quakeforge/libs/video/renderer/sw32/sw32_rpart.c
Bill Currie fbc1bd9f6e [renderer] Clean up entity_t to a certain extent
This is the first step towards component-based entities.

There's still some transform-related stuff in the struct that needs to
be moved, but it's all entirely client related (rather than renderer)
and will probably go into a "client" component. Also, the current
components are directly included structs rather than references as I
didn't want to deal with the object management at this stage.

As part of the process (because transforms use simd) this also starts
the process of moving QF to using simd for vectors and matrices. There's
now a mess of simd and sisd code mixed together, but it works
surprisingly well together.
2021-03-10 00:01:41 +09:00

936 lines
20 KiB
C

/*
sw32_rpart.c
24 bit color software renderer particle effects.
Copyright (C) 1996-1997 Id Software, Inc.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to:
Free Software Foundation, Inc.
59 Temple Place - Suite 330
Boston, MA 02111-1307, USA
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#define NH_DEFINE
#include "namehack.h"
#include <stdlib.h>
#ifdef HAVE_STRING_H
# include <string.h>
#endif
#ifdef HAVE_STRINGS_H
# include <strings.h>
#endif
#include "QF/cvar.h"
#include "QF/mersenne.h"
#include "QF/qargs.h"
#include "QF/quakefs.h"
#include "QF/render.h"
#include "QF/sys.h"
#include "QF/va.h"
#include "compat.h"
#include "r_internal.h"
static int ramp1[8] = { 0x6f, 0x6d, 0x6b, 0x69, 0x67, 0x65, 0x63, 0x61 };
//static int ramp2[8] = { 0x6f, 0x6e, 0x6d, 0x6c, 0x6b, 0x6a, 0x68, 0x66 };
static int ramp3[8] = { 0x6d, 0x6b, 6, 5, 4, 3 };
static mtstate_t mt; // private PRNG state
void
sw32_R_InitParticles (void)
{
mtwist_seed (&mt, 0xdeadbeef);
}
void
sw32_R_ClearParticles (void)
{
unsigned int i;
free_particles = &particles[0];
active_particles = NULL;
for (i = 0; i < r_maxparticles; i++)
particles[i].next = &particles[i + 1];
if (r_maxparticles)
particles[r_maxparticles - 1].next = NULL;
}
void
sw32_R_ReadPointFile_f (void)
{
QFile *f;
vec3_t org;
int r;
int c;
particle_t *p;
const char *name;
char *mapname;
mapname = strdup (r_worldentity.renderer.model->path);
if (!mapname)
Sys_Error ("Can't duplicate mapname!");
QFS_StripExtension (mapname, mapname);
name = va (0, "maps/%s.pts", mapname);
free (mapname);
f = QFS_FOpenFile (name);
if (!f) {
Sys_Printf ("couldn't open %s\n", name);
return;
}
Sys_Printf ("Reading %s...\n", name);
c = 0;
for (;;) {
char buf[64];
Qgets (f, buf, sizeof (buf));
r = sscanf (buf, "%f %f %f\n", &org[0], &org[1], &org[2]);
if (r != 3)
break;
c++;
if (!free_particles) {
Sys_Printf ("Not enough free particles\n");
break;
}
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = 99999;
p->color = (-c) & 15;
p->type = pt_static;
p->phys = R_ParticlePhysics (p->type);
VectorZero (p->vel);
VectorCopy (org, p->org);
}
Qclose (f);
Sys_Printf ("%i points read\n", c);
}
static void
R_ParticleExplosion_QF (const vec3_t org)
{
int i, j;
particle_t *p;
if (!r_particles->int_val)
return;
for (i = 0; i < 1024; i++) {
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 5;
p->color = ramp1[0];
p->ramp = mtwist_rand (&mt) & 3;
if (i & 1) {
p->type = pt_explode;
for (j = 0; j < 3; j++) {
p->org[j] = org[j] + ((mtwist_rand (&mt) % 32) - 16);
p->vel[j] = (mtwist_rand (&mt) % 512) - 256;
}
} else {
p->type = pt_explode2;
for (j = 0; j < 3; j++) {
p->org[j] = org[j] + ((mtwist_rand (&mt) % 32) - 16);
p->vel[j] = (mtwist_rand (&mt) % 512) - 256;
