
shockwave.reType = RT_MODEL;
shockwave.shaderTime = re->shaderTime;
VectorCopy(re->origin, shockwave.origin);
test[0] = le->angles.trBase[0];
test[1] = le->angles.trBase[1];
test[2] = le->angles.trBase[2];
AnglesToAxis( test, axis );
c = (float)(t - KAMI_SHOCKWAVE2_STARTTIME) / (float)(KAMI_SHOCKWAVE2_ENDTIME - KAMI_SHOCKWAVE2_STARTTIME);
VectorScale( axis[0], c * KAMI_SHOCKWAVE2_MAXRADIUS / KAMI_SHOCKWAVEMODEL_RADIUS, shockwave.axis[0] );
VectorScale( axis[1], c * KAMI_SHOCKWAVE2_MAXRADIUS / KAMI_SHOCKWAVEMODEL_RADIUS, shockwave.axis[1] );
VectorScale( axis[2], c * KAMI_SHOCKWAVE2_MAXRADIUS / KAMI_SHOCKWAVEMODEL_RADIUS, shockwave.axis[2] );
shockwave.nonNormalizedAxes = qtrue;
if (t > KAMI_SHOCKWAVE2FADE_STARTTIME) {
c = (float)(t - KAMI_SHOCKWAVE2FADE_STARTTIME) / (float)(KAMI_SHOCKWAVE2_ENDTIME - KAMI_SHOCKWAVE2FADE_STARTTIME);
}
else {
c = 0;
}
c *= 0xff;
shockwave.shaderRGBA[0] = 0xff - c;
shockwave.shaderRGBA[1] = 0xff - c;
shockwave.shaderRGBA[2] = 0xff - c;
shockwave.shaderRGBA[3] = 0xff - c;
trap_R_AddRefEntityToScene( &shockwave );
}
}
/*
===============
CG_LightningBolt
Origin will be the exact tag point, which is slightly
different than the muzzle point used for determining hits.
The cent should be the non-predicted cent if it is from the player,
so the endpoint will reflect the simulated strike (lagging the predicted
angle)
===============
*/
static void CG_LightningBolt( centity_t *cent, vec3_t origin, int viewHeight ) {
trace_t trace;
refEntity_t beam;
vec3_t forward;
vec3_t muzzlePoint, endPoint;
fxParent_t fxParent;
if (cent->currentState.weapon != WP_LIGHTNING) {
return;
}
memset( &beam, 0, sizeof( beam ) );
// CPMA "true" lightning
if (cg.playerCent && (cent->currentState.number == cg.playerCent->currentState.number) && (cg_trueLightning.value != 0)) {
vec3_t angle;
int i;
for (i = 0; i < 3; i++) {
float a = cent->lerpAngles[i] - cg.refdefViewAngles[i];
if (a > 180) {
a -= 360;
}
if (a < -180) {
a += 360;
}
angle[i] = cg.refdefViewAngles[i] + a * (1.0 - cg_trueLightning.value);
if (angle[i] < 0) {
angle[i] += 360;
}
if (angle[i] > 360) {
angle[i] -= 360;
}
}
AngleVectors(angle, forward, NULL, NULL );
VectorCopy(cent->lerpOrigin, muzzlePoint );
// VectorCopy(cg.refdef.vieworg, muzzlePoint );
} else {
// !CPMA
AngleVectors( cent->lerpAngles, forward, NULL, NULL );
VectorCopy(cent->lerpOrigin, muzzlePoint );
}
// FIXME: crouch
//Cana viewheight fix
// muzzlePoint[2] += DEFAULT_VIEWHEIGHT;
muzzlePoint[2] += viewHeight;
VectorMA( muzzlePoint, 14, forward, muzzlePoint );
// project forward by the lightning range
VectorMA( muzzlePoint, LIGHTNING_RANGE, forward, endPoint );
// see if it hit a wall
CG_Trace( &trace, muzzlePoint, vec3_origin, vec3_origin, endPoint,
cent->currentState.number, MASK_SHOT );
#if 1
VectorCopy( origin, fxParent.origin );
VectorSubtract( trace.endpos, origin, fxParent.dir );
fxParent.flags = FXP_ORIGIN | FXP_DIR;
trap_FX_Run( cgs.fx.lightning.trail, &fxParent, cent );
#else
// this is the endpoint
VectorCopy( trace.endpos, beam.oldorigin );
// use the provided origin, even though it may be slightly
// different than the muzzle origin
VectorCopy( origin, beam.origin );
beam.reType = RT_LIGHTNING;
beam.customShader = cgs.media.lightningShader;
trap_R_AddRefEntityToScene( &beam );
// add the impact flare if it hit something
if ( trace.fraction < 1.0 ) {
vec3_t angles;
vec3_t dir;
VectorSubtract( beam.oldorigin, beam.origin, dir );
VectorNormalize( dir );
memset( &beam, 0, sizeof( beam ) );
beam.hModel = cgs.media.lightningExplosionModel;
VectorMA( trace.endpos, -16, dir, beam.origin );
// make a random orientation
angles[0] = rand() % 360;
angles[1] = rand() % 360;
angles[2] = rand() % 360;
AnglesToAxis( angles, beam.axis );
trap_R_AddRefEntityToScene( &beam );
}
#endif
}
/*
* CG_SkeletalPoseGetAttachment
* Get the tag from the interpolated and transformed pose
*/
qboolean CG_SkeletalPoseGetAttachment( orientation_t *orient, cgs_skeleton_t *skel, bonepose_t *boneposes, char *bonename )
{
int i;
quat_t quat;
cgs_bone_t *bone;
bonepose_t *bonepose;
cg_tagmask_t *tagmask;
if( !boneposes || !skel )
{
CG_Printf( "CG_SkeletalPoseLerpAttachment: Wrong model or boneposes %s\n", bonename );
return qfalse;
}
tagmask = CG_TagMask( bonename, skel );
// find the appropriate attachment bone
if( tagmask )
{
bone = skel->bones;
for( i = 0; i < skel->numBones; i++, bone++ )
{
if( !Q_stricmp( bone->name, tagmask->bonename ) )
break;
}
}
else
{
bone = skel->bones;
for( i = 0; i < skel->numBones; i++, bone++ )
{
if( !Q_stricmp( bone->name, bonename ) )
break;
}
}
if( i == skel->numBones )
{
CG_Printf( "CG_SkeletalPoseLerpAttachment: no such bone %s\n", bonename );
return qfalse;
}
// get the desired bone
bonepose = boneposes + i;
// copy the inverted bone into the tag
Quat_Inverse( &bonepose->dualquat[0], quat ); // inverse the tag direction
Quat_Matrix( quat, orient->axis );
DualQuat_GetVector( bonepose->dualquat, orient->origin );
// normalize each axis
for( i = 0; i < 3; i++ )
VectorNormalizeFast( orient->axis[i] );
// do the offseting if having a tagmask
if( tagmask )
{
// we want to place a rotated model over this tag, not to rotate the tag,
// because all rotations would move. So we create a new orientation for the
// model and we position the new orientation in tag space
if( tagmask->rotate[YAW] || tagmask->rotate[PITCH] || tagmask->rotate[ROLL] )
{
orientation_t modOrient, newOrient;
VectorCopy( tagmask->offset, modOrient.origin );
AnglesToAxis( tagmask->rotate, modOrient.axis );
VectorCopy( vec3_origin, newOrient.origin );
Matrix_Identity( newOrient.axis );
CG_MoveToTag( newOrient.origin, newOrient.axis,
orient->origin, orient->axis,
modOrient.origin, modOrient.axis
);
Matrix_Copy( newOrient.axis, orient->axis );
VectorCopy( newOrient.origin, orient->origin );
}
else
{
// offset
for( i = 0; i < 3; i++ )
{
if( tagmask->offset[i] )
VectorMA( orient->origin, tagmask->offset[i], orient->axis[i], orient->origin );
}
}
}
return qtrue;
}
/*
===============
Main_MenuDraw
===============
*/
static void Main_MenuDraw( void ) {
refdef_t refdef;
refEntity_t ent;
vec3_t origin;
vec3_t angles;
float adjust;
float x, y, w, h;
vec4_t color = {0.5, 0, 0, 1};
// setup the refdef
memset( &refdef, 0, sizeof( refdef ) );
refdef.rdflags = RDF_NOWORLDMODEL;
AxisClear( refdef.viewaxis );
x = 0;
y = 0;
w = 640;
h = 120;
UI_AdjustFrom640( &x, &y, &w, &h );
refdef.x = x;
refdef.y = y;
refdef.width = w;
refdef.height = h;
adjust = 0; // JDC: Kenneth asked me to stop this 1.0 * sin( (float)uis.realtime / 1000 );
refdef.fov_x = 70 + adjust;
refdef.fov_y = 19.6875 + adjust;
refdef.time = uis.realtime;
origin[0] = 300;
origin[1] = 0;
origin[2] = -32;
trap_R_ClearScene();
// add the model
memset( &ent, 0, sizeof(ent) );
adjust = 20.0 * sin( (float)uis.realtime / 3000 );
VectorSet( angles, 0, 180 + adjust, 0 );
AnglesToAxis( angles, ent.axis );
ent.hModel = s_main.bannerModel;
VectorCopy( origin, ent.origin );
VectorCopy( origin, ent.lightingOrigin );
ent.renderfx = RF_LIGHTING_ORIGIN | RF_NOSHADOW;
VectorCopy( ent.origin, ent.oldorigin );
trap_R_AddRefEntityToScene( &ent );
// standard menu drawing
Menu_Draw( &s_main.menu );
trap_R_RenderScene( &refdef );
/* if (uis.demoversion) {
UI_DrawProportionalString( 320, 372, "DEMO FOR MATURE AUDIENCES DEMO", UI_CENTER|UI_SMALLFONT, color );
UI_DrawString( 320, 400, "Quake III Arena(c) 1999-2000, Id Software, Inc. All Rights Reserved", UI_CENTER|UI_SMALLFONT, color );
} else {
UI_DrawString( 320, 450, "Quake III Arena(c) 1999-2000, Id Software, Inc. All Rights Reserved", UI_CENTER|UI_SMALLFONT, color );
}*/
}
static void CG_PlasmaTrail( centity_t *cent, const weaponInfo_t *wi ) {
localEntity_t *le;
refEntity_t *re;
entityState_t *es;
vec3_t velocity, xvelocity, origin;
vec3_t offset, xoffset;
vec3_t v[3];
int t, startTime, step;
float waterScale = 1.0f;
if ( cg_noProjectileTrail.integer || cg_oldPlasma.integer ) {
return;
}
step = 50;
es = ¢->currentState;
startTime = cent->trailTime;
t = step * ( (startTime + step) / step );
BG_EvaluateTrajectory( &es->pos, cg.time, origin );
le = CG_AllocLocalEntity();
re = &le->refEntity;
velocity[0] = 60 - 120 * crandom();
velocity[1] = 40 - 80 * crandom();
velocity[2] = 100 - 200 * crandom();
le->leType = LE_MOVE_SCALE_FADE;
le->leFlags = LEF_TUMBLE;
le->leBounceSoundType = LEBS_NONE;
le->leMarkType = LEMT_NONE;
le->startTime = cg.time;
le->endTime = le->startTime + 600;
le->pos.trType = TR_GRAVITY;
le->pos.trTime = cg.time;
AnglesToAxis( cent->lerpAngles, v );
offset[0] = 2;
offset[1] = 2;
offset[2] = 2;
xoffset[0] = offset[0] * v[0][0] + offset[1] * v[1][0] + offset[2] * v[2][0];
xoffset[1] = offset[0] * v[0][1] + offset[1] * v[1][1] + offset[2] * v[2][1];
xoffset[2] = offset[0] * v[0][2] + offset[1] * v[1][2] + offset[2] * v[2][2];
VectorAdd( origin, xoffset, re->origin );
VectorCopy( re->origin, le->pos.trBase );
if ( CG_PointContents( re->origin, -1 ) & CONTENTS_WATER ) {
waterScale = 0.10f;
}
xvelocity[0] = velocity[0] * v[0][0] + velocity[1] * v[1][0] + velocity[2] * v[2][0];
xvelocity[1] = velocity[0] * v[0][1] + velocity[1] * v[1][1] + velocity[2] * v[2][1];
xvelocity[2] = velocity[0] * v[0][2] + velocity[1] * v[1][2] + velocity[2] * v[2][2];
VectorScale( xvelocity, waterScale, le->pos.trDelta );
AxisCopy( axisDefault, re->axis );
re->shaderTime = cg.time / 1000.0f;
re->reType = RT_SPRITE;
re->radius = 0.25f;
re->customShader = cgs.media.railRingsShader;
le->bounceFactor = 0.3f;
re->shaderRGBA[0] = wi->flashDlightColor[0] * 63;
re->shaderRGBA[1] = wi->flashDlightColor[1] * 63;
re->shaderRGBA[2] = wi->flashDlightColor[2] * 63;
re->shaderRGBA[3] = 63;
le->color[0] = wi->flashDlightColor[0] * 0.2;
le->color[1] = wi->flashDlightColor[1] * 0.2;
le->color[2] = wi->flashDlightColor[2] * 0.2;
le->color[3] = 0.25f;
le->angles.trType = TR_LINEAR;
le->angles.trTime = cg.time;
le->angles.trBase[0] = rand()&31;
le->angles.trBase[1] = rand()&31;
le->angles.trBase[2] = rand()&31;
le->angles.trDelta[0] = 1;
le->angles.trDelta[1] = 0.5;
le->angles.trDelta[2] = 0;
}
/*
=================
R_LoadMDC
=================
*/
qboolean R_LoadMDC(model_t * mod, int lod, void *buffer, int bufferSize, const char *modName)
{
int i, j, k, l;
mdcHeader_t *mdcModel;
md3Frame_t *mdcFrame;
mdcSurface_t *mdcSurf;
md3Shader_t *mdcShader;
md3Triangle_t *mdcTri;
md3St_t *mdcst;
md3XyzNormal_t *mdcxyz;
mdcXyzCompressed_t *mdcxyzComp;
mdcTag_t *mdcTag;
mdcTagName_t *mdcTagName;
mdvModel_t *mdvModel;
mdvFrame_t *frame;
mdvSurface_t *surf, *surface;
srfTriangle_t *tri;
mdvVertex_t *v;
mdvSt_t *st;
mdvTag_t *tag;
mdvTagName_t *tagName;
short *ps;
int version;
int size;
mdcModel = (mdcHeader_t *) buffer;
version = LittleLong(mdcModel->version);
if(version != MDC_VERSION)
{
ri.Printf(PRINT_WARNING, "R_LoadMD3: %s has wrong version (%i should be %i)\n", modName, version, MDC_VERSION);
return qfalse;
}
mod->type = MOD_MESH;
size = LittleLong(mdcModel->ofsEnd);
mod->dataSize += size;
mdvModel = mod->mdv[lod] = ri.Hunk_Alloc(sizeof(mdvModel_t), h_low);
LL(mdcModel->ident);
LL(mdcModel->version);
LL(mdcModel->numFrames);
LL(mdcModel->numTags);
LL(mdcModel->numSurfaces);
LL(mdcModel->ofsFrames);
LL(mdcModel->ofsTags);
LL(mdcModel->ofsSurfaces);
LL(mdcModel->ofsEnd);
LL(mdcModel->ofsEnd);
LL(mdcModel->flags);
LL(mdcModel->numSkins);
if(mdcModel->numFrames < 1)
{
ri.Printf(PRINT_WARNING, "R_LoadMDC: '%s' has no frames\n", modName);
return qfalse;
}
// swap all the frames
mdvModel->numFrames = mdcModel->numFrames;
mdvModel->frames = frame = ri.Hunk_Alloc(sizeof(*frame) * mdcModel->numFrames, h_low);
mdcFrame = (md3Frame_t *) ((byte *) mdcModel + mdcModel->ofsFrames);
for(i = 0; i < mdcModel->numFrames; i++, frame++, mdcFrame++)
{
#if 1
// RB: ET HACK
if(strstr(mod->name, "sherman") || strstr(mod->name, "mg42"))
{
frame->radius = 256;
for(j = 0; j < 3; j++)
{
frame->bounds[0][j] = 128;
frame->bounds[1][j] = -128;
frame->localOrigin[j] = LittleFloat(mdcFrame->localOrigin[j]);
}
}
else
#endif
{
frame->radius = LittleFloat(mdcFrame->radius);
for(j = 0; j < 3; j++)
{
frame->bounds[0][j] = LittleFloat(mdcFrame->bounds[0][j]);
frame->bounds[1][j] = LittleFloat(mdcFrame->bounds[1][j]);
frame->localOrigin[j] = LittleFloat(mdcFrame->localOrigin[j]);
}
}
}
// swap all the tags
mdvModel->numTags = mdcModel->numTags;
mdvModel->tags = tag = ri.Hunk_Alloc(sizeof(*tag) * (mdcModel->numTags * mdcModel->numFrames), h_low);
mdcTag = (mdcTag_t *) ((byte *) mdcModel + mdcModel->ofsTags);
for(i = 0; i < mdcModel->numTags * mdcModel->numFrames; i++, tag++, mdcTag++)
{
vec3_t angles;
for(j = 0; j < 3; j++)
{
tag->origin[j] = (float)LittleShort(mdcTag->xyz[j]) * MD3_XYZ_SCALE;
angles[j] = (float)LittleShort(mdcTag->angles[j]) * MDC_TAG_ANGLE_SCALE;
}
AnglesToAxis(angles, tag->axis);
}
mdvModel->tagNames = tagName = ri.Hunk_Alloc(sizeof(*tagName) * (mdcModel->numTags), h_low);
mdcTagName = (mdcTagName_t *) ((byte *) mdcModel + mdcModel->ofsTagNames);
for(i = 0; i < mdcModel->numTags; i++, tagName++, mdcTagName++)
{
Q_strncpyz(tagName->name, mdcTagName->name, sizeof(tagName->name));
}
// swap all the surfaces
mdvModel->numSurfaces = mdcModel->numSurfaces;
mdvModel->surfaces = surf = ri.Hunk_Alloc(sizeof(*surf) * mdcModel->numSurfaces, h_low);
mdcSurf = (mdcSurface_t *) ((byte *) mdcModel + mdcModel->ofsSurfaces);
for(i = 0; i < mdcModel->numSurfaces; i++)
{
LL(mdcSurf->ident);
LL(mdcSurf->flags);
LL(mdcSurf->numBaseFrames);
LL(mdcSurf->numCompFrames);
LL(mdcSurf->numShaders);
LL(mdcSurf->numTriangles);
LL(mdcSurf->ofsTriangles);
LL(mdcSurf->numVerts);
LL(mdcSurf->ofsShaders);
LL(mdcSurf->ofsSt);
LL(mdcSurf->ofsXyzNormals);
LL(mdcSurf->ofsXyzNormals);
LL(mdcSurf->ofsXyzCompressed);
LL(mdcSurf->ofsFrameBaseFrames);
LL(mdcSurf->ofsFrameCompFrames);
LL(mdcSurf->ofsEnd);
if(mdcSurf->numVerts > SHADER_MAX_VERTEXES)
{
ri.Error(ERR_DROP, "R_LoadMDC: %s has more than %i verts on a surface (%i)",
modName, SHADER_MAX_VERTEXES, mdcSurf->numVerts);
}
if(mdcSurf->numTriangles > SHADER_MAX_TRIANGLES)
{
ri.Error(ERR_DROP, "R_LoadMDC: %s has more than %i triangles on a surface (%i)",
modName, SHADER_MAX_TRIANGLES, mdcSurf->numTriangles);
}
// change to surface identifier
surf->surfaceType = SF_MDV;
// give pointer to model for Tess_SurfaceMDX
surf->model = mdvModel;
// copy surface name
Q_strncpyz(surf->name, mdcSurf->name, sizeof(surf->name));
// lowercase the surface name so skin compares are faster
Q_strlwr(surf->name);
// strip off a trailing _1 or _2
// this is a crutch for q3data being a mess
j = strlen(surf->name);
if(j > 2 && surf->name[j - 2] == '_')
{
surf->name[j - 2] = 0;
}
// register the shaders
/*
surf->numShaders = md3Surf->numShaders;
surf->shaders = shader = ri.Hunk_Alloc(sizeof(*shader) * md3Surf->numShaders, h_low);
