quakeforge/qw/source/gl_dyn_part.c
Ragnvald Maartmann-Moe IV 93290fcb07 Easter's over. (aww...)
2001-04-20 19:45:42 +00:00

816 lines
20 KiB
C

/*
gl_dyn_part.c
OpenGL particle system.
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
$Id$
*/
#ifdef HAVE_CONFIG_H
# include "config.h"
#endif
#ifdef HAVE_STRING_H
# include <string.h>
#endif
#ifdef HAVE_STRINGS_H
# include <strings.h>
#endif
#include <stdlib.h>
#include "QF/cmd.h"
#include "QF/compat.h"
#include "QF/console.h"
#include "QF/qargs.h"
#include "QF/sys.h"
#include "client.h"
#include "glquake.h"
#include "host.h"
#include "r_dynamic.h"
#include "render.h"
typedef enum {
pt_static, pt_grav, pt_blob, pt_blob2,
pt_smoke, pt_smokering, pt_smokecloud, pt_bloodcloud,
pt_fadespark, pt_fadespark2, pt_fallfadespark
} ptype_t;
typedef struct particle_s {
vec3_t org;
vec3_t up;
vec3_t right;
int tex;
float color;
float alpha;
float scale;
vec3_t vel;
float ramp;
float die;
ptype_t type;
} particle_t;
typedef struct varray_s {
float texcoord[2];
unsigned char color[4];
float vertex[3];
} varray_t;
static particle_t *particles, **freeparticles;
static short r_numparticles, numparticles;
//static varray_t *vertex_array;
extern qboolean lighthalf;
extern cvar_t *cl_max_particles;
extern int part_tex_dot;
extern int part_tex_spark;
extern int part_tex_smoke[8];
extern int part_tex_smoke_ring[8];
int ramp[8] = { 0x6d, 0x6b, 0x06, 0x05, 0x04, 0x03, 0x02, 0x01 };
inline particle_t *
particle_new (ptype_t type, int texnum, vec3_t org, float scale, vec3_t vel,
float die, byte color, byte alpha, vec3_t up, vec3_t right)
{
particle_t *part;
if (numparticles >= r_numparticles) {
// Con_Printf("FAILED PARTICLE ALLOC!\n");
return NULL;
}
part = &particles[numparticles++];
part->type = type;
VectorCopy (org, part->org);
VectorCopy (vel, part->vel);
part->die = die;
part->color = color;
part->alpha = alpha;
part->tex = texnum;
part->scale = scale;
VectorScale (up, 1.5, part->up);
VectorScale (right, 1.5, part->right);
return part;
}
inline particle_t *
particle_new_random (ptype_t type, int texnum, vec3_t org, int org_fuzz,
float scale, int vel_fuzz, float die, byte color,
byte alpha)
{
vec3_t porg, pvel;
int j;
for (j = 0; j < 3; j++) {
if (org_fuzz)
porg[j] = lhrandom (-org_fuzz, org_fuzz) + org[j];
if (vel_fuzz)
pvel[j] = lhrandom (-vel_fuzz, vel_fuzz);
}
return particle_new (type, texnum, porg, scale, pvel, die, color, alpha, vec3_origin, vec3_origin);
}
/*
R_MaxParticlesCheck
Misty-chan: Dynamically change the maximum amount of particles on the fly.
Thanks to a LOT of help from Taniwha, Deek, Mercury, Lordhavoc, and lots of others.
*/
void
R_MaxParticlesCheck (cvar_t *var)
{
/*
Catchall. If the user changed the setting to a number less than zero *or* if we had a wacky cfg get past
the init code check, this will make sure we don't have problems. Also note that grabbing the var->int_val is IMPORTANT:
Prevents a segfault since if we grabbed the int_val of cl_max_particles we'd sig11 right here at startup.
