#define NUMVERTEXNORMALS 162
siextern float r_avertexnormals[NUMVERTEXNORMALS][3];
#define m_bytenormals r_avertexnormals
-#define VectorNormalizeFast VectorNormalize
#define CL_PointQ1Contents(v) (Mod_PointInLeaf(v,cl.worldmodel)->contents)
typedef unsigned char qbyte;
#define cl_stainmaps.integer 0
#define CL_ParseParticleEffect R_ParseParticleEffect
#define CL_ParticleExplosion R_ParticleExplosion
#define CL_ParticleExplosion2 R_ParticleExplosion2
+#define CL_TeleportSplash R_TeleportSplash
#define CL_BlobExplosion R_BlobExplosion
#define CL_RunParticleEffect R_RunParticleEffect
#define CL_LavaSplash R_LavaSplash
-#define CL_RocketTrail2 R_RocketTrail2
void R_CalcBeam_Vertex3f (float *vert, vec3_t org1, vec3_t org2, float width)
{
vec3_t right1, right2, diff, normal;
VectorSubtract (org2, org1, normal);
- VectorNormalizeFast (normal);
+ VectorNormalize (normal);
// calculate 'right' vector for start
VectorSubtract (r_vieworigin, org1, diff);
- VectorNormalizeFast (diff);
+ VectorNormalize (diff);
CrossProduct (normal, diff, right1);
// calculate 'right' vector for end
VectorSubtract (r_vieworigin, org2, diff);
- VectorNormalizeFast (diff);
+ VectorNormalize (diff);
CrossProduct (normal, diff, right2);
vert[ 0] = org1[0] + width * right1[0];
for (sizepower = 0;(1 << sizepower) < size;sizepower++);
if (size != (1 << sizepower))
- Sys_Error("fractalnoise: size must be power of 2\n");
+ {
+ Con_Printf("fractalnoise: size must be power of 2\n");
+ return;
+ }
for (gridpower = 0;(1 << gridpower) < startgrid;gridpower++);
if (startgrid != (1 << gridpower))
- Sys_Error("fractalnoise: grid must be power of 2\n");
+ {
+ Con_Printf("fractalnoise: grid must be power of 2\n");
+ return;
+ }
startgrid = bound(0, startgrid, size);
right[0] -= d * forward[0];
right[1] -= d * forward[1];
right[2] -= d * forward[2];
- VectorNormalizeFast(right);
+ VectorNormalize(right);
CrossProduct(right, forward, up);
}
#if QW
#include "pmove.h"
extern qboolean PM_RecursiveHullCheck (hull_t *hull, int num, float p1f, float p2f, vec3_t p1, vec3_t p2, pmtrace_t *trace);
#endif
-float CL_TraceLine (vec3_t start, vec3_t end, vec3_t impact, vec3_t normal, int hitbmodels, void **hitent, int hitsupercontentsmask)
+trace_t CL_TraceBox (vec3_t start, vec3_t mins, vec3_t maxs, vec3_t end, int hitbmodels, int *hitent, int hitsupercontentsmask, qboolean hitplayers)
{
#if QW
pmtrace_t trace;
#else
RecursiveHullCheck (cl.worldmodel->hulls, 0, 0, 1, start, end, &trace);
#endif
- VectorCopy(trace.endpos, impact);
- VectorCopy(trace.plane.normal, normal);
- return trace.fraction;
+ return trace;
}
#else
#include "cl_collision.h"
#define MAX_PARTICLES 32768 // default max # of particles at one time
#define ABSOLUTE_MIN_PARTICLES 512 // no fewer than this no matter what's on the command line
-typedef enum
-{
- pt_dead, pt_static, pt_rain, pt_bubble, pt_blood, pt_grow, pt_decal, pt_decalfade, pt_ember
-}
-ptype_t;
-
typedef enum
{
PARTICLE_BILLBOARD = 0,
}
pblend_t;
+typedef struct particletype_s
+{
+ pblend_t blendmode;
+ porientation_t orientation;
+ qboolean lighting;
+}
+particletype_t;
+
+typedef enum
+{
+ pt_alphastatic, pt_static, pt_spark, pt_beam, pt_rain, pt_raindecal, pt_snow, pt_bubble, pt_blood, pt_smoke, pt_decal, pt_entityparticle, pt_total
+}
+ptype_t;
+
+// must match ptype_t values
+particletype_t particletype[pt_total] =
+{
+ {PBLEND_ALPHA, PARTICLE_BILLBOARD, false}, //pt_alphastatic
+ {PBLEND_ADD, PARTICLE_BILLBOARD, false}, //pt_static
+ {PBLEND_ADD, PARTICLE_SPARK, false}, //pt_spark
+ {PBLEND_ADD, PARTICLE_BEAM, false}, //pt_beam
+ {PBLEND_ADD, PARTICLE_SPARK, false}, //pt_rain
+ {PBLEND_ADD, PARTICLE_ORIENTED_DOUBLESIDED, false}, //pt_raindecal
+ {PBLEND_ADD, PARTICLE_BILLBOARD, false}, //pt_snow
+ {PBLEND_ADD, PARTICLE_BILLBOARD, false}, //pt_bubble
+ {PBLEND_MOD, PARTICLE_BILLBOARD, false}, //pt_blood
+ {PBLEND_ADD, PARTICLE_BILLBOARD, false}, //pt_smoke
+ {PBLEND_MOD, PARTICLE_ORIENTED_DOUBLESIDED, false}, //pt_decal
+ {PBLEND_ALPHA, PARTICLE_BILLBOARD, false}, //pt_entityparticle
+};
+
typedef struct particle_s
{
- ptype_t type;
- int orientation;
+ particletype_t *type;
int texnum;
- int blendmode;
vec3_t org;
- vec3_t vel;
- float die;
- float scalex;
- float scaley;
+ vec3_t vel; // velocity of particle, or orientation of decal, or end point of beam
+ float size;
float alpha; // 0-255
float alphafade; // how much alpha reduces per second
- float time2; // used for various things (snow fluttering, for example)
+ float time2; // used for snow fluttering and decal fade
float bounce; // how much bounce-back from a surface the particle hits (0 = no physics, 1 = stop and slide, 2 = keep bouncing forever, 1.5 is typical)
float gravity; // how much gravity affects this particle (1.0 = normal gravity, 0.0 = none)
- vec3_t oldorg;
- vec3_t vel2; // used for snow fluttering (base velocity, wind for instance)
float friction; // how much air friction affects this object (objects with a low mass/size ratio tend to get more air friction)
- float pressure; // if non-zero, apply pressure to other particles
qbyte color[4];
-#ifndef WORKINGLQUAKE
- entity_render_t *owner; // decal stuck to this entity
+ unsigned short owner; // decal stuck to this entity
model_t *ownermodel; // model the decal is stuck to (used to make sure the entity is still alive)
vec3_t relativeorigin; // decal at this location in entity's coordinate space
vec3_t relativedirection; // decal oriented this way relative to entity's coordinate space
-#endif
}
particle_t;
cvar_t cl_particles_blood_alpha = {CVAR_SAVE, "cl_particles_blood_alpha", "0.5"};
cvar_t cl_particles_blood_bloodhack = {CVAR_SAVE, "cl_particles_blood_bloodhack", "1"};
cvar_t cl_particles_bulletimpacts = {CVAR_SAVE, "cl_particles_bulletimpacts", "1"};
+cvar_t cl_particles_explosions_bubbles = {CVAR_SAVE, "cl_particles_explosions_bubbles", "1"};
+cvar_t cl_particles_explosions_smoke = {CVAR_SAVE, "cl_particles_explosions_smokes", "0"};
+cvar_t cl_particles_explosions_sparks = {CVAR_SAVE, "cl_particles_explosions_sparks", "1"};
+cvar_t cl_particles_explosions_shell = {CVAR_SAVE, "cl_particles_explosions_shell", "0"};
cvar_t cl_particles_smoke = {CVAR_SAVE, "cl_particles_smoke", "1"};
cvar_t cl_particles_smoke_alpha = {CVAR_SAVE, "cl_particles_smoke_alpha", "0.5"};
cvar_t cl_particles_smoke_alphafade = {CVAR_SAVE, "cl_particles_smoke_alphafade", "0.55"};
cvar_t cl_decals_time = {CVAR_SAVE, "cl_decals_time", "0"};
cvar_t cl_decals_fadetime = {CVAR_SAVE, "cl_decals_fadetime", "20"};
-#ifndef WORKINGLQUAKE
-static mempool_t *cl_part_mempool;
-#endif
-
void CL_Particles_Clear(void)
{
cl_numparticles = 0;
{
int i;
+// COMMANDLINEOPTION: Client: -particles <number> changes maximum number of particles at once, default 32768
i = COM_CheckParm ("-particles");
if (i && i < com_argc - 1)
Cvar_RegisterVariable (&cl_particles_blood);
Cvar_RegisterVariable (&cl_particles_blood_alpha);
Cvar_RegisterVariable (&cl_particles_blood_bloodhack);
+ Cvar_RegisterVariable (&cl_particles_explosions_bubbles);
+ Cvar_RegisterVariable (&cl_particles_explosions_smoke);
+ Cvar_RegisterVariable (&cl_particles_explosions_sparks);
+ Cvar_RegisterVariable (&cl_particles_explosions_shell);
Cvar_RegisterVariable (&cl_particles_bulletimpacts);
Cvar_RegisterVariable (&cl_particles_smoke);
Cvar_RegisterVariable (&cl_particles_smoke_alpha);
#ifdef WORKINGLQUAKE
particles = (particle_t *) Hunk_AllocName(cl_maxparticles * sizeof(particle_t), "particles");
#else
- cl_part_mempool = Mem_AllocPool("CL_Part", 0, NULL);
- particles = (particle_t *) Mem_Alloc(cl_part_mempool, cl_maxparticles * sizeof(particle_t));
+ particles = (particle_t *) Mem_Alloc(cl_mempool, cl_maxparticles * sizeof(particle_t));
#endif
CL_Particles_Clear();
}
+void CL_Particles_Shutdown (void)
+{
+#ifdef WORKINGLQUAKE
+ // No clue what to do here...