md3Shader = (md3Shader_t *) ((byte *) md3Surf + md3Surf->ofsShaders);
for(j = 0; j < md3Surf->numShaders; j++, shader++, md3Shader++)
{
shader_t *sh;
sh = R_FindShader(md3Shader->name, SHADER_3D_DYNAMIC, qtrue);
if(sh->defaultShader)
{
shader->shaderIndex = 0;
}
else
{
shader->shaderIndex = sh->index;
}
}
*/
// only consider the first shader
mdcShader = (md3Shader_t *) ((byte *) mdcSurf + mdcSurf->ofsShaders);
surf->shader = R_FindShader(mdcShader->name, SHADER_3D_DYNAMIC, qtrue);
// swap all the triangles
surf->numTriangles = mdcSurf->numTriangles;
surf->triangles = tri = ri.Hunk_Alloc(sizeof(*tri) * mdcSurf->numTriangles, h_low);
mdcTri = (md3Triangle_t *) ((byte *) mdcSurf + mdcSurf->ofsTriangles);
for(j = 0; j < mdcSurf->numTriangles; j++, tri++, mdcTri++)
{
tri->indexes[0] = LittleLong(mdcTri->indexes[0]);
tri->indexes[1] = LittleLong(mdcTri->indexes[1]);
tri->indexes[2] = LittleLong(mdcTri->indexes[2]);
}
R_CalcSurfaceTriangleNeighbors(surf->numTriangles, surf->triangles);
// swap all the XyzNormals
mdcxyz = (md3XyzNormal_t *) ((byte *) mdcSurf + mdcSurf->ofsXyzNormals);
for(j = 0; j < mdcSurf->numVerts * mdcSurf->numBaseFrames; j++, mdcxyz++)
{
mdcxyz->xyz[0] = LittleShort(mdcxyz->xyz[0]);
mdcxyz->xyz[1] = LittleShort(mdcxyz->xyz[1]);
mdcxyz->xyz[2] = LittleShort(mdcxyz->xyz[2]);
mdcxyz->normal = LittleShort(mdcxyz->normal);
}
// swap all the XyzCompressed
mdcxyzComp = (mdcXyzCompressed_t *) ((byte *) mdcSurf + mdcSurf->ofsXyzCompressed);
for(j = 0; j < mdcSurf->numVerts * mdcSurf->numCompFrames; j++, mdcxyzComp++)
{
LL(mdcxyzComp->ofsVec);
}
// swap the frameBaseFrames
ps = (short *)((byte *) mdcSurf + mdcSurf->ofsFrameBaseFrames);
for(j = 0; j < mdcModel->numFrames; j++, ps++)
{
*ps = LittleShort(*ps);
}
// swap the frameCompFrames
ps = (short *)((byte *) mdcSurf + mdcSurf->ofsFrameCompFrames);
for(j = 0; j < mdcModel->numFrames; j++, ps++)
{
*ps = LittleShort(*ps);
}
surf->numVerts = mdcSurf->numVerts;
surf->verts = v = ri.Hunk_Alloc(sizeof(*v) * (mdcSurf->numVerts * mdcModel->numFrames), h_low);
for(j = 0; j < mdcModel->numFrames; j++)
{
int baseFrame;
int compFrame;
baseFrame = (int) *((short *)((byte *) mdcSurf + mdcSurf->ofsFrameBaseFrames) + j);
mdcxyz = (md3XyzNormal_t *)((byte *) mdcSurf + mdcSurf->ofsXyzNormals + baseFrame * mdcSurf->numVerts * sizeof(md3XyzNormal_t));
if(mdcSurf->numCompFrames > 0)
{
compFrame = (int) *((short *)((byte *) mdcSurf + mdcSurf->ofsFrameCompFrames) + j);
if(compFrame >= 0)
{
mdcxyzComp = (mdcXyzCompressed_t *) ((byte *) mdcSurf + mdcSurf->ofsXyzCompressed + compFrame * mdcSurf->numVerts * sizeof(mdcXyzCompressed_t));
}
}
for(k = 0; k < mdcSurf->numVerts; k++, v++, mdcxyz++)
{
v->xyz[0] = LittleShort(mdcxyz->xyz[0]) * MD3_XYZ_SCALE;
v->xyz[1] = LittleShort(mdcxyz->xyz[1]) * MD3_XYZ_SCALE;
v->xyz[2] = LittleShort(mdcxyz->xyz[2]) * MD3_XYZ_SCALE;
if(mdcSurf->numCompFrames > 0 && compFrame >= 0)
{
vec3_t ofsVec;
vec3_t normal;
R_MDC_DecodeXyzCompressed(LittleShort(mdcxyzComp->ofsVec), ofsVec, normal);
VectorAdd(v->xyz, ofsVec, v->xyz);
mdcxyzComp++;
}
}
}
// swap all the ST
surf->st = st = ri.Hunk_Alloc(sizeof(*st) * mdcSurf->numVerts, h_low);
mdcst = (md3St_t *) ((byte *) mdcSurf + mdcSurf->ofsSt);
for(j = 0; j < mdcSurf->numVerts; j++, mdcst++, st++)
{
st->st[0] = LittleFloat(mdcst->st[0]);
st->st[1] = LittleFloat(mdcst->st[1]);
}
// find the next surface
mdcSurf = (mdcSurface_t *) ((byte *) mdcSurf + mdcSurf->ofsEnd);
surf++;
}
#if 1
// create VBO surfaces from md3 surfaces
{
growList_t vboSurfaces;
srfVBOMDVMesh_t *vboSurf;
byte *data;
int dataSize;
int dataOfs;
vec4_t tmp;
GLuint ofsTexCoords;
GLuint ofsTangents;
GLuint ofsBinormals;
GLuint ofsNormals;
GLuint sizeXYZ;
GLuint sizeTangents;
GLuint sizeBinormals;
GLuint sizeNormals;
int vertexesNum;
int f;
Com_InitGrowList(&vboSurfaces, 10);
for(i = 0, surf = mdvModel->surfaces; i < mdvModel->numSurfaces; i++, surf++)
{
// calc tangent spaces
{
const float *v0, *v1, *v2;
const float *t0, *t1, *t2;
vec3_t tangent;
vec3_t binormal;
vec3_t normal;
for(j = 0, v = surf->verts; j < (surf->numVerts * mdvModel->numFrames); j++, v++)
{
VectorClear(v->tangent);
VectorClear(v->binormal);
VectorClear(v->normal);
}
for(f = 0; f < mdvModel->numFrames; f++)
{
for(j = 0, tri = surf->triangles; j < surf->numTriangles; j++, tri++)
{
v0 = surf->verts[surf->numVerts * f + tri->indexes[0]].xyz;
v1 = surf->verts[surf->numVerts * f + tri->indexes[1]].xyz;
v2 = surf->verts[surf->numVerts * f + tri->indexes[2]].xyz;
t0 = surf->st[tri->indexes[0]].st;
t1 = surf->st[tri->indexes[1]].st;
t2 = surf->st[tri->indexes[2]].st;
#if 1
R_CalcTangentSpace(tangent, binormal, normal, v0, v1, v2, t0, t1, t2);
#else
R_CalcNormalForTriangle(normal, v0, v1, v2);
R_CalcTangentsForTriangle(tangent, binormal, v0, v1, v2, t0, t1, t2);
#endif
for(k = 0; k < 3; k++)
{
float *v;
v = surf->verts[surf->numVerts * f + tri->indexes[k]].tangent;
VectorAdd(v, tangent, v);
v = surf->verts[surf->numVerts * f + tri->indexes[k]].binormal;
VectorAdd(v, binormal, v);
v = surf->verts[surf->numVerts * f + tri->indexes[k]].normal;
VectorAdd(v, normal, v);
}
}
}
for(j = 0, v = surf->verts; j < (surf->numVerts * mdvModel->numFrames); j++, v++)
{
VectorNormalize(v->tangent);
VectorNormalize(v->binormal);
VectorNormalize(v->normal);
}
}
//ri.Printf(PRINT_ALL, "...calculating MDC mesh VBOs ( '%s', %i verts %i tris )\n", surf->name, surf->numVerts, surf->numTriangles);
// create surface
vboSurf = ri.Hunk_Alloc(sizeof(*vboSurf), h_low);
Com_AddToGrowList(&vboSurfaces, vboSurf);
vboSurf->surfaceType = SF_VBO_MDVMESH;
vboSurf->mdvModel = mdvModel;
vboSurf->mdvSurface = surf;
vboSurf->numIndexes = surf->numTriangles * 3;
vboSurf->numVerts = surf->numVerts;
/*
vboSurf->vbo = R_CreateVBO2(va("staticWorldMesh_vertices %i", vboSurfaces.currentElements), numVerts, optimizedVerts,
ATTR_POSITION | ATTR_TEXCOORD | ATTR_LIGHTCOORD | ATTR_TANGENT | ATTR_BINORMAL | ATTR_NORMAL
| ATTR_COLOR);
*/
vboSurf->ibo = R_CreateIBO2(va("staticMDCMesh_IBO %s", surf->name), surf->numTriangles, surf->triangles, VBO_USAGE_STATIC);
// create VBO
vertexesNum = surf->numVerts;
dataSize = (surf->numVerts * mdvModel->numFrames * sizeof(vec4_t) * 4) + // xyz, tangent, binormal, normal
(surf->numVerts * sizeof(vec4_t)); // texcoords
data = ri.Malloc(dataSize);
dataOfs = 0;
// feed vertex XYZ
for(f = 0; f < mdvModel->numFrames; f++)
{
for(j = 0; j < vertexesNum; j++)
{
for(k = 0; k < 3; k++)
{
tmp[k] = surf->verts[f * vertexesNum + j].xyz[k];
}
tmp[3] = 1;
Com_Memcpy(data + dataOfs, (vec_t *) tmp, sizeof(vec4_t));
dataOfs += sizeof(vec4_t);
}
if(f == 0)
{
sizeXYZ = dataOfs;
}
}
// feed vertex texcoords
ofsTexCoords = dataOfs;
for(j = 0; j < vertexesNum; j++)
{
for(k = 0; k < 2; k++)
{
tmp[k] = surf->st[j].st[k];
}
tmp[2] = 0;
tmp[3] = 1;
Com_Memcpy(data + dataOfs, (vec_t *) tmp, sizeof(vec4_t));
dataOfs += sizeof(vec4_t);
}
// feed vertex tangents
ofsTangents = dataOfs;
for(f = 0; f < mdvModel->numFrames; f++)
{
for(j = 0; j < vertexesNum; j++)
{
for(k = 0; k < 3; k++)
{
tmp[k] = surf->verts[f * vertexesNum + j].tangent[k];
}
tmp[3] = 1;
Com_Memcpy(data + dataOfs, (vec_t *) tmp, sizeof(vec4_t));
dataOfs += sizeof(vec4_t);
}
if(f == 0)
{
sizeTangents = dataOfs - ofsTangents;
}
}
// feed vertex binormals
ofsBinormals = dataOfs;
for(f = 0; f < mdvModel->numFrames; f++)
{
for(j = 0; j < vertexesNum; j++)
{
for(k = 0; k < 3; k++)
{
tmp[k] = surf->verts[f * vertexesNum + j].binormal[k];
}
tmp[3] = 1;
Com_Memcpy(data + dataOfs, (vec_t *) tmp, sizeof(vec4_t));
dataOfs += sizeof(vec4_t);
}
if(f == 0)
{
sizeBinormals = dataOfs - ofsBinormals;
}
}
// feed vertex normals
ofsNormals = dataOfs;
for(f = 0; f < mdvModel->numFrames; f++)
{
for(j = 0; j < vertexesNum; j++)
{
for(k = 0; k < 3; k++)
{
tmp[k] = surf->verts[f * vertexesNum + j].normal[k];
}
tmp[3] = 1;
Com_Memcpy(data + dataOfs, (vec_t *) tmp, sizeof(vec4_t));
dataOfs += sizeof(vec4_t);
}
if(f == 0)
{
sizeNormals = dataOfs - ofsNormals;
}
}
vboSurf->vbo = R_CreateVBO(va("staticMDCMesh_VBO '%s'", surf->name), data, dataSize, VBO_USAGE_STATIC);
vboSurf->vbo->ofsXYZ = 0;
vboSurf->vbo->ofsTexCoords = ofsTexCoords;
vboSurf->vbo->ofsLightCoords = ofsTexCoords;
vboSurf->vbo->ofsTangents = ofsTangents;
vboSurf->vbo->ofsBinormals = ofsBinormals;
vboSurf->vbo->ofsNormals = ofsNormals;
vboSurf->vbo->sizeXYZ = sizeXYZ;
vboSurf->vbo->sizeTangents = sizeTangents;
vboSurf->vbo->sizeBinormals = sizeBinormals;
vboSurf->vbo->sizeNormals = sizeNormals;
ri.Free(data);
}
// move VBO surfaces list to hunk
mdvModel->numVBOSurfaces = vboSurfaces.currentElements;
mdvModel->vboSurfaces = ri.Hunk_Alloc(mdvModel->numVBOSurfaces * sizeof(*mdvModel->vboSurfaces), h_low);
for(i = 0; i < mdvModel->numVBOSurfaces; i++)
{
mdvModel->vboSurfaces[i] = (srfVBOMDVMesh_t *) Com_GrowListElement(&vboSurfaces, i);
}
Com_DestroyGrowList(&vboSurfaces);
}
#endif
return qtrue;
}
void CGCam_Update( void )
{
int i;
qboolean checkFollow = qfalse;
qboolean checkTrack = qfalse;
// Apply new roff data to the camera as needed
if ( client_camera.info_state & CAMERA_ROFFING )
{
CGCam_Roff();
}
//Check for a zoom
if (client_camera.info_state & CAMERA_ACCEL)
{
// x = x0 + vt + 0.5*a*t*t
float actualFOV_X = client_camera.FOV;
float sanityMin = 1, sanityMax = 180;
float t = (cg.time - client_camera.FOV_time)*0.001; // mult by 0.001 cuz otherwise t is too darned big
float fovDuration = client_camera.FOV_duration;
#ifndef FINAL_BUILD
if (cg_roffval4.integer)
{
fovDuration = cg_roffval4.integer;
}
#endif
if ( client_camera.FOV_time + fovDuration < cg.time )
{
client_camera.info_state &= ~CAMERA_ACCEL;
}
else
{
float initialPosVal = client_camera.FOV2;
float velVal = client_camera.FOV_vel;
float accVal = client_camera.FOV_acc;
#ifndef FINAL_BUILD
if (cg_roffdebug.integer)
{
if (fabs(cg_roffval1.value) > 0.001f)
{
initialPosVal = cg_roffval1.value;
}
if (fabs(cg_roffval2.value) > 0.001f)
{
velVal = cg_roffval2.value;
}
if (fabs(cg_roffval3.value) > 0.001f)
{
accVal = cg_roffval3.value;
}
}
#endif
float initialPos = initialPosVal;
float vel = velVal*t;
float acc = 0.5*accVal*t*t;
actualFOV_X = initialPos + vel + acc;
if (cg_roffdebug.integer)
{
Com_Printf("%d: fovaccel from %2.1f using vel = %2.4f, acc = %2.4f (current fov calc = %5.6f)\n",
cg.time, initialPosVal, velVal, accVal, actualFOV_X);
}
if (actualFOV_X < sanityMin)
{
actualFOV_X = sanityMin;
}
else if (actualFOV_X > sanityMax)
{
actualFOV_X = sanityMax;
}
client_camera.FOV = actualFOV_X;
}
CG_CalcFOVFromX( actualFOV_X );
}
else if ( client_camera.info_state & CAMERA_ZOOMING )
{
float actualFOV_X;
if ( client_camera.FOV_time + client_camera.FOV_duration < cg.time )
{
actualFOV_X = client_camera.FOV = client_camera.FOV2;
client_camera.info_state &= ~CAMERA_ZOOMING;
}
else
{
actualFOV_X = client_camera.FOV + (( ( client_camera.FOV2 - client_camera.FOV ) ) / client_camera.FOV_duration ) * ( cg.time - client_camera.FOV_time );
}
CG_CalcFOVFromX( actualFOV_X );
}
else
{
CG_CalcFOVFromX( client_camera.FOV );
}
//Check for roffing angles
if ( (client_camera.info_state & CAMERA_ROFFING) && !(client_camera.info_state & CAMERA_FOLLOWING) )
{
if (client_camera.info_state & CAMERA_CUT)
{
// we're doing a cut, so just go to the new angles. none of this hifalutin lerping business.
for ( i = 0; i < 3; i++ )
{
cg.refdefViewAngles[i] = AngleNormalize360( ( client_camera.angles[i] + client_camera.angles2[i] ) );
}
}
else
{
for ( i = 0; i < 3; i++ )
{
cg.refdefViewAngles[i] = client_camera.angles[i] + ( client_camera.angles2[i] / client_camera.pan_duration ) * ( cg.time - client_camera.pan_time );
}
}
}
else if ( client_camera.info_state & CAMERA_PANNING )
{
if (client_camera.info_state & CAMERA_CUT)
{
// we're doing a cut, so just go to the new angles. none of this hifalutin lerping business.
for ( i = 0; i < 3; i++ )
{
cg.refdefViewAngles[i] = AngleNormalize360( ( client_camera.angles[i] + client_camera.angles2[i] ) );
}
}
else
{
//Note: does not actually change the camera's angles until the pan time is done!
if ( client_camera.pan_time + client_camera.pan_duration < cg.time )
{//finished panning
for ( i = 0; i < 3; i++ )
{
client_camera.angles[i] = AngleNormalize360( ( client_camera.angles[i] + client_camera.angles2[i] ) );
}
client_camera.info_state &= ~CAMERA_PANNING;
VectorCopy(client_camera.angles, cg.refdefViewAngles );
}
else
{//still panning
for ( i = 0; i < 3; i++ )
{
//NOTE: does not store the resultant angle in client_camera.angles until pan is done
cg.refdefViewAngles[i] = client_camera.angles[i] + ( client_camera.angles2[i] / client_camera.pan_duration ) * ( cg.time - client_camera.pan_time );
}
}
}
}
else
{
checkFollow = qtrue;
}
//Check for movement
if ( client_camera.info_state & CAMERA_MOVING )
{
//NOTE: does not actually move the camera until the movement time is done!
if ( client_camera.move_time + client_camera.move_duration < cg.time )
{
VectorCopy( client_camera.origin2, client_camera.origin );
client_camera.info_state &= ~CAMERA_MOVING;
VectorCopy( client_camera.origin, cg.refdef.vieworg );
}
else
{
if (client_camera.info_state & CAMERA_CUT)
{
// we're doing a cut, so just go to the new origin. none of this fancypants lerping stuff.
for ( i = 0; i < 3; i++ )
{
cg.refdef.vieworg[i] = client_camera.origin2[i];
}
}
else
{
for ( i = 0; i < 3; i++ )
{
cg.refdef.vieworg[i] = client_camera.origin[i] + (( ( client_camera.origin2[i] - client_camera.origin[i] ) ) / client_camera.move_duration ) * ( cg.time - client_camera.move_time );
}
}
}
}
else
{
checkTrack = qtrue;
}
if ( checkFollow )
{
if ( client_camera.info_state & CAMERA_FOLLOWING )
{//This needs to be done after camera movement
CGCam_FollowUpdate();
}
VectorCopy(client_camera.angles, cg.refdefViewAngles );
}
if ( checkTrack )
{
if ( client_camera.info_state & CAMERA_TRACKING )
{//This has to run AFTER Follow if the camera is following a cameraGroup
CGCam_TrackUpdate();
}
VectorCopy( client_camera.origin, cg.refdef.vieworg );
}
//Bar fading
if ( client_camera.info_state & CAMERA_BAR_FADING )
{
CGCam_UpdateBarFade();
}
//Normal fading - separate call because can finish after camera is disabled
CGCam_UpdateFade();
//Update shaking if there's any
//CGCam_UpdateSmooth( cg.refdef.vieworg, cg.refdefViewAngles );
CGCam_UpdateShake( cg.refdef.vieworg, cg.refdefViewAngles );
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
}
void Wolfcam_AddViewWeapon (void)
{
vec3_t origin;
centity_t *cent;
const entityState_t *es;
refEntity_t hand;
const clientInfo_t *ci;
float fovOffset;
vec3_t angles;
const weaponInfo_t *weapon;
float gunX;
int fov;
if (!wolfcam_following) {
return;
}
cent = &cg_entities[wcg.clientNum];
es = ¢->currentState;
if (!cg_drawGun.integer) {
if (es->eFlags & EF_FIRING && es->weapon == WP_LIGHTNING) {
// special hack for lightning gun...