*/
r_numparticles = max(var->int_val, 0);
/*
Enable this to see how many particles are ACTUALLY allocated whenever you do a cl_max_particles change
Also note it's damned useful for checking for if this thing is running more than it should!
Con_Printf ("%d", r_numparticles);
*/
// Be very careful the next time we do something like this. calloc/free are IMPORTANT
// and the compiler doesn't know when we do bad things with them.
free (particles);
free (freeparticles);
//free (vertex_array);
particles = (particle_t *)
calloc (r_numparticles, sizeof (particle_t));
freeparticles = (particle_t **)
calloc (r_numparticles, sizeof (particle_t*));
//vertex_array = (float *) calloc(r_numparticles, sizeof (varray_t));
R_ClearParticles();
}
/*
R_Particles_Init_Cvars
*/
void
R_Particles_Init_Cvars (void)
{
// Misty-chan: This is a cvar that does callbacks. Whenever it
// changes, it calls the function R_MaxParticlesCheck and therefore
// is very nifty.
Cvar_Get ("cl_max_particles", "2048", CVAR_ARCHIVE, R_MaxParticlesCheck,
"Maximum amount of particles to display. No maximum, minimum is 0, although it's best to use r_particles 0 instead.");
}
/*
R_ClearParticles
*/
void
R_ClearParticles (void)
{
numparticles = 0;
}
void
R_ReadPointFile_f (void)
{
QFile *f;
vec3_t org;
int r;
int c;
char name[MAX_OSPATH], *mapname, *t1;
mapname = strdup (cl.worldmodel->name);
if (!mapname)
Sys_Error ("Can't duplicate mapname!");
t1 = strrchr (mapname, '.');
if (!t1)
Sys_Error ("Can't find .!");
t1[0] = '\0';
snprintf (name, sizeof (name), "%s.pts", mapname);
free (mapname);
COM_FOpenFile (name, &f);
if (!f) {
Con_Printf ("couldn't open %s\n", name);
return;
}
Con_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 (!particle_new (pt_static, part_tex_dot, org, 1.5, vec3_origin,
99999, (-c) & 15, 255, vec3_origin, vec3_origin)) {
Con_Printf ("Not enough free particles\n");
break;
}
}
Qclose (f);
Con_Printf ("%i points read\n", c);
}
/*
R_ParticleExplosion
*/
void
R_ParticleExplosion (vec3_t org)
{
if (!r_particles->int_val)
return;
particle_new_random (pt_smokecloud, part_tex_smoke[rand () & 7], org, 4, 30,
8, cl.time + 5, (rand () & 7) + 8,
128 + (rand () & 63));
}
/*
R_BlobExplosion
*/
void
R_BlobExplosion (vec3_t org)
{
int i;
if (!r_particles->int_val)
return;
for (i = 0; i < 512; i++) {
particle_new_random (pt_blob, part_tex_dot, org, 12, 2, 256,
(cl.time + 1 + (rand () & 8) * 0.05),
(66 + rand () % 6), 255);
}
for (i = 0; i < 512; i++) {
particle_new_random (pt_blob2, part_tex_dot, org, 12, 2, 256,
(cl.time + 1 + (rand () & 8) * 0.05),
(150 + rand () % 6), 255);
}
}
static void
R_RunSparkEffect (vec3_t org, int count, int ofuzz)
{
if (!r_particles->int_val)
return;
particle_new (pt_smokecloud, part_tex_smoke[rand () & 7], org,
(ofuzz / 8) * .75, vec3_origin, cl.time + 99,
12 + (rand () & 3), 96, vec3_origin, vec3_origin);
while (count--)
particle_new_random (pt_fallfadespark, part_tex_spark, org, ofuzz * .75,
1, 96, cl.time + 5, ramp[rand () % 6],
lhrandom (0, 255));
}
static void
R_RunGunshotEffect (vec3_t org, int count)
{
int scale;
if (!r_particles->int_val)
return;
if (count > 6)
scale = 3;