}
}
p->phys = R_ParticlePhysics (p->type);
}
}
static void
R_ParticleExplosion2_QF (const vec3_t org, int colorStart, int colorLength)
{
int i, j;
particle_t *p;
int colorMod = 0;
for (i=0; i<512; i++)
{
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 0.3;
p->color = colorStart + (colorMod % colorLength);
colorMod++;
p->type = pt_blob;
p->phys = R_ParticlePhysics (p->type);
for (j=0 ; j<3 ; j++)
{
p->org[j] = org[j] + ((mtwist_rand (&mt)%32)-16);
p->vel[j] = (mtwist_rand (&mt)%512)-256;
}
}
}
static void
R_BlobExplosion_QF (const vec3_t org)
{
int i, j;
particle_t *p;
if (!r_particles->int_val)
return;
for (i = 0; i < 1024; i++) {
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 1 + (mtwist_rand (&mt) & 8) * 0.05;
if (i & 1) {
p->type = pt_blob;
p->color = 66 + mtwist_rand (&mt) % 6;
for (j = 0; j < 3; j++) {
p->org[j] = org[j] + ((mtwist_rand (&mt) % 32) - 16);
p->vel[j] = (mtwist_rand (&mt) % 512) - 256;
}
} else {
p->type = pt_blob2;
p->color = 150 + mtwist_rand (&mt) % 6;
for (j = 0; j < 3; j++) {
p->org[j] = org[j] + ((mtwist_rand (&mt) % 32) - 16);
p->vel[j] = (mtwist_rand (&mt) % 512) - 256;
}
}
p->phys = R_ParticlePhysics (p->type);
}
}
static void
R_LavaSplash_QF (const vec3_t org)
{
int i, j, k;
particle_t *p;
float vel;
vec3_t dir;
if (!r_particles->int_val)
return;
for (i = -16; i < 16; i++)
for (j = -16; j < 16; j++)
for (k = 0; k < 1; k++) {
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 2 + (mtwist_rand (&mt) & 31) * 0.02;
p->color = 224 + (mtwist_rand (&mt) & 7);
p->type = pt_grav;
p->phys = R_ParticlePhysics (p->type);
dir[0] = j * 8 + (mtwist_rand (&mt) & 7);
dir[1] = i * 8 + (mtwist_rand (&mt) & 7);
dir[2] = 256;
p->org[0] = org[0] + dir[0];
p->org[1] = org[1] + dir[1];
p->org[2] = org[2] + (mtwist_rand (&mt) & 63);
VectorNormalize (dir);
vel = 50 + (mtwist_rand (&mt) & 63);
VectorScale (dir, vel, p->vel);
}
}
static void
R_TeleportSplash_QF (const vec3_t org)
{
float vel;
int i, j, k;
particle_t *p;
vec3_t dir;
if (!r_particles->int_val)
return;
for (i = -16; i < 16; i += 4) {
for (j = -16; j < 16; j += 4) {
for (k = -24; k < 32; k += 4) {
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 0.2 + (mtwist_rand (&mt) & 7) * 0.02;
p->color = 7 + (mtwist_rand (&mt) & 7);
p->type = pt_grav;
p->phys = R_ParticlePhysics (p->type);
dir[0] = j * 8;
dir[1] = i * 8;
dir[2] = k * 8;
p->org[0] = org[0] + i + (mtwist_rand (&mt) & 3);
p->org[1] = org[1] + j + (mtwist_rand (&mt) & 3);
p->org[2] = org[2] + k + (mtwist_rand (&mt) & 3);
VectorNormalize (dir);
vel = 50 + (mtwist_rand (&mt) & 63);
VectorScale (dir, vel, p->vel);
}
}
}
}
static void
R_DarkFieldParticles_ID (const entity_t *ent)
{
int i, j, k;
unsigned int rnd;
float vel;
particle_t *p;
vec3_t dir, org;
org[0] = ent->origin[0];
org[1] = ent->origin[1];
org[2] = ent->origin[2];
for (i = -16; i < 16; i += 8) {
for (j = -16; j < 16; j += 8) {
for (k = 0; k < 32; k += 8) {
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
rnd = mtwist_rand (&mt);
p->die = vr_data.realtime + 0.2 + (rnd & 7) * 0.02;
p->color = 150 + mtwist_rand (&mt) % 6;
p->type = pt_slowgrav;
p->phys = R_ParticlePhysics (p->type);
dir[0] = j * 8;
dir[1] = i * 8;
dir[2] = k * 8;
p->org[0] = org[0] + i + ((rnd >> 3) & 3);
p->org[1] = org[1] + j + ((rnd >> 5) & 3);
p->org[2] = org[2] + k + ((rnd >> 7) & 3);
VectorNormalize (dir);
vel = 50 + ((rnd >> 9) & 63);
VectorScale (dir, vel, p->vel);
}
}
}
}
static vec3_t avelocities[NUMVERTEXNORMALS];
static void
R_EntityParticles_ID (const entity_t *ent)
