fteqw/engine/client/p_script.c
Spoike bfe545222e added con_textsize to resize console separately from everything else.
qcc: added support for variable arguments via the va_arg intrinsic.
qcc: fix up some comment/whitespace issues with the preprocessor.
random hacks to try to improve dp compatibility a little.

git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@4573 fc73d0e0-1445-4013-8a0c-d673dee63da5
2013-12-29 22:48:28 +00:00

5810 lines
156 KiB
C

/*
Copyright (C) 1996-1997 Id Software, Inc.
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License
as published by the Free Software Foundation; either version 2
of the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
/*
The aim of this particle system is to have as much as possible configurable.
Some parts still fail here, and are marked FIXME
Effects are flushed on new maps.
The engine has a few builtins.
*/
#include "quakedef.h"
#ifdef PSET_SCRIPT
#ifdef GLQUAKE
#include "glquake.h"//hack
#endif
#include "shader.h"
#ifdef D3DQUAKE
//d3d is awkward
//we can't include two versions of header files
extern void *d3dexplosiontexture;
extern void *d3dballtexture;
#endif
#include "renderque.h"
#include "r_partset.h"
struct
{
char *name;
char **data;
} partset_list[] =
{
{"none", NULL},
R_PARTSET_BUILTINS
{NULL}
};
extern qbyte *host_basepal;
extern particleengine_t pe_classic;
particleengine_t *fallback = NULL; //does this really need to be 'extern'?
#define FALLBACKBIAS 0x1000000
static int pt_pointfile = P_INVALID;
static int pe_default = P_INVALID;
static int pe_size2 = P_INVALID;
static int pe_size3 = P_INVALID;
static int pe_defaulttrail = P_INVALID;
static qboolean pe_script_enabled;
static float psintable[256];
static qboolean P_LoadParticleSet(char *name, qboolean implicit);
static void buildsintable(void)
{
int i;
for (i = 0; i < 256; i++)
psintable[i] = sin((i*M_PI)/128);
}
#define sin(x) (psintable[(int)((x)*(128/M_PI)) & 255])
#define cos(x) (psintable[((int)((x)*(128/M_PI)) + 64) & 255])
typedef struct particle_s
{
struct particle_s *next;
float die;
// driver-usable fields
vec3_t org;
vec4_t rgba;
float scale;
float s1, t1, s2, t2;
vec3_t vel; //renderer uses for sparks
float angle;
union {
float nextemit;
trailstate_t *trailstate;
} state;
// drivers never touch the following fields
float rotationspeed;
} particle_t;
typedef struct clippeddecal_s
{
struct clippeddecal_s *next;
float die;
vec3_t center;
vec3_t vertex[3];
vec2_t texcoords[3];
vec4_t rgba;
} clippeddecal_t;
#define BS_LASTSEG 0x1 // no draw to next, no delete
#define BS_DEAD 0x2 // segment is dead
#define BS_NODRAW 0x4 // only used for lerp switching
typedef struct beamseg_s
{
struct beamseg_s *next; // next in beamseg list
particle_t *p;
int flags; // flags for beamseg
vec3_t dir;
float texture_s;
} beamseg_t;
typedef struct skytris_s {
struct skytris_s *next;
vec3_t org;
vec3_t x;
vec3_t y;
float area;
float nexttime;
struct msurface_s *face;
} skytris_t;
//these is the required render state for each particle
//dynamic per-particle stuff isn't important. only static state.
typedef struct {
enum {PT_NORMAL, PT_SPARK, PT_SPARKFAN, PT_TEXTUREDSPARK, PT_BEAM, PT_CDECAL, PT_UDECAL} type;
blendmode_t blendmode;
shader_t *shader;
float scalefactor;
float invscalefactor;
float stretch;
} plooks_t;
//these could be deltas or absolutes depending on ramping mode.