+#endif
+}
+
// list of all 26 parameters:
// ptype - any of the pt_ enum values (pt_static, pt_blood, etc), see ptype_t near the top of this file
-// porientation - PARTICLE_ enum values (PARTICLE_BILLBOARD, PARTICLE_SPARK, etc)
// pcolor1,pcolor2 - minimum and maximum ranges of color, randomly interpolated to decide particle color
// ptex - any of the tex_ values such as tex_smoke[rand()&7] or tex_particle
-// plight - no longer used (this used to turn on particle lighting)
-// pblendmode - PBLEND_ enum values (PBLEND_ALPHA, PBLEND_ADD, etc)
-// pscalex,pscaley - width and height of particle (according to orientation), these are normally the same except when making sparks and beams
+// psize - size of particle (or thickness for PARTICLE_SPARK and PARTICLE_BEAM)
// palpha - opacity of particle as 0-255 (can be more than 255)
// palphafade - rate of fade per second (so 256 would mean a 256 alpha particle would fade to nothing in 1 second)
// ptime - how long the particle can live (note it is also removed if alpha drops to nothing)
// pbounce - how much bounce the particle has when it hits a surface (0-1), -1 makes a blood splat when it hits a surface, 0 does not even check for collisions
// px,py,pz - starting origin of particle
// pvx,pvy,pvz - starting velocity of particle
-// ptime2 - extra time parameter for certain particle types (pt_decal delayed fades and pt_rain snowflutter use this)
-// pvx2,pvy2,pvz2 - for PARTICLE_ORIENTED_DOUBLESIDED this is the surface normal of the orientation (forward vector), pt_rain uses this for snow fluttering
// pfriction - how much the particle slows down per second (0-1 typically, can slowdown faster than 1)
-// ppressure - pushes other particles away if they are within 64 units distance, the force is based on scalex, this feature is supported but not currently used
-particle_t *particle(ptype_t ptype, porientation_t porientation, int pcolor1, int pcolor2, int ptex, int plight, pblend_t pblendmode, float pscalex, float pscaley, float palpha, float palphafade, float ptime, float pgravity, float pbounce, float px, float py, float pz, float pvx, float pvy, float pvz, float ptime2, float pvx2, float pvy2, float pvz2, float pfriction, float ppressure)
+particle_t *particle(particletype_t *ptype, int pcolor1, int pcolor2, int ptex, float psize, float palpha, float palphafade, float pgravity, float pbounce, float px, float py, float pz, float pvx, float pvy, float pvz, float pfriction)
{
particle_t *part;
int ptempcolor, ptempcolor2, pcr1, pcg1, pcb1, pcr2, pcg2, pcb2;
part->color[1] = pcg2;
part->color[2] = pcb2;
part->color[3] = 0xFF;
- part->orientation = porientation;
part->texnum = ptex;
- part->blendmode = pblendmode;
- part->scalex = (pscalex);
- part->scaley = (pscaley);
+ part->size = (psize);
part->alpha = (palpha);
part->alphafade = (palphafade);
- part->die = cl.time + (ptime);
part->gravity = (pgravity);
part->bounce = (pbounce);
part->org[0] = (px);
part->vel[0] = (pvx);
part->vel[1] = (pvy);
part->vel[2] = (pvz);
- part->time2 = (ptime2);
- part->vel2[0] = (pvx2);
- part->vel2[1] = (pvy2);
- part->vel2[2] = (pvz2);
+ part->time2 = 0;
part->friction = (pfriction);
- part->pressure = (ppressure);
return part;
}
-void CL_SpawnDecalParticleForSurface(void *hitent, const vec3_t org, const vec3_t normal, int color1, int color2, int texnum, float size, float alpha)
+void CL_SpawnDecalParticleForSurface(int hitent, const vec3_t org, const vec3_t normal, int color1, int color2, int texnum, float size, float alpha)
{
particle_t *p;
if (!cl_decals.integer)
return;
- p = particle(pt_decal, PARTICLE_ORIENTED_DOUBLESIDED, color1, color2, texnum, false, PBLEND_MOD, size, size, alpha, 0, cl_decals_time.value + cl_decals_fadetime.value, 0, 0, org[0] + normal[0], org[1] + normal[1], org[2] + normal[2], 0, 0, 0, cl.time + cl_decals_time.value, normal[0], normal[1], normal[2], 0, 0);
-#ifndef WORKINGLQUAKE
+ p = particle(particletype + pt_decal, color1, color2, texnum, size, alpha, 0, 0, 0, org[0] + normal[0], org[1] + normal[1], org[2] + normal[2], normal[0], normal[1], normal[2], 0);
if (p)
{
+ p->time2 = cl.time;
+#ifndef WORKINGLQUAKE
p->owner = hitent;
- p->ownermodel = p->owner->model;
- Matrix4x4_Transform(&p->owner->inversematrix, org, p->relativeorigin);
- Matrix4x4_Transform3x3(&p->owner->inversematrix, normal, p->relativedirection);
+ p->ownermodel = cl_entities[p->owner].render.model;
+ Matrix4x4_Transform(&cl_entities[p->owner].render.inversematrix, org, p->relativeorigin);
+ Matrix4x4_Transform3x3(&cl_entities[p->owner].render.inversematrix, normal, p->relativedirection);
VectorAdd(p->relativeorigin, p->relativedirection, p->relativeorigin);
- }
#endif
+ }
}
void CL_SpawnDecalParticleForPoint(const vec3_t org, float maxdist, float size, float alpha, int texnum, int color1, int color2)
{
int i;
float bestfrac, bestorg[3], bestnormal[3];
- float frac, v[3], normal[3], org2[3];
-#ifdef WORKINGLQUAKE
- void *besthitent = NULL, *hitent;
-#else
- entity_render_t *besthitent = NULL, *hitent;
-#endif
+ float org2[3];
+ int besthitent = 0, hitent;
+ trace_t trace;
bestfrac = 10;
for (i = 0;i < 32;i++)
{
VectorRandom(org2);
VectorMA(org, maxdist, org2, org2);
- frac = CL_TraceLine(org, org2, v, normal, true, &hitent, SUPERCONTENTS_SOLID);
- if (bestfrac > frac)
+ trace = CL_TraceBox(org, vec3_origin, vec3_origin, org2, true, &hitent, SUPERCONTENTS_SOLID, false);
+ if (bestfrac > trace.fraction)
{
- bestfrac = frac;
+ bestfrac = trace.fraction;
besthitent = hitent;
- VectorCopy(v, bestorg);
- VectorCopy(normal, bestnormal);
+ VectorCopy(trace.endpos, bestorg);
+ VectorCopy(trace.plane.normal, bestnormal);
}
}
if (bestfrac < 1)
forward[2] = -sp;
#ifdef WORKINGLQUAKE
- particle(pt_static, PARTICLE_BILLBOARD, particlepalette[0x6f], particlepalette[0x6f], tex_particle, false, PBLEND_ADD, 2, 2, 255, 0, 0, 0, 0, ent->origin[0] + m_bytenormals[i][0]*dist + forward[0]*beamlength, ent->origin[1] + m_bytenormals[i][1]*dist + forward[1]*beamlength, ent->origin[2] + m_bytenormals[i][2]*dist + forward[2]*beamlength, 0, 0, 0, 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_entityparticle, particlepalette[0x6f], particlepalette[0x6f], tex_particle, 2, 255, 0, 0, 0, ent->origin[0] + m_bytenormals[i][0]*dist + forward[0]*beamlength, ent->origin[1] + m_bytenormals[i][1]*dist + forward[1]*beamlength, ent->origin[2] + m_bytenormals[i][2]*dist + forward[2]*beamlength, 0, 0, 0, 0);
#else
- particle(pt_static, PARTICLE_BILLBOARD, particlepalette[0x6f], particlepalette[0x6f], tex_particle, false, PBLEND_ADD, 2, 2, 255, 0, 0, 0, 0, ent->render.origin[0] + m_bytenormals[i][0]*dist + forward[0]*beamlength, ent->render.origin[1] + m_bytenormals[i][1]*dist + forward[1]*beamlength, ent->render.origin[2] + m_bytenormals[i][2]*dist + forward[2]*beamlength, 0, 0, 0, 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_entityparticle, particlepalette[0x6f], particlepalette[0x6f], tex_particle, 2, 255, 0, 0, 0, ent->render.origin[0] + m_bytenormals[i][0]*dist + forward[0]*beamlength, ent->render.origin[1] + m_bytenormals[i][1]*dist + forward[1]*beamlength, ent->render.origin[2] + m_bytenormals[i][2]*dist + forward[2]*beamlength, 0, 0, 0, 0);
#endif
}
}
if (cl_numparticles < cl_maxparticles - 3)
{
s++;
- particle(pt_static, PARTICLE_BILLBOARD, particlepalette[(-c)&15], particlepalette[(-c)&15], tex_particle, false, PBLEND_ALPHA, 2, 2, 255, 0, 99999, 0, 0, org[0], org[1], org[2], 0, 0, 0, 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, particlepalette[(-c)&15], particlepalette[(-c)&15], tex_particle, 2, 255, 0, 0, 0, org[0], org[1], org[2], 0, 0, 0, 0);
}
}
#ifndef WORKINGLQUAKE
VectorCopy(leakorg, org);
Con_Printf("%i points read (%i particles spawned)\nLeak at %f %f %f\n", c, s, org[0], org[1], org[2]);
- particle(pt_static, PARTICLE_BEAM, 0xFF0000, 0xFF0000, tex_beam, false, PBLEND_ALPHA, 64, 64, 255, 0, 99999, 0, 0, org[0] - 4096, org[1], org[2], 0, 0, 0, 0, org[0] + 4096, org[1], org[2], 0, 0);
- particle(pt_static, PARTICLE_BEAM, 0x00FF00, 0x00FF00, tex_beam, false, PBLEND_ALPHA, 64, 64, 255, 0, 99999, 0, 0, org[0], org[1] - 4096, org[2], 0, 0, 0, 0, org[0], org[1] + 4096, org[2], 0, 0);
- particle(pt_static, PARTICLE_BEAM, 0x0000FF, 0x0000FF, tex_beam, false, PBLEND_ALPHA, 64, 64, 255, 0, 99999, 0, 0, org[0], org[1], org[2] - 4096, 0, 0, 0, 0, org[0], org[1], org[2] + 4096, 0, 0);
+ particle(particletype + pt_beam, 0xFF0000, 0xFF0000, tex_beam, 64, 255, 0, 0, 0, org[0] - 4096, org[1], org[2], org[0] + 4096, org[1], org[2], 0);
+ particle(particletype + pt_beam, 0x00FF00, 0x00FF00, tex_beam, 64, 255, 0, 0, 0, org[0], org[1] - 4096, org[2], org[0], org[1] + 4096, org[2], 0);
+ particle(particletype + pt_beam, 0x0000FF, 0x0000FF, tex_beam, 64, 255, 0, 0, 0, org[0], org[1], org[2] - 4096, org[0], org[1], org[2] + 4096, 0);
}
/*
vec3_t org, dir;
int i, count, msgcount, color;
- MSG_ReadVector(org);
+ MSG_ReadVector(org, cl.protocol);
for (i=0 ; i<3 ; i++)
dir[i] = MSG_ReadChar () * (1.0/16);
msgcount = MSG_ReadByte ();
void CL_ParticleExplosion (vec3_t org)
{
int i;
+ trace_t trace;
//vec3_t v;
//vec3_t v2;
if (cl_stainmaps.integer)
R_Stain(org, 96, 80, 80, 80, 64, 176, 176, 176, 64);
CL_SpawnDecalParticleForPoint(org, 40, 48, 255, tex_bulletdecal[rand()&7], 0xFFFFFF, 0xFFFFFF);
- i = CL_PointQ1Contents(org);
- if ((i == CONTENTS_SLIME || i == CONTENTS_WATER) && cl_particles.integer && cl_particles_bubbles.integer)
+ i = CL_PointSuperContents(org);
+ if (i & (SUPERCONTENTS_SLIME | SUPERCONTENTS_WATER))
{
- for (i = 0;i < 128 * cl_particles_quality.value;i++)
- particle(pt_bubble, PARTICLE_BILLBOARD, 0x404040, 0x808080, tex_bubble, false, PBLEND_ADD, 2, 2, (1.0f / cl_particles_quality.value) * lhrandom(128, 255), (1.0f / cl_particles_quality.value) * 256, 9999, -0.25, 1.5, org[0] + lhrandom(-16, 16), org[1] + lhrandom(-16, 16), org[2] + lhrandom(-16, 16), lhrandom(-96, 96), lhrandom(-96, 96), lhrandom(-96, 96), 0, 0, 0, 0, (1.0 / 16.0), 0);
+ if (cl_particles.integer && cl_particles_bubbles.integer && cl_particles_explosions_bubbles.integer)
+ for (i = 0;i < 128 * cl_particles_quality.value;i++)
+ particle(particletype + pt_bubble, 0x404040, 0x808080, tex_bubble, 2, (1.0f / cl_particles_quality.value) * lhrandom(128, 255), (1.0f / cl_particles_quality.value) * 128, -0.125, 1.5, org[0] + lhrandom(-16, 16), org[1] + lhrandom(-16, 16), org[2] + lhrandom(-16, 16), lhrandom(-96, 96), lhrandom(-96, 96), lhrandom(-96, 96), (1.0 / 16.0));
}
else
{
- /*
// LordHavoc: smoke effect similar to UT2003, chews fillrate too badly up close
// smoke puff
- if (cl_particles.integer && cl_particles_smoke.integer)
+ if (cl_particles.integer && cl_particles_smoke.integer && cl_particles_explosions_smoke.integer)
{
- for (i = 0;i < 64;i++)
+ for (i = 0;i < 32;i++)
{
+ int k;
+ vec3_t v, v2;
#ifdef WORKINGLQUAKE
- v2[0] = lhrandom(-64, 64);
- v2[1] = lhrandom(-64, 64);
- v2[2] = lhrandom(-8, 24);
+ v2[0] = lhrandom(-48, 48);
+ v2[1] = lhrandom(-48, 48);
+ v2[2] = lhrandom(-48, 48);
#else
for (k = 0;k < 16;k++)
{
- v[0] = org[0] + lhrandom(-64, 64);
- v[1] = org[1] + lhrandom(-64, 64);
- v[2] = org[2] + lhrandom(-8, 24);
- if (CL_TraceLine(org, v, v2, NULL, true, NULL, SUPERCONTENTS_SOLID) >= 0.1)
+ v[0] = org[0] + lhrandom(-48, 48);
+ v[1] = org[1] + lhrandom(-48, 48);
+ v[2] = org[2] + lhrandom(-48, 48);
+ trace = CL_TraceBox(org, vec3_origin, vec3_origin, v, true, NULL, SUPERCONTENTS_SOLID, false);