{
int i;
float angle, sp, sy, cp, cy; // cr, sr
float beamlength = 16.0, dist = 64.0;
particle_t *p;
vec3_t forward;
for (i = 0; i < NUMVERTEXNORMALS; i++) {
int k;
for (k = 0; k < 3; k++) {
avelocities[i][k] = (mtwist_rand (&mt) & 255) * 0.01;
}
}
for (i = 0; i < NUMVERTEXNORMALS; i++) {
angle = vr_data.realtime * avelocities[i][0];
cy = cos (angle);
sy = sin (angle);
angle = vr_data.realtime * avelocities[i][1];
cp = cos (angle);
sp = sin (angle);
// Next 3 lines results aren't currently used, may be in future. --Despair
// angle = vr_data.realtime * avelocities[i][2];
// sr = sin (angle);
// cr = cos (angle);
forward[0] = cp * cy;
forward[1] = cp * sy;
forward[2] = -sp;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 0.01;
p->color = 0x6f;
p->type = pt_explode;
p->phys = R_ParticlePhysics (p->type);
p->org[0] = ent->origin[0] + r_avertexnormals[i][0] * dist +
forward[0] * beamlength;
p->org[1] = ent->origin[1] + r_avertexnormals[i][1] * dist +
forward[1] * beamlength;
p->org[2] = ent->origin[2] + r_avertexnormals[i][2] * dist +
forward[2] * beamlength;
}
}
static void
R_RunParticleEffect_QF (const vec3_t org, const vec3_t dir, int color,
int count)
{
int i, j;
particle_t *p;
if (!r_particles->int_val)
return;
for (i = 0; i < count; i++) {
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 0.1 * (mtwist_rand (&mt) % 5);
p->color = (color & ~7) + (mtwist_rand (&mt) & 7);
p->type = pt_slowgrav;
p->phys = R_ParticlePhysics (p->type);
for (j = 0; j < 3; j++) {
p->org[j] = org[j] + ((mtwist_rand (&mt) & 15) - 8);
p->vel[j] = dir[j]; // + (mtwist_rand (&mt)%300)-150;
}
}
}
static void
R_SpikeEffect_QF (const vec3_t org)
{
R_RunParticleEffect_QF (org, vec3_origin, 0, 10);
}
static void
R_SuperSpikeEffect_QF (const vec3_t org)
{
R_RunParticleEffect_QF (org, vec3_origin, 0, 20);
}
static void
R_KnightSpikeEffect_QF (const vec3_t org)
{
R_RunParticleEffect_QF (org, vec3_origin, 226, 20);
}
static void
R_WizSpikeEffect_QF (const vec3_t org)
{
R_RunParticleEffect_QF (org, vec3_origin, 20, 30);
}
static void
R_BloodPuffEffect_QF (const vec3_t org, int count)
{
R_RunParticleEffect_QF (org, vec3_origin, 73, count);
}
static void
R_GunshotEffect_QF (const vec3_t org, int count)
{
R_RunParticleEffect_QF (org, vec3_origin, 0, count);
}
static void
R_LightningBloodEffect_QF (const vec3_t org)
{
R_RunParticleEffect_QF (org, vec3_origin, 225, 50);
}
static void
R_RocketTrail_QF (const entity_t *ent)
{
float len;
int j;
particle_t *p;
vec3_t old_origin, vec;
if (!r_particles->int_val)
return;
VectorCopy (ent->old_origin, old_origin);
VectorSubtract (ent->origin, ent->old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
len -= 3;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
VectorZero (p->vel);
p->die = vr_data.realtime + 2;
p->ramp = (mtwist_rand (&mt) & 3);
p->color = ramp3[(int) p->ramp];
p->type = pt_fire;
p->phys = R_ParticlePhysics (p->type);
for (j = 0; j < 3; j++)
p->org[j] = old_origin[j] + ((mtwist_rand (&mt) % 6) - 3);
VectorAdd (old_origin, vec, old_origin);
}
}
static void
R_GrenadeTrail_QF (const entity_t *ent)
{
float len;
int j;
particle_t *p;
vec3_t old_origin, vec;
if (!r_particles->int_val)
return;
VectorCopy (ent->old_origin, old_origin);
VectorSubtract (ent->origin, old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
len -= 3;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
VectorZero (p->vel);
p->die = vr_data.realtime + 2;
p->ramp = (mtwist_rand (&mt) & 3) + 2;
p->color = ramp3[(int) p->ramp];
p->type = pt_fire;