VectorCopy( cg.refdef.vieworg, origin );
VectorMA( origin, -8, cg.refdef.viewaxis[2], origin );
CG_LightningBolt( &cg_entities[es->number], origin );
//FIXME is this adding the sound twice?
CG_AddLoopingSound( cent->currentState.number, cent->lerpOrigin, vec3_origin, cg_weapons[es->weapon].firingSound );
}
return;
}
// don't draw if testing a gun model
if (cg.testGun) {
return;
}
gunX = cg_gun_x.value;
if (es->weapon == WP_GRAPPLING_HOOK) {
gunX += 8.9;
}
fov = cg_fov.integer;
//FIXME option
// drop gun lower at higher fov
if (fov > 90) {
fovOffset = -0.2 * (fov - 90);
} else {
fovOffset = 0;
}
CG_RegisterWeapon(es->weapon);
weapon = &cg_weapons[es->weapon];
memset(&hand, 0, sizeof(hand));
// set up gun position
Wolfcam_CalculateWeaponPosition(hand.origin, angles);
VectorMA( hand.origin, gunX, cg.refdef.viewaxis[0], hand.origin );
VectorMA( hand.origin, cg_gun_y.value, cg.refdef.viewaxis[1], hand.origin );
VectorMA( hand.origin, (cg_gun_z.value+fovOffset), cg.refdef.viewaxis[2], hand.origin );
AnglesToAxis( angles, hand.axis );
// map torso animations to weapon animations
//cg_gun_frame.integer = 1;
if ( cg_gun_frame.integer ) {
// development tool
hand.frame = hand.oldframe = cg_gun_frame.integer;
hand.backlerp = 0;
} else { //if (0) {
// these are just for calling CG_PlayerAnimation()
int legsOld;
int legs;
float legsBackLerp;
int torsoOld;
int torso;
float torsoBackLerp;
// get clientinfo for animation map
ci = &cgs.clientinfo[ cent->currentState.clientNum ];
// animations weren't run for /follow'ed player
CG_PlayerAnimation(cent, &legsOld, &legs, &legsBackLerp, &torsoOld, &torso, &torsoBackLerp);
hand.frame = CG_MapTorsoToWeaponFrame( ci, cent->pe.torso.frame );
hand.oldframe = CG_MapTorsoToWeaponFrame( ci, cent->pe.torso.oldFrame );
hand.backlerp = cent->pe.torso.backlerp;
}
hand.hModel = weapon->handsModel;
hand.renderfx = RF_DEPTHHACK | RF_FIRST_PERSON | RF_MINLIGHT;
// add everything onto the hand
Wolfcam_AddPlayerWeapon(&hand, cent, cgs.clientinfo[cent->currentState.clientNum].team);
}
//----------------------------
void CEmitter::UpdateAngles()
{
VectorMA( mAngles, theFxHelper.mFrameTime * 0.01f, mAngleDelta, mAngles ); // was 0.001f, but then you really have to jack up the delta to even notice anything
AnglesToAxis( mAngles, mRefEnt.axis );
}
void Wolfcam_AddPlayerWeapon (const refEntity_t *parent, centity_t *cent, int team)
{
refEntity_t gun;
refEntity_t barrel;
refEntity_t flash;
vec3_t angles;
weapon_t weaponNum;
const weaponInfo_t *weapon;
centity_t *nonPredictedCent;
// int col
clientInfo_t *ci;
float flashSize;
float dlight[3];
float f;
qboolean revertColors = qfalse;
vec3_t origColor1;
vec3_t origColor2;
if (!cent->inCurrentSnapshot) {
// this can happen with /follow which can stay in victim position
// (frag hover)
return;
}
ci = &cgs.clientinfo[ cent->currentState.clientNum ];
weaponNum = cent->currentState.weapon;
if (weaponNum <= WP_NONE || weaponNum >= WP_NUM_WEAPONS) {
return;
}
CG_RegisterWeapon( weaponNum );
weapon = &cg_weapons[weaponNum];
// add the weapon
memset( &gun, 0, sizeof( gun ) );
VectorCopy( parent->lightingOrigin, gun.lightingOrigin );
gun.shadowPlane = parent->shadowPlane;
gun.renderfx = parent->renderfx;
// set custom shading for railgun refire rate
if (0) { //( ps ) {
} else {
if (weaponNum == WP_RAILGUN) {
qboolean teamRail;
qboolean enemyRail;
if (cg_railUseOwnColors.integer && CG_IsUs(ci)) {
VectorCopy(ci->color1, origColor1);
VectorCopy(ci->color2, origColor2);
VectorCopy(cg.color1, ci->color1);
VectorCopy(cg.color2, ci->color2);
revertColors = qtrue;
}
teamRail = CG_IsTeammate(ci);
enemyRail = CG_IsEnemy(ci);
if (cgs.gametype < GT_TEAM) {
if (!CG_IsUs(ci)) {
if (*cg_enemyRailItemColor.string) {
SC_ByteVec3ColorFromCvar(gun.shaderRGBA, &cg_enemyRailItemColor);
gun.shaderRGBA[3] = 255;
} else {
gun.shaderRGBA[0] = 255 * ci->color1[0];
gun.shaderRGBA[1] = 255 * ci->color1[1];
gun.shaderRGBA[2] = 255 * ci->color1[2];
gun.shaderRGBA[3] = 255;
}
} else {
gun.shaderRGBA[0] = 255 * ci->color1[0];
gun.shaderRGBA[1] = 255 * ci->color1[1];
gun.shaderRGBA[2] = 255 * ci->color1[2];
gun.shaderRGBA[3] = 255;
}
} else { // team game
if (!CG_IsUs(ci) && teamRail) {
if (cg_teamRailItemColorTeam.integer) {
if (ci->team == TEAM_RED) {
SC_ByteVec3ColorFromCvar(gun.shaderRGBA, &cg_weaponRedTeamColor);
} else {
SC_ByteVec3ColorFromCvar(gun.shaderRGBA, &cg_weaponBlueTeamColor);
}
gun.shaderRGBA[3] = 255;
} else if (*cg_teamRailItemColor.string) {
SC_ByteVec3ColorFromCvar(gun.shaderRGBA, &cg_teamRailItemColor);
gun.shaderRGBA[3] = 255;
} else {
gun.shaderRGBA[0] = 255 * ci->color1[0];
gun.shaderRGBA[1] = 255 * ci->color1[1];
gun.shaderRGBA[2] = 255 * ci->color1[2];
gun.shaderRGBA[3] = 255;
}
} else if (!CG_IsUs(ci) && enemyRail) {
if (cg_enemyRailItemColorTeam.integer) {
if (ci->team == TEAM_RED) {
SC_ByteVec3ColorFromCvar(gun.shaderRGBA, &cg_weaponRedTeamColor);
} else {
SC_ByteVec3ColorFromCvar(gun.shaderRGBA, &cg_weaponBlueTeamColor);
}
gun.shaderRGBA[3] = 255;
} else if (*cg_enemyRailItemColor.string) {
SC_ByteVec3ColorFromCvar(gun.shaderRGBA, &cg_enemyRailItemColor);
gun.shaderRGBA[3] = 255;
} else {
gun.shaderRGBA[0] = 255 * ci->color1[0];
gun.shaderRGBA[1] = 255 * ci->color1[1];
gun.shaderRGBA[2] = 255 * ci->color1[2];
gun.shaderRGBA[3] = 255;
}
} else { // us
gun.shaderRGBA[0] = 255 * ci->color1[0];
gun.shaderRGBA[1] = 255 * ci->color1[1];
gun.shaderRGBA[2] = 255 * ci->color1[2];
gun.shaderRGBA[3] = 255;
}
}
// end weapon == WP_RAILGUN
//cent->pe.muzzleFlashTime
//Com_Printf("yes....\n");
//f = cg.time - (cent->pe.muzzleFlashTime + 1500);
f = cg.time - (cent->pe.muzzleFlashTime + 1460); // hack
//Com_Printf("f %f\n", f);
if (f < 0) {
f = 1.0 - (f / -1500);
gun.shaderRGBA[0] *= 0.314 * f;
gun.shaderRGBA[1] *= 0.314 * f;
gun.shaderRGBA[2] *= 0.314 * f;
}
}
}
gun.hModel = weapon->weaponModel;
if (!gun.hModel) {
//Com_Printf("no gun model '%s'\n", weapNamesCasual[weaponNum]);
//FIXME grapple returns here
//FIXME fx
//CG_PositionEntityOnTag(&gun, parent, parent->hModel, "tag_weapon");
//CG_CheckFxWeaponFlash(cent, weaponNum, gun.origin);
//return;
}
CG_PositionEntityOnTag( &gun, parent, parent->hModel, "tag_weapon");
CG_ScaleModel(&gun, cg_gunSize.value);
// custom weapon shaders
{
vmCvar_t *firstPersonShaders[MAX_WEAPONS] = { NULL, &cg_firstPersonShaderWeaponGauntlet, &cg_firstPersonShaderWeaponMachineGun, &cg_firstPersonShaderWeaponShotgun, &cg_firstPersonShaderWeaponGrenadeLauncher, &cg_firstPersonShaderWeaponRocketLauncher, &cg_firstPersonShaderWeaponLightningGun, &cg_firstPersonShaderWeaponRailGun, &cg_firstPersonShaderWeaponPlasmaGun, &cg_firstPersonShaderWeaponBFG, &cg_firstPersonShaderWeaponGrapplingHook, &cg_firstPersonShaderWeaponNailGun, &cg_firstPersonShaderWeaponProximityLauncher, &cg_firstPersonShaderWeaponChainGun, &cg_firstPersonShaderWeaponHeavyMachineGun };
if (firstPersonShaders[weaponNum] && *(firstPersonShaders[weaponNum]->string)) {
gun.customShader = trap_R_RegisterShader(firstPersonShaders[weaponNum]->string);
}
}
if (gun.hModel) {
if (cg_drawGun.integer > 2) {
gun.customShader = cgs.media.ghostWeaponShader;
gun.shaderRGBA[0] = 255;
gun.shaderRGBA[1] = 255;
gun.shaderRGBA[2] = 255;
gun.shaderRGBA[3] = 255;
}
CG_AddWeaponWithPowerups( &gun, cent->currentState.powerups );
}
// add the spinning barrel
if ( weapon->barrelModel ) {
memset( &barrel, 0, sizeof( barrel ) );
VectorCopy( parent->lightingOrigin, barrel.lightingOrigin );
barrel.shadowPlane = parent->shadowPlane;
barrel.renderfx = parent->renderfx;
barrel.hModel = weapon->barrelModel;
angles[YAW] = 0;
angles[PITCH] = 0;
angles[ROLL] = CG_MachinegunSpinAngle( cent );
AnglesToAxis( angles, barrel.axis );
CG_PositionRotatedEntityOnTag( &barrel, &gun, weapon->weaponModel, "tag_barrel" );
CG_ScaleModel(&barrel, cg_gunSize.value);
if (cg_drawGun.integer > 2) {
barrel.customShader = cgs.media.ghostWeaponShader;
barrel.shaderRGBA[0] = 255;
barrel.shaderRGBA[1] = 255;
barrel.shaderRGBA[2] = 255;
barrel.shaderRGBA[3] = 255;
}
CG_AddWeaponWithPowerups( &barrel, cent->currentState.powerups );
}
// make sure we aren't looking at cg.predictedPlayerEntity for LG
nonPredictedCent = &cg_entities[cent->currentState.clientNum];
#if 0
// if the index of the nonPredictedCent is not the same as the clientNum
// then this is a fake player (like on teh single player podiums), so
// go ahead and use the cent
if( ( nonPredictedCent - cg_entities ) != cent->currentState.clientNum ) {
nonPredictedCent = cent;
//Com_Printf("fake player %d -> %d\n", nonPredictedCent - cg_entities, cent->currentState.clientNum);
}
#endif
// add the flash
//if ( ( weaponNum == WP_LIGHTNING || weaponNum == WP_GAUNTLET || weaponNum == WP_GRAPPLING_HOOK ) && (cent->currentState.eFlags & EF_FIRING)) {
if ( ( weaponNum == WP_LIGHTNING || weaponNum == WP_GAUNTLET || weaponNum == WP_GRAPPLING_HOOK ) && (nonPredictedCent->currentState.eFlags & EF_FIRING)) {
// && ( nonPredictedCent->currentState.eFlags & EF_FIRING ) ) {
// continuous flash
} else {
//int ftime;
if (weaponNum == WP_LIGHTNING && cent->currentState.eFlags & EF_FIRING) {
//Com_Printf("%f wtf ps %p\n", cg.ftime, ps);
}
// impulse flash
//if ( cg.time - cent->pe.muzzleFlashTime > MUZZLE_FLASH_TIME && !cent->pe.railgunFlash ) {
if ( cg.time - nonPredictedCent->pe.muzzleFlashTime > MUZZLE_FLASH_TIME && !nonPredictedCent->pe.railgunFlash ) {
//Com_Printf("returning for %d (%d)\n", cent - cg_entities, cent->currentState.number);
//goto bolt;
// not called, in case code changes
if (revertColors) {
VectorCopy(origColor1, ci->color1);
VectorCopy(origColor2, ci->color2);
}
return;
}
}
memset( &flash, 0, sizeof( flash ) );
VectorCopy( parent->lightingOrigin, flash.lightingOrigin );
flash.shadowPlane = parent->shadowPlane;
flash.renderfx = parent->renderfx;
flash.hModel = weapon->flashModel;
/*
if (weaponNum == WP_HEAVY_MACHINEGUN) {
flash.hModel = cg_weapons[WP_MACHINEGUN].flashModel;
}
*/
if (!flash.hModel) {
//Com_Printf("no flash model '%s'\n", weapNamesCasual[weaponNum]);
//FIXME fx
//return;
}
angles[YAW] = 0;
angles[PITCH] = 0;
angles[ROLL] = crandom() * 10;
AnglesToAxis( angles, flash.axis );
// colorize the railgun blast
if ( weaponNum == WP_RAILGUN ) {
//clientInfo_t *ci;
//ci = &cgs.clientinfo[ cent->currentState.clientNum ];
if (cg_railUseOwnColors.integer && CG_IsUs(ci)) {
flash.shaderRGBA[0] = 255 * cg.color1[0];
flash.shaderRGBA[1] = 255 * cg.color1[1];
flash.shaderRGBA[2] = 255 * cg.color1[2];
} else {
flash.shaderRGBA[0] = 255 * ci->color1[0];
flash.shaderRGBA[1] = 255 * ci->color1[1];
flash.shaderRGBA[2] = 255 * ci->color1[2];
}
}
if (0) { //(weapon->hasFlashScript) {
//CG_RunQ3mmeFlashScript(weapon, dlight, flash.shaderRGBA, &flashSize);
//VectorCopy(flash.origin, ScriptVars.origin);
//CG_RunQ3mmeScript((char *)weapon->flashScript);
//return;
} else {
dlight[0] = weapon->flashDlightColor[0];
dlight[1] = weapon->flashDlightColor[1];
dlight[2] = weapon->flashDlightColor[2];
/*
flash.shaderRGBA[0] = 255;
flash.shaderRGBA[1] = 255;
flash.shaderRGBA[2] = 255;
flash.shaderRGBA[3] = 0;
*/
flashSize = 300 + (rand()&31);
}
CG_PositionRotatedEntityOnTag( &flash, &gun, weapon->weaponModel, "tag_flash");
//Com_Printf("ps:%d %p\n", ps != NULL, cent);
if (0) { //(cent == &cg.predictedPlayerEntity && !cg.renderingThirdPerson && !ps) {
// don't run flash script twice for first person view
} else if (EffectScripts.weapons[weaponNum].hasFlashScript) {
//CG_RunQ3mmeFlashScript(weapon, dlight, flash.shaderRGBA, &flashSize);
//memset(&ScriptVars, 0, sizeof(ScriptVars));
//CG_Printf("addplayerweapon() flash script cent %d\n", cent - cg_entities);
CG_ResetScriptVars();
CG_CopyPlayerDataToScriptData(cent);
VectorCopy(flash.origin, ScriptVars.origin);
VectorCopy(flash.origin, ScriptVars.parentOrigin);
VectorCopy(cent->lastFlashIntervalPosition, ScriptVars.lastIntervalPosition);
ScriptVars.lastIntervalTime = cent->lastFlashIntervalTime;
VectorCopy(cent->lastFlashDistancePosition, ScriptVars.lastDistancePosition);
ScriptVars.lastDistanceTime = cent->lastFlashDistanceTime;
CG_RunQ3mmeScript((char *)EffectScripts.weapons[weaponNum].flashScript, NULL);
VectorCopy(ScriptVars.lastIntervalPosition, cent->lastFlashIntervalPosition);
cent->lastFlashIntervalTime = ScriptVars.lastIntervalTime;
VectorCopy(ScriptVars.lastDistancePosition, cent->lastFlashDistancePosition);
cent->lastFlashDistanceTime = ScriptVars.lastDistanceTime;
//return;
}
if (!cg_muzzleFlash.integer) {
// pass
} else {
if (flash.hModel) {
CG_AddRefEntity(&flash);
}
}
// bolt:
if (1) {
// add lightning bolt
if (1) {
CG_LightningBolt( nonPredictedCent, flash.origin );
//Com_Printf("adding bolt\n");
// add rail trail
CG_SpawnRailTrail( cent, flash.origin );
//if ((dlight[0] || dlight[1] || dlight[2]) && !weapon->hasFlashScript) {
if ((dlight[0] || dlight[1] || dlight[2]) && !EffectScripts.weapons[weaponNum].hasFlashScript) {
trap_R_AddLightToScene(flash.origin, flashSize, dlight[0], dlight[1], dlight[2]);
}
}
} else {
//Com_Printf("%f no...\n", cg.ftime);
}
if (revertColors) {
VectorCopy(origColor1, ci->color1);
VectorCopy(origColor2, ci->color2);
}
}
/*
==================
CG_Buildable
==================
*/
void CG_Buildable( centity_t *cent )
{
refEntity_t ent;
entityState_t *es = ¢->currentState;
vec3_t angles;
vec3_t surfNormal, xNormal, mins, maxs;
vec3_t refNormal = { 0.0f, 0.0f, 1.0f };
float rotAngle;
buildableTeam_t team = (buildableTeam_t)BG_FindTeamForBuildable( es->modelindex );
float scale;
int health;
float healthScale;
//must be before EF_NODRAW check
if( team == BIT_ALIENS )
CG_Creep( cent );
// if set to invisible, skip
if( es->eFlags & EF_NODRAW )
{
if( CG_IsParticleSystemValid( ¢->buildablePS ) )
CG_DestroyParticleSystem( ¢->buildablePS );
return;
}
memset ( &ent, 0, sizeof( ent ) );
VectorCopy( cent->lerpOrigin, ent.origin );
VectorCopy( cent->lerpOrigin, ent.oldorigin );
VectorCopy( cent->lerpOrigin, ent.lightingOrigin );
VectorCopy( es->origin2, surfNormal );
VectorCopy( es->angles, angles );
BG_FindBBoxForBuildable( es->modelindex, mins, maxs );
if( es->pos.trType == TR_STATIONARY )
CG_PositionAndOrientateBuildable( angles, ent.origin, surfNormal, es->number,
mins, maxs, ent.axis, ent.origin );
//offset on the Z axis if required
VectorMA( ent.origin, BG_FindZOffsetForBuildable( es->modelindex ), surfNormal, ent.origin );
VectorCopy( ent.origin, ent.oldorigin ); // don't positionally lerp at all
VectorCopy( ent.origin, ent.lightingOrigin );
ent.hModel = cg_buildables[ es->modelindex ].models[ 0 ];
if( !( es->generic1 & B_SPAWNED_TOGGLEBIT ) )
{
sfxHandle_t prebuildSound = cgs.media.humanBuildablePrebuild;
if( team == BIT_HUMANS )
{
ent.customShader = cgs.media.humanSpawningShader;
prebuildSound = cgs.media.humanBuildablePrebuild;
}
else if( team == BIT_ALIENS )
prebuildSound = cgs.media.alienBuildablePrebuild;
//trap_S_AddLoopingSound( es->number, cent->lerpOrigin, vec3_origin, prebuildSound, 0 );
}
CG_BuildableAnimation( cent, &ent.oldframe, &ent.frame, &ent.backlerp );
//rescale the model
scale = BG_FindModelScaleForBuildable( es->modelindex );
if( scale != 1.0f )
{
VectorScale( ent.axis[ 0 ], scale, ent.axis[ 0 ] );
VectorScale( ent.axis[ 1 ], scale, ent.axis[ 1 ] );
VectorScale( ent.axis[ 2 ], scale, ent.axis[ 2 ] );
ent.nonNormalizedAxes = qtrue;
}
else
ent.nonNormalizedAxes = qfalse;
//add to refresh list
trap_R_AddRefEntityToScene( &ent );
CrossProduct( surfNormal, refNormal, xNormal );
VectorNormalize( xNormal );
rotAngle = RAD2DEG( acos( DotProduct( surfNormal, refNormal ) ) );
//turret barrel bit
if( cg_buildables[ es->modelindex ].models[ 1 ] )
{
refEntity_t turretBarrel;
vec3_t flatAxis[ 3 ];