+ if (trace.fraction >= 0.1)
break;
}
- VectorSubtract(v2, org, v2);
+ VectorSubtract(trace.endpos, org, v2);
#endif
VectorScale(v2, 2.0f, v2);
- particle(pt_static, PARTICLE_BILLBOARD, 0x101010, 0x202020, tex_smoke[rand()&7], true, PBLEND_ADD, 12, 12, 255, 512, 9999, 0, 0, org[0], org[1], org[2], v2[0], v2[1], v2[2], 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_smoke, 0x202020, 0x404040, tex_smoke[rand()&7], 12, 32, 64, 0, 0, org[0], org[1], org[2], v2[0], v2[1], v2[2], 0);
}
}
- */
-#if 1
- if (cl_particles.integer && cl_particles_sparks.integer)
+ if (cl_particles.integer && cl_particles_sparks.integer && cl_particles_explosions_sparks.integer)
for (i = 0;i < 128 * cl_particles_quality.value;i++)
- particle(pt_static, PARTICLE_SPARK, 0x903010, 0xFFD030, tex_particle, false, PBLEND_ADD, 1.0f, 0.02f, (1.0f / cl_particles_quality.value) * lhrandom(0, 255), (1.0f / cl_particles_quality.value) * 512, 9999, 1, 0, org[0], org[1], org[2], lhrandom(-256, 256), lhrandom(-256, 256), lhrandom(-256, 256) + 80, 0, 0, 0, 0, 0.2, 0);
- }
-
- //if (cl_explosions.integer)
- // R_NewExplosion(org);
-#elif 1
- if (cl_particles.integer && cl_particles_sparks.integer)
- for (i = 0;i < 64 * cl_particles_quality.value;i++)
- particle(pt_ember, PARTICLE_SPARK, 0x903010, 0xFFD030, tex_particle, false, PBLEND_ADD, 1.0f, 0.01f, (1.0f / cl_particles_quality.value) * lhrandom(0, 255), (1.0f / cl_particles_quality.value) * 256, 9999, 0.7, 0, org[0], org[1], org[2], lhrandom(-256, 256), lhrandom(-256, 256), lhrandom(-256, 256) + 80, cl.time, 0, 0, 0, 0, 0);
- }
-
- //if (cl_explosions.integer)
- // R_NewExplosion(org);
-#else
- if (cl_particles.integer && cl_particles_sparks.integer)
- for (i = 0;i < 256 * cl_particles_quality.value;i++)
- particle(pt_static, PARTICLE_SPARK, 0x903010, 0xFFD030, tex_particle, false, PBLEND_ADD, 1.5f, 0.05f, (1.0f / cl_particles_quality.value) * lhrandom(0, 255), (1.0f / cl_particles_quality.value) * 512, 9999, 1, 0, org[0], org[1], org[2], lhrandom(-192, 192), lhrandom(-192, 192), lhrandom(-192, 192) + 160, 0, 0, 0, 0, 0.2, 0);
+ particle(particletype + pt_spark, 0x903010, 0xFFD030, tex_particle, 1.0f, (1.0f / cl_particles_quality.value) * lhrandom(0, 255), (1.0f / cl_particles_quality.value) * 512, 1, 0, org[0], org[1], org[2], lhrandom(-256, 256), lhrandom(-256, 256), lhrandom(-256, 256) + 80, 0.2);
}
- if (cl_explosions.integer)
+ if (cl_particles_explosions_shell.integer)
R_NewExplosion(org);
-#endif
}
/*
VectorScale (offset, 8, offset);
k = particlepalette[colorStart + (i % colorLength)];
pscale = lhrandom(0.5, 1.5);
- particle(pt_static, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ADD, pscale, pscale, (1.0f / cl_particles_quality.value) * 255, (1.0f/cl_particles_quality.value)*512, 9999, 0, 0, org[0] + offset[0], org[1] + offset[1], org[2] + offset[2], vel[0], vel[1], vel[2], 0, 0, 0, 0, lhrandom(1.5, 3), 0);
+ particle(particletype + pt_static, k, k, tex_particle, pscale, (1.0f / cl_particles_quality.value) * 255, (1.0f/cl_particles_quality.value)*512, 0, 0, org[0] + offset[0], org[1] + offset[1], org[2] + offset[2], vel[0], vel[1], vel[2], lhrandom(1.5, 3));
}
}
*/
void CL_BlobExplosion (vec3_t org)
{
- if (cl_stainmaps.integer)
- R_Stain(org, 96, 80, 80, 80, 64, 176, 176, 176, 64);
- CL_SpawnDecalParticleForPoint(org, 40, 48, 255, tex_bulletdecal[rand()&7], 0xFFFFFF, 0xFFFFFF);
-
- if (cl_explosions.integer)
- R_NewExplosion(org);
+ CL_ParticleExplosion(org);
}
/*
{
k = particlepalette[color + (rand()&7)];
if (gamemode == GAME_GOODVSBAD2)
- particle(pt_static, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ALPHA, 5, 5, (1.0f / cl_particles_quality.value) * 255, (1.0f / cl_particles_quality.value) * 300, 9999, 0, 0, org[0] + lhrandom(-8, 8), org[1] + lhrandom(-8, 8), org[2] + lhrandom(-8, 8), lhrandom(-10, 10), lhrandom(-10, 10), lhrandom(-10, 10), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_alphastatic, k, k, tex_particle, 5, (1.0f / cl_particles_quality.value) * 255, (1.0f / cl_particles_quality.value) * 300, 0, 0, org[0] + lhrandom(-8, 8), org[1] + lhrandom(-8, 8), org[2] + lhrandom(-8, 8), lhrandom(-10, 10), lhrandom(-10, 10), lhrandom(-10, 10), 0);
else
- particle(pt_static, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ALPHA, 1, 1, (1.0f / cl_particles_quality.value) * 255, (1.0f / cl_particles_quality.value) * 512, 9999, 0, 0, org[0] + lhrandom(-8, 8), org[1] + lhrandom(-8, 8), org[2] + lhrandom(-8, 8), dir[0] + lhrandom(-15, 15), dir[1] + lhrandom(-15, 15), dir[2] + lhrandom(-15, 15), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_alphastatic, k, k, tex_particle, 1, (1.0f / cl_particles_quality.value) * 255, (1.0f / cl_particles_quality.value) * 512, 0, 0, org[0] + lhrandom(-8, 8), org[1] + lhrandom(-8, 8), org[2] + lhrandom(-8, 8), dir[0] + lhrandom(-15, 15), dir[1] + lhrandom(-15, 15), dir[2] + lhrandom(-15, 15), 0);
}
}
CL_SparkShower
===============
*/
-void CL_SparkShower (vec3_t org, vec3_t dir, int count)
+void CL_SparkShower (vec3_t org, vec3_t dir, int count, vec_t gravityscale)
{
- vec3_t org2, org3;
int k;
- if (cl_stainmaps.integer)
- R_Stain(org, 32, 96, 96, 96, 24, 128, 128, 128, 24);
- CL_SpawnDecalParticleForPoint(org, 6, 3, 255, tex_bulletdecal[rand()&7], 0xFFFFFF, 0xFFFFFF);
-
if (!cl_particles.integer) return;
- if (cl_particles_bulletimpacts.integer)
+ if (cl_particles_sparks.integer)
{
- // smoke puff
- if (cl_particles_smoke.integer)
+ // sparks
+ count *= cl_particles_quality.value;
+ while(count--)
{
- k = count * 0.25 * cl_particles_quality.value;
- while(k--)
- {
- org2[0] = org[0] + 0.125f * lhrandom(-count, count);
- org2[1] = org[1] + 0.125f * lhrandom(-count, count);
- org2[2] = org[2] + 0.125f * lhrandom(-count, count);
- CL_TraceLine(org, org2, org3, NULL, true, NULL, SUPERCONTENTS_SOLID);
- particle(pt_grow, PARTICLE_BILLBOARD, 0x101010, 0x202020, tex_smoke[rand()&7], true, PBLEND_ADD, 3, 3, (1.0f / cl_particles_quality.value) * 255, (1.0f / cl_particles_quality.value) * 1024, 9999, -0.2, 0, org3[0], org3[1], org3[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(0, 16), 15, 0, 0, 0, 0.2, 0);
- }
+ k = particlepalette[0x68 + (rand() & 7)];
+ particle(particletype + pt_spark, k, k, tex_particle, 0.4f, (1.0f / cl_particles_quality.value) * lhrandom(64, 255), (1.0f / cl_particles_quality.value) * 512, gravityscale, 0, org[0], org[1], org[2], lhrandom(-64, 64) + dir[0], lhrandom(-64, 64) + dir[1], lhrandom(0, 128) + dir[2], 0);
}
+ }
+}
+
+void CL_Smoke (vec3_t org, vec3_t dir, int count)
+{
+ vec3_t org2;
+ int k;
+ trace_t trace;
+
+ if (!cl_particles.integer) return;
- if (cl_particles_sparks.integer)
+ // smoke puff
+ if (cl_particles_smoke.integer)
+ {
+ k = count * 0.25 * cl_particles_quality.value;
+ while(k--)
{
- // sparks
- count *= cl_particles_quality.value;
- while(count--)
- {
- k = particlepalette[0x68 + (rand() & 7)];
- particle(pt_static, PARTICLE_SPARK, k, k, tex_particle, false, PBLEND_ADD, 0.4f, 0.015f, (1.0f / cl_particles_quality.value) * lhrandom(64, 255), (1.0f / cl_particles_quality.value) * 512, 9999, 1, 0, org[0], org[1], org[2], lhrandom(-64, 64) + dir[0], lhrandom(-64, 64) + dir[1], lhrandom(0, 128) + dir[2], 0, 0, 0, 0, 0.2, 0);
- }
+ org2[0] = org[0] + 0.125f * lhrandom(-count, count);
+ org2[1] = org[1] + 0.125f * lhrandom(-count, count);
+ org2[2] = org[2] + 0.125f * lhrandom(-count, count);
+ trace = CL_TraceBox(org, vec3_origin, vec3_origin, org2, true, NULL, SUPERCONTENTS_SOLID, false);
+ particle(particletype + pt_smoke, 0x101010, 0x202020, tex_smoke[rand()&7], 3, (1.0f / cl_particles_quality.value) * 255, (1.0f / cl_particles_quality.value) * 1024, 0, 0, trace.endpos[0], trace.endpos[1], trace.endpos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0);
}
}
}
+void CL_BulletMark (vec3_t org)
+{
+ if (cl_stainmaps.integer)
+ R_Stain(org, 32, 96, 96, 96, 24, 128, 128, 128, 24);
+ CL_SpawnDecalParticleForPoint(org, 6, 3, 255, tex_bulletdecal[rand()&7], 0xFFFFFF, 0xFFFFFF);
+}
+
void CL_PlasmaBurn (vec3_t org)
{
if (cl_stainmaps.integer)
void CL_BloodPuff (vec3_t org, vec3_t vel, int count)
{
float s;
- vec3_t org2, org3;
+ vec3_t org2;
+ trace_t trace;
// bloodcount is used to accumulate counts too small to cause a blood particle
if (!cl_particles.integer) return;
if (!cl_particles_blood.integer) return;
org2[0] = org[0] + 0.125f * lhrandom(-bloodcount, bloodcount);
org2[1] = org[1] + 0.125f * lhrandom(-bloodcount, bloodcount);
org2[2] = org[2] + 0.125f * lhrandom(-bloodcount, bloodcount);
- CL_TraceLine(org, org2, org3, NULL, true, NULL, SUPERCONTENTS_SOLID);
- particle(pt_blood, PARTICLE_BILLBOARD, 0xFFFFFF, 0xFFFFFF, tex_bloodparticle[rand()&7], true, PBLEND_MOD, 8, 8, cl_particles_blood_alpha.value * 768 / cl_particles_quality.value, cl_particles_blood_alpha.value * 384 / cl_particles_quality.value, 9999, 0, -1, org3[0], org3[1], org3[2], vel[0] + lhrandom(-s, s), vel[1] + lhrandom(-s, s), vel[2] + lhrandom(-s, s), 0, 0, 0, 0, 1, 0);
+ trace = CL_TraceBox(org, vec3_origin, vec3_origin, org2, true, NULL, SUPERCONTENTS_SOLID, false);
+ particle(particletype + pt_blood, 0xFFFFFF, 0xFFFFFF, tex_bloodparticle[rand()&7], 8, cl_particles_blood_alpha.value * 768 / cl_particles_quality.value, cl_particles_blood_alpha.value * 384 / cl_particles_quality.value, 0, -1, trace.endpos[0], trace.endpos[1], trace.endpos[2], vel[0] + lhrandom(-s, s), vel[1] + lhrandom(-s, s), vel[2] + lhrandom(-s, s), 1);
bloodcount -= 16 / cl_particles_quality.value;
}
}
vel[1] = (org[1] - center[1]) * velscale[1];
vel[2] = (org[2] - center[2]) * velscale[2];
bloodcount -= 16 / cl_particles_quality.value;
- particle(pt_blood, PARTICLE_BILLBOARD, 0xFFFFFF, 0xFFFFFF, tex_bloodparticle[rand()&7], true, PBLEND_MOD, 8, 8, cl_particles_blood_alpha.value * 768 / cl_particles_quality.value, cl_particles_blood_alpha.value * 384 / cl_particles_quality.value, 9999, 0, -1, org[0], org[1], org[2], vel[0], vel[1], vel[2], 0, 0, 0, 0, 1, 0);
+ particle(particletype + pt_blood, 0xFFFFFF, 0xFFFFFF, tex_bloodparticle[rand()&7], 8, cl_particles_blood_alpha.value * 768 / cl_particles_quality.value, cl_particles_blood_alpha.value * 384 / cl_particles_quality.value, 0, -1, org[0], org[1], org[2], vel[0], vel[1], vel[2], 1);
}
}
while (count--)
{
k = particlepalette[colorbase + (rand()&3)];
- particle(pt_static, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ALPHA, 2, 2, 255 / cl_particles_quality.value, 0, lhrandom(1, 2), gravity ? 1 : 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(mins[2], maxs[2]), dir[0] + lhrandom(-randomvel, randomvel), dir[1] + lhrandom(-randomvel, randomvel), dir[2] + lhrandom(-randomvel, randomvel), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_alphastatic, k, k, tex_particle, 2, 255 / cl_particles_quality.value, (255 / cl_particles_quality.value) / 2, gravity ? 1 : 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(mins[2], maxs[2]), dir[0] + lhrandom(-randomvel, randomvel), dir[1] + lhrandom(-randomvel, randomvel), dir[2] + lhrandom(-randomvel, randomvel), 0);
}
}
{
int k;
float t, z, minz, maxz;
+ particle_t *p;
if (!cl_particles.integer) return;
if (maxs[0] <= mins[0]) {t = mins[0];mins[0] = maxs[0];maxs[0] = t;}
if (maxs[1] <= mins[1]) {t = mins[1];mins[1] = maxs[1];maxs[1] = t;}
if (maxs[2] <= mins[2]) {t = mins[2];mins[2] = maxs[2];maxs[2] = t;}
if (dir[2] < 0) // falling
- {
- t = (maxs[2] - mins[2]) / -dir[2];
z = maxs[2];
- }
else // rising??