p->phys = R_ParticlePhysics (p->type);
for (j = 0; j < 3; j++)
p->org[j] = old_origin[j] + ((mtwist_rand (&mt) % 6) - 3);
VectorAdd (old_origin, vec, old_origin);
}
}
static void
R_BloodTrail_QF (const entity_t *ent)
{
float len;
int j;
particle_t *p;
vec3_t old_origin, vec;
if (!r_particles->int_val)
return;
VectorCopy (ent->old_origin, old_origin);
VectorSubtract (ent->origin, old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
len -= 3;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
VectorZero (p->vel);
p->die = vr_data.realtime + 2;
p->type = pt_slowgrav;
p->phys = R_ParticlePhysics (p->type);
p->color = 67 + (mtwist_rand (&mt) & 3);
for (j = 0; j < 3; j++)
p->org[j] = old_origin[j] + ((mtwist_rand (&mt) % 6) - 3);
VectorAdd (old_origin, vec, old_origin);
}
}
static void
R_SlightBloodTrail_QF (const entity_t *ent)
{
float len;
int j;
particle_t *p;
vec3_t old_origin, vec;
if (!r_particles->int_val)
return;
VectorCopy (ent->old_origin, old_origin);
VectorSubtract (ent->origin, old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
len -= 6;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
VectorZero (p->vel);
p->die = vr_data.realtime + 2;
p->type = pt_slowgrav;
p->phys = R_ParticlePhysics (p->type);
p->color = 67 + (mtwist_rand (&mt) & 3);
for (j = 0; j < 3; j++)
p->org[j] = old_origin[j] + ((mtwist_rand (&mt) % 6) - 3);
VectorAdd (old_origin, vec, old_origin);
}
}
static void
R_WizTrail_QF (const entity_t *ent)
{
float len;
particle_t *p;
vec3_t old_origin, vec;
if (!r_particles->int_val)
return;
VectorCopy (ent->old_origin, old_origin);
VectorSubtract (ent->origin, old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
static int tracercount;
len -= 3;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 0.5;
p->type = pt_static;
p->phys = R_ParticlePhysics (p->type);
p->color = 52 + ((tracercount & 4) << 1);
tracercount++;
VectorCopy (old_origin, p->org);
if (tracercount & 1) {
p->vel[0] = 30.0 * vec[1];
p->vel[1] = 30.0 * -vec[0];
} else {
p->vel[0] = 30.0 * -vec[1];
p->vel[1] = 30.0 * vec[0];
}
p->vel[2] = 0.0;
VectorAdd (old_origin, vec, old_origin);
}
}
static void
R_FlameTrail_QF (const entity_t *ent)
{
float len;
particle_t *p;
vec3_t old_origin, vec;
if (!r_particles->int_val)
return;
VectorCopy (ent->old_origin, old_origin);
VectorSubtract (ent->origin, old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
static int tracercount;
len -= 3;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
p->die = vr_data.realtime + 0.5;
p->type = pt_static;
p->phys = R_ParticlePhysics (p->type);
p->color = 230 + ((tracercount & 4) << 1);
tracercount++;
VectorCopy (old_origin, p->org);
if (tracercount & 1) {
p->vel[0] = 30.0 * vec[1];
p->vel[1] = 30.0 * -vec[0];
} else {
p->vel[0] = 30.0 * -vec[1];
p->vel[1] = 30.0 * vec[0];
}
p->vel[2] = 0.0;
VectorAdd (old_origin, vec, old_origin);
}
}
static void
R_VoorTrail_QF (const entity_t *ent)
{
float len;
int j;
particle_t *p;
vec3_t old_origin, vec;
if (!r_particles->int_val)
return;
VectorCopy (ent->old_origin, old_origin);
VectorSubtract (ent->origin, old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
len -= 3;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
VectorZero (p->vel);
p->die = vr_data.realtime + 0.3;
p->type = pt_static;
p->phys = R_ParticlePhysics (p->type);
p->color = 9 * 16 + 8 + (mtwist_rand (&mt) & 3);
for (j = 0; j < 3; j++)
p->org[j] = old_origin[j] + ((mtwist_rand (&mt) & 15) - 8);
VectorAdd (old_origin, vec, old_origin);
}
}
void