typedef struct {
vec3_t rgb;
float alpha;
float scale;
float rotation;
} ramp_t;
typedef struct {
char name[MAX_QPATH];
model_t *model;
float framestart;
float frameend;
float framerate;
float alpha;
} partmodels_t;
// TODO: merge in alpha with rgb to gain benefit of vector opts
typedef struct part_type_s {
char name[MAX_QPATH];
char config[MAX_QPATH];
char texname[MAX_QPATH];
int nummodels;
partmodels_t *models;
char soundname[MAX_QPATH];
float soundvol;
float soundattn;
float sounddelay;
float soundpitch;
vec3_t rgb; //initial colour
float alpha;
vec3_t rgbchange; //colour delta (per second)
float alphachange;
vec3_t rgbrand; //random rgb colour to start with
float alpharand;
int colorindex; //get colour from a palette
int colorrand; //and add up to this amount
float rgbchangetime;//colour stops changing at this time
vec3_t rgbrandsync; //like rgbrand, but a single random value instead of separate (can mix)
float scale; //initial scale
float scalerand; //with up to this much extra
float die, randdie; //how long it lasts (plus some rand)
float randomvel, randomvelvert, randomvelvertbias; //random velocity (unaligned=worldspace)
float veladd; //scale the incoming velocity by this much
float orgadd; //spawn the particle this far along its velocity direction
float spawnvel, spawnvelvert; //spawn the particle with a velocity based upon its spawn type (generally so it flies outwards)
vec3_t orgbias; //static 3d world-coord bias
float s1, t1, s2, t2; //texture coords
float texsstride; //addition for s for each random slot.
int randsmax; //max times the stride can be added
plooks_t *slooks; //shared looks, so state switches don't apply between particles so much
plooks_t looks;
float spawntime; //time limit for trails
float spawnchance; //if < 0, particles might not spawn so many
float rotationstartmin, rotationstartrand;
float rotationmin, rotationrand;
float scaledelta;
int countextra;
float count;
float countrand;
int assoc;
int cliptype;
int inwater;
float clipcount;
int emit;
float emittime;
float emitrand;
float emitstart;
float areaspread;
float areaspreadvert;
float spawnparam1;
float spawnparam2;
/* float spawnparam3; */
float offsetup; // make this into a vec3_t later with dir, possibly for mdls
enum {
SM_BOX, //box = even spread within the area
SM_CIRCLE, //circle = around edge of a circle
SM_BALL, //ball = filled sphere
SM_SPIRAL, //spiral = spiral trail
SM_TRACER, //tracer = tracer trail
SM_TELEBOX, //telebox = q1-style telebox
SM_LAVASPLASH, //lavasplash = q1-style lavasplash
SM_UNICIRCLE, //unicircle = uniform circle
SM_FIELD, //field = synced field (brightfield, etc)
SM_DISTBALL // uneven distributed ball
} spawnmode;
float gravity;
vec3_t friction;
float clipbounce;
float stainonimpact;
vec3_t dl_rgb;
float dl_radius;
float dl_time;
vec4_t dl_decay;
//PT_NODLSHADOW
int dl_cubemapnum;
vec3_t stain_rgb;
float stain_radius;
enum {RAMP_NONE, RAMP_DELTA, RAMP_NEAREST, RAMP_LERP} rampmode;
int rampindexes;
ramp_t *ramp;
int loaded; //0 if not loaded, 1 if automatically loaded, 2 if user loaded
particle_t *particles;
clippeddecal_t *clippeddecals;
beamseg_t *beams;
skytris_t *skytris;
struct part_type_s *nexttorun;
unsigned int flags;
#define PT_VELOCITY 0x001
#define PT_FRICTION 0x002
#define PT_CHANGESCOLOUR 0x004
#define PT_CITRACER 0x008 // Q1-style tracer behavior for colorindex
#define PT_INVFRAMETIME 0x010 // apply inverse frametime to count (causes emits to be per frame)
#define PT_AVERAGETRAIL 0x020 // average trail points from start to end, useful with t_lightning, etc
#define PT_NOSTATE 0x040 // don't use trailstate for this emitter (careful with assoc...)