- {
- t = (maxs[2] - mins[2]) / dir[2];
z = mins[2];
- }
- if (t < 0 || t > 2) // sanity check
- t = 2;
minz = z - fabs(dir[2]) * 0.1;
maxz = z + fabs(dir[2]) * 0.1;
{
k = particlepalette[colorbase + (rand()&3)];
if (gamemode == GAME_GOODVSBAD2)
- {
- particle(pt_rain, PARTICLE_SPARK, k, k, tex_particle, true, PBLEND_ADD, 20, 20, lhrandom(8, 16) / cl_particles_quality.value, 0, t, 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], cl.time + 9999, dir[0], dir[1], dir[2], 0, 0);
- }
+ particle(particletype + pt_rain, k, k, tex_particle, 20, lhrandom(8, 16) / cl_particles_quality.value, 0, 0, -1, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], 0);
else
- {
- particle(pt_rain, PARTICLE_SPARK, k, k, tex_particle, true, PBLEND_ADD, 0.5, 0.02, lhrandom(8, 16) / cl_particles_quality.value, 0, t, 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], cl.time + 9999, dir[0], dir[1], dir[2], 0, 0);
- }
+ particle(particletype + pt_rain, k, k, tex_particle, 0.5, lhrandom(8, 16) / cl_particles_quality.value, 0, 0, -1, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], 0);
}
break;
case 1:
{
k = particlepalette[colorbase + (rand()&3)];
if (gamemode == GAME_GOODVSBAD2)
- {
- particle(pt_rain, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ADD, 20, 20, lhrandom(64, 128) / cl_particles_quality.value, 0, t, 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], 0, dir[0], dir[1], dir[2], 0, 0);
- }
+ p = particle(particletype + pt_snow, k, k, tex_particle, 20, lhrandom(64, 128) / cl_particles_quality.value, 0, 0, -1, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], 0);
else
- {
- particle(pt_rain, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ADD, 1, 1, lhrandom(64, 128) / cl_particles_quality.value, 0, t, 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], 0, dir[0], dir[1], dir[2], 0, 0);
- }
+ p = particle(particletype + pt_snow, k, k, tex_particle, 1, lhrandom(64, 128) / cl_particles_quality.value, 0, 0, -1, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(minz, maxz), dir[0], dir[1], dir[2], 0);
+ if (p)
+ VectorCopy(p->vel, p->relativedirection);
}
break;
default:
- Host_Error("CL_ParticleRain: unknown type %i (0 = rain, 1 = snow)\n", type);
+ Con_Printf ("CL_ParticleRain: unknown type %i (0 = rain, 1 = snow)\n", type);
}
}
o[1] = lhrandom(mins[1], maxs[1]);
o[2] = lhrandom(mins[2], maxs[2]);
VectorSubtract(o, center, v);
- VectorNormalizeFast(v);
+ VectorNormalize(v);
VectorScale(v, 100, v);
v[2] += sv_gravity.value * 0.15f;
- particle(pt_static, PARTICLE_BILLBOARD, 0x903010, 0xFFD030, tex_particle, false, PBLEND_ADD, 1.5, 1.5, lhrandom(64, 128) / cl_particles_quality.value, 128 / cl_particles_quality.value, 9999, 1, 0, o[0], o[1], o[2], v[0], v[1], v[2], 0, 0, 0, 0, 0.2, 0);
+ particle(particletype + pt_static, 0x903010, 0xFFD030, tex_particle, 1.5, lhrandom(64, 128) / cl_particles_quality.value, 128 / cl_particles_quality.value, 1, 0, o[0], o[1], o[2], v[0], v[1], v[2], 0.2);
}
}
while (count--)
{
k = particlepalette[224 + (rand()&15)];
- particle(pt_static, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ADD, 4, 4, lhrandom(64, 128) / cl_particles_quality.value, 384 / cl_particles_quality.value, 9999, -1, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(mins[2], maxs[2]), lhrandom(-32, 32), lhrandom(-32, 32), lhrandom(0, 64), 0, 0, 0, 0, 1, 0);
+ particle(particletype + pt_static, k, k, tex_particle, 4, lhrandom(64, 128) / cl_particles_quality.value, 384 / cl_particles_quality.value, -1, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(mins[2], maxs[2]), lhrandom(-32, 32), lhrandom(-32, 32), lhrandom(0, 64), 1);
if (count & 1)
- particle(pt_static, PARTICLE_BILLBOARD, 0x303030, 0x606060, tex_smoke[rand()&7], false, PBLEND_ADD, 6, 6, lhrandom(48, 96) / cl_particles_quality.value, 64 / cl_particles_quality.value, 9999, 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(mins[2], maxs[2]), lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(0, 32), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, 0x303030, 0x606060, tex_smoke[rand()&7], 6, lhrandom(48, 96) / cl_particles_quality.value, 64 / cl_particles_quality.value, 0, 0, lhrandom(mins[0], maxs[0]), lhrandom(mins[1], maxs[1]), lhrandom(mins[2], maxs[2]), lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(0, 32), 0);
}
}
while (count--)
{
k = particlepalette[224 + (rand()&15)];
- particle(pt_static, PARTICLE_BILLBOARD, k, k, tex_particle, false, PBLEND_ADD, 4, 4, lhrandom(64, 128) / cl_particles_quality.value, 384 / cl_particles_quality.value, 9999, -1, 1.1, org[0], org[1], org[2], vel[0] + lhrandom(-128, 128), vel[1] + lhrandom(-128, 128), vel[2] + lhrandom(-128, 128), 0, 0, 0, 0, 1, 0);
+ particle(particletype + pt_static, k, k, tex_particle, 4, lhrandom(64, 128) / cl_particles_quality.value, 384 / cl_particles_quality.value, -1, 1.1, org[0], org[1], org[2], vel[0] + lhrandom(-128, 128), vel[1] + lhrandom(-128, 128), vel[2] + lhrandom(-128, 128), 1);
}
}
{
k = particlepalette[0 + (rand()&255)];
l = particlepalette[0 + (rand()&255)];
- particle(pt_static, PARTICLE_BILLBOARD, k, l, tex_particle, false, PBLEND_ADD, 12, 12, inc * 8, inc * 8, 9999, 0.05, 1, org[0], org[1], org[2], dir[0] * vel, dir[1] * vel, dir[2] * vel, 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, k, l, tex_particle, 12, inc * 8, inc * 8, 0.05, 1, org[0], org[1], org[2], dir[0] * vel, dir[1] * vel, dir[2] * vel, 0);
}
else
{
k = l = particlepalette[224 + (rand()&7)];
- particle(pt_static, PARTICLE_BILLBOARD, k, l, tex_particle, false, PBLEND_ADD, 12, 12, inc * 8, inc * 8, 9999, 0.05, 0, org[0], org[1], org[2], dir[0] * vel, dir[1] * vel, dir[2] * vel, 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, k, l, tex_particle, 12, inc * 8, inc * 8, 0.05, 0, org[0], org[1], org[2], dir[0] * vel, dir[1] * vel, dir[2] * vel, 0);
}
}
}
===============
*/
-#if WORKINGLQUAKE
-void R_TeleportSplash (vec3_t org)
+void CL_TeleportSplash (vec3_t org)
{
float i, j, k, inc;
if (!cl_particles.integer) return;
for (i = -16;i < 16;i += inc)
for (j = -16;j < 16;j += inc)
for (k = -24;k < 32;k += inc)
- particle(pt_static, PARTICLE_BILLBOARD, 0xA0A0A0, 0xFFFFFF, tex_particle, false, PBLEND_ADD, 10, 10, inc * 32, inc * lhrandom(8, 16), inc * 32, 9999, 0, 0, org[0] + i + lhrandom(0, 8), org[1] + j + lhrandom(0, 8), org[2] + k + lhrandom(0, 8), lhrandom(-64, 64), lhrandom(-64, 64), lhrandom(-256, 256), 0, 0, 0, 0, 1, 0);
+ particle(particletype + pt_static, 0xA0A0A0, 0xFFFFFF, tex_particle, 10, inc * lhrandom(8, 16), inc * 32, 0, 0, org[0] + i + lhrandom(0, 8), org[1] + j + lhrandom(0, 8), org[2] + k + lhrandom(0, 8), lhrandom(-64, 64), lhrandom(-64, 64), lhrandom(-256, 256), 1);
}
-#endif
#ifdef WORKINGLQUAKE
void R_RocketTrail (vec3_t start, vec3_t end, int type)
#else
-void CL_RocketTrail (vec3_t start, vec3_t end, int type, entity_t *ent)
+void CL_RocketTrail (vec3_t start, vec3_t end, int type, int color, entity_t *ent)
#endif
{
vec3_t vec, dir, vel, pos;
float len, dec, speed, qd;
- int contents, smoke, blood, bubbles;
+ int smoke, blood, bubbles;
+#ifdef WORKINGLQUAKE
+ int contents;
+#endif
if (end[0] == start[0] && end[1] == start[1] && end[2] == start[2])
return;
if (speed)
speed = 1.0f / speed;
VectorSubtract(ent->state_current.origin, ent->state_previous.origin, vel);
+ color = particlepalette[color];
#endif
VectorScale(vel, speed, vel);
VectorMA(start, dec, vec, pos);
len -= dec;
- contents = CL_PointQ1Contents(pos);
- if (contents == CONTENTS_SKY || contents == CONTENTS_LAVA)
- return;
-
smoke = cl_particles.integer && cl_particles_smoke.integer;
blood = cl_particles.integer && cl_particles_blood.integer;
+#ifdef WORKINGLQUAKE
+ contents = CL_PointQ1Contents(pos);
bubbles = cl_particles.integer && cl_particles_bubbles.integer && (contents == CONTENTS_WATER || contents == CONTENTS_SLIME);
+#else
+ bubbles = cl_particles.integer && cl_particles_bubbles.integer && (CL_PointSuperContents(pos) & (SUPERCONTENTS_WATER | SUPERCONTENTS_SLIME));
+#endif
qd = 1.0f / cl_particles_quality.value;
while (len >= 0)
dec = qd*3;
if (smoke)
{
- particle(pt_grow, PARTICLE_BILLBOARD, 0x303030, 0x606060, tex_smoke[rand()&7], false, PBLEND_ADD, 3, 3, qd*cl_particles_smoke_alpha.value*125, qd*cl_particles_smoke_alphafade.value*125, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-5, 5), lhrandom(-5, 5), lhrandom(-5, 5), 7, 0, 0, 0, 0, 0);
- particle(pt_static, PARTICLE_BILLBOARD, 0x801010, 0xFFA020, tex_smoke[rand()&7], false, PBLEND_ADD, 3, 3, qd*cl_particles_smoke_alpha.value*288, qd*cl_particles_smoke_alphafade.value*1400, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-20, 20), lhrandom(-20, 20), lhrandom(-20, 20), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_smoke, 0x303030, 0x606060, tex_smoke[rand()&7], 3, qd*cl_particles_smoke_alpha.value*125, qd*cl_particles_smoke_alphafade.value*125, 0, 0, pos[0], pos[1], pos[2], lhrandom(-5, 5), lhrandom(-5, 5), lhrandom(-5, 5), 0);
+ particle(particletype + pt_static, 0x801010, 0xFFA020, tex_smoke[rand()&7], 3, qd*cl_particles_smoke_alpha.value*288, qd*cl_particles_smoke_alphafade.value*1400, 0, 0, pos[0], pos[1], pos[2], lhrandom(-20, 20), lhrandom(-20, 20), lhrandom(-20, 20), 0);
}
if (bubbles)
- particle(pt_bubble, PARTICLE_BILLBOARD, 0x404040, 0x808080, tex_bubble, false, PBLEND_ADD, 2, 2, qd*lhrandom(64, 255), qd*256, 9999, -0.25, 1.5, pos[0], pos[1], pos[2], lhrandom(-16, 16), lhrandom(-16, 16), lhrandom(-16, 16), 0, 0, 0, 0, (1.0 / 16.0), 0);
+ particle(particletype + pt_bubble, 0x404040, 0x808080, tex_bubble, 2, qd*lhrandom(64, 255), qd*256, -0.25, 1.5, pos[0], pos[1], pos[2], lhrandom(-16, 16), lhrandom(-16, 16), lhrandom(-16, 16), (1.0 / 16.0));
break;
case 1: // grenade trail
// FIXME: make it gradually stop smoking
dec = qd*3;
if (smoke)