else
scale = 2;
R_RunSparkEffect (org, count * 10, 8 * scale);
return;
}
static void
R_BloodPuff (vec3_t org, int count)
{
if (!r_particles->int_val)
return;
particle_new (pt_bloodcloud, part_tex_smoke[rand () & 7], org, 9,
vec3_origin, cl.time + 99, 68 + (rand () & 3), 128,
vec3_origin, vec3_origin);
}
/*
R_RunPuffEffect
*/
void
R_RunPuffEffect (vec3_t org, byte type, byte count)
{
if (!r_particles->int_val)
return;
switch (type) {
case TE_GUNSHOT:
R_RunGunshotEffect (org, count);
break;
case TE_BLOOD:
R_BloodPuff (org, count);
break;
case TE_LIGHTNINGBLOOD:
R_BloodPuff (org, 5 + (rand () & 1));
break;
}
}
/*
R_RunParticleEffect
*/
void
R_RunParticleEffect (vec3_t org, int color, int count)
{
int i, j, scale;
vec3_t porg;
if (!r_particles->int_val)
return;
if (count > 130)
scale = 3;
else if (count > 20)
scale = 2;
else
scale = 1;
for (i = 0; i < count; i++) {
for (j = 0; j < 3; j++) {
porg[j] = org[j] + scale * ((rand () & 15) - 8);
}
particle_new (pt_grav, part_tex_dot, porg, 1.5, vec3_origin,
(cl.time + 0.1 * (rand () % 5)),
(color & ~7) + (rand () & 7), 255, vec3_origin, vec3_origin);
}
}
void
R_RunSpikeEffect (vec3_t org, byte type)
{
switch (type) {
case TE_SPIKE:
R_RunSparkEffect (org, 5, 8);
break;
case TE_SUPERSPIKE:
R_RunSparkEffect (org, 10, 8);
break;
case TE_KNIGHTSPIKE:
R_RunSparkEffect (org, 10, 8);
break;
case TE_WIZSPIKE:
R_RunSparkEffect (org, 15, 16);
break;
}
}
/*
R_LavaSplash
*/
void
R_LavaSplash (vec3_t org)
{
int i, j;
float vel;
vec3_t dir, porg, pvel;
if (!r_particles->int_val)
return;
for (i = -8; i < 8; i++) {
for (j = -8; j < 8; j++) {
dir[0] = j * 16 + (rand () & 7);
dir[1] = i * 16 + (rand () & 7);
dir[2] = 256;
porg[0] = org[0] + dir[0];
porg[1] = org[1] + dir[1];
porg[2] = org[2] + (rand () & 63);
VectorNormalize (dir);
vel = 50 + (rand () & 63);
VectorScale (dir, vel, pvel);
particle_new (pt_grav, part_tex_dot, porg, 3, pvel,
(cl.time + 2 + (rand () & 31) * 0.02),
(224 + (rand () & 7)), 193, vec3_origin, vec3_origin);
}
}
}
/*
R_TeleportSplash
*/
void
R_TeleportSplash (vec3_t org)
{
int i, j, k;
float vel;
vec3_t dir, porg, pvel;
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) {
dir[0] = j * 8;
dir[1] = i * 8;
dir[2] = k * 8;
porg[0] = org[0] + i + (rand () & 3);
porg[1] = org[1] + j + (rand () & 3);
porg[2] = org[2] + k + (rand () & 3);
VectorNormalize (dir);
vel = 50 + (rand () & 63);
VectorScale (dir, vel, pvel);
particle_new (pt_grav, part_tex_spark, porg, 0.6, pvel,
(cl.time + 0.2 + (rand () & 7) * 0.02),
(7 + (rand () & 7)), 255, vec3_origin, vec3_origin);
}
}
void
R_RocketTrail (int type, entity_t *ent)
{
vec3_t vec, subtract;
float len, dist;
int j, ptex;
ptype_t ptype;
vec3_t porg, pvel, up, right;
float pdie, pscale;
byte palpha, pcolor;
if (type == 0)
R_AddFire (ent->old_origin, ent->origin, ent);
if (!r_particles->int_val)
return;
VectorSubtract (ent->origin, ent->old_origin, vec);
len = VectorNormalize (vec);
while (len > 0) {
VectorCopy (vec3_origin, up);
VectorCopy (vec3_origin, right);
VectorCopy (vec3_origin, pvel);
pdie = cl.time + 2;
ptype = pt_static;
ptex = part_tex_dot;
palpha = 255;
pcolor = 0;
pscale = 6;