#define PT_NOSPREADFIRST 0x080 // don't randomize org/vel for first generated particle
#define PT_NOSPREADLAST 0x100 // don't randomize org/vel for last generated particle
#define PT_TROVERWATER 0x200 // don't spawn if underwater
#define PT_TRUNDERWATER 0x400 // don't spawn if overwater
#define PT_NODLSHADOW 0x800 // dlights from this effect don't cast shadows.
unsigned int state;
#define PS_INRUNLIST 0x1 // particle type is currently in execution list
} part_type_t;
typedef struct pcfg_s
{
struct pcfg_s *next;
char name[1];
} pcfg_t;
static pcfg_t *loadedconfigs;
#ifndef TYPESONLY
//triangle fan sparks use these. // defined but not used
//static double sint[7] = {0.000000, 0.781832, 0.974928, 0.433884, -0.433884, -0.974928, -0.781832};
//static double cost[7] = {1.000000, 0.623490, -0.222521, -0.900969, -0.900969, -0.222521, 0.623490};
#define crand() (rand()%32767/16383.5f-1)
static void P_ReadPointFile_f (void);
static void P_ExportBuiltinSet_f(void);
#define MAX_BEAMSEGS 2048 // default max # of beam segments
#define MAX_PARTICLES 32768 // default max # of particles at one
// time
#define MAX_DECALS 4096 // this is going to be expensive
#define MAX_TRAILSTATES 512 // default max # of trailstates
//int ramp1[8] = {0x6f, 0x6d, 0x6b, 0x69, 0x67, 0x65, 0x63, 0x61};
//int ramp2[8] = {0x6f, 0x6e, 0x6d, 0x6c, 0x6b, 0x6a, 0x68, 0x66};
//int ramp3[8] = {0x6d, 0x6b, 6, 5, 4, 3, 2, 1};
particle_t *free_particles;
particle_t *particles; //contains the initial list of alloced particles.
int r_numparticles;
beamseg_t *free_beams;
beamseg_t *beams;
int r_numbeams;
clippeddecal_t *free_decals;
clippeddecal_t *decals;
int r_numdecals;
trailstate_t *trailstates;
int ts_cycle; // current cyclic index of trailstates
int r_numtrailstates;
static qboolean r_plooksdirty; //a particle effect was changed, reevaluate shared looks.
extern cvar_t r_bouncysparks;
extern cvar_t r_part_rain;
extern cvar_t r_bloodstains;
extern cvar_t gl_part_flame;
// callbacks
static void R_ParticleDesc_Callback(struct cvar_s *var, char *oldvalue);
extern cvar_t r_particledesc;
extern cvar_t r_part_rain_quantity;
extern cvar_t r_particle_tracelimit;
extern cvar_t r_part_sparks;
extern cvar_t r_part_sparks_trifan;
extern cvar_t r_part_sparks_textured;
extern cvar_t r_part_beams;
extern cvar_t r_part_contentswitch;
extern cvar_t r_part_density;
static float particletime;
#define BUFFERVERTS 2048*4
static vecV_t pscriptverts[BUFFERVERTS];
static avec4_t pscriptcolours[BUFFERVERTS];
static vec2_t pscripttexcoords[BUFFERVERTS];
static index_t pscriptquadindexes[(BUFFERVERTS/4)*6];
static index_t pscripttriindexes[BUFFERVERTS];
static mesh_t pscriptmesh;
static mesh_t pscripttmesh;
static int numparticletypes;
static part_type_t *part_type;
static part_type_t *part_run_list;
static char part_parsenamespace[MAX_QPATH];
static qboolean part_parseweak;
static struct {
char *oldn;
char *newn;
} legacynames[] =
{
{"t_rocket", "TR_ROCKET"},
//{"t_blastertrail", "TR_BLASTERTRAIL"},
{"t_grenade", "TR_GRENADE"},
{"t_gib", "TR_BLOOD"},
{"te_plasma", "TE_TEI_PLASMAHIT"},
{"te_smoke", "TE_TEI_SMOKE"},
{NULL}
};
static part_type_t *P_GetParticleType(char *config, char *name)
{
int i;
part_type_t *ptype;
part_type_t *oldlist = part_type;
char cfgbuf[MAX_QPATH];
char *dot = strchr(name, '.');
if (dot && (dot - name) < MAX_QPATH-1)
{
config = cfgbuf;
memcpy(cfgbuf, name, dot - name);
cfgbuf[dot - name] = 0;
name = dot+1;
}
for (i = 0; legacynames[i].oldn; i++)
{
if (!strcmp(name, legacynames[i].oldn))
{
name = legacynames[i].newn;
break;
}
}
for (i = 0; i < numparticletypes; i++)
{
ptype = &part_type[i];
if (!stricmp(ptype->name, name))
if (!stricmp(ptype->config, config)) //must be an exact match.