- particle(pt_grow, PARTICLE_BILLBOARD, 0x303030, 0x606060, tex_smoke[rand()&7], false, PBLEND_ADD, 3, 3, qd*cl_particles_smoke_alpha.value*100, qd*cl_particles_smoke_alphafade.value*100, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-5, 5), lhrandom(-5, 5), lhrandom(-5, 5), 7, 0, 0, 0, 0, 0);
+ particle(particletype + pt_smoke, 0x303030, 0x606060, tex_smoke[rand()&7], 3, qd*cl_particles_smoke_alpha.value*100, qd*cl_particles_smoke_alphafade.value*100, 0, 0, pos[0], pos[1], pos[2], lhrandom(-5, 5), lhrandom(-5, 5), lhrandom(-5, 5), 0);
break;
case 4: // slight blood
dec = qd*16;
if (blood)
- particle(pt_blood, PARTICLE_BILLBOARD, 0xFFFFFF, 0xFFFFFF, tex_bloodparticle[rand()&7], true, PBLEND_MOD, 8, 8, qd * cl_particles_blood_alpha.value * 768.0f, qd * cl_particles_blood_alpha.value * 384.0f, 9999, 0, -1, pos[0], pos[1], pos[2], vel[0] * 0.5f + lhrandom(-64, 64), vel[1] * 0.5f + lhrandom(-64, 64), vel[2] * 0.5f + lhrandom(-64, 64), 0, 0, 0, 0, 1, 0);
+ particle(particletype + pt_blood, 0xFFFFFF, 0xFFFFFF, tex_bloodparticle[rand()&7], 8, qd * cl_particles_blood_alpha.value * 768.0f, qd * cl_particles_blood_alpha.value * 384.0f, 0, -1, pos[0], pos[1], pos[2], vel[0] * 0.5f + lhrandom(-64, 64), vel[1] * 0.5f + lhrandom(-64, 64), vel[2] * 0.5f + lhrandom(-64, 64), 1);
break;
case 3: // green tracer
if (smoke)
{
if (gamemode == GAME_GOODVSBAD2)
- particle(pt_static, PARTICLE_BILLBOARD, 0x00002E, 0x000030, tex_particle, false, PBLEND_ADD, 6, 6, qd*128, qd*384, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, 0x00002E, 0x000030, tex_particle, 6, qd*128, qd*384, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0);
else
- particle(pt_static, PARTICLE_BILLBOARD, 0x002000, 0x003000, tex_particle, false, PBLEND_ADD, 6, 6, qd*128, qd*384, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, 0x002000, 0x003000, tex_particle, 6, qd*128, qd*384, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0);
}
break;
case 5: // flame tracer
dec = qd*6;
if (smoke)
- particle(pt_static, PARTICLE_BILLBOARD, 0x301000, 0x502000, tex_particle, false, PBLEND_ADD, 6, 6, qd*128, qd*384, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, 0x301000, 0x502000, tex_particle, 6, qd*128, qd*384, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0);
break;
case 6: // voor trail
if (smoke)
{
if (gamemode == GAME_GOODVSBAD2)
- particle(pt_static, PARTICLE_BILLBOARD, particlepalette[0 + (rand()&255)], particlepalette[0 + (rand()&255)], tex_particle, false, PBLEND_ALPHA, 6, 6, qd*255, qd*384, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_alphastatic, particlepalette[0 + (rand()&255)], particlepalette[0 + (rand()&255)], tex_particle, 6, qd*255, qd*384, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0);
else if (gamemode == GAME_PRYDON)
- particle(pt_static, PARTICLE_BILLBOARD, 0x103040, 0x204050, tex_particle, false, PBLEND_ADD, 6, 6, qd*128, qd*384, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, 0x103040, 0x204050, tex_particle, 6, qd*128, qd*384, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0);
else
- particle(pt_static, PARTICLE_BILLBOARD, 0x502030, 0x502030, tex_particle, false, PBLEND_ADD, 6, 6, qd*128, qd*384, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, 0x502030, 0x502030, tex_particle, 6, qd*128, qd*384, 0, 0, pos[0], pos[1], pos[2], lhrandom(-8, 8), lhrandom(-8, 8), lhrandom(-8, 8), 0);
}
break;
-
+#ifndef WORKINGLQUAKE
case 7: // Nehahra smoke tracer
dec = qd*7;
if (smoke)
- particle(pt_static, PARTICLE_BILLBOARD, 0x303030, 0x606060, tex_smoke[rand()&7], true, PBLEND_ALPHA, 7, 7, qd*64, qd*320, 9999, 0, 0, pos[0], pos[1], pos[2], lhrandom(-4, 4), lhrandom(-4, 4), lhrandom(0, 16), 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_alphastatic, 0x303030, 0x606060, tex_smoke[rand()&7], 7, qd*64, qd*320, 0, 0, pos[0], pos[1], pos[2], lhrandom(-4, 4), lhrandom(-4, 4), lhrandom(0, 16), 0);
break;
case 8: // Nexuiz plasma trail
dec = qd*4;
if (smoke)
- particle(pt_static, PARTICLE_BILLBOARD, 0x283880, 0x283880, tex_particle, false, PBLEND_ADD, 4, 4, qd*255, qd*1024, 9999, 0, 0, pos[0], pos[1], pos[2], 0, 0, 0, 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_static, 0x283880, 0x283880, tex_particle, 4, qd*255, qd*1024, 0, 0, pos[0], pos[1], pos[2], 0, 0, 0, 0);
+ break;
+ case 9: // glow trail
+ dec = qd*3;
+ if (smoke)
+ particle(particletype + pt_alphastatic, color, color, tex_particle, 5, qd*128, qd*320, 0, 0, pos[0], pos[1], pos[2], 0, 0, 0, 0);
break;
+#endif
}
// advance to next time and position
#endif
}
-void CL_RocketTrail2 (vec3_t start, vec3_t end, int color, entity_t *ent)
-{
- float dec, len;
- vec3_t vec, pos;
- if (!cl_particles.integer) return;
- if (!cl_particles_smoke.integer) return;
-
- VectorCopy(start, pos);
- VectorSubtract(end, start, vec);
-#ifdef WORKINGLQUAKE
- len = VectorNormalize(vec);
-#else
- len = VectorNormalizeLength(vec);
-#endif
- color = particlepalette[color];
- dec = 3.0f / cl_particles_quality.value;
- while (len > 0)
- {
- particle(pt_static, PARTICLE_BILLBOARD, color, color, tex_particle, false, PBLEND_ALPHA, 5, 5, 128 / cl_particles_quality.value, 320 / cl_particles_quality.value, 9999, 0, 0, pos[0], pos[1], pos[2], 0, 0, 0, 0, 0, 0, 0, 0, 0);
- len -= dec;
- VectorMA(pos, dec, vec, pos);
- }
-}
-
void CL_BeamParticle (const vec3_t start, const vec3_t end, vec_t radius, float red, float green, float blue, float alpha, float lifetime)
{
int tempcolor2, cr, cg, cb;
cg = green * 255;
cb = blue * 255;
tempcolor2 = (bound(0, cr, 255) << 16) | (bound(0, cg, 255) << 8) | bound(0, cb, 255);
- particle(pt_static, PARTICLE_BEAM, tempcolor2, tempcolor2, tex_beam, false, PBLEND_ADD, radius, radius, alpha * 255, alpha * 255 / lifetime, 9999, 0, 0, start[0], start[1], start[2], 0, 0, 0, 0, end[0], end[1], end[2], 0, 0);
+ particle(particletype + pt_beam, tempcolor2, tempcolor2, tex_beam, radius, alpha * 255, alpha * 255 / lifetime, 0, 0, start[0], start[1], start[2], end[0], end[1], end[2], 0);
}
void CL_Tei_Smoke(const vec3_t org, const vec3_t dir, int count)
// smoke puff
if (cl_particles_smoke.integer)
for (f = 0;f < count;f += 4.0f / cl_particles_quality.value)
- particle(pt_grow, PARTICLE_BILLBOARD, 0x202020, 0x404040, tex_smoke[rand()&7], true, PBLEND_ADD, 5, 5, 255 / cl_particles_quality.value, 512 / cl_particles_quality.value, 9999, 0, 0, org[0] + 0.125f * lhrandom(-count, count), org[1] + 0.125f * lhrandom (-count, count), org[2] + 0.125f * lhrandom(-count, count), dir[0] + lhrandom(-count, count) * 0.5f, dir[1] + lhrandom(-count, count) * 0.5f, dir[2] + lhrandom(-count, count) * 0.5f, 15, 0, 0, 0, 0, 0);
+ particle(particletype + pt_smoke, 0x202020, 0x404040, tex_smoke[rand()&7], 5, 255 / cl_particles_quality.value, 512 / cl_particles_quality.value, 0, 0, org[0] + 0.125f * lhrandom(-count, count), org[1] + 0.125f * lhrandom (-count, count), org[2] + 0.125f * lhrandom(-count, count), dir[0] + lhrandom(-count, count) * 0.5f, dir[1] + lhrandom(-count, count) * 0.5f, dir[2] + lhrandom(-count, count) * 0.5f, 0);
}
void CL_Tei_PlasmaHit(const vec3_t org, const vec3_t dir, int count)
// smoke puff
if (cl_particles_smoke.integer)
for (f = 0;f < count;f += 4.0f / cl_particles_quality.value)
- particle(pt_grow, PARTICLE_BILLBOARD, 0x202020, 0x404040, tex_smoke[rand()&7], true, PBLEND_ADD, 5, 5, 255 / cl_particles_quality.value, 512 / cl_particles_quality.value, 9999, 0, 0, org[0] + 0.125f * lhrandom(-count, count), org[1] + 0.125f * lhrandom (-count, count), org[2] + 0.125f * lhrandom(-count, count), dir[0] + lhrandom(-count, count), dir[1] + lhrandom(-count, count), dir[2] + lhrandom(-count, count), 15, 0, 0, 0, 0, 0);
+ particle(particletype + pt_smoke, 0x202020, 0x404040, tex_smoke[rand()&7], 5, 255 / cl_particles_quality.value, 512 / cl_particles_quality.value, 0, 0, org[0] + 0.125f * lhrandom(-count, count), org[1] + 0.125f * lhrandom (-count, count), org[2] + 0.125f * lhrandom(-count, count), dir[0] + lhrandom(-count, count), dir[1] + lhrandom(-count, count), dir[2] + lhrandom(-count, count), 0);
// sparks
if (cl_particles_sparks.integer)
for (f = 0;f < count;f += 1.0f / cl_particles_quality.value)
- particle(pt_static, PARTICLE_SPARK, 0x2030FF, 0x80C0FF, tex_particle, false, PBLEND_ADD, 2.0f, 0.1f, lhrandom(64, 255) / cl_particles_quality.value, 512 / cl_particles_quality.value, 9999, 0, 0, org[0], org[1], org[2], lhrandom(-count, count) * 3.0f + dir[0], lhrandom(-count, count) * 3.0f + dir[1], lhrandom(-count, count) * 3.0f + dir[2], 0, 0, 0, 0, 0, 0);
+ particle(particletype + pt_spark, 0x2030FF, 0x80C0FF, tex_particle, 2.0f, lhrandom(64, 255) / cl_particles_quality.value, 512 / cl_particles_quality.value, 0, 0, org[0], org[1], org[2], lhrandom(-count, count) * 3.0f + dir[0], lhrandom(-count, count) * 3.0f + dir[1], lhrandom(-count, count) * 3.0f + dir[2], 0);
}
/*
{
particle_t *p;
int i, maxparticle, j, a, content;
- float gravity, dvel, bloodwaterfade, frametime, f, dist, normal[3], v[3], org[3];
-#ifdef WORKINGLQUAKE
- void *hitent;
-#else
- entity_render_t *hitent;
-#endif
+ float gravity, dvel, bloodwaterfade, frametime, f, dist, org[3], oldorg[3];
+ int hitent;
+ trace_t trace;
// LordHavoc: early out condition
if (!cl_numparticles)
continue;
maxparticle = i;
content = 0;
- VectorCopy(p->org, p->oldorg);
- VectorMA(p->org, frametime, p->vel, p->org);
- VectorCopy(p->org, org);
- if (p->bounce)
+
+ p->alpha -= p->alphafade * frametime;
+
+ if (p->alpha <= 0)
{
- if (CL_TraceLine(p->oldorg, p->org, v, normal, true, &hitent, SUPERCONTENTS_SOLID) < 1)
+ p->type = NULL;
+ continue;
+ }
+
+ if (p->type->orientation != PARTICLE_BEAM)
+ {
+ VectorCopy(p->org, oldorg);
+ VectorMA(p->org, frametime, p->vel, p->org);
+ VectorCopy(p->org, org);
+ if (p->bounce)
{
- VectorCopy(v, p->org);
- if (p->bounce < 0)
+ if (p->type == particletype + pt_rain)
{
- // assume it's blood (lame, but...)