dist = 40;
switch (type) {
case 0: // rocket trail
pdie = cl.time + 60;
// ptype = pt_smokering; // Mercury's Rings
ptype = pt_smoke;
pscale = lhrandom (9, 12);
// pcolor = (rand () & 255); // Misty-chan's Easter Egg
pcolor = (rand () & 3) + 12;
palpha = 128 + (rand () & 31);
// VectorVectors(vec, right, up); // Mercury's Rings
VectorCopy (ent->old_origin, porg);
// ptex = part_tex_smoke_ring[rand () & 7]; // Mercury's Rings
ptex = part_tex_smoke[rand () & 7];
break;
case 1: // grenade trail
ptype = pt_smoke;
pscale = lhrandom (6, 9);
// pcolor = (rand () & 255); // Misty-chan's Easter Egg
pcolor = (rand () & 2);
palpha = 128 + (rand () & 31);
VectorCopy (ent->old_origin, porg);
ptex = part_tex_smoke[rand () & 7];
break;
case 2: // blood
pscale = 12;
case 4: // slight blood
pscale += lhrandom (0, 3);
ptex = part_tex_smoke[rand () & 7];
pcolor = 68 + (rand () & 3);
for (j = 0; j < 3; j++) {
pvel[j] = lhrandom (-3, 3) * type;
porg[j] = ent->old_origin[j] + lhrandom (-1.5, 1.5);
}
ptype = pt_grav;
break;
case 6: // voor trail
// Use smoke ring effects here, once merged with nq? --Despair
dist = 3;
pcolor = 9 * 16 + 8 + (rand () & 3);
ptype = pt_static;
pscale = lhrandom (.75, 1.5);
pdie = cl.time + 0.3;
for (j = 0; j < 3; j++)
porg[j] = ent->old_origin[j] + lhrandom (-8, 8);
break;
case 3:
case 5: // tracer
{
static int tracercount;
dist = 3;
pdie = cl.time + 0.5;
ptype = pt_static;
pscale = lhrandom (1.5, 3);
if (type == 3)
pcolor = 52 + ((tracercount & 4) << 1);
else
pcolor = 230 + ((tracercount & 4) << 1);
tracercount++;
VectorCopy (ent->old_origin, porg);
if (tracercount & 1) {
pvel[0] = 30 * vec[1];
pvel[1] = 30 * -vec[0];
} else {
pvel[0] = 30 * -vec[1];
pvel[1] = 30 * vec[0];
}
break;
}
}
VectorScale (vec, min(dist, len), subtract);
VectorAdd (ent->old_origin, subtract, ent->old_origin);
len -= dist;
particle_new (ptype, ptex, porg, pscale, pvel, pdie, pcolor, palpha,
up, right);
}
}
/*
R_DrawParticles
*/
void
R_DrawParticles (void)
{
byte i;
float grav, fast_grav, dvel;
float minparticledist;
unsigned char *at;
byte alpha;
float scale;
particle_t *part;
vec3_t up, right, o_up, o_right;
vec3_t up_scale, right_scale, up_right_scale;
int activeparticles, maxparticle, j, k, vnum;
varray_t vertex_array[4];
// LordHavoc: particles should not affect zbuffer
glDepthMask (GL_FALSE);
VectorScale (vup, 1.5, o_up);
VectorScale (vright, 1.5, o_right);
glInterleavedArrays (GL_T2F_C4UB_V3F, 0, (void *) &(vertex_array[0]));
vertex_array[0].texcoord[0] = 0; vertex_array[0].texcoord[1] = 1;
vertex_array[1].texcoord[0] = 0; vertex_array[1].texcoord[1] = 0;
vertex_array[2].texcoord[0] = 1; vertex_array[2].texcoord[1] = 0;
vertex_array[3].texcoord[0] = 1; vertex_array[3].texcoord[1] = 1;
vnum = 0;
grav = (fast_grav = host_frametime * 800) * 0.05;
dvel = 4 * host_frametime;
minparticledist = DotProduct (r_refdef.vieworg, vpn) + 32.0f;
activeparticles = 0;
maxparticle = -1;
j = 0;
for (k = 0, part = particles; k < numparticles; k++, part++) {
// LordHavoc: this is probably no longer necessary, as it is checked at the end, but could still happen on weird particle effects, left for safety...