return ptype;
}
part_type = BZ_Realloc(part_type, sizeof(part_type_t)*(numparticletypes+1));
ptype = &part_type[numparticletypes++];
memset(ptype, 0, sizeof(*ptype));
Q_strncpyz(ptype->name, name, sizeof(ptype->name));
Q_strncpyz(ptype->config, config, sizeof(ptype->config));
ptype->assoc = P_INVALID;
ptype->inwater = P_INVALID;
ptype->cliptype = P_INVALID;
ptype->emit = P_INVALID;
if (oldlist)
{
if (part_run_list)
part_run_list = (part_type_t*)((char*)part_run_list - (char*)oldlist + (char*)part_type);
for (i = 0; i < numparticletypes; i++)
if (part_type[i].nexttorun)
part_type[i].nexttorun = (part_type_t*)((char*)part_type[i].nexttorun - (char*)oldlist + (char*)part_type);
}
ptype->loaded = 0;
ptype->ramp = NULL;
ptype->particles = NULL;
ptype->beams = NULL;
r_plooksdirty = true;
return ptype;
}
//unconditionally allocates a particle object. this allows out-of-order allocations.
static int P_AllocateParticleType(char *config, char *name) //guarentees that the particle type exists, returning it's index.
{
part_type_t *pt = P_GetParticleType(config, name);
return pt - part_type;
}
//public interface. get without creating.
static int PScript_FindParticleType(char *name)
{
int i;
part_type_t *ptype = NULL;
char cfg[MAX_QPATH];
char *dot;
dot = strchr(name, '.');
if (dot && (dot - name) < MAX_QPATH-1)
{
memcpy(cfg, name, dot - name);
cfg[dot-name] = 0;
name = dot+1;
}
else
*cfg = 0;
for (i = 0; legacynames[i].oldn; i++)
{
if (!strcmp(name, legacynames[i].oldn))
{
name = legacynames[i].newn;
break;
}
}
if (*cfg)
{ //favour the namespace if one is specified
for (i = 0; i < numparticletypes; i++)
{
if (!stricmp(part_type[i].name, name))
{
if (!stricmp(part_type[i].config, cfg))
{
ptype = &part_type[i];
break;
}
}
}
}
else
{
//but be prepared to load it from any namespace if its not got a namespace specified.
for (i = 0; i < numparticletypes; i++)
{
if (!stricmp(part_type[i].name, name))
{
ptype = &part_type[i];
break;
}
}
}
if (!ptype || !ptype->loaded)
{
if (*cfg)
P_LoadParticleSet(cfg, true);
if (fallback)
{
if (!strncmp(name, "classic_", 8))
i = fallback->FindParticleType(name+8);
else
i = fallback->FindParticleType(name);
if (i != P_INVALID)
return i+FALLBACKBIAS;
}
return P_INVALID;
}
return i;
}
static void P_SetModified(void) //called when the particle system changes (from console).
{
if (Cmd_IsInsecure())
return; //server stuffed particle descriptions don't count.
f_modified_particles = true;
if (care_f_modified)
{
care_f_modified = false;
Cbuf_AddText("say particles description has changed\n", RESTRICT_LOCAL);
}
}
static int CheckAssosiation(char *config, char *name, int from)
{
int to, orig;
orig = to = P_AllocateParticleType(config, name);
while(to != P_INVALID)
{
if (to == from)
{
Con_Printf("Assosiation of %s would cause infinate loop\n", name);
return P_INVALID;
}
to = part_type[to].assoc;
}
return orig;
}
static void P_LoadTexture(part_type_t *ptype, qboolean warn)
{
texnums_t tn;
char *defaultshader;
char *namepostfix;
int i;
if (qrenderer == QR_NONE)
return;
for (i = 0; i < ptype->nummodels; i++)
ptype->models[i].model = NULL;
if (*ptype->texname && ptype->looks.blendmode == BM_BLEND)
{
/*try and load the shader, fail if we would need to generate one*/
ptype->looks.shader = R_RegisterCustom(ptype->texname, SUF_NONE, NULL, NULL);
}
else
ptype->looks.shader = NULL;