-#ifndef WORKINGLQUAKE
- if (cl_stainmaps.integer)
- R_Stain(v, 32, 32, 16, 16, p->alpha * p->scalex * (1.0f / 40.0f), 192, 48, 48, p->alpha * p->scalex * (1.0f / 40.0f));
-#endif
- if (!cl_decals.integer)
+ // raindrop - splash on solid/water/slime/lava
+ trace = CL_TraceBox(oldorg, vec3_origin, vec3_origin, p->org, true, NULL, SUPERCONTENTS_SOLID | SUPERCONTENTS_LIQUIDSMASK, false);
+ if (trace.fraction < 1)
{
- p->type = pt_dead;
- continue;
+ // convert from a raindrop particle to a rainsplash decal
+ VectorCopy(trace.endpos, p->org);
+ VectorCopy(trace.plane.normal, p->vel);
+ VectorAdd(p->org, p->vel, p->org);
+ p->type = particletype + pt_raindecal;
+ p->texnum = tex_rainsplash[0];
+ p->time2 = cl.time;
+ p->alphafade = p->alpha / 0.4;
+ p->bounce = 0;
+ p->friction = 0;
+ p->gravity = 0;
+ p->size = 8.0;
}
-
- p->type = pt_decal;
- p->orientation = PARTICLE_ORIENTED_DOUBLESIDED;
- // convert from a blood particle to a blood decal
- p->texnum = tex_blooddecal[rand()&7];
+ }
+ else if (p->type == particletype + pt_blood)
+ {
+ // blood - splash on solid
+ trace = CL_TraceBox(oldorg, vec3_origin, vec3_origin, p->org, true, &hitent, SUPERCONTENTS_SOLID, false);
+ if (trace.fraction < 1)
+ {
+ // convert from a blood particle to a blood decal
+ VectorCopy(trace.endpos, p->org);
+ VectorCopy(trace.plane.normal, p->vel);
+ VectorAdd(p->org, p->vel, p->org);
+#ifndef WORKINGLQUAKE
+ if (cl_stainmaps.integer)
+ R_Stain(p->org, 32, 32, 16, 16, p->alpha * p->size * (1.0f / 40.0f), 192, 48, 48, p->alpha * p->size * (1.0f / 40.0f));
+#endif
+ if (!cl_decals.integer)
+ {
+ p->type = NULL;
+ continue;
+ }
+
+ p->type = particletype + pt_decal;
+ p->texnum = tex_blooddecal[rand()&7];
#ifndef WORKINGLQUAKE
- p->owner = hitent;
- p->ownermodel = hitent->model;
- Matrix4x4_Transform(&hitent->inversematrix, v, p->relativeorigin);
- Matrix4x4_Transform3x3(&hitent->inversematrix, normal, p->relativedirection);
- VectorAdd(p->relativeorigin, p->relativedirection, p->relativeorigin);
+ p->owner = hitent;
+ p->ownermodel = cl_entities[hitent].render.model;
+ Matrix4x4_Transform(&cl_entities[hitent].render.inversematrix, p->org, p->relativeorigin);
+ Matrix4x4_Transform3x3(&cl_entities[hitent].render.inversematrix, p->vel, p->relativedirection);
#endif
- p->time2 = cl.time + cl_decals_time.value;
- p->die = p->time2 + cl_decals_fadetime.value;
- p->alphafade = 0;
- VectorCopy(normal, p->vel2);
- VectorClear(p->vel);
- VectorAdd(p->org, normal, p->org);
- p->bounce = 0;
- p->friction = 0;
- p->gravity = 0;
- p->scalex *= 1.25f;
- p->scaley *= 1.25f;
+ p->time2 = cl.time;
+ p->alphafade = 0;
+ p->bounce = 0;
+ p->friction = 0;
+ p->gravity = 0;
+ p->size *= 2.0f;
+ }
}
else
{
- dist = DotProduct(p->vel, normal) * -p->bounce;
- VectorMA(p->vel, dist, normal, p->vel);
- if (DotProduct(p->vel, p->vel) < 0.03)
- VectorClear(p->vel);
+ trace = CL_TraceBox(oldorg, vec3_origin, vec3_origin, p->org, true, NULL, SUPERCONTENTS_SOLID, false);
+ if (trace.fraction < 1)
+ {
+ VectorCopy(trace.endpos, p->org);
+ if (p->bounce < 0)
+ {
+ p->type = NULL;
+ continue;
+ }
+ else
+ {
+ dist = DotProduct(p->vel, trace.plane.normal) * -p->bounce;
+ VectorMA(p->vel, dist, trace.plane.normal, p->vel);
+ if (DotProduct(p->vel, p->vel) < 0.03)
+ VectorClear(p->vel);
+ }
+ }
}
}
- }
-
- p->vel[2] -= p->gravity * gravity;
-
- p->alpha -= p->alphafade * frametime;
-
- if (p->alpha <= 0 || cl.time > p->die)
- {
- p->type = pt_dead;
- continue;
- }
+ p->vel[2] -= p->gravity * gravity;
- if (p->friction)
- {
- f = p->friction * frametime;
- if (!content)
- content = CL_PointQ1Contents(p->org);
- if (content != CONTENTS_EMPTY)
- f *= 4;
- f = 1.0f - f;
- VectorScale(p->vel, f, p->vel);
+ if (p->friction)
+ {
+ f = p->friction * frametime;
+#ifdef WORKINGLQUAKE
+ if (CL_PointQ1Contents(p->org) != CONTENTS_EMPTY)
+#else
+ if (CL_PointSuperContents(p->org) & SUPERCONTENTS_LIQUIDSMASK)
+#endif
+ f *= 4;
+ f = 1.0f - f;
+ VectorScale(p->vel, f, p->vel);
+ }
}
- if (p->type != pt_static)
+ if (p->type != particletype + pt_static)
{
- switch (p->type)
+ switch (p->type - particletype)
{
+ case pt_entityparticle:
+ // particle that removes itself after one rendered frame
+ if (p->time2)
+ p->type = NULL;
+ else
+ p->time2 = 1;
+ break;
case pt_blood:
- if (!content)
- content = CL_PointQ1Contents(p->org);
- a = content;
- if (a != CONTENTS_EMPTY)
+#ifdef WORKINGLQUAKE
+ a = CL_PointQ1Contents(p->org);
+ if (a <= CONTENTS_WATER)
+#else
+ a = CL_PointSuperContents(p->org);
+ if (a & (SUPERCONTENTS_WATER | SUPERCONTENTS_SLIME))
+#endif
{
- if (a == CONTENTS_WATER || a == CONTENTS_SLIME)
- {
- p->scalex += frametime * 8;
- p->scaley += frametime * 8;
- //p->alpha -= bloodwaterfade;
- }
- else
- p->type = pt_dead;
+ p->size += frametime * 8;
+ //p->alpha -= bloodwaterfade;
}
else
p->vel[2] -= gravity;
+#ifdef WORKINGLQUAKE
+ if (a == CONTENTS_SOLID || a == CONTENTS_LAVA)
+#else
+ if (a & (SUPERCONTENTS_SOLID | SUPERCONTENTS_LAVA | SUPERCONTENTS_NODROP))
+#endif
+ p->type = NULL;
break;
case pt_bubble:
- if (!content)
- content = CL_PointQ1Contents(p->org);
- if (content != CONTENTS_WATER && content != CONTENTS_SLIME)
+#ifdef WORKINGLQUAKE
+ a = CL_PointQ1Contents(p->org);
+ if (a != CONTENTS_WATER && a != CONTENTS_SLIME)
+#else
+ a = CL_PointSuperContents(p->org);
+ if (!(a & (SUPERCONTENTS_WATER | SUPERCONTENTS_SLIME)))
+#endif
{
- p->type = pt_dead;
+ p->type = NULL;
break;
}
break;
case pt_rain:
+#ifdef WORKINGLQUAKE
+ a = CL_PointQ1Contents(p->org);
+ if (a != CONTENTS_EMPTY && a != CONTENTS_SKY)
+#else
+ a = CL_PointSuperContents(p->org);
+ if (a & (SUPERCONTENTS_SOLID | SUPERCONTENTS_LIQUIDSMASK))
+#endif
+ p->type = NULL;
+ break;
+ case pt_snow:
if (cl.time > p->time2)
{
// snow flutter
p->time2 = cl.time + (rand() & 3) * 0.1;
- p->vel[0] = lhrandom(-32, 32) + p->vel2[0];
- p->vel[1] = lhrandom(-32, 32) + p->vel2[1];
- p->vel[2] = /*lhrandom(-32, 32) +*/ p->vel2[2];
+ p->vel[0] = p->relativedirection[0] + lhrandom(-32, 32);
+ p->vel[1] = p->relativedirection[1] + lhrandom(-32, 32);
+ //p->vel[2] = p->relativedirection[2] + lhrandom(-32, 32);
}
- if (!content)
- content = CL_PointQ1Contents(p->org);
- a = content;
+#ifdef WORKINGLQUAKE
+ a = CL_PointQ1Contents(p->org);
if (a != CONTENTS_EMPTY && a != CONTENTS_SKY)
- p->type = pt_dead;
+#else
+ a = CL_PointSuperContents(p->org);
+ if (a & (SUPERCONTENTS_SOLID | SUPERCONTENTS_LIQUIDSMASK))
+#endif
+ p->type = NULL;
break;
- case pt_grow:
- p->scalex += frametime * p->time2;
- p->scaley += frametime * p->time2;
+ case pt_smoke:
+ //p->size += frametime * 15;
break;
case pt_decal:
+ // FIXME: this has fairly wacky handling of alpha
+ p->alphafade = cl.time > (p->time2 + cl_decals_time.value) ? (255 / cl_decals_fadetime.value) : 0;
#ifndef WORKINGLQUAKE
- if (p->owner->model == p->ownermodel)
+ if (cl_entities[p->owner].render.model == p->ownermodel)
{
- Matrix4x4_Transform(&p->owner->matrix, p->relativeorigin, p->org);
- Matrix4x4_Transform3x3(&p->owner->matrix, p->relativedirection, p->vel2);
- if (cl.time > p->time2)
- {
- p->alphafade = p->alpha / (p->die - cl.time);
- p->type = pt_decalfade;
- }
+ Matrix4x4_Transform(&cl_entities[p->owner].render.matrix, p->relativeorigin, p->org);
+ Matrix4x4_Transform3x3(&cl_entities[p->owner].render.matrix, p->relativedirection, p->vel);
}
else
- p->type = pt_dead;
+ p->type = NULL;
#endif
break;
- case pt_decalfade:
-#ifndef WORKINGLQUAKE
- if (p->owner->model == p->ownermodel)
- {
- Matrix4x4_Transform(&p->owner->matrix, p->relativeorigin, p->org);
- Matrix4x4_Transform3x3(&p->owner->matrix, p->relativedirection, p->vel2);
- }
+ case pt_raindecal:
+ a = max(0, (cl.time - p->time2) * 40);
+ if (a < 16)
+ p->texnum = tex_rainsplash[a];
else
- p->type = pt_dead;
-#endif
- break;
- case pt_ember:
- while (cl.time > p->time2)
- {
- p->time2 += 0.025;
- particle(pt_static, PARTICLE_SPARK, 0x903010, 0xFFD030, tex_particle, false, PBLEND_ADD, p->scalex * 0.75, p->scaley * 0.75, p->alpha, p->alphafade, 9999, 0.5, 0, p->org[0], p->org[1], p->org[2], p->vel[0] * lhrandom(0.4, 0.6), p->vel[1] * lhrandom(0.4, 0.6), p->vel[2] * lhrandom(0.4, 0.6), 0, 0, 0, 0, 0, 0);
- }
+ p->type = NULL;
break;
default:
- Con_Printf("unknown particle type %i\n", p->type);
- p->type = pt_dead;
break;
}
}
static cvar_t r_drawparticles = {0, "r_drawparticles", "1"};
+#define PARTICLETEXTURESIZE 64
+#define PARTICLEFONTSIZE (PARTICLETEXTURESIZE*8)
+
static qbyte shadebubble(float dx, float dy, vec3_t light)
{
float dz, f, dot;