if (part->die <= cl.time) {
freeparticles[j++] = part;
continue;
}
maxparticle = k;
activeparticles++;
// Don't render particles too close to us.
// Note, we must still do physics and such on them.
if (!(DotProduct (part->org, vpn) < minparticledist) &&
r_particles->int_val) {
at = (byte *) & d_8to24table[(byte) part->color];
alpha = part->alpha;
if (VectorCompare(part->up, part->right)) {
memcpy(up, o_up, sizeof(up));
memcpy(right, o_right, sizeof(right));
} else {
memcpy(up, part->up, sizeof(up));
memcpy(right, part->right, sizeof(right));
}
if (lighthalf) {
vertex_array[0].color[0] = (byte) ((int) at[0] >> 1);
vertex_array[0].color[1] = (byte) ((int) at[1] >> 1);
vertex_array[0].color[2] = (byte) ((int) at[2] >> 1);
} else {
memcpy(vertex_array[0].color, at, 3);
}
vertex_array[0].color[3] = alpha;
memcpy(vertex_array[1].color, vertex_array[0].color, 4);
memcpy(vertex_array[2].color, vertex_array[0].color, 4);
memcpy(vertex_array[3].color, vertex_array[0].color, 4);
scale = part->scale;
up_scale[0] = up[0] * scale;
up_scale[1] = up[1] * scale;
up_scale[2] = up[2] * scale;
right_scale[0] = right[0] * scale;
right_scale[1] = right[1] * scale;
right_scale[2] = right[2] * scale;
up_right_scale[0] = (up[0] + right[0]) * scale;
up_right_scale[1] = (up[1] + right[1]) * scale;
up_right_scale[2] = (up[2] + right[2]) * scale;
vertex_array[0].vertex[0] = part->org[0] + up_right_scale[0];
vertex_array[0].vertex[1] = part->org[1] + up_right_scale[1];
vertex_array[0].vertex[2] = part->org[2] + up_right_scale[2];
vertex_array[1].vertex[0] =
part->org[0] + (-up_scale[0]) + right_scale[0];
vertex_array[1].vertex[1] =
part->org[1] + (-up_scale[1]) + right_scale[1];
vertex_array[1].vertex[2] =
part->org[2] + (-up_scale[2]) + right_scale[2];
vertex_array[2].vertex[0] = part->org[0] + -up_right_scale[0];
vertex_array[2].vertex[1] = part->org[1] + -up_right_scale[1];
vertex_array[2].vertex[2] = part->org[2] + -up_right_scale[2];
vertex_array[3].vertex[0] =
part->org[0] + up_scale[0] + (-right_scale[0]);
vertex_array[3].vertex[1] =
part->org[1] + up_scale[1] + (-right_scale[1]);
vertex_array[3].vertex[2] =
part->org[2] + up_scale[2] + (-right_scale[2]);
/*
*/
/*
vertex_array[0].vertex[0] =
(part->org[0] + ((up[0] + right[0]) * scale));
vertex_array[0].vertex[1] =
(part->org[1] + ((up[1] + right[1]) * scale));
vertex_array[0].vertex[2] =
(part->org[2] + ((up[2] + right[2]) * scale));
vertex_array[1].vertex[0] =
(part->org[0] + (up[0] * -scale) + (right[0] * scale));
vertex_array[1].vertex[1] =
(part->org[1] + (up[1] * -scale) + (right[1] * scale));