memset( &turretBarrel, 0, sizeof( turretBarrel ) );
turretBarrel.hModel = cg_buildables[ es->modelindex ].models[ 1 ];
CG_PositionEntityOnTag( &turretBarrel, &ent, ent.hModel, "tag_turret" );
VectorCopy( cent->lerpOrigin, turretBarrel.lightingOrigin );
AnglesToAxis( es->angles2, flatAxis );
RotatePointAroundVector( turretBarrel.axis[ 0 ], xNormal, flatAxis[ 0 ], -rotAngle );
RotatePointAroundVector( turretBarrel.axis[ 1 ], xNormal, flatAxis[ 1 ], -rotAngle );
RotatePointAroundVector( turretBarrel.axis[ 2 ], xNormal, flatAxis[ 2 ], -rotAngle );
turretBarrel.oldframe = ent.oldframe;
turretBarrel.frame = ent.frame;
turretBarrel.backlerp = ent.backlerp;
turretBarrel.customShader = ent.customShader;
if( scale != 1.0f )
{
VectorScale( turretBarrel.axis[ 0 ], scale, turretBarrel.axis[ 0 ] );
VectorScale( turretBarrel.axis[ 1 ], scale, turretBarrel.axis[ 1 ] );
VectorScale( turretBarrel.axis[ 2 ], scale, turretBarrel.axis[ 2 ] );
turretBarrel.nonNormalizedAxes = qtrue;
}
else
turretBarrel.nonNormalizedAxes = qfalse;
trap_R_AddRefEntityToScene( &turretBarrel );
}
//turret barrel bit
if( cg_buildables[ es->modelindex ].models[ 2 ] )
{
refEntity_t turretTop;
vec3_t flatAxis[ 3 ];
vec3_t swivelAngles;
memset( &turretTop, 0, sizeof( turretTop ) );
VectorCopy( es->angles2, swivelAngles );
swivelAngles[ PITCH ] = 0.0f;
turretTop.hModel = cg_buildables[ es->modelindex ].models[ 2 ];
CG_PositionRotatedEntityOnTag( &turretTop, &ent, ent.hModel, "tag_turret" );
VectorCopy( cent->lerpOrigin, turretTop.lightingOrigin );
AnglesToAxis( swivelAngles, flatAxis );
RotatePointAroundVector( turretTop.axis[ 0 ], xNormal, flatAxis[ 0 ], -rotAngle );
RotatePointAroundVector( turretTop.axis[ 1 ], xNormal, flatAxis[ 1 ], -rotAngle );
RotatePointAroundVector( turretTop.axis[ 2 ], xNormal, flatAxis[ 2 ], -rotAngle );
turretTop.oldframe = ent.oldframe;
turretTop.frame = ent.frame;
turretTop.backlerp = ent.backlerp;
turretTop.customShader = ent.customShader;
if( scale != 1.0f )
{
VectorScale( turretTop.axis[ 0 ], scale, turretTop.axis[ 0 ] );
VectorScale( turretTop.axis[ 1 ], scale, turretTop.axis[ 1 ] );
VectorScale( turretTop.axis[ 2 ], scale, turretTop.axis[ 2 ] );
turretTop.nonNormalizedAxes = qtrue;
}
else
turretTop.nonNormalizedAxes = qfalse;
trap_R_AddRefEntityToScene( &turretTop );
}
switch( cg.predictedPlayerState.weapon )
{
case WP_ABUILD:
case WP_ABUILD2:
case WP_HBUILD:
case WP_HBUILD2:
if( BG_FindTeamForBuildable( es->modelindex ) ==
BG_FindTeamForWeapon( cg.predictedPlayerState.weapon ) )
CG_BuildableHealthBar( cent );
break;
default:
break;
}
//weapon effects for turrets
if( es->eFlags & EF_FIRING )
{
weaponInfo_t *weapon = &cg_weapons[ es->weapon ];
if( cg.time - cent->muzzleFlashTime > MUZZLE_FLASH_TIME ||
BG_FindProjTypeForBuildable( es->modelindex ) == WP_TESLAGEN )
{
if( weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 0 ] ||
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 1 ] ||
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 2 ] )
{
trap_R_AddLightToScene( cent->lerpOrigin, 320, 1.25 + (rand() & 31) / 128,
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 0 ],
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 1 ],
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 2 ],
0,
0 );
}
}
if( weapon->wim[ WPM_PRIMARY ].firingSound )
{
/*trap_S_AddLoopingSound( es->number, cent->lerpOrigin, vec3_origin,
weapon->wim[ WPM_PRIMARY ].firingSound, 0 );*/
}
else if( weapon->readySound ) {
//trap_S_AddLoopingSound( es->number, cent->lerpOrigin, vec3_origin, weapon->readySound, 0 );
}
}
health = es->generic1 & ~( B_POWERED_TOGGLEBIT | B_DCCED_TOGGLEBIT | B_SPAWNED_TOGGLEBIT );
healthScale = (float)health / B_HEALTH_SCALE;
if( healthScale < cent->lastBuildableHealthScale && ( es->generic1 & B_SPAWNED_TOGGLEBIT ) )
{
if( cent->lastBuildableDamageSoundTime + BUILDABLE_SOUND_PERIOD < cg.time )
{
if( team == BIT_HUMANS )
{
int i = rand( ) % 4;
trap_S_StartSound( NULL, es->number, CHAN_BODY, cgs.media.humanBuildableDamage[ i ] );
}
else if( team == BIT_ALIENS )
trap_S_StartSound( NULL, es->number, CHAN_BODY, cgs.media.alienBuildableDamage );
cent->lastBuildableDamageSoundTime = cg.time;
}
}
cent->lastBuildableHealthScale = healthScale;
//smoke etc for damaged buildables
CG_BuildableParticleEffects( cent );
}
/*
==================
CG_Buildable
==================
*/
void CG_Buildable( centity_t *cent )
{
refEntity_t ent;
entityState_t *es = ¢->currentState;
vec3_t angles;
vec3_t surfNormal, xNormal, mins, maxs;
vec3_t refNormal = { 0.0f, 0.0f, 1.0f };
float rotAngle;
team_t team = BG_Buildable( es->modelindex )->team;
float scale;
int health;
//must be before EF_NODRAW check
if( team == TEAM_ALIENS )
CG_Creep( cent );
// if set to invisible, skip
if( es->eFlags & EF_NODRAW )
{
if( CG_IsParticleSystemValid( ¢->buildablePS ) )
CG_DestroyParticleSystem( ¢->buildablePS );
return;
}
memset ( &ent, 0, sizeof( ent ) );
VectorCopy( cent->lerpOrigin, ent.origin );
VectorCopy( cent->lerpOrigin, ent.oldorigin );
VectorCopy( cent->lerpOrigin, ent.lightingOrigin );
VectorCopy( es->origin2, surfNormal );
VectorCopy( es->angles, angles );
BG_BuildableBoundingBox( es->modelindex, mins, maxs );
if( es->pos.trType == TR_STATIONARY )
{
// Positioning a buildable involves potentially up to two traces, and
// seeing as buildables rarely move, we cache the results and recalculate
// only if the buildable moves or changes orientation
if( VectorCompare( cent->buildableCache.cachedOrigin, cent->lerpOrigin ) &&
VectorCompare( cent->buildableCache.cachedNormal, surfNormal ) )
{
VectorCopy( cent->buildableCache.axis[ 0 ], ent.axis[ 0 ] );
VectorCopy( cent->buildableCache.axis[ 1 ], ent.axis[ 1 ] );
VectorCopy( cent->buildableCache.axis[ 2 ], ent.axis[ 2 ] );
VectorCopy( cent->buildableCache.origin, ent.origin );
}
else
{
CG_PositionAndOrientateBuildable( angles, ent.origin, surfNormal,
es->number, mins, maxs, ent.axis,
ent.origin );
VectorCopy( ent.axis[ 0 ], cent->buildableCache.axis[ 0 ] );
VectorCopy( ent.axis[ 1 ], cent->buildableCache.axis[ 1 ] );
VectorCopy( ent.axis[ 2 ], cent->buildableCache.axis[ 2 ] );
VectorCopy( ent.origin, cent->buildableCache.origin );
VectorCopy( cent->lerpOrigin, cent->buildableCache.cachedOrigin );
VectorCopy( surfNormal, cent->buildableCache.cachedNormal );
}
}
//offset on the Z axis if required
VectorMA( ent.origin, BG_BuildableConfig( es->modelindex )->zOffset, surfNormal, ent.origin );
VectorCopy( ent.origin, ent.oldorigin ); // don't positionally lerp at all
VectorCopy( ent.origin, ent.lightingOrigin );
ent.hModel = cg_buildables[ es->modelindex ].models[ 0 ];
if( !( es->eFlags & EF_B_SPAWNED ) )
{
sfxHandle_t prebuildSound = cgs.media.humanBuildablePrebuild;
if( team == TEAM_HUMANS )
{
ent.customShader = cgs.media.humanSpawningShader;
prebuildSound = cgs.media.humanBuildablePrebuild;
}
else if( team == TEAM_ALIENS )
prebuildSound = cgs.media.alienBuildablePrebuild;
trap_S_AddLoopingSound( es->number, cent->lerpOrigin, vec3_origin, prebuildSound );
}
CG_BuildableAnimation( cent, &ent.oldframe, &ent.frame, &ent.backlerp );
//rescale the model
scale = BG_BuildableConfig( es->modelindex )->modelScale;
if( scale != 1.0f )
{
VectorScale( ent.axis[ 0 ], scale, ent.axis[ 0 ] );
VectorScale( ent.axis[ 1 ], scale, ent.axis[ 1 ] );
VectorScale( ent.axis[ 2 ], scale, ent.axis[ 2 ] );
ent.nonNormalizedAxes = qtrue;
}
else
ent.nonNormalizedAxes = qfalse;
if( CG_PlayerIsBuilder( es->modelindex ) && CG_BuildableRemovalPending( es->number ) )
ent.customShader = cgs.media.redBuildShader;
//add to refresh list
trap_R_AddRefEntityToScene( &ent );
CrossProduct( surfNormal, refNormal, xNormal );
VectorNormalize( xNormal );
rotAngle = RAD2DEG( acos( DotProduct( surfNormal, refNormal ) ) );
//turret barrel bit
if( cg_buildables[ es->modelindex ].models[ 1 ] )
{
refEntity_t turretBarrel;
vec3_t flatAxis[ 3 ];
memset( &turretBarrel, 0, sizeof( turretBarrel ) );
turretBarrel.hModel = cg_buildables[ es->modelindex ].models[ 1 ];
CG_PositionEntityOnTag( &turretBarrel, &ent, ent.hModel, "tag_turret" );
VectorCopy( cent->lerpOrigin, turretBarrel.lightingOrigin );
AnglesToAxis( es->angles2, flatAxis );
RotatePointAroundVector( turretBarrel.axis[ 0 ], xNormal, flatAxis[ 0 ], -rotAngle );
RotatePointAroundVector( turretBarrel.axis[ 1 ], xNormal, flatAxis[ 1 ], -rotAngle );
RotatePointAroundVector( turretBarrel.axis[ 2 ], xNormal, flatAxis[ 2 ], -rotAngle );
turretBarrel.oldframe = ent.oldframe;
turretBarrel.frame = ent.frame;
turretBarrel.backlerp = ent.backlerp;
turretBarrel.customShader = ent.customShader;
if( scale != 1.0f )
{
VectorScale( turretBarrel.axis[ 0 ], scale, turretBarrel.axis[ 0 ] );
VectorScale( turretBarrel.axis[ 1 ], scale, turretBarrel.axis[ 1 ] );
VectorScale( turretBarrel.axis[ 2 ], scale, turretBarrel.axis[ 2 ] );
turretBarrel.nonNormalizedAxes = qtrue;
}
else
turretBarrel.nonNormalizedAxes = qfalse;
if( CG_PlayerIsBuilder( es->modelindex ) && CG_BuildableRemovalPending( es->number ) )
turretBarrel.customShader = cgs.media.redBuildShader;
trap_R_AddRefEntityToScene( &turretBarrel );
}
//turret barrel bit
if( cg_buildables[ es->modelindex ].models[ 2 ] )
{
refEntity_t turretTop;
vec3_t flatAxis[ 3 ];
vec3_t swivelAngles;
memset( &turretTop, 0, sizeof( turretTop ) );
VectorCopy( es->angles2, swivelAngles );
swivelAngles[ PITCH ] = 0.0f;
turretTop.hModel = cg_buildables[ es->modelindex ].models[ 2 ];
CG_PositionRotatedEntityOnTag( &turretTop, &ent, ent.hModel, "tag_turret" );
VectorCopy( cent->lerpOrigin, turretTop.lightingOrigin );
AnglesToAxis( swivelAngles, flatAxis );
RotatePointAroundVector( turretTop.axis[ 0 ], xNormal, flatAxis[ 0 ], -rotAngle );
RotatePointAroundVector( turretTop.axis[ 1 ], xNormal, flatAxis[ 1 ], -rotAngle );
RotatePointAroundVector( turretTop.axis[ 2 ], xNormal, flatAxis[ 2 ], -rotAngle );
turretTop.oldframe = ent.oldframe;
turretTop.frame = ent.frame;
turretTop.backlerp = ent.backlerp;
turretTop.customShader = ent.customShader;
if( scale != 1.0f )
{
VectorScale( turretTop.axis[ 0 ], scale, turretTop.axis[ 0 ] );
VectorScale( turretTop.axis[ 1 ], scale, turretTop.axis[ 1 ] );
VectorScale( turretTop.axis[ 2 ], scale, turretTop.axis[ 2 ] );
turretTop.nonNormalizedAxes = qtrue;
}
else
turretTop.nonNormalizedAxes = qfalse;
if( CG_PlayerIsBuilder( es->modelindex ) && CG_BuildableRemovalPending( es->number ) )
turretTop.customShader = cgs.media.redBuildShader;
trap_R_AddRefEntityToScene( &turretTop );
}
//weapon effects for turrets
if( es->eFlags & EF_FIRING )
{
weaponInfo_t *weapon = &cg_weapons[ es->weapon ];
if( cg.time - cent->muzzleFlashTime > MUZZLE_FLASH_TIME ||
BG_Buildable( es->modelindex )->turretProjType == WP_TESLAGEN )
{
if( weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 0 ] ||
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 1 ] ||
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 2 ] )
{
trap_R_AddLightToScene( cent->lerpOrigin, 300 + ( rand( ) & 31 ),
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 0 ],
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 1 ],
weapon->wim[ WPM_PRIMARY ].flashDlightColor[ 2 ] );
}
}
if( weapon->wim[ WPM_PRIMARY ].firingSound )
{
trap_S_AddLoopingSound( es->number, cent->lerpOrigin, vec3_origin,
weapon->wim[ WPM_PRIMARY ].firingSound );
}
else if( weapon->readySound )
trap_S_AddLoopingSound( es->number, cent->lerpOrigin, vec3_origin, weapon->readySound );
}
health = es->generic1;
if( health < cent->lastBuildableHealth &&
( es->eFlags & EF_B_SPAWNED ) )
{
if( cent->lastBuildableDamageSoundTime + BUILDABLE_SOUND_PERIOD < cg.time )
{
if( team == TEAM_HUMANS )
{
int i = rand( ) % 4;
trap_S_StartSound( NULL, es->number, CHAN_BODY, cgs.media.humanBuildableDamage[ i ] );
}
else if( team == TEAM_ALIENS )
trap_S_StartSound( NULL, es->number, CHAN_BODY, cgs.media.alienBuildableDamage );
cent->lastBuildableDamageSoundTime = cg.time;
}
}
cent->lastBuildableHealth = health;
//smoke etc for damaged buildables
CG_BuildableParticleEffects( cent );
}
void CG_Spotlight( centity_t *cent, float *color, vec3_t realstart, vec3_t lightDir, int segs, float range, int startWidth, float coneAngle, int flags ) {
int i, j;
vec3_t start, traceEnd, proj;
vec3_t right, up;
vec3_t v1, v2;
vec3_t startvec, endvec; // the vectors to rotate around lightDir to create the circles
vec3_t conevec;
vec3_t start_points[MAX_SPOT_SEGS], end_points[MAX_SPOT_SEGS];
vec3_t coreright;
polyVert_t verts[MAX_SPOT_SEGS * 4]; // x4 for 4 verts per poly
polyVert_t plugVerts[MAX_SPOT_SEGS];
vec3_t endCenter;
polyVert_t coreverts[4];
trace_t tr;
float alpha;
float radius = 0.0; // TTimo might be used uninitialized
float coreEndRadius;
qboolean capStart = qtrue;
float hitDist; // the actual distance of the trace impact (0 is no hit)
float beamLen; // actual distance of the drawn beam
float endAlpha = 0.0;
vec4_t colorNorm; // normalized color vector
refEntity_t ent;
vec3_t angles;
VectorCopy( realstart, start );
// normalize color
colorNorm[3] = 0; // store normalize multiplier in alpha index
for ( i = 0; i < 3; i++ ) {
if ( color[i] > colorNorm[3] ) {
colorNorm[3] = color[i]; // find largest color value in RGB
}
}
if ( colorNorm[3] != 1 ) { // it needs to be boosted
VectorMA( color, 1.0 / colorNorm[3], color, colorNorm ); // FIXME: div by 0
} else {
VectorCopy( color, colorNorm );
}
colorNorm[3] = color[3];
if ( flags & SL_NOSTARTCAP ) {
capStart = qfalse;
}
if ( startWidth == 0 ) { // cone, not cylinder
capStart = qfalse;
}
if ( flags & SL_LOCKTRACETORANGE ) {
VectorMA( start, range, lightDir, traceEnd ); // trace out to 'range'
} else {
VectorMA( start, MAX_SPOT_RANGE, lightDir, traceEnd ); // trace all the way out to max dist
}
// first trace to see if anything is hit
if ( flags & SL_NOTRACE ) {
tr.fraction = 1.0; // force no hit
} else {
if ( flags & SL_TRACEWORLDONLY ) {
CG_Trace( &tr, start, NULL, NULL, traceEnd, -1, CONTENTS_SOLID );
} else {
CG_Trace( &tr, start, NULL, NULL, traceEnd, -1, MASK_SHOT );
}
// CG_Trace( &tr, start, NULL, NULL, traceEnd, -1, MASK_ALL &~(CONTENTS_MONSTERCLIP|CONTENTS_AREAPORTAL|CONTENTS_CLUSTERPORTAL));
}
if ( tr.fraction < 1.0 ) {
hitDist = beamLen = MAX_SPOT_RANGE * tr.fraction;
if ( beamLen > range ) {
beamLen = range;
}
} else {
hitDist = 0;
beamLen = range;
}
if ( flags & SL_LOCKUV ) {
if ( beamLen < range ) {
endAlpha = 255.0f * ( color[3] - ( color[3] * beamLen / range ) );
}
}
if ( segs >= MAX_SPOT_SEGS ) {
segs = MAX_SPOT_SEGS - 1;
}
// TODO: adjust segs based on r_lodbias
// TODO: move much of this to renderer
// model at base
if ( cent->currentState.modelindex ) {
memset( &ent, 0, sizeof( ent ) );
ent.frame = 0;
ent.oldframe = 0;
ent.backlerp = 0;
VectorCopy( cent->lerpOrigin, ent.origin );
VectorCopy( cent->lerpOrigin, ent.oldorigin );
ent.hModel = cgs.gameModels[cent->currentState.modelindex];
// AnglesToAxis( cent->lerpAngles, ent.axis );
vectoangles( lightDir, angles );
AnglesToAxis( angles, ent.axis );
trap_R_AddRefEntityToScene( &ent );
memcpy( ¢->refEnt, &ent, sizeof( refEntity_t ) );
// push start out a bit so the beam fits to the front of the base model
VectorMA( start, 14, lightDir, start );
}
//// BEAM
PerpendicularVector( up, lightDir );
CrossProduct( lightDir, up, right );
// find first vert of the start
VectorScale( right, startWidth, startvec );
// find the first vert of the end
RotatePointAroundVector( conevec, up, lightDir, -coneAngle );
VectorMA( startvec, beamLen, conevec, endvec ); // this applies the offset of the start diameter before finding the end points
VectorScale( lightDir, beamLen, endCenter );
VectorSubtract( endCenter, endvec, coreverts[3].xyz ); // get a vector of the radius out at the end for the core to use