static void setuptex(int texnum, qbyte *data, qbyte *particletexturedata)
{
int basex, basey, y;
- basex = ((texnum >> 0) & 7) * 32;
- basey = ((texnum >> 3) & 7) * 32;
- particletexture[texnum].s1 = (basex + 1) / 256.0f;
- particletexture[texnum].t1 = (basey + 1) / 256.0f;
- particletexture[texnum].s2 = (basex + 31) / 256.0f;
- particletexture[texnum].t2 = (basey + 31) / 256.0f;
- for (y = 0;y < 32;y++)
- memcpy(particletexturedata + ((basey + y) * 256 + basex) * 4, data + y * 32 * 4, 32 * 4);
+ basex = ((texnum >> 0) & 7) * PARTICLETEXTURESIZE;
+ basey = ((texnum >> 3) & 7) * PARTICLETEXTURESIZE;
+ particletexture[texnum].s1 = (basex + 1) / (float)PARTICLEFONTSIZE;
+ particletexture[texnum].t1 = (basey + 1) / (float)PARTICLEFONTSIZE;
+ particletexture[texnum].s2 = (basex + PARTICLETEXTURESIZE - 1) / (float)PARTICLEFONTSIZE;
+ particletexture[texnum].t2 = (basey + PARTICLETEXTURESIZE - 1) / (float)PARTICLEFONTSIZE;
+ for (y = 0;y < PARTICLETEXTURESIZE;y++)
+ memcpy(particletexturedata + ((basey + y) * PARTICLEFONTSIZE + basex) * 4, data + y * PARTICLETEXTURESIZE * 4, PARTICLETEXTURESIZE * 4);
}
void particletextureblotch(qbyte *data, float radius, float red, float green, float blue, float alpha)
int x, y;
float cx, cy, dx, dy, f, iradius;
qbyte *d;
- cx = lhrandom(radius + 1, 30 - radius);
- cy = lhrandom(radius + 1, 30 - radius);
+ cx = (lhrandom(radius + 1, PARTICLETEXTURESIZE - 2 - radius) + lhrandom(radius + 1, PARTICLETEXTURESIZE - 2 - radius)) * 0.5f;
+ cy = (lhrandom(radius + 1, PARTICLETEXTURESIZE - 2 - radius) + lhrandom(radius + 1, PARTICLETEXTURESIZE - 2 - radius)) * 0.5f;
iradius = 1.0f / radius;
alpha *= (1.0f / 255.0f);
- for (y = 0;y < 32;y++)
+ for (y = 0;y < PARTICLETEXTURESIZE;y++)
{
- for (x = 0;x < 32;x++)
+ for (x = 0;x < PARTICLETEXTURESIZE;x++)
{
dx = (x - cx);
dy = (y - cy);
f = (1.0f - sqrt(dx * dx + dy * dy) * iradius) * alpha;
if (f > 0)
{
- d = data + (y * 32 + x) * 4;
+ d = data + (y * PARTICLETEXTURESIZE + x) * 4;
d[0] += f * (red - d[0]);
d[1] += f * (green - d[1]);
d[2] += f * (blue - d[2]);
void particletextureclamp(qbyte *data, int minr, int ming, int minb, int maxr, int maxg, int maxb)
{
int i;
- for (i = 0;i < 32*32;i++, data += 4)
+ for (i = 0;i < PARTICLETEXTURESIZE*PARTICLETEXTURESIZE;i++, data += 4)
{
data[0] = bound(minr, data[0], maxr);
data[1] = bound(ming, data[1], maxg);
void particletextureinvert(qbyte *data)
{
int i;
- for (i = 0;i < 32*32;i++, data += 4)
+ for (i = 0;i < PARTICLETEXTURESIZE*PARTICLETEXTURESIZE;i++, data += 4)
{
data[0] = 255 - data[0];
data[1] = 255 - data[1];
}
}
+// Those loops are in a separate function to work around an optimization bug in Mac OS X's GCC
+static void R_InitBloodTextures (qbyte *particletexturedata)
+{
+ int i, j, k, m;
+ qbyte data[PARTICLETEXTURESIZE][PARTICLETEXTURESIZE][4];
+
+ // blood particles
+ for (i = 0;i < 8;i++)
+ {
+ memset(&data[0][0][0], 255, sizeof(data));
+ for (k = 0;k < 24;k++)
+ particletextureblotch(&data[0][0][0], PARTICLETEXTURESIZE/16, 96, 0, 0, 160);
+ //particletextureclamp(&data[0][0][0], 32, 32, 32, 255, 255, 255);
+ particletextureinvert(&data[0][0][0]);
+ setuptex(tex_bloodparticle[i], &data[0][0][0], particletexturedata);
+ }
+
+ // blood decals
+ for (i = 0;i < 8;i++)
+ {
+ memset(&data[0][0][0], 255, sizeof(data));
+ m = 8;
+ for (j = 1;j < 10;j++)
+ for (k = min(j, m - 1);k < m;k++)
+ particletextureblotch(&data[0][0][0], (float)j*PARTICLETEXTURESIZE/64.0f, 96, 0, 0, 192 - j * 8);
+ //particletextureclamp(&data[0][0][0], 32, 32, 32, 255, 255, 255);
+ particletextureinvert(&data[0][0][0]);
+ setuptex(tex_blooddecal[i], &data[0][0][0], particletexturedata);
+ }
+
+}
+
static void R_InitParticleTexture (void)
{
- int x, y, d, i, j, k, m;
+ int x, y, d, i, k, m;
float dx, dy, radius, f, f2;
- qbyte data[32][32][4], noise1[64][64], noise2[64][64], data2[64][16][4];
+ qbyte data[PARTICLETEXTURESIZE][PARTICLETEXTURESIZE][4], noise3[64][64], data2[64][16][4];
vec3_t light;
- qbyte particletexturedata[256*256*4];
+ qbyte *particletexturedata;
// a note: decals need to modulate (multiply) the background color to
// properly darken it (stain), and they need to be able to alpha fade,
// and white on black background) so we can alpha fade it to black, then
// we invert it again during the blendfunc to make it work...
- memset(particletexturedata, 255, sizeof(particletexturedata));
+ particletexturedata = Mem_Alloc(tempmempool, PARTICLEFONTSIZE*PARTICLEFONTSIZE*4);
+ memset(particletexturedata, 255, PARTICLEFONTSIZE*PARTICLEFONTSIZE*4);
// smoke
for (i = 0;i < 8;i++)
memset(&data[0][0][0], 255, sizeof(data));
do
{
- fractalnoise(&noise1[0][0], 64, 4);
- fractalnoise(&noise2[0][0], 64, 8);
+ qbyte noise1[PARTICLETEXTURESIZE*2][PARTICLETEXTURESIZE*2], noise2[PARTICLETEXTURESIZE*2][PARTICLETEXTURESIZE*2];
+
+ fractalnoise(&noise1[0][0], PARTICLETEXTURESIZE*2, PARTICLETEXTURESIZE/8);
+ fractalnoise(&noise2[0][0], PARTICLETEXTURESIZE*2, PARTICLETEXTURESIZE/4);
m = 0;
- for (y = 0;y < 32;y++)
+ for (y = 0;y < PARTICLETEXTURESIZE;y++)
{
- dy = y - 16;
- for (x = 0;x < 32;x++)
+ dy = (y - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ for (x = 0;x < PARTICLETEXTURESIZE;x++)
{
- dx = x - 16;
+ dx = (x - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
d = (noise2[y][x] - 128) * 3 + 192;
if (d > 0)
- d = d * (256 - (int) (dx*dx+dy*dy)) / 256;
+ d = d * (1-(dx*dx+dy*dy));
d = (d * noise1[y][x]) >> 7;
d = bound(0, d, 255);
data[y][x][3] = (qbyte) d;
for (i = 0;i < 16;i++)
{
memset(&data[0][0][0], 255, sizeof(data));
- radius = i * 3.0f / 16.0f;
+ radius = i * 3.0f / 4.0f / 16.0f;
f2 = 255.0f * ((15.0f - i) / 15.0f);
- for (y = 0;y < 32;y++)
+ for (y = 0;y < PARTICLETEXTURESIZE;y++)
{
- dy = (y - 16) * 0.25f;
- for (x = 0;x < 32;x++)
+ dy = (y - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ for (x = 0;x < PARTICLETEXTURESIZE;x++)
{
- dx = (x - 16) * 0.25f;
- f = (1.0 - fabs(radius - sqrt(dx*dx+dy*dy))) * f2;
+ dx = (x - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ f = f2 * (1.0 - 4.0f * fabs(radius - sqrt(dx*dx+dy*dy)));
data[y][x][3] = (int) (bound(0.0f, f, 255.0f));
}
}
// normal particle
memset(&data[0][0][0], 255, sizeof(data));
- for (y = 0;y < 32;y++)
+ for (y = 0;y < PARTICLETEXTURESIZE;y++)
{
- dy = y - 16;
- for (x = 0;x < 32;x++)
+ dy = (y - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ for (x = 0;x < PARTICLETEXTURESIZE;x++)
{
- dx = x - 16;
- d = (256 - (dx*dx+dy*dy));
+ dx = (x - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ d = 256 * (1 - (dx*dx+dy*dy));
d = bound(0, d, 255);
data[y][x][3] = (qbyte) d;
}
memset(&data[0][0][0], 255, sizeof(data));
light[0] = 1;light[1] = 1;light[2] = 1;
VectorNormalize(light);
- for (y = 0;y < 32;y++)
- for (x = 0;x < 32;x++)
- data[y][x][3] = shadebubble((x - 16) * (1.0 / 8.0), y < 24 ? (y - 24) * (1.0 / 24.0) : (y - 24) * (1.0 / 8.0), light);
+ for (y = 0;y < PARTICLETEXTURESIZE;y++)
+ {
+ dy = (y - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ // stretch upper half of bubble by +50% and shrink lower half by -50%
+ // (this gives an elongated teardrop shape)
+ if (dy > 0.5f)
+ dy = (dy - 0.5f) * 2.0f;
+ else
+ dy = (dy - 0.5f) / 1.5f;
+ for (x = 0;x < PARTICLETEXTURESIZE;x++)
+ {
+ dx = (x - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ // shrink bubble width to half
+ dx *= 2.0f;
+ data[y][x][3] = shadebubble(dx, dy, light);
+ }
+ }
setuptex(tex_raindrop, &data[0][0][0], particletexturedata);
// bubble
memset(&data[0][0][0], 255, sizeof(data));
light[0] = 1;light[1] = 1;light[2] = 1;
VectorNormalize(light);
- for (y = 0;y < 32;y++)
- for (x = 0;x < 32;x++)
- data[y][x][3] = shadebubble((x - 16) * (1.0 / 16.0), (y - 16) * (1.0 / 16.0), light);
- setuptex(tex_bubble, &data[0][0][0], particletexturedata);
-
- // blood particles
- for (i = 0;i < 8;i++)
+ for (y = 0;y < PARTICLETEXTURESIZE;y++)
{
- memset(&data[0][0][0], 255, sizeof(data));
- for (k = 0;k < 24;k++)
- particletextureblotch(&data[0][0][0], 2, 96, 0, 0, 160);
- //particletextureclamp(&data[0][0][0], 32, 32, 32, 255, 255, 255);
- particletextureinvert(&data[0][0][0]);
- setuptex(tex_bloodparticle[i], &data[0][0][0], particletexturedata);
+ dy = (y - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ for (x = 0;x < PARTICLETEXTURESIZE;x++)
+ {
+ dx = (x - 0.5f*PARTICLETEXTURESIZE) / (PARTICLETEXTURESIZE*0.5f-1);
+ data[y][x][3] = shadebubble(dx, dy, light);
+ }
}
+ setuptex(tex_bubble, &data[0][0][0], particletexturedata);
- // blood decals
- for (i = 0;i < 8;i++)
- {
- memset(&data[0][0][0], 255, sizeof(data));