sw32_R_DrawParticles (void)
{
particle_t *p, **particle;
VectorScale (vright, sw32_xscaleshrink, r_pright);
VectorScale (vup, sw32_yscaleshrink, r_pup);
VectorCopy (vpn, r_ppn);
for (particle = &active_particles; *particle;) {
if ((*particle)->die < vr_data.realtime) {
p = (*particle)->next;
(*particle)->next = free_particles;
free_particles = (*particle);
(*particle) = p;
} else {
p = *particle;
particle = &(*particle)->next;
sw32_D_DrawParticle (p);
p->phys (p);
}
}
}
void
sw32_r_easter_eggs_f (cvar_t *var)
{
}
void
sw32_r_particles_style_f (cvar_t *var)
{
}
static void
sw32_R_Particle_New (ptype_t type, int texnum, const vec3_t org, float scale,
const vec3_t vel, float die, int color, float alpha,
float ramp)
{
particle_t *p;
if (!free_particles)
return;
p = free_particles;
free_particles = p->next;
p->next = active_particles;
active_particles = p;
VectorCopy (org, p->org);
p->color = color;
p->tex = texnum;
p->scale = scale;
p->alpha = alpha;
VectorCopy (vel, p->vel);
p->type = type;
p->phys = R_ParticlePhysics (p->type);
p->die = die;
p->ramp = ramp;
}
static void
sw32_R_Particle_NewRandom (ptype_t type, int texnum, const vec3_t org,
int org_fuzz, float scale, int vel_fuzz, float die,
int color, float alpha, float ramp)
{
float o_fuzz = org_fuzz, v_fuzz = vel_fuzz;
int rnd;
vec3_t porg, pvel;
rnd = mtwist_rand (&mt);
porg[0] = o_fuzz * ((rnd & 63) - 31.5) / 63.0 + org[0];
porg[1] = o_fuzz * (((rnd >> 6) & 63) - 31.5) / 63.0 + org[1];
porg[2] = o_fuzz * (((rnd >> 12) & 63) - 31.5) / 63.0 + org[2];
rnd = mtwist_rand (&mt);
pvel[0] = v_fuzz * ((rnd & 63) - 31.5) / 63.0;
pvel[1] = v_fuzz * (((rnd >> 6) & 63) - 31.5) / 63.0;
pvel[2] = v_fuzz * (((rnd >> 12) & 63) - 31.5) / 63.0;
sw32_R_Particle_New (type, texnum, porg, scale, pvel, die, color, alpha, ramp);
}
static vid_particle_funcs_t particles_QF = {
R_RocketTrail_QF,
R_GrenadeTrail_QF,
R_BloodTrail_QF,
R_SlightBloodTrail_QF,
R_WizTrail_QF,
R_FlameTrail_QF,
R_VoorTrail_QF,
0,//R_GlowTrail_QF,
R_RunParticleEffect_QF,
R_BloodPuffEffect_QF,
R_GunshotEffect_QF,
R_LightningBloodEffect_QF,
R_SpikeEffect_QF,
R_KnightSpikeEffect_QF,
R_SuperSpikeEffect_QF,
R_WizSpikeEffect_QF,
R_BlobExplosion_QF,
R_ParticleExplosion_QF,
R_ParticleExplosion2_QF,
R_LavaSplash_QF,
R_TeleportSplash_QF,
R_DarkFieldParticles_ID,
R_EntityParticles_ID,
R_Particle_New,
R_Particle_NewRandom,
};
static void
R_ParticleFunctionInit (void)
{
sw32_vid_render_funcs.particles = &particles_QF;
}
static void
r_particles_nearclip_f (cvar_t *var)
{
Cvar_SetValue (r_particles_nearclip, bound (r_nearclip->value, var->value,
r_farclip->value));
}
static void
r_particles_f (cvar_t *var)
{
R_MaxParticlesCheck (var, r_particles_max);
}
static void
r_particles_max_f (cvar_t *var)
{
R_MaxParticlesCheck (r_particles, var);
}
void
sw32_R_Particles_Init_Cvars (void)
{
easter_eggs = Cvar_Get ("easter_eggs", "0", CVAR_NONE, r_easter_eggs_f,
"Enables easter eggs.");
r_particles = Cvar_Get ("r_particles", "1", CVAR_ARCHIVE, r_particles_f,
"Toggles drawing of particles.");
r_particles_max = Cvar_Get ("r_particles_max", "2048", CVAR_ARCHIVE,
r_particles_max_f, "Maximum amount of "
"particles to display. No maximum, minimum "
"is 0.");
r_particles_nearclip = Cvar_Get ("r_particles_nearclip", "32",
CVAR_ARCHIVE, r_particles_nearclip_f,
"Distance of the particle near clipping "
"plane from the player.");
r_particles_style = Cvar_Get ("r_particles_style", "1", CVAR_ARCHIVE,
r_particles_style_f, "Sets particle style. "
"0 for Id, 1 for QF.");
R_ParticleFunctionInit ();
}