coreEndRadius = VectorLength( coreverts[3].xyz );
#define CORESCALE 0.6f
//
// generate the flat beam 'core'
//
if ( !( flags & SL_NOCORE ) ) {
VectorSubtract( start, cg.refdef.vieworg, v1 );
VectorNormalize( v1 );
VectorSubtract( traceEnd, cg.refdef.vieworg, v2 );
VectorNormalize( v2 );
CrossProduct( v1, v2, coreright );
VectorNormalize( coreright );
memset( &coreverts[0], 0, 4 * sizeof( polyVert_t ) );
VectorMA( start, startWidth * 0.5f, coreright, coreverts[0].xyz );
VectorMA( start, -startWidth * 0.5f, coreright, coreverts[1].xyz );
VectorMA( endCenter, -coreEndRadius * CORESCALE, coreright, coreverts[2].xyz );
VectorAdd( start, coreverts[2].xyz, coreverts[2].xyz );
VectorMA( endCenter, coreEndRadius * CORESCALE, coreright, coreverts[3].xyz );
VectorAdd( start, coreverts[3].xyz, coreverts[3].xyz );
for ( i = 0; i < 4; i++ ) {
coreverts[i].modulate[0] = color[0] * 200.0f;
coreverts[i].modulate[1] = color[1] * 200.0f;
coreverts[i].modulate[2] = color[2] * 200.0f;
coreverts[i].modulate[3] = color[3] * 200.0f;
if ( i > 1 ) {
coreverts[i].modulate[3] = 0;
}
}
trap_R_AddPolyToScene( cgs.media.spotLightBeamShader, 4, &coreverts[0] );
}
//
// generate the beam cylinder
//
for ( i = 0; i <= segs; i++ ) {
RotatePointAroundVector( start_points[i], lightDir, startvec, ( 360.0f / (float)segs ) * i );
VectorAdd( start_points[i], start, start_points[i] );
RotatePointAroundVector( end_points[i], lightDir, endvec, ( 360.0f / (float)segs ) * i );
VectorAdd( end_points[i], start, end_points[i] );
}
for ( i = 0; i < segs; i++ ) {
j = ( i * 4 );
VectorCopy( start_points[i], verts[( i * 4 )].xyz );
verts[j].st[0] = 0;
verts[j].st[1] = 1;
verts[j].modulate[0] = color[0] * 255.0f;
verts[j].modulate[1] = color[1] * 255.0f;
verts[j].modulate[2] = color[2] * 255.0f;
verts[j].modulate[3] = color[3] * 255.0f;
j++;
VectorCopy( end_points[i], verts[j].xyz );
verts[j].st[0] = 0;
verts[j].st[1] = 0;
verts[j].modulate[0] = color[0] * 255.0f;
verts[j].modulate[1] = color[1] * 255.0f;
verts[j].modulate[2] = color[2] * 255.0f;
verts[j].modulate[3] = endAlpha;
j++;
VectorCopy( end_points[i + 1], verts[j].xyz );
verts[j].st[0] = 1;
verts[j].st[1] = 0;
verts[j].modulate[0] = color[0] * 255.0f;
verts[j].modulate[1] = color[1] * 255.0f;
verts[j].modulate[2] = color[2] * 255.0f;
verts[j].modulate[3] = endAlpha;
j++;
VectorCopy( start_points[i + 1], verts[j].xyz );
verts[j].st[0] = 1;
verts[j].st[1] = 1;
verts[j].modulate[0] = color[0] * 255.0f;
verts[j].modulate[1] = color[1] * 255.0f;
verts[j].modulate[2] = color[2] * 255.0f;
verts[j].modulate[3] = color[3] * 255.0f;
if ( capStart ) {
VectorCopy( start_points[i], plugVerts[i].xyz );
plugVerts[i].st[0] = 0;
plugVerts[i].st[1] = 0;
plugVerts[i].modulate[0] = color[0] * 255.0f;
plugVerts[i].modulate[1] = color[1] * 255.0f;
plugVerts[i].modulate[2] = color[2] * 255.0f;
plugVerts[i].modulate[3] = color[3] * 255.0f;
}
}
trap_R_AddPolysToScene( cgs.media.spotLightBeamShader, 4, &verts[0], segs );
// plug up the start circle
if ( capStart ) {
trap_R_AddPolyToScene( cgs.media.spotLightBeamShader, segs, &plugVerts[0] );
}
// show the endpoint
if ( !( flags & SL_NOIMPACT ) ) {
if ( hitDist ) {
VectorMA( startvec, hitDist, conevec, endvec );
alpha = 0.3f;
radius = coreEndRadius * ( hitDist / beamLen );
VectorNegate( lightDir, proj );
CG_ImpactMark( cgs.media.spotLightShader, tr.endpos, proj, 0, colorNorm[0], colorNorm[1], colorNorm[2], alpha, qfalse, radius, qtrue, -1 );
}
}
// add d light at end
if ( !( flags & SL_NODLIGHT ) ) {
vec3_t dlightLoc;
// VectorMA(tr.endpos, -60, lightDir, dlightLoc); // back away from the hit
// trap_R_AddLightToScene(dlightLoc, 200, colorNorm[0], colorNorm[1], colorNorm[2], 0); // ,REF_JUNIOR_DLIGHT);
VectorMA( tr.endpos, 0, lightDir, dlightLoc ); // back away from the hit
// trap_R_AddLightToScene(dlightLoc, radius*2, colorNorm[0], colorNorm[1], colorNorm[2], 0); // ,REF_JUNIOR_DLIGHT);
trap_R_AddLightToScene( dlightLoc, radius * 2, 0.3, 0.3, 0.3, 0 ); // ,REF_JUNIOR_DLIGHT);
}
// draw flare at source
if ( !( flags & SL_NOFLARE ) ) {
qboolean lightInEyes = qfalse;
vec3_t camloc, dirtolight;
float dot, deg, dist;
float flarescale = 0.0; // TTimo: might be used uninitialized
// get camera position and direction to lightsource
VectorCopy( cg.snap->ps.origin, camloc );
camloc[2] += cg.snap->ps.viewheight;
VectorSubtract( start, camloc, dirtolight );
dist = VectorNormalize( dirtolight );
// first use dot to determine if it's facing the camera
dot = DotProduct( lightDir, dirtolight );
// it's facing the camera, find out how closely and trace to see if the source can be seen
deg = RAD2DEG( M_PI - acos( dot ) );
if ( deg <= 35 ) { // start flare a bit before the camera gets inside the cylinder
lightInEyes = qtrue;
flarescale = 1 - ( deg / 35 );
}
if ( lightInEyes ) { // the dot check succeeded, now do a trace
CG_Trace( &tr, start, NULL, NULL, camloc, -1, MASK_ALL & ~( CONTENTS_MONSTERCLIP | CONTENTS_AREAPORTAL | CONTENTS_CLUSTERPORTAL ) );
if ( tr.fraction != 1 ) {
lightInEyes = qfalse;
}
}
if ( lightInEyes ) {
float coronasize = flarescale;
if ( dist < 512 ) { // make even bigger if you're close enough
coronasize *= ( 512.0f / dist );
}
trap_R_AddCoronaToScene( start, colorNorm[0], colorNorm[1], colorNorm[2], coronasize, cent->currentState.number, qtrue );
} else {
// even though it's off, still need to add it, but turned off so it can fade in/out properly
trap_R_AddCoronaToScene( start, colorNorm[0], colorNorm[1], colorNorm[2], 0, cent->currentState.number, qfalse );
}
}
}
/*
===============
CG_GroundVehicle
===============
*/
void CG_LQM( centity_t *cent, clientInfo_t *ci )
{
vec3_t velocity;
vec3_t right, up, temp, start;
DrawInfo_LQM_t drawInfo;
int ONOFF = cent->currentState.ONOFF;
memset( &drawInfo, 0, sizeof(drawInfo) );
drawInfo.basicInfo.vehicleIndex = ci->vehicle;
drawInfo.basicInfo.ONOFF = ONOFF;
// Copy Weapon Index
drawInfo.weaponIndex = cent->currentState.weaponIndex;
// Copy animation state
drawInfo.anim = cent->currentState.vehicleAnim;
// Copy animation frames
drawInfo.lastTorsoAngle = cent->bayAnim;
drawInfo.lastLegsAngle = cent->gearAnim;
drawInfo.torsoFrame = cent->bayAnimFrame;
drawInfo.legsFrame = cent->gearAnimFrame;
drawInfo.torsoTime = cent->bayAnimStartTime;
drawInfo.legsTime = cent->gearAnimStartTime;
// get speed
VectorCopy( cent->currentState.pos.trDelta, velocity );
drawInfo.basicInfo.speed = VectorLength( velocity );
// entitynum
drawInfo.basicInfo.entityNum = cent->currentState.number;
// get the rotation information
VectorCopy( cent->currentState.angles, cent->lerpAngles );
AnglesToAxis( cent->lerpAngles, drawInfo.basicInfo.axis );
// position and orientation
VectorCopy( cent->lerpOrigin, drawInfo.basicInfo.origin );
VectorCopy( cent->lerpAngles, drawInfo.basicInfo.angles );
// throttle
drawInfo.basicInfo.throttle = cent->currentState.frame;
// loadout
drawInfo.basicInfo.usedLoadout = 0;//&cg_loadouts[cent->currentState.number];
// muzzleflash
if( cg.time - cent->muzzleFlashTime <= MUZZLE_FLASH_TIME ) {
drawInfo.basicInfo.drawMuzzleFlash = true;
drawInfo.basicInfo.flashWeaponIndex = cent->muzzleFlashWeapon;
}
// draw lqm
CG_DrawLQM(&drawInfo);
// return frames
cent->bayAnim = drawInfo.lastTorsoAngle;
cent->gearAnim = drawInfo.lastLegsAngle;
cent->bayAnimFrame = drawInfo.torsoFrame;
cent->bayAnimStartTime = drawInfo.torsoTime;
cent->gearAnimFrame = drawInfo.legsFrame;
cent->gearAnimStartTime = drawInfo.legsTime;
// flags
CG_LQMFlags( cent );
// reticles
if( cent == &cg.predictedPlayerEntity )
{
refEntity_t reticle;
vec3_t forward, ang, end;
trace_t tr;
// playerState_t * ps = &cg.snap->ps;
float len;
float mindist = cg_thirdPersonRange.integer + availableVehicles[ci->vehicle].cam_dist[ CAMERA_V_DEFAULT ] + availableVehicles[ci->vehicle].maxs[0] + 20;
memset( &reticle, 0, sizeof(reticle) );
CG_ResetReticles();
reticle.customShader = availableWeapons[availableVehicles[ci->vehicle].weapons[cent->currentState.weaponNum]].crosshair;
reticle.hModel = cgs.media.reticle[availableWeapons[availableVehicles[ci->vehicle].weapons[cent->currentState.weaponNum]].crosshair];
AngleVectors( cent->currentState.angles, forward, right, up );
RotatePointAroundVector( temp, up, forward, cent->currentState.angles2[ROLL] );
CrossProduct( up, temp, right );
RotatePointAroundVector( forward, right, temp, cent->currentState.angles2[PITCH] );
VectorMA( cent->lerpOrigin, availableVehicles[ci->vehicle].gunoffset[0], forward, start );
VectorMA( start, availableVehicles[ci->vehicle].gunoffset[1], right, start );
VectorMA( start, availableVehicles[ci->vehicle].gunoffset[2], up, start );
VectorMA( start, 2000, forward, end );
vectoangles( forward, ang );
ang[2] = 0;
AnglesToAxis( ang, reticle.axis );
CG_Trace( &tr, start, 0, 0, end, cg.snap->ps.clientNum, MASK_SOLID );
if( tr.entityNum < MAX_CLIENTS )
{
cg.crosshairClientNum = tr.entityNum;
cg.crosshairClientTime = cg.time;
}
VectorCopy( tr.endpos, end );
CG_Trace( &tr, cg.refdef.vieworg, 0, 0, end, cg.snap->ps.clientNum, MASK_SOLID );
VectorSubtract( tr.endpos, cg.refdef.vieworg, forward );
len = VectorNormalize(forward);
if( len > mindist )
{
VectorMA( cg.refdef.vieworg, mindist, forward, reticle.origin );
}
else
{
VectorMA( cg.refdef.vieworg, len - 5, forward, reticle.origin );
}
VectorCopy( reticle.origin, reticle.lightingOrigin );
reticle.renderfx = RF_LIGHTING_ORIGIN|RF_SHADOW_PLANE;
CG_AddReticleEntityToScene( &reticle, NULL );
}
}
/*
==================
CG_LaunchGib
==================
*/
void CG_LaunchGib( centity_t *cent, vec3_t origin, vec3_t angles, vec3_t velocity, qhandle_t hModel, float sizeScale, int breakCount ) {
localEntity_t *le;
refEntity_t *re;
int i;
if ( !cg_blood.integer ) {
return;
}
le = CG_AllocLocalEntity();
re = &le->refEntity;
le->leType = LE_FRAGMENT;
le->startTime = cg.time;
// le->endTime = le->startTime + 60000 + random() * 60000;
le->endTime = le->startTime + 20000 + ( crandom() * 5000 );
le->breakCount = breakCount;
le->sizeScale = sizeScale;
VectorCopy( angles, le->angles.trBase );
VectorCopy( origin, re->origin );
AnglesToAxis( angles, re->axis );
if ( sizeScale != 1.0 ) {
for ( i = 0; i < 3; i++ ) VectorScale( re->axis[i], sizeScale, re->axis[i] );
}
re->hModel = hModel;
// re->fadeStartTime = le->endTime - 3000;
re->fadeStartTime = le->endTime - 1000;
re->fadeEndTime = le->endTime;
switch ( cent->currentState.aiChar ) {
case AICHAR_ZOMBIE:
le->pos.trType = TR_GRAVITY_LOW;
le->angles.trDelta[0] = 400 * crandom();
le->angles.trDelta[1] = 400 * crandom();
le->angles.trDelta[2] = 400 * crandom();
le->leBounceSoundType = LEBS_BONE;
le->bounceFactor = 0.5;
break;
default:
le->leBounceSoundType = LEBS_BLOOD;
le->leMarkType = LEMT_BLOOD;
le->pos.trType = TR_GRAVITY;
le->angles.trDelta[0] = ( 10 + ( rand() & 50 ) ) - 30;
// le->angles.trDelta[0] = (100 + (rand()&500)) - 300; // pitch
le->angles.trDelta[1] = ( 100 + ( rand() & 500 ) ) - 300; // (SA) this is the safe one right now (yaw) turn the others up when I have tumbling things landing properly
le->angles.trDelta[2] = ( 10 + ( rand() & 50 ) ) - 30;
// le->angles.trDelta[2] = (100 + (rand()&500)) - 300; // roll
le->bounceFactor = 0.3;
break;
}
VectorCopy( origin, le->pos.trBase );
VectorCopy( velocity, le->pos.trDelta );
le->pos.trTime = cg.time;
le->angles.trType = TR_LINEAR;
le->angles.trTime = cg.time;
le->ownerNum = cent->currentState.number;
// Ridah, if the player is on fire, then spawn some flaming gibs
if ( cent && CG_EntOnFire( cent ) ) {
le->onFireStart = cent->currentState.onFireStart;
le->onFireEnd = re->fadeEndTime + 1000;
} else if ( ( cent->currentState.aiChar == AICHAR_ZOMBIE ) && IS_FLAMING_ZOMBIE( cent->currentState ) ) {
le->onFireStart = cg.time - 1000;
le->onFireEnd = re->fadeEndTime + 1000;
}
}
/*
==============
R_CalcBone
==============
*/
void R_CalcBone(mdsHeader_t *header, const refEntity_t *refent, int boneNum)
{
thisBoneInfo = &boneInfo[boneNum];
if (thisBoneInfo->torsoWeight)
{
cTBonePtr = &cBoneListTorso[boneNum];
isTorso = qtrue;
if (thisBoneInfo->torsoWeight == 1.0f)
{
fullTorso = qtrue;
}
}
else
{
isTorso = qfalse;
fullTorso = qfalse;
}
cBonePtr = &cBoneList[boneNum];
bonePtr = &bones[boneNum];
// we can assume the parent has already been uncompressed for this frame + lerp
if (thisBoneInfo->parent >= 0)
{
parentBone = &bones[thisBoneInfo->parent];
parentBoneInfo = &boneInfo[thisBoneInfo->parent];
}
else
{
parentBone = NULL;
parentBoneInfo = NULL;
}
#ifdef HIGH_PRECISION_BONES
// rotation
if (fullTorso)
{
VectorCopy(cTBonePtr->angles, angles);
}
else
{
VectorCopy(cBonePtr->angles, angles);
if (isTorso)
{
VectorCopy(cTBonePtr->angles, tangles);
// blend the angles together
for (j = 0; j < 3; j++)
{
diff = tangles[j] - angles[j];
if (Q_fabs(diff) > 180)
{
diff = AngleNormalize180(diff);
}
angles[j] = angles[j] + thisBoneInfo->torsoWeight * diff;
}
}
}
#else
// rotation
if (fullTorso)
{
sh = (short *)cTBonePtr->angles;
pf = angles;
ANGLES_SHORT_TO_FLOAT(pf, sh);
}
else
{
sh = (short *)cBonePtr->angles;
pf = angles;
ANGLES_SHORT_TO_FLOAT(pf, sh);
if (isTorso)
{
int j;
sh = (short *)cTBonePtr->angles;
pf = tangles;
ANGLES_SHORT_TO_FLOAT(pf, sh);
// blend the angles together
for (j = 0; j < 3; j++)
{
diff = tangles[j] - angles[j];
if (Q_fabs(diff) > 180)
{
diff = AngleNormalize180(diff);
}
angles[j] = angles[j] + thisBoneInfo->torsoWeight * diff;
}
}
}
#endif
AnglesToAxis(angles, bonePtr->matrix);
// translation
if (parentBone)
{
#ifdef HIGH_PRECISION_BONES
if (fullTorso)
{
angles[0] = cTBonePtr->ofsAngles[0];
angles[1] = cTBonePtr->ofsAngles[1];
angles[2] = 0;
LocalAngleVector(angles, vec);
LocalVectorMA(parentBone->translation, thisBoneInfo->parentDist, vec, bonePtr->translation);
}
else
{
angles[0] = cBonePtr->ofsAngles[0];
angles[1] = cBonePtr->ofsAngles[1];
angles[2] = 0;
LocalAngleVector(angles, vec);
if (isTorso)
{
tangles[0] = cTBonePtr->ofsAngles[0];
tangles[1] = cTBonePtr->ofsAngles[1];
tangles[2] = 0;
LocalAngleVector(tangles, v2);
// blend the angles together
SLerp_Normal(vec, v2, thisBoneInfo->torsoWeight, vec);
LocalVectorMA(parentBone->translation, thisBoneInfo->parentDist, vec, bonePtr->translation);
}
else // legs bone
{
LocalVectorMA(parentBone->translation, thisBoneInfo->parentDist, vec, bonePtr->translation);
}
}
#else
if (fullTorso)
{
sh = (short *)cTBonePtr->ofsAngles; pf = angles;
*(pf++) = SHORT2ANGLE(*(sh++)); *(pf++) = SHORT2ANGLE(*(sh++)); *(pf++) = 0;
LocalAngleVector(angles, vec);
LocalVectorMA(parentBone->translation, thisBoneInfo->parentDist, vec, bonePtr->translation);
}
else
{
sh = (short *)cBonePtr->ofsAngles; pf = angles;
*(pf++) = SHORT2ANGLE(*(sh++)); *(pf++) = SHORT2ANGLE(*(sh++)); *(pf++) = 0;
LocalAngleVector(angles, vec);
if (isTorso)
{
sh = (short *)cTBonePtr->ofsAngles;
pf = tangles;
*(pf++) = SHORT2ANGLE(*(sh++)); *(pf++) = SHORT2ANGLE(*(sh++)); *(pf++) = 0;
LocalAngleVector(tangles, v2);
// blend the angles together
SLerp_Normal(vec, v2, thisBoneInfo->torsoWeight, vec);
LocalVectorMA(parentBone->translation, thisBoneInfo->parentDist, vec, bonePtr->translation);
}
else // legs bone
{
LocalVectorMA(parentBone->translation, thisBoneInfo->parentDist, vec, bonePtr->translation);
}
}
#endif
}
else // just use the frame position
{
bonePtr->translation[0] = frame->parentOffset[0];
bonePtr->translation[1] = frame->parentOffset[1];
bonePtr->translation[2] = frame->parentOffset[2];
}
if (boneNum == header->torsoParent) // this is the torsoParent
{
VectorCopy(bonePtr->translation, torsoParentOffset);
}
validBones[boneNum] = 1;
rawBones[boneNum] = *bonePtr;
newBones[boneNum] = 1;
}
/*
* SV_Push
*
* Objects need to be moved back on a failed push,
* otherwise riders would continue to slide.