vertex_array[1].vertex[2] =
(part->org[2] + (up[2] * -scale) + (right[2] * scale));
vertex_array[2].vertex[0] =
(part->org[0] + ((up[0] + right[0]) * -scale));
vertex_array[2].vertex[1] =
(part->org[1] + ((up[1] + right[1]) * -scale));
vertex_array[2].vertex[2] =
(part->org[2] + ((up[2] + right[2]) * -scale));
vertex_array[3].vertex[0] =
(part->org[0] + (up[0] * scale) + (right[0] * -scale));
vertex_array[3].vertex[1] =
(part->org[1] + (up[1] * scale) + (right[1] * -scale));
vertex_array[3].vertex[2] =
(part->org[2] + (up[2] * scale) + (right[2] * -scale));
*/
glBindTexture (GL_TEXTURE_2D, part->tex);
glDrawArrays (GL_QUADS, 0, 4);
}
for (i = 0; i < 3; i++)
part->org[i] += part->vel[i] * host_frametime;
switch (part->type) {
case pt_static:
break;
case pt_blob:
for (i = 0; i < 3; i++)
part->vel[i] += part->vel[i] * dvel;
part->vel[2] -= grav;
break;
case pt_blob2:
for (i = 0; i < 2; i++)
part->vel[i] -= part->vel[i] * dvel;
part->vel[2] -= grav;
break;
case pt_grav:
part->vel[2] -= grav;
break;
case pt_smoke:
if ((part->alpha -= host_frametime * 90) < 1)
part->die = -1;
part->scale += host_frametime * 6;
part->org[2] += host_frametime * 30;
break;
case pt_smokering:
if ((part->alpha -= host_frametime * 130) < 1)
part->die = -1;
part->scale += host_frametime * 10;
part->org[2] += host_frametime * 30;
break;
case pt_smokecloud:
if ((part->alpha -= host_frametime * 128) < 1)
part->die = -1;
part->scale += host_frametime * 60;
part->org[2] += host_frametime * 90;
break;
case pt_bloodcloud:
/*
if (Mod_PointInLeaf(part->org, cl.worldmodel)->contents != CONTENTS_EMPTY)
{
part->die = -1;
break;
}
*/
if ((part->alpha -= host_frametime * 64) < 1)
{
part->die = -1;
// extra break only helps here
break;
}
part->scale += host_frametime * 4;
part->vel[2] -= grav;
break;
case pt_fadespark:
if ((part->alpha -= host_frametime * 256) < 1)
part->die = -1;
part->vel[2] -= grav;
break;
case pt_fadespark2:
if ((part->alpha -= host_frametime * 512) < 1)
part->die = -1;
part->vel[2] -= grav;
break;
case pt_fallfadespark:
if ((part->alpha -= host_frametime * 256) < 1)
part->die = -1;
part->vel[2] -= fast_grav;
break;
}
// LordHavoc: immediate removal of unnecessary particles (must be done to ensure compactor below operates properly in all cases)
if (part->die <= cl.time)
freeparticles[j++] = part;
}
k = 0;
while (maxparticle >= activeparticles) {
*freeparticles[k++] = particles[maxparticle--];
while (maxparticle >= activeparticles
&& particles[maxparticle].die <= cl.time)
maxparticle--;
}
numparticles = activeparticles;
glColor3ubv (lighthalf_v);
glDepthMask (GL_TRUE);
}