- for (k = 0;k < 24;k++)
- particletextureblotch(&data[0][0][0], 2, 96, 0, 0, 96);
- for (j = 3;j < 7;j++)
- for (k = 0, m = rand() % 12;k < m;k++)
- particletextureblotch(&data[0][0][0], j, 96, 0, 0, 192);
- //particletextureclamp(&data[0][0][0], 32, 32, 32, 255, 255, 255);
- particletextureinvert(&data[0][0][0]);
- setuptex(tex_blooddecal[i], &data[0][0][0], particletexturedata);
- }
+ // Blood particles and blood decals
+ R_InitBloodTextures (particletexturedata);
// bullet decals
for (i = 0;i < 8;i++)
{
memset(&data[0][0][0], 255, sizeof(data));
for (k = 0;k < 12;k++)
- particletextureblotch(&data[0][0][0], 2, 0, 0, 0, 128);
+ particletextureblotch(&data[0][0][0], PARTICLETEXTURESIZE/16, 0, 0, 0, 128);
for (k = 0;k < 3;k++)
- particletextureblotch(&data[0][0][0], 14, 0, 0, 0, 160);
+ particletextureblotch(&data[0][0][0], PARTICLETEXTURESIZE/2, 0, 0, 0, 160);
//particletextureclamp(&data[0][0][0], 64, 64, 64, 255, 255, 255);
particletextureinvert(&data[0][0][0]);
setuptex(tex_bulletdecal[i], &data[0][0][0], particletexturedata);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
#else
+
+#if 0
+ Image_WriteTGARGBA ("particles/particlefont.tga", PARTICLEFONTSIZE, PARTICLEFONTSIZE, particletexturedata);
+#endif
+
particlefonttexture = loadtextureimage(particletexturepool, "particles/particlefont.tga", 0, 0, false, TEXF_ALPHA | TEXF_PRECACHE);
if (!particlefonttexture)
- particlefonttexture = R_LoadTexture2D(particletexturepool, "particlefont", 256, 256, particletexturedata, TEXTYPE_RGBA, TEXF_ALPHA | TEXF_PRECACHE, NULL);
+ particlefonttexture = R_LoadTexture2D(particletexturepool, "particlefont", PARTICLEFONTSIZE, PARTICLEFONTSIZE, particletexturedata, TEXTYPE_RGBA, TEXF_ALPHA | TEXF_PRECACHE, NULL);
for (i = 0;i < MAX_PARTICLETEXTURES;i++)
particletexture[i].texture = particlefonttexture;
// nexbeam
- fractalnoise(&noise1[0][0], 64, 4);
+ fractalnoise(&noise3[0][0], 64, 4);
m = 0;
for (y = 0;y < 64;y++)
{
+ dy = (y - 0.5f*64) / (64*0.5f-1);
for (x = 0;x < 16;x++)
{
- if (x < 8)
- d = x;
- else
- d = (15 - x);
- d = d * d * noise1[y][x] / (7 * 7);
+ dx = (x - 0.5f*16) / (16*0.5f-2);
+ d = (1 - sqrt(fabs(dx))) * noise3[y][x];
data2[y][x][0] = data2[y][x][1] = data2[y][x][2] = (qbyte) bound(0, d, 255);
data2[y][x][3] = 255;
}
}
+#if 0
+ Image_WriteTGARGBA ("particles/nexbeam.tga", 64, 64, &data2[0][0][0]);
+#endif
+
particletexture[tex_beam].texture = loadtextureimage(particletexturepool, "particles/nexbeam.tga", 0, 0, false, TEXF_ALPHA | TEXF_PRECACHE);
if (!particletexture[tex_beam].texture)
particletexture[tex_beam].texture = R_LoadTexture2D(particletexturepool, "nexbeam", 16, 64, &data2[0][0][0], TEXTYPE_RGBA, TEXF_PRECACHE, NULL);
particletexture[tex_beam].s2 = 1;
particletexture[tex_beam].t2 = 1;
#endif
+ Mem_Free(particletexturedata);
}
static void r_part_start(void)
const particle_t *p = calldata1;
rmeshstate_t m;
#endif
- float org[3], up2[3], v[3], right[3], up[3], fog, ifog, fogvec[3], cr, cg, cb, ca;
+ pblend_t blendmode;
+ float org[3], up2[3], v[3], right[3], up[3], fog, ifog, fogvec[3], cr, cg, cb, ca, size;
particletexture_t *tex;
VectorCopy(p->org, org);
+ blendmode = p->type->blendmode;
tex = &particletexture[p->texnum];
cr = p->color[0] * (1.0f / 255.0f);
cg = p->color[1] * (1.0f / 255.0f);
cb = p->color[2] * (1.0f / 255.0f);
ca = p->alpha * (1.0f / 255.0f);
- if (p->blendmode == PBLEND_MOD)
+ if (blendmode == PBLEND_MOD)
{
cr *= ca;
cg *= ca;
cb = min(cb, 1);
ca = 1;
}
-
#ifndef WORKINGLQUAKE
- if (fogenabled && p->blendmode != PBLEND_MOD)
+ if (p->type->lighting)
+ {
+ float ambient[3], diffuse[3], diffusenormal[3];
+ R_CompleteLightPoint(ambient, diffuse, diffusenormal, org, true);
+ cr *= (ambient[0] + 0.5 * diffuse[0]);
+ cg *= (ambient[1] + 0.5 * diffuse[1]);
+ cb *= (ambient[2] + 0.5 * diffuse[2]);
+ }
+ if (fogenabled)
{
VectorSubtract(org, r_vieworigin, fogvec);
fog = exp(fogdensity/DotProduct(fogvec,fogvec));
cr = cr * ifog;
cg = cg * ifog;
cb = cb * ifog;
- if (p->blendmode == 0)
+ if (blendmode == PBLEND_ALPHA)
{
cr += fogcolor[0] * fog;
cg += fogcolor[1] * fog;
GL_Color(cr, cg, cb, ca);
- if (p->blendmode == 0)
+ if (blendmode == PBLEND_ALPHA)
GL_BlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
- else if (p->blendmode == 1)
+ else if (blendmode == PBLEND_ADD)
GL_BlendFunc(GL_SRC_ALPHA, GL_ONE);
- else
+ else //if (blendmode == PBLEND_MOD)
GL_BlendFunc(GL_ZERO, GL_ONE_MINUS_SRC_COLOR);
GL_DepthMask(false);
GL_DepthTest(true);
#endif
- if (p->orientation == PARTICLE_BILLBOARD || p->orientation == PARTICLE_ORIENTED_DOUBLESIDED)
+ size = p->size * cl_particles_size.value;
+ if (p->type->orientation == PARTICLE_BILLBOARD || p->type->orientation == PARTICLE_ORIENTED_DOUBLESIDED)
{
- if (p->orientation == PARTICLE_ORIENTED_DOUBLESIDED)
+ if (p->type->orientation == PARTICLE_ORIENTED_DOUBLESIDED)
{
// double-sided
- if (DotProduct(p->vel2, r_vieworigin) > DotProduct(p->vel2, org))
+ if (DotProduct(p->vel, r_vieworigin) > DotProduct(p->vel, org))
{
- VectorNegate(p->vel2, v);
+ VectorNegate(p->vel, v);
VectorVectors(v, right, up);
}
else
- VectorVectors(p->vel2, right, up);
- VectorScale(right, p->scalex, right);
- VectorScale(up, p->scaley, up);
+ VectorVectors(p->vel, right, up);
+ VectorScale(right, size, right);
+ VectorScale(up, size, up);
}
else
{
- VectorScale(r_viewleft, -p->scalex, right);
- VectorScale(r_viewup, p->scaley, up);
+ VectorScale(r_viewleft, -size, right);
+ VectorScale(r_viewup, size, up);
}
particle_vertex3f[ 0] = org[0] - right[0] - up[0];
particle_vertex3f[ 1] = org[1] - right[1] - up[1];
particle_texcoord2f[4] = tex->s2;particle_texcoord2f[5] = tex->t1;
particle_texcoord2f[6] = tex->s2;particle_texcoord2f[7] = tex->t2;
}
- else if (p->orientation == PARTICLE_SPARK)
+ else if (p->type->orientation == PARTICLE_SPARK)
{
- VectorMA(p->org, -p->scaley, p->vel, v);
- VectorMA(p->org, p->scaley, p->vel, up2);
- R_CalcBeam_Vertex3f(particle_vertex3f, v, up2, p->scalex);
+ VectorMA(p->org, -0.02, p->vel, v);
+ VectorMA(p->org, 0.02, p->vel, up2);
+ R_CalcBeam_Vertex3f(particle_vertex3f, v, up2, size);
particle_texcoord2f[0] = tex->s1;particle_texcoord2f[1] = tex->t2;
particle_texcoord2f[2] = tex->s1;particle_texcoord2f[3] = tex->t1;
particle_texcoord2f[4] = tex->s2;particle_texcoord2f[5] = tex->t1;
particle_texcoord2f[6] = tex->s2;particle_texcoord2f[7] = tex->t2;
}
- else if (p->orientation == PARTICLE_BEAM)
+ else if (p->type->orientation == PARTICLE_BEAM)
{
- R_CalcBeam_Vertex3f(particle_vertex3f, p->org, p->vel2, p->scalex);
- VectorSubtract(p->vel2, p->org, up);
- VectorNormalizeFast(up);
- v[0] = DotProduct(p->org, up) * (1.0f / 64.0f) - cl.time * 0.25;
- v[1] = DotProduct(p->vel2, up) * (1.0f / 64.0f) - cl.time * 0.25;
+ R_CalcBeam_Vertex3f(particle_vertex3f, p->org, p->vel, size);
+ VectorSubtract(p->vel, p->org, up);
+ VectorNormalize(up);
+ v[0] = DotProduct(p->org, up) * (1.0f / 64.0f);
+ v[1] = DotProduct(p->vel, up) * (1.0f / 64.0f);
particle_texcoord2f[0] = 1;particle_texcoord2f[1] = v[0];
particle_texcoord2f[2] = 0;particle_texcoord2f[3] = v[0];
particle_texcoord2f[4] = 0;particle_texcoord2f[5] = v[1];
particle_texcoord2f[6] = 1;particle_texcoord2f[7] = v[1];
}
else
- Host_Error("R_DrawParticles: unknown particle orientation %i\n", p->orientation);
+ {
+ Con_Printf("R_DrawParticles: unknown particle orientation %i\n", p->type->orientation);
+ return;
+ }
#if WORKINGLQUAKE
- if (p->blendmode == 0)
+ if (blendmode == PBLEND_ALPHA)
glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
- else if (p->blendmode == 1)
+ else if (blendmode == PBLEND_ADD)
glBlendFunc(GL_SRC_ALPHA, GL_ONE);
- else
+ else //if (blendmode == PBLEND_MOD)
glBlendFunc(GL_ZERO, GL_ONE_MINUS_SRC_COLOR);
glColor4f(cr, cg, cb, ca);
glBegin(GL_QUADS);
glTexCoord2f(particle_texcoord2f[6], particle_texcoord2f[7]);glVertex3f(particle_vertex3f[ 9], particle_vertex3f[10], particle_vertex3f[11]);
glEnd();
#else
- R_Mesh_Draw(4, 2, polygonelements);
+ R_Mesh_Draw(0, 4, 2, polygonelements);
#endif
}
if (p->type)
{
c_particles++;
- if (DotProduct(p->org, r_viewforward) >= minparticledist || p->orientation == PARTICLE_BEAM)
- R_MeshQueue_AddTransparent(p->org, R_DrawParticleCallback, p, 0);
+ if (DotProduct(p->org, r_viewforward) >= minparticledist || p->type->orientation == PARTICLE_BEAM)
+ {
+ if (p->type == particletype + pt_decal)
+ R_DrawParticleCallback(p, 0);
+ else
+ R_MeshQueue_AddTransparent(p->org, R_DrawParticleCallback, p, 0);
+ }
}
}
#endif
projects / xonotic / darkplaces.git / blobdiff