*/
static bool SV_Push( edict_t *pusher, vec3_t move, vec3_t amove ) {
int i, e;
edict_t *check, *block;
vec3_t mins, maxs;
pushed_t *p;
mat3_t axis;
vec3_t org, org2, move2;
// find the bounding box
for( i = 0; i < 3; i++ ) {
mins[i] = pusher->r.absmin[i] + move[i];
maxs[i] = pusher->r.absmax[i] + move[i];
}
// we need this for pushing things later
VectorNegate( amove, org );
AnglesToAxis( org, axis );
// save the pusher's original position
pushed_p->ent = pusher;
VectorCopy( pusher->s.origin, pushed_p->origin );
VectorCopy( pusher->s.angles, pushed_p->angles );
if( pusher->r.client ) {
VectorCopy( pusher->r.client->ps.pmove.velocity, pushed_p->pmove_origin );
pushed_p->yaw = pusher->r.client->ps.viewangles[YAW];
}
pushed_p++;
// move the pusher to its final position
VectorAdd( pusher->s.origin, move, pusher->s.origin );
VectorAdd( pusher->s.angles, amove, pusher->s.angles );
GClip_LinkEntity( pusher );
// see if any solid entities are inside the final position
check = game.edicts + 1;
for( e = 1; e < game.numentities; e++, check++ ) {
if( !check->r.inuse ) {
continue;
}
if( check->movetype == MOVETYPE_PUSH
|| check->movetype == MOVETYPE_STOP
|| check->movetype == MOVETYPE_NONE
|| check->movetype == MOVETYPE_NOCLIP ) {
continue;
}
if( !check->areagrid[0].prev ) {
continue; // not linked in anywhere
}
// if the entity is standing on the pusher, it will definitely be moved
if( check->groundentity != pusher ) {
// see if the ent needs to be tested
if( check->r.absmin[0] >= maxs[0]
|| check->r.absmin[1] >= maxs[1]
|| check->r.absmin[2] >= maxs[2]
|| check->r.absmax[0] <= mins[0]
|| check->r.absmax[1] <= mins[1]
|| check->r.absmax[2] <= mins[2] ) {
continue;
}
// see if the ent's bbox is inside the pusher's final position
if( !SV_TestEntityPosition( check ) ) {
continue;
}
}
if( ( pusher->movetype == MOVETYPE_PUSH ) || ( check->groundentity == pusher ) ) {
// move this entity
pushed_p->ent = check;
VectorCopy( check->s.origin, pushed_p->origin );
VectorCopy( check->s.angles, pushed_p->angles );
pushed_p++;
// try moving the contacted entity
VectorAdd( check->s.origin, move, check->s.origin );
if( check->r.client ) {
// FIXME: doesn't rotate monsters?
VectorAdd( check->r.client->ps.pmove.origin, move, check->r.client->ps.pmove.origin );
check->r.client->ps.viewangles[YAW] += amove[YAW];
}
// figure movement due to the pusher's amove
VectorSubtract( check->s.origin, pusher->s.origin, org );
Matrix3_TransformVector( axis, org, org2 );
VectorSubtract( org2, org, move2 );
VectorAdd( check->s.origin, move2, check->s.origin );
if( check->movetype != MOVETYPE_BOUNCEGRENADE ) {
// may have pushed them off an edge
if( check->groundentity != pusher ) {
check->groundentity = NULL;
}
}
block = SV_TestEntityPosition( check );
if( !block ) {
// pushed ok
GClip_LinkEntity( check );
// impact?
continue;
} else {
// try to fix block
// if it is ok to leave in the old position, do it
// this is only relevant for riding entities, not pushed
VectorSubtract( check->s.origin, move, check->s.origin );
VectorSubtract( check->s.origin, move2, check->s.origin );
block = SV_TestEntityPosition( check );
if( !block ) {
pushed_p--;
continue;
}
}
}
// save off the obstacle so we can call the block function
obstacle = check;
// move back any entities we already moved
// go backwards, so if the same entity was pushed
// twice, it goes back to the original position
for( p = pushed_p - 1; p >= pushed; p-- ) {
VectorCopy( p->origin, p->ent->s.origin );
VectorCopy( p->angles, p->ent->s.angles );
if( p->ent->r.client ) {
VectorCopy( p->pmove_origin, p->ent->r.client->ps.pmove.origin );
p->ent->r.client->ps.viewangles[YAW] = p->yaw;
}
GClip_LinkEntity( p->ent );
}
return false;
}
//FIXME: is there a better way to handle this?
// see if anything we moved has touched a trigger
for( p = pushed_p - 1; p >= pushed; p-- )
GClip_TouchTriggers( p->ent );
return true;
}
/*
==============
R_CalcBoneLerp
==============
*/
void R_CalcBoneLerp(mdsHeader_t *header, const refEntity_t *refent, int boneNum)
{
if (!refent || !header || boneNum < 0 || boneNum >= MDS_MAX_BONES)
{
return;
}
thisBoneInfo = &boneInfo[boneNum];
if (!thisBoneInfo)
{
return;
}
if (thisBoneInfo->parent >= 0)
{
parentBone = &bones[thisBoneInfo->parent];
parentBoneInfo = &boneInfo[thisBoneInfo->parent];
}
else
{
parentBone = NULL;
parentBoneInfo = NULL;
}
if (thisBoneInfo->torsoWeight)
{
cTBonePtr = &cBoneListTorso[boneNum];
cOldTBonePtr = &cOldBoneListTorso[boneNum];
isTorso = qtrue;
if (thisBoneInfo->torsoWeight == 1.0f)
{
fullTorso = qtrue;
}
}
else
{
isTorso = qfalse;
fullTorso = qfalse;
}
cBonePtr = &cBoneList[boneNum];
cOldBonePtr = &cOldBoneList[boneNum];
bonePtr = &bones[boneNum];
newBones[boneNum] = 1;
// rotation (take into account 170 to -170 lerps, which need to take the shortest route)
if (fullTorso)
{
sh = (short *)cTBonePtr->angles;
sh2 = (short *)cOldTBonePtr->angles;
pf = angles;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - torsoBacklerp * diff;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - torsoBacklerp * diff;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - torsoBacklerp * diff;
}
else
{
sh = (short *)cBonePtr->angles;
sh2 = (short *)cOldBonePtr->angles;
pf = angles;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - backlerp * diff;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - backlerp * diff;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - backlerp * diff;
if (isTorso)
{
int j;
sh = (short *)cTBonePtr->angles;
sh2 = (short *)cOldTBonePtr->angles;
pf = tangles;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - torsoBacklerp * diff;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - torsoBacklerp * diff;
a1 = SHORT2ANGLE(*(sh++)); a2 = SHORT2ANGLE(*(sh2++)); diff = AngleNormalize180(a1 - a2);
*(pf++) = a1 - torsoBacklerp * diff;
// blend the angles together
for (j = 0; j < 3; j++)
{
diff = tangles[j] - angles[j];
if (Q_fabs(diff) > 180)
{
diff = AngleNormalize180(diff);
}
angles[j] = angles[j] + thisBoneInfo->torsoWeight * diff;
}
}
}
AnglesToAxis(angles, bonePtr->matrix);
if (parentBone)
{
if (fullTorso)
{
sh = (short *)cTBonePtr->ofsAngles;
sh2 = (short *)cOldTBonePtr->ofsAngles;
}
else
{
sh = (short *)cBonePtr->ofsAngles;
sh2 = (short *)cOldBonePtr->ofsAngles;
}
pf = angles;
*(pf++) = SHORT2ANGLE(*(sh++));
*(pf++) = SHORT2ANGLE(*(sh++));
*(pf++) = 0;
LocalAngleVector(angles, v2); // new
pf = angles;
*(pf++) = SHORT2ANGLE(*(sh2++));
*(pf++) = SHORT2ANGLE(*(sh2++));
*(pf++) = 0;
LocalAngleVector(angles, vec); // old
// blend the angles together
if (fullTorso)
{
SLerp_Normal(vec, v2, torsoFrontlerp, dir);
}
else
{
SLerp_Normal(vec, v2, frontlerp, dir);
}
// translation
if (!fullTorso && isTorso) // partial legs/torso, need to lerp according to torsoWeight
{ // calc the torso frame
sh = (short *)cTBonePtr->ofsAngles;
sh2 = (short *)cOldTBonePtr->ofsAngles;
pf = angles;
*(pf++) = SHORT2ANGLE(*(sh++));
*(pf++) = SHORT2ANGLE(*(sh++));
*(pf++) = 0;
LocalAngleVector(angles, v2); // new
pf = angles;
*(pf++) = SHORT2ANGLE(*(sh2++));
*(pf++) = SHORT2ANGLE(*(sh2++));
*(pf++) = 0;
LocalAngleVector(angles, vec); // old
// blend the angles together
SLerp_Normal(vec, v2, torsoFrontlerp, v2);
// blend the torso/legs together
SLerp_Normal(dir, v2, thisBoneInfo->torsoWeight, dir);
}
LocalVectorMA(parentBone->translation, thisBoneInfo->parentDist, dir, bonePtr->translation);
}
else // just interpolate the frame positions
{
bonePtr->translation[0] = frontlerp * frame->parentOffset[0] + backlerp * oldFrame->parentOffset[0];
bonePtr->translation[1] = frontlerp * frame->parentOffset[1] + backlerp * oldFrame->parentOffset[1];
bonePtr->translation[2] = frontlerp * frame->parentOffset[2] + backlerp * oldFrame->parentOffset[2];
}
if (boneNum == header->torsoParent) // this is the torsoParent
{
VectorCopy(bonePtr->translation, torsoParentOffset);
}
validBones[boneNum] = 1;
rawBones[boneNum] = *bonePtr;
newBones[boneNum] = 1;
}
/*
==========================
CG_MachineGunEjectBrass
==========================
*/
static void CG_MachineGunEjectBrass( centity_t *cent ) {
localEntity_t *le;
refEntity_t *re;
vec3_t velocity, xvelocity;
vec3_t offset, xoffset;
float waterScale = 1.0f;
vec3_t v[3];
if ( cg_brassTime.integer <= 0 ) {
return;
}
le = CG_AllocLocalEntity();
re = &le->refEntity;
velocity[0] = 0;
velocity[1] = -50 + 40 * crandom();
velocity[2] = 100 + 50 * crandom();
le->leType = LE_FRAGMENT;
le->startTime = cg.time;
le->endTime = le->startTime + cg_brassTime.integer + ( cg_brassTime.integer / 4 ) * random();
le->pos.trType = TR_GRAVITY;
le->pos.trTime = cg.time - (rand()&15);
AnglesToAxis( cent->lerpAngles, v );
offset[0] = 8;
offset[1] = -4;
offset[2] = 24;
xoffset[0] = offset[0] * v[0][0] + offset[1] * v[1][0] + offset[2] * v[2][0];
xoffset[1] = offset[0] * v[0][1] + offset[1] * v[1][1] + offset[2] * v[2][1];
xoffset[2] = offset[0] * v[0][2] + offset[1] * v[1][2] + offset[2] * v[2][2];
VectorAdd( cent->lerpOrigin, xoffset, re->origin );
VectorCopy( re->origin, le->pos.trBase );
if ( CG_PointContents( re->origin, -1 ) & CONTENTS_WATER ) {
waterScale = 0.10f;
}
xvelocity[0] = velocity[0] * v[0][0] + velocity[1] * v[1][0] + velocity[2] * v[2][0];
xvelocity[1] = velocity[0] * v[0][1] + velocity[1] * v[1][1] + velocity[2] * v[2][1];
xvelocity[2] = velocity[0] * v[0][2] + velocity[1] * v[1][2] + velocity[2] * v[2][2];
VectorScale( xvelocity, waterScale, le->pos.trDelta );
AxisCopy( axisDefault, re->axis );
re->hModel = cgs.media.machinegunBrassModel;
le->bounceFactor = 0.4 * waterScale;
le->angles.trType = TR_LINEAR;
le->angles.trTime = cg.time;
le->angles.trBase[0] = rand()&31;
le->angles.trBase[1] = rand()&31;
le->angles.trBase[2] = rand()&31;
le->angles.trDelta[0] = 2;
le->angles.trDelta[1] = 1;
le->angles.trDelta[2] = 0;
le->leFlags = LEF_TUMBLE;
le->leBounceSoundType = LEBS_BRASS;
le->leMarkType = LEMT_NONE;
}
/*
===============
CG_CalcViewValues
Sets cg.refdef view values
===============
*/
static int CG_CalcViewValues( void ) {
playerState_t *ps;
memset( &cg.refdef, 0, sizeof( cg.refdef ) );
// strings for in game rendering
// Q_strncpyz( cg.refdef.text[0], "Park Ranger", sizeof(cg.refdef.text[0]) );
// Q_strncpyz( cg.refdef.text[1], "19", sizeof(cg.refdef.text[1]) );
// calculate size of 3D view
CG_CalcVrect();
ps = &cg.cur_lc->predictedPlayerState;
/*
if (cg.cameraMode) {
vec3_t origin, angles;
if (trap_getCameraInfo(cg.time, &origin, &angles)) {
VectorCopy(origin, cg.refdef.vieworg);
angles[ROLL] = 0;
VectorCopy(angles, cg.refdefViewAngles);
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
return CG_CalcFov();
} else {
cg.cameraMode = qfalse;
}
}
*/
// intermission view
if ( ps->pm_type == PM_INTERMISSION ) {
VectorCopy( ps->origin, cg.refdef.vieworg );
VectorCopy( ps->viewangles, cg.refdefViewAngles );
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
return CG_CalcFov();
}
cg.bobcycle = ( ps->bobCycle & 128 ) >> 7;
cg.bobfracsin = fabs( sin( ( ps->bobCycle & 127 ) / 127.0 * M_PI ) );
cg.xyspeed = sqrt( ps->velocity[0] * ps->velocity[0] +
ps->velocity[1] * ps->velocity[1] );
VectorCopy( ps->origin, cg.refdef.vieworg );
VectorCopy( ps->viewangles, cg.refdefViewAngles );
if (cg_cameraOrbit.integer) {
if (cg.time > cg.nextOrbitTime) {
cg.nextOrbitTime = cg.time + cg_cameraOrbitDelay.integer;
cg_thirdPersonAngle[cg.cur_localClientNum].value += cg_cameraOrbit.value;
}
}
// add error decay
if ( cg_errorDecay.value > 0 ) {
int t;
float f;
t = cg.time - cg.cur_lc->predictedErrorTime;
f = ( cg_errorDecay.value - t ) / cg_errorDecay.value;
if ( f > 0 && f < 1 ) {
VectorMA( cg.refdef.vieworg, f, cg.cur_lc->predictedError, cg.refdef.vieworg );
} else {
cg.cur_lc->predictedErrorTime = 0;
}
}
if ( cg.cur_lc->renderingThirdPerson ) {
// back away from character
CG_OffsetThirdPersonView();
} else {
// offset for local bobbing and kicks
CG_OffsetFirstPersonView();
}
// position eye relative to origin
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
if ( cg.cur_lc->hyperspace ) {
cg.refdef.rdflags |= RDF_NOWORLDMODEL | RDF_HYPERSPACE;
}
// field of view
return CG_CalcFov();
}
/*
===============
CG_CalcViewValues
Sets cg.refdef view values
===============
*/
static int CG_CalcViewValues( void ) {
playerState_t *ps;
memset( &cg.refdef, 0, sizeof( cg.refdef ) );
// strings for in game rendering
// Q_strncpyz( cg.refdef.text[0], "Park Ranger", sizeof(cg.refdef.text[0]) );
// Q_strncpyz( cg.refdef.text[1], "19", sizeof(cg.refdef.text[1]) );
// calculate size of 3D view
CG_CalcVrect();
ps = &cg.predictedPlayerState;
// intermission view
if ( ps->pm_type == PM_INTERMISSION ) {
VectorCopy( ps->origin, cg.refdef.vieworg );
VectorCopy( ps->viewangles, cg.refdefViewAngles );
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
return CG_CalcFov();
}
cg.bobcycle = ( ps->bobCycle & 128 ) >> 7;
cg.bobfracsin = fabs( sin( ( ps->bobCycle & 127 ) / 127.0 * M_PI ) );
cg.bobfraccos = fabs( cos( ( ps->bobCycle & 127 ) / 127.0 * M_PI ) );
cg.bobfracsin2 = fabs( sin( ( ps->bobCycle & 127) / 127.0 * (M_PI) ));
cg.xyspeed = sqrt( ps->velocity[0] * ps->velocity[0] +
ps->velocity[1] * ps->velocity[1] );
VectorCopy( ps->origin, cg.refdef.vieworg );
VectorCopy( ps->viewangles, cg.refdefViewAngles );
if (cg_cameraOrbit.integer) {
if (cg.time > cg.nextOrbitTime) {
cg.nextOrbitTime = cg.time + cg_cameraOrbitDelay.integer;
cg_thirdPersonAngle.value += cg_cameraOrbit.value;
}
}
// add error decay
if ( cg_errorDecay.value > 0 ) {
int t;
float f;
t = cg.time - cg.predictedErrorTime;
f = ( cg_errorDecay.value - t ) / cg_errorDecay.value;
if ( f > 0 && f < 1 ) {
VectorMA( cg.refdef.vieworg, f, cg.predictedError, cg.refdef.vieworg );
} else {
cg.predictedErrorTime = 0;
}
}
if ( cg.renderingThirdPerson ) {
// back away from character
CG_OffsetThirdPersonView();
} else {
// offset for local bobbing and kicks
CG_OffsetFirstPersonView();
}
// leilei - View-from-the-model-eyes feature, aka "fullbody awareness" lol
if (cg_cameraEyes.integer && !cg.renderingThirdPerson){
vec3_t forward, right, up;
cg.refdefViewAngles[ROLL] = headang[ROLL];
cg.refdefViewAngles[PITCH] = headang[PITCH];
cg.refdefViewAngles[YAW] = headang[YAW];
AngleVectors( headang, forward, NULL, up );
if (cg_cameraEyes.integer == 2){
VectorMA( headpos, 0, forward, headpos );
VectorMA( headpos, 4, up, headpos );
}
else
{
VectorMA( headpos, cg_cameraEyes_Fwd.value, forward, headpos );
VectorMA( headpos, cg_cameraEyes_Up.value, up, headpos );
}
cg.refdef.vieworg[0] = ps->origin[0] + headpos[0];
cg.refdef.vieworg[1] = ps->origin[1] + headpos[1];
cg.refdef.vieworg[2] = ps->origin[2] + headpos[2];
}
// position eye reletive to origin
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
if ( cg.hyperspace ) {
cg.refdef.rdflags |= RDF_NOWORLDMODEL | RDF_HYPERSPACE;
}
// field of view
return CG_CalcFov();
}
// Used for both the view weapon (ps is valid) and the world modelother character models (ps is NULL)
// The main player will have this called for BOTH cases, so effects like light and sound should only be done on the
// world model case.
void CG_AddPlayerWeapon( refEntity_t *parent, playerState_t *ps, centity_t *cent, int team, vector3 *newAngles, qboolean thirdPerson ) {
refEntity_t gun, barrel, flash;
vector3 angles;
weapon_t weaponNum;
weaponInfo_t *weapon;
centity_t *nonPredictedCent;
if ( !thirdPerson && cg_fakeGun.integer ) {
weaponNum = (weapon_t)cg_fakeGun.integer;
}
else {
weaponNum = (weapon_t)cent->currentState.weapon;
}
if ( weaponNum == WP_EMPLACED_GUN )
return;
// spectator mode, don't draw it...
if ( cg.predictedPlayerState.pm_type == PM_SPECTATOR
&& cent->currentState.number == cg.predictedPlayerState.clientNum )
{
return;
}
CG_RegisterWeapon( weaponNum );
weapon = &cg_weapons[weaponNum];
memset( &gun, 0, sizeof(gun) );
// only do this if we are in first person, since world weapons are now handled on the server by Ghoul2
if ( !thirdPerson ) {
// add the weapon
VectorCopy( &parent->lightingOrigin, &gun.lightingOrigin );
gun.shadowPlane = parent->shadowPlane;
gun.renderfx = parent->renderfx;
// this player, in first person view
if ( ps )
gun.hModel = weapon->viewModel;
else
gun.hModel = weapon->weaponModel;
if ( !gun.hModel )
return;
if ( !ps ) {
// add weapon ready sound
if ( (cent->currentState.eFlags & EF_FIRING) && weapon->firingSound ) {
trap->S_AddLoopingSound( cent->currentState.number, ¢->lerpOrigin, &vec3_origin,
weapon->firingSound
);
}
else if ( weapon->readySound ) {
trap->S_AddLoopingSound( cent->currentState.number, ¢->lerpOrigin, &vec3_origin,
weapon->readySound
);
}
}
CG_PositionEntityOnTag( &gun, parent, parent->hModel, "tag_weapon" );
if ( !CG_IsMindTricked( cent->currentState.trickedEntIndex, cg.snap->ps.clientNum ) ) {
// don't draw the weapon if the player is invisible
CG_AddWeaponWithPowerups( &gun, cent->currentState.powerups );
}
if ( weaponNum == WP_STUN_BATON ) {
int i;
for ( i = 0; i < 3; i++ ) {
memset( &barrel, 0, sizeof(barrel) );
VectorCopy( &parent->lightingOrigin, &barrel.lightingOrigin );
barrel.shadowPlane = parent->shadowPlane;
barrel.renderfx = parent->renderfx;
if ( i == 0 ) {
barrel.hModel = trap->R_RegisterModel( "models/weapons2/stun_baton/baton_barrel.md3" );
}
else if ( i == 1 ) {
barrel.hModel = trap->R_RegisterModel( "models/weapons2/stun_baton/baton_barrel2.md3" );
}
else {
barrel.hModel = trap->R_RegisterModel( "models/weapons2/stun_baton/baton_barrel3.md3" );
}
angles.yaw = 0;
angles.pitch = 0;
angles.roll = 0;
AnglesToAxis( &angles, barrel.axis );
if ( i == 0 ) {
CG_PositionRotatedEntityOnTag( &barrel, parent, weapon->handsModel, "tag_barrel" );
}
else if ( i == 1 ) {
CG_PositionRotatedEntityOnTag( &barrel, parent, weapon->handsModel, "tag_barrel2" );
}
else {
CG_PositionRotatedEntityOnTag( &barrel, parent, weapon->handsModel, "tag_barrel3" );
}
CG_AddWeaponWithPowerups( &barrel, cent->currentState.powerups );
}
}
else {
// add the spinning barrel
if ( weapon->barrelModel ) {
memset( &barrel, 0, sizeof(barrel) );
VectorCopy( &parent->lightingOrigin, &barrel.lightingOrigin );
barrel.shadowPlane = parent->shadowPlane;
barrel.renderfx = parent->renderfx;
barrel.hModel = weapon->barrelModel;
angles.yaw = 0;
angles.pitch = 0;
angles.roll = 0;
AnglesToAxis( &angles, barrel.axis );
CG_PositionRotatedEntityOnTag( &barrel, parent, weapon->handsModel, "tag_barrel" );
CG_AddWeaponWithPowerups( &barrel, cent->currentState.powerups );
}
}
}
memset( &flash, 0, sizeof(flash) );
CG_PositionEntityOnTag( &flash, &gun, gun.hModel, "tag_flash" );
VectorCopy( &flash.origin, &cg.lastFPFlashPoint );
// Do special charge bits
// Make the guns do their charging visual in True View.
if ( (ps || cg.renderingThirdPerson || cg.predictedPlayerState.clientNum != cent->currentState.number || cg_trueGuns.integer) &&
((cent->currentState.modelindex2 == WEAPON_CHARGING_ALT && weaponNum == WP_BRYAR_PISTOL) ||
(cent->currentState.modelindex2 == WEAPON_CHARGING_ALT && weaponNum == WP_BRYAR_OLD) ||
(weaponNum == WP_BOWCASTER && cent->currentState.modelindex2 == WEAPON_CHARGING) ||
(weaponNum == WP_DEMP2 && cent->currentState.modelindex2 == WEAPON_CHARGING_ALT)) ) {
int shader = 0;
float val = 0.0f;
float scale = 1.0f;
addspriteArgStruct_t fxSArgs;
vector3 flashorigin, flashdir;
if ( !thirdPerson ) {
VectorCopy( &flash.origin, &flashorigin );
VectorCopy( &flash.axis[0], &flashdir );
}
else {
mdxaBone_t boltMatrix;
// it's quite possible that we may have have no weapon model and be in a valid state, so return here if this is the case
if ( !trap->G2API_HasGhoul2ModelOnIndex( &(cent->ghoul2), 1 ) )
return;
// Couldn't find bolt point.
if ( !trap->G2API_GetBoltMatrix( cent->ghoul2, 1, 0, &boltMatrix, newAngles, ¢->lerpOrigin, cg.time,
cgs.gameModels, ¢->modelScale ) ) {
return;
}
BG_GiveMeVectorFromMatrix( &boltMatrix, ORIGIN, &flashorigin );
BG_GiveMeVectorFromMatrix( &boltMatrix, POSITIVE_X, &flashdir );
}
if ( weaponNum == WP_BRYAR_PISTOL || weaponNum == WP_BRYAR_OLD ) {
// Hardcoded max charge time of 1 second
val = (cg.time - cent->currentState.constantLight) * 0.001f;
shader = media.gfx.world.bryarFrontFlash;
}
else if ( weaponNum == WP_BOWCASTER ) {
// Hardcoded max charge time of 1 second
val = (cg.time - cent->currentState.constantLight) * 0.001f;
shader = media.gfx.world.greenFrontFlash;
}
else if ( weaponNum == WP_DEMP2 ) {
val = (cg.time - cent->currentState.constantLight) * 0.001f;
shader = media.gfx.world.lightningFlash;
scale = 1.75f;
}
if ( val < 0.0f )
val = 0.0f;
else if ( val > 1.0f ) {
val = 1.0f;
if ( ps && cent->currentState.number == ps->clientNum )
CGCam_Shake( 0.2f, 100 );
}
else if ( ps && cent->currentState.number == ps->clientNum )
CGCam_Shake( val * val * 0.6f, 100 );
val += random() * 0.5f;
VectorCopy( &flashorigin, &fxSArgs.origin );
VectorClear( &fxSArgs.vel );
VectorClear( &fxSArgs.accel );
fxSArgs.scale = 3.0f*val*scale;
fxSArgs.dscale = 0.0f;
fxSArgs.sAlpha = 0.7f;
fxSArgs.eAlpha = 0.7f;
fxSArgs.rotation = random() * 360;
fxSArgs.bounce = 0.0f;
fxSArgs.life = 1.0f;
fxSArgs.shader = shader;
fxSArgs.flags = 0x08000000;
trap->FX_AddSprite( &fxSArgs );
}
// make sure we aren't looking at cg.predictedPlayerEntity for LG
nonPredictedCent = &cg_entities[cent->currentState.clientNum];
// if the index of the nonPredictedCent is not the same as the clientNum then this is a fake player (like on the
// single player podiums), so go ahead and use the cent
if ( nonPredictedCent - cg_entities != cent->currentState.clientNum )
nonPredictedCent = cent;
// add the flash
if ( weaponNum != WP_DEMP2 || (nonPredictedCent->currentState.eFlags & EF_FIRING) ) {
// impulse flash
if ( cg.time - cent->muzzleFlashTime > MUZZLE_FLASH_TIME )
return;
}
if ( ps || cg.renderingThirdPerson || cg_trueGuns.integer
|| cent->currentState.number != cg.predictedPlayerState.clientNum ) {
// Make sure we don't do the thirdperson model effects for the local player if we're in first person
vector3 flashorigin, flashdir;
refEntity_t tpflash;
memset( &tpflash, 0, sizeof(tpflash) );
if ( !thirdPerson ) {
CG_PositionEntityOnTag( &tpflash, &gun, gun.hModel, "tag_flash" );
VectorCopy( &tpflash.origin, &flashorigin );
VectorCopy( &tpflash.axis[0], &flashdir );
}
else {
mdxaBone_t boltMatrix;
// it's quite possible that we may have have no weapon model and be in a valid state, so return here if this is the case
if ( !trap->G2API_HasGhoul2ModelOnIndex( &(cent->ghoul2), 1 ) )
return;
// Couldn't find bolt point.
if ( !trap->G2API_GetBoltMatrix( cent->ghoul2, 1, 0, &boltMatrix, newAngles, ¢->lerpOrigin, cg.time, cgs.gameModels, ¢->modelScale ) )
return;
BG_GiveMeVectorFromMatrix( &boltMatrix, ORIGIN, &flashorigin );
BG_GiveMeVectorFromMatrix( &boltMatrix, POSITIVE_X, &flashdir );
}
if ( cg.time - cent->muzzleFlashTime <= MUZZLE_FLASH_TIME + 10 ) {
// Handle muzzle flashes
if ( cent->currentState.eFlags & EF_ALT_FIRING ) {
// Check the alt firing first.
if ( weapon->altMuzzleEffect ) {
if ( !thirdPerson )
trap->FX_PlayEntityEffectID( weapon->altMuzzleEffect, &flashorigin, tpflash.axis, -1, -1, -1, -1 );
else
trap->FX_PlayEffectID( weapon->altMuzzleEffect, &flashorigin, &flashdir, -1, -1, qfalse );
}
}
else {
// Regular firing
if ( weapon->muzzleEffect ) {
if ( !thirdPerson )
trap->FX_PlayEntityEffectID( weapon->muzzleEffect, &flashorigin, tpflash.axis, -1, -1, -1, -1 );
else
trap->FX_PlayEffectID( weapon->muzzleEffect, &flashorigin, &flashdir, -1, -1, qfalse );
}
}
}
if ( weapon->flashDlightColor.r || weapon->flashDlightColor.g || weapon->flashDlightColor.b ) {
trap->R_AddLightToScene( &flashorigin, 300 + (rand() & 31), weapon->flashDlightColor.r, weapon->flashDlightColor.g,
weapon->flashDlightColor.b );
}
}
}
/*
===============
UI_DrawPlayer
===============
*/
void UI_DrawPlayer( float x, float y, float w, float h, playerInfo_t *pi, int time ) {
refdef_t refdef;
refEntity_t legs;
refEntity_t torso;
refEntity_t head;
refEntity_t gun;
refEntity_t barrel;
refEntity_t flash;
vec3_t origin;
int renderfx;
vec3_t mins = {-16, -16, -24};
vec3_t maxs = {16, 16, 32};
float len;
float xx;
if ( !pi->legsModel || !pi->torsoModel || !pi->headModel || !pi->animations[0].numFrames ) {
return;
}
// this allows the ui to cache the player model on the main menu
if (w == 0 || h == 0) {
return;
}
dp_realtime = time;
if ( pi->pendingWeapon != WP_NUM_WEAPONS && dp_realtime > pi->weaponTimer ) {
pi->weapon = pi->pendingWeapon;
pi->lastWeapon = pi->pendingWeapon;
pi->pendingWeapon = WP_NUM_WEAPONS;
pi->weaponTimer = 0;
if( pi->currentWeapon != pi->weapon ) {
trap_S_StartLocalSound( weaponChangeSound, CHAN_LOCAL );
}
}
UI_AdjustFrom640( &x, &y, &w, &h );
y -= jumpHeight;
memset( &refdef, 0, sizeof( refdef ) );
memset( &legs, 0, sizeof(legs) );
memset( &torso, 0, sizeof(torso) );
memset( &head, 0, sizeof(head) );
refdef.rdflags = RDF_NOWORLDMODEL;
AxisClear( refdef.viewaxis );
refdef.x = x;
refdef.y = y;
refdef.width = w;
refdef.height = h;
refdef.fov_x = (int)((float)refdef.width / uiInfo.uiDC.xscale / 640.0f * 90.0f);
xx = refdef.width / uiInfo.uiDC.xscale / tan( refdef.fov_x / 360 * M_PI );
refdef.fov_y = atan2( refdef.height / uiInfo.uiDC.yscale, xx );
refdef.fov_y *= ( 360 / (float)M_PI );
// calculate distance so the player nearly fills the box
len = 0.7 * ( maxs[2] - mins[2] );
origin[0] = len / tan( DEG2RAD(refdef.fov_x) * 0.5 );
origin[1] = 0.5 * ( mins[1] + maxs[1] );
origin[2] = -0.5 * ( mins[2] + maxs[2] );
refdef.time = dp_realtime;
trap_R_ClearScene();
// get the rotation information
UI_PlayerAngles( pi, legs.axis, torso.axis, head.axis );
// get the animation state (after rotation, to allow feet shuffle)
UI_PlayerAnimation( pi, &legs.oldframe, &legs.frame, &legs.backlerp,
&torso.oldframe, &torso.frame, &torso.backlerp );
renderfx = RF_LIGHTING_ORIGIN | RF_NOSHADOW;
//
// add the legs
//
legs.hModel = pi->legsModel;
legs.customSkin = pi->legsSkin;
VectorCopy( origin, legs.origin );
VectorCopy( origin, legs.lightingOrigin );
legs.renderfx = renderfx;
VectorCopy (legs.origin, legs.oldorigin);
trap_R_AddRefEntityToScene( &legs );
if (!legs.hModel) {
return;
}
//
// add the torso
//
torso.hModel = pi->torsoModel;
if (!torso.hModel) {
return;
}
torso.customSkin = pi->torsoSkin;
VectorCopy( origin, torso.lightingOrigin );
UI_PositionRotatedEntityOnTag( &torso, &legs, pi->legsModel, "tag_torso");
torso.renderfx = renderfx;
trap_R_AddRefEntityToScene( &torso );
//
// add the head
//
head.hModel = pi->headModel;
if (!head.hModel) {
return;
}
head.customSkin = pi->headSkin;
VectorCopy( origin, head.lightingOrigin );
UI_PositionRotatedEntityOnTag( &head, &torso, pi->torsoModel, "tag_head");
head.renderfx = renderfx;
trap_R_AddRefEntityToScene( &head );
//
// add the gun
//
if ( pi->currentWeapon != WP_NONE ) {
memset( &gun, 0, sizeof(gun) );
gun.hModel = pi->weaponModel;
VectorCopy( origin, gun.lightingOrigin );
UI_PositionEntityOnTag( &gun, &torso, pi->torsoModel, "tag_weapon");
gun.renderfx = renderfx;
trap_R_AddRefEntityToScene( &gun );
}
//
// add the spinning barrel
//
if ( pi->realWeapon == WP_MACHINEGUN || pi->realWeapon == WP_GAUNTLET || pi->realWeapon == WP_BFG ) {
vec3_t angles;
memset( &barrel, 0, sizeof(barrel) );
VectorCopy( origin, barrel.lightingOrigin );
barrel.renderfx = renderfx;
barrel.hModel = pi->barrelModel;
angles[YAW] = 0;
angles[PITCH] = 0;
angles[ROLL] = UI_MachinegunSpinAngle( pi );
if( pi->realWeapon == WP_GAUNTLET || pi->realWeapon == WP_BFG ) {
angles[PITCH] = angles[ROLL];
angles[ROLL] = 0;
}
AnglesToAxis( angles, barrel.axis );
UI_PositionRotatedEntityOnTag( &barrel, &gun, pi->weaponModel, "tag_barrel");
trap_R_AddRefEntityToScene( &barrel );
}
//
// add muzzle flash
//
if ( dp_realtime <= pi->muzzleFlashTime ) {
if ( pi->flashModel ) {
memset( &flash, 0, sizeof(flash) );
flash.hModel = pi->flashModel;
VectorCopy( origin, flash.lightingOrigin );
UI_PositionEntityOnTag( &flash, &gun, pi->weaponModel, "tag_flash");
flash.renderfx = renderfx;
trap_R_AddRefEntityToScene( &flash );
}
// make a dlight for the flash
if ( pi->flashDlightColor[0] || pi->flashDlightColor[1] || pi->flashDlightColor[2] ) {
trap_R_AddLightToScene( flash.origin, 200 + (rand()&31), pi->flashDlightColor[0],
pi->flashDlightColor[1], pi->flashDlightColor[2] );
}
}
//
// add the chat icon
//
if ( pi->chat ) {
UI_PlayerFloatSprite( pi, origin, trap_R_RegisterShaderNoMip( "sprites/balloon3" ) );
}
//
// add an accent light
//
origin[0] -= 100; // + = behind, - = in front
origin[1] += 100; // + = left, - = right
origin[2] += 100; // + = above, - = below
trap_R_AddLightToScene( origin, 500, 1.0, 1.0, 1.0 );
origin[0] -= 100;
origin[1] -= 100;
origin[2] -= 100;
trap_R_AddLightToScene( origin, 500, 1.0, 0.0, 0.0 );
trap_R_RenderScene( &refdef );
}
// Add the weapon, and flash for the player's view
void CG_AddViewWeapon( playerState_t *ps ) {
// no gun if in third person view or a camera is active
if ( ps->persistant[PERS_TEAM] == TEAM_SPECTATOR || ps->pm_type == PM_INTERMISSION || cg.renderingThirdPerson ) {
return;
}
const int weap = cg_fakeGun.integer ? cg_fakeGun.integer : ps->weapon;
float desiredFov = 0.0f;
if ( !cg.renderingThirdPerson
&& (cg_trueGuns.integer || weap == WP_SABER || weap == WP_MELEE)
&& cg_trueFOV.value
&& cg.predictedPlayerState.pm_type != PM_SPECTATOR
&& cg.predictedPlayerState.pm_type != PM_INTERMISSION )
{
desiredFov = cg_fovViewmodel.integer ? cg_fovViewmodel.value : cg_trueFOV.value;
}
else {
desiredFov = cg_fovViewmodel.integer ? cg_fovViewmodel.value : cg_fov.value;
}
desiredFov = Q_clampi( 1, desiredFov, 180 );
// allow the gun to be completely removed
if ( !cg_fakeGun.integer && (!cg_drawGun.integer || cg.predictedPlayerState.zoomMode || cg_trueGuns.integer
|| weap == WP_SABER || weap == WP_MELEE) ) {
return;
}
// don't draw if testing a gun model
if ( cg.testGun ) {
return;
}
centity_t *cent = &cg_entities[cg.predictedPlayerState.clientNum];
CG_RegisterWeapon( weap );
refEntity_t hand;
memset( &hand, 0, sizeof(hand) );
// set up gun position
vector3 angles;
CG_CalculateWeaponPosition( &hand.origin, &angles );
refdef_t *refdef = CG_GetRefdef();
VectorMA( &hand.origin, cg.gunAlign.x, &refdef->viewaxis[0], &hand.origin );
VectorMA( &hand.origin, cg.gunAlign.y, &refdef->viewaxis[1], &hand.origin );
VectorMA( &hand.origin, cg.gunAlign.z, &refdef->viewaxis[2], &hand.origin );
AnglesToAxis( &angles, hand.axis );
if ( cg_fovViewmodel.integer ) {
float fracDistFOV, fracWeapFOV;
float fov = desiredFov;
if ( cg_fovAspectAdjust.integer ) {
// Based on LordHavoc's code for Darkplaces
// http://www.quakeworld.nu/forum/topic/53/what-does-your-qw-look-like/page/30
const float baseAspect = 0.75f; // 3/4
const float aspect = (float)cgs.glconfig.vidWidth / (float)cgs.glconfig.vidHeight;
fov = atanf( tanf( desiredFov*M_PI / 360.0f ) * baseAspect*aspect )*360.0f / M_PI;
}
fracDistFOV = tanf( refdef->fov_x * M_PI / 360.0f );
fracWeapFOV = (1.0f / fracDistFOV) * tanf( fov * M_PI / 360.0f );
VectorScale( &hand.axis[0], fracWeapFOV, &hand.axis[0] );
}
// map torso animations to weapon animations
if ( cg_debugGunFrame.integer ) {
// development tool
hand.frame = hand.oldframe = cg_debugGunFrame.integer;
hand.backlerp = 0;
}
else {
float currentFrame;
// get clientinfo for animation map
clientInfo_t *ci = nullptr;
if ( cent->currentState.eType == ET_NPC ) {
if ( !cent->npcClient ) {
return;
}
ci = cent->npcClient;
}
else {
ci = &cgs.clientinfo[cent->currentState.clientNum];
}
// smoother first-person anims by eezstreet http://jkhub.org/topic/1499-/
// actually ported from SP
#if 1
// Sil's fix
trap->G2API_GetBoneFrame( cent->ghoul2, "lower_lumbar", cg.time, ¤tFrame, cgs.gameModels, 0 );
hand.frame = CG_MapTorsoToWeaponFrame( ci, ceilf( currentFrame ), cent->currentState.torsoAnim );
hand.oldframe = CG_MapTorsoToWeaponFrame( ci, floorf( currentFrame ), cent->currentState.torsoAnim );
hand.backlerp = 1.0f - (currentFrame - floorf( currentFrame ));
#else
// basejka style
hand.frame = CG_MapTorsoToWeaponFrame( ci, cent->pe.torso.frame, cent->currentState.torsoAnim );
hand.oldframe = CG_MapTorsoToWeaponFrame( ci, cent->pe.torso.oldFrame, cent->currentState.torsoAnim );
hand.backlerp = cent->pe.torso.backlerp;
#endif
// Handle the fringe situation where oldframe is invalid
if ( hand.frame == -1 ) {
hand.frame = 0;
hand.oldframe = 0;
hand.backlerp = 0;
}
else if ( hand.oldframe == -1 ) {
hand.oldframe = hand.frame;
hand.backlerp = 0;
}
}
weaponInfo_t *wi = &cg_weapons[weap];
hand.hModel = wi->handsModel;
hand.renderfx = RF_DEPTHHACK | RF_FIRST_PERSON;
// add everything onto the hand
CG_AddPlayerWeapon( &hand, ps, &cg_entities[cg.predictedPlayerState.clientNum], ps->persistant[PERS_TEAM], &angles, qfalse );
}
/*
================
CG_AddFragment
================
*/
void CG_AddFragment( localEntity_t *le ) {
vec3_t newOrigin;
trace_t trace;
if ( le->pos.trType == TR_STATIONARY ) {
// sink into the ground if near the removal time
int t;
float oldZ;
t = le->endTime - cg.time;
if ( t < SINK_TIME ) {
// we must use an explicit lighting origin, otherwise the
// lighting would be lost as soon as the origin went
// into the ground
VectorCopy( le->refEntity.origin, le->refEntity.lightingOrigin );
le->refEntity.renderfx |= RF_LIGHTING_ORIGIN;
oldZ = le->refEntity.origin[2];
le->refEntity.origin[2] -= 16 * ( 1.0 - (float)t / SINK_TIME );
trap_R_AddRefEntityToScene( &le->refEntity );
le->refEntity.origin[2] = oldZ;
} else {
trap_R_AddRefEntityToScene( &le->refEntity );
}
return;
}
// calculate new position
BG_EvaluateTrajectory( &le->pos, cg.time, newOrigin );
// trace a line from previous position to new position
CG_Trace( &trace, le->refEntity.origin, NULL, NULL, newOrigin, -1, CONTENTS_SOLID );
if ( trace.fraction == 1.0 ) {
// still in free fall
VectorCopy( newOrigin, le->refEntity.origin );
if ( le->leFlags & LEF_TUMBLE ) {
vec3_t angles;
BG_EvaluateTrajectory( &le->angles, cg.time, angles );
AnglesToAxis( angles, le->refEntity.axis );
}
trap_R_AddRefEntityToScene( &le->refEntity );
// add a blood trail
if ( le->leBounceSoundType == LEBS_BLOOD ) {
CG_BloodTrail( le );
}
return;
}
// if it is in a nodrop zone, remove it
// this keeps gibs from waiting at the bottom of pits of death
// and floating levels
if ( trap_CM_PointContents( trace.endpos, 0 ) & CONTENTS_NODROP ) {
CG_FreeLocalEntity( le );
return;
}
// leave a mark
CG_FragmentBounceMark( le, &trace );
// do a bouncy sound
CG_FragmentBounceSound( le, &trace );
// reflect the velocity on the trace plane
CG_ReflectVelocity( le, &trace );
trap_R_AddRefEntityToScene( &le->refEntity );
}
/*
===============
CG_CalcViewValues
Sets cg.refdef view values
===============
*/
static int CG_CalcViewValues( void ) {
playerState_t *ps;
memset( &cg.refdef, 0, sizeof( cg.refdef ) );
// strings for in game rendering
// Q_strncpyz( cg.refdef.text[0], "Park Ranger", sizeof(cg.refdef.text[0]) );
// Q_strncpyz( cg.refdef.text[1], "19", sizeof(cg.refdef.text[1]) );
// calculate size of 3D view
CG_CalcVrect();
ps = &cg.predictedPlayerState;
if ( cg.cameraMode ) {
vec3_t origin, angles;
float fov = 90;
float x;
if ( trap_getCameraInfo( CAM_PRIMARY, cg.time, &origin, &angles, &fov ) ) {
VectorCopy( origin, cg.refdef.vieworg );
angles[ROLL] = 0;
angles[PITCH] = -angles[PITCH]; // (SA) compensate for reversed pitch (this makes the game match the editor, however I'm guessing the real fix is to be done there)
VectorCopy( angles, cg.refdefViewAngles );
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
x = cg.refdef.width / tan( fov / 360 * M_PI );
cg.refdef.fov_y = atan2( cg.refdef.height, x );
cg.refdef.fov_y = cg.refdef.fov_y * 360 / M_PI;
cg.refdef.fov_x = fov;
trap_SendClientCommand( va( "setCameraOrigin %f %f %f", origin[0], origin[1], origin[2] ) );
return 0;
} else {
cg.cameraMode = qfalse;
trap_Cvar_Set( "cg_letterbox", "0" );
trap_SendClientCommand( "stopCamera" );
CG_Fade( 0, 0, 0, 255, 0 ); // go black
CG_Fade( 0, 0, 0, 0, 1500 ); // then fadeup
}
}
// intermission view
if ( ps->pm_type == PM_INTERMISSION ) {
VectorCopy( ps->origin, cg.refdef.vieworg );
VectorCopy( ps->viewangles, cg.refdefViewAngles );
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
return CG_CalcFov();
}
cg.bobcycle = ( ps->bobCycle & 128 ) >> 7;
cg.bobfracsin = fabs( sin( ( ps->bobCycle & 127 ) / 127.0 * M_PI ) );
cg.xyspeed = sqrt( ps->velocity[0] * ps->velocity[0] +
ps->velocity[1] * ps->velocity[1] );
// VectorCopy( ps->origin, cg.refdef.vieworg );
// Arnout: see if we're attached to a gun
if ( cg.renderingThirdPerson && ps->eFlags & EF_MG42_ACTIVE ) {
centity_t *mg42 = &cg_entities[ps->viewlocked_entNum];
vec3_t forward, right, up;
AngleVectors( ps->viewangles, forward, right, up );
VectorMA( mg42->currentState.pos.trBase, -36, forward, cg.refdef.vieworg );
cg.refdef.vieworg[2] = ps->origin[2];
} else {
VectorCopy( ps->origin, cg.refdef.vieworg );
}
VectorCopy( ps->viewangles, cg.refdefViewAngles );
// add error decay
if ( cg_errorDecay.value > 0 ) {
int t;
float f;
t = cg.time - cg.predictedErrorTime;
f = ( cg_errorDecay.value - t ) / cg_errorDecay.value;
if ( f > 0 && f < 1 ) {
VectorMA( cg.refdef.vieworg, f, cg.predictedError, cg.refdef.vieworg );
} else {
cg.predictedErrorTime = 0;
}
}
// Ridah, lock the viewangles if the game has told us to
if ( ps->viewlocked ) {
/*
if (ps->viewlocked == 4)
{
centity_t *tent;
tent = &cg_entities[ps->viewlocked_entNum];
VectorCopy (tent->currentState.apos.trBase, cg.refdefViewAngles);
}
else
*/
// DHM - Nerve :: don't bother evaluating if set to 7 (look at medic)
if ( ps->viewlocked != 7 && ps->viewlocked != 3 && ps->viewlocked != 2 ) {
BG_EvaluateTrajectory( &cg_entities[ps->viewlocked_entNum].currentState.apos, cg.time, cg.refdefViewAngles );
}
if ( ps->viewlocked == 2 ) {
cg.refdefViewAngles[0] += crandom();
cg.refdefViewAngles[1] += crandom();
}
}
// done.
if ( cg.renderingThirdPerson ) {
// back away from character
CG_OffsetThirdPersonView();
} else {
// offset for local bobbing and kicks
CG_OffsetFirstPersonView();
// Ridah, lock the viewangles if the game has told us to
if ( ps->viewlocked == 7 ) {
centity_t *tent;
vec3_t vec;
tent = &cg_entities[ps->viewlocked_entNum];
VectorCopy( tent->lerpOrigin, vec );
VectorSubtract( vec, cg.refdef.vieworg, vec );
vectoangles( vec, cg.refdefViewAngles );
} else if ( ps->viewlocked == 4 ) {
vec3_t fwd;
AngleVectors( cg.refdefViewAngles, fwd, NULL, NULL );
VectorMA( cg_entities[ps->viewlocked_entNum].currentState.pos.trBase, 16, fwd, cg.refdef.vieworg );
} else if ( ps->viewlocked ) {
vec3_t fwd;
float oldZ;
// set our position to be behind it
oldZ = cg.refdef.vieworg[2];
AngleVectors( cg.refdefViewAngles, fwd, NULL, NULL );
VectorMA( cg_entities[ps->viewlocked_entNum].currentState.pos.trBase, -34, fwd, cg.refdef.vieworg );
cg.refdef.vieworg[2] = oldZ;
// CG_Printf( "ps->origin[2]: %f\n", ps->origin[2] );
// CG_Printf( "fwd: %f %f %f\n", fwd[0], fwd[1], fwd[2] );
// CG_Printf( "base: %f %f %f\n", cg_entities[ps->viewlocked_entNum].currentState.pos.trBase[0], cg_entities[ps->viewlocked_entNum].currentState.pos.trBase[1], cg_entities[ps->viewlocked_entNum].currentState.pos.trBase[2] );
}
// done.
}
// position eye relative to origin
AnglesToAxis( cg.refdefViewAngles, cg.refdef.viewaxis );
if ( cg.hyperspace ) {
cg.refdef.rdflags |= RDF_NOWORLDMODEL | RDF_HYPERSPACE;
}
// field of view
return CG_CalcFov();
}
static void CG_DistortionOrb( centity_t *cent )
{
refEntity_t ent;
vec3_t ang;
float scale = 0.5f;
float vLen;
if (!cg_renderToTextureFX.integer)
{
return;
}
memset( &ent, 0, sizeof( ent ) );
VectorCopy( cent->lerpOrigin, ent.origin );
VectorSubtract(ent.origin, cg.refdef.vieworg, ent.axis[0]);
vLen = VectorLength(ent.axis[0]);
if (VectorNormalize(ent.axis[0]) <= 0.1f)
{ // Entity is right on vieworg. quit.
return;
}
// VectorCopy(cg.refdef.viewaxis[2], ent.axis[2]);
// CrossProduct(ent.axis[0], ent.axis[2], ent.axis[1]);
vectoangles(ent.axis[0], ang);
ang[ROLL] = cent->trickAlpha;
cent->trickAlpha += 16; //spin the half-sphere to give a "screwdriver" effect
AnglesToAxis(ang, ent.axis);
//radius must be a power of 2, and is the actual captured texture size
if (vLen < 128)
{
ent.radius = 256;
}
else if (vLen < 256)
{
ent.radius = 128;
}
else if (vLen < 512)
{
ent.radius = 64;
}
else
{
ent.radius = 32;
}
VectorScale(ent.axis[0], scale, ent.axis[0]);
VectorScale(ent.axis[1], scale, ent.axis[1]);
VectorScale(ent.axis[2], -scale, ent.axis[2]);
ent.hModel = cgs.media.halfShieldModel;
ent.customShader = 0;//cgs.media.halfShieldShader;
#if 1
ent.renderfx = (RF_DISTORTION|RF_RGB_TINT);
//tint the whole thing a shade of blue
ent.shaderRGBA[0] = 200.0f;
ent.shaderRGBA[1] = 200.0f;
ent.shaderRGBA[2] = 255.0f;
#else //no tint
ent.renderfx = RF_DISTORTION;
#endif
trap->R_AddRefEntityToScene( &ent );
}
void SP_misc_gamemodel(void)
{
char *model;
vec_t angle;
vec3_t angles;
vec_t scale;
vec3_t vScale;
vec3_t org;
cg_gamemodel_t *gamemodel;
int i;
if (CG_SpawnString("targetname", "", &model) || CG_SpawnString("scriptname", "", &model) || CG_SpawnString("spawnflags", "", &model))
{
// Gordon: this model may not be static, so let the server handle it
return;
}
if (cg.numMiscGameModels >= MAX_STATIC_GAMEMODELS)
{
CG_Error("^1MAX_STATIC_GAMEMODELS(%i) hit", MAX_STATIC_GAMEMODELS);
}
CG_SpawnString("model", "", &model);
CG_SpawnVector("origin", "0 0 0", org);
if (!CG_SpawnVector("angles", "0 0 0", angles))
{
if (CG_SpawnFloat("angle", "0", &angle))
{
angles[YAW] = angle;
}
}
if (!CG_SpawnVector("modelscale_vec", "1 1 1", vScale))
{
if (CG_SpawnFloat("modelscale", "1", &scale))
{
VectorSet(vScale, scale, scale, scale);
}
}
gamemodel = &cgs.miscGameModels[cg.numMiscGameModels++];
gamemodel->model = trap_R_RegisterModel(model);
AnglesToAxis(angles, gamemodel->axes);
for (i = 0; i < 3; i++)
{
VectorScale(gamemodel->axes[i], vScale[i], gamemodel->axes[i]);
}
VectorCopy(org, gamemodel->org);
if (gamemodel->model)
{
vec3_t mins, maxs;
trap_R_ModelBounds(gamemodel->model, mins, maxs);
for (i = 0; i < 3; i++)
{
mins[i] *= vScale[i];
maxs[i] *= vScale[i];
}
gamemodel->radius = RadiusFromBounds(mins, maxs);
}
else
{
gamemodel->radius = 0;
}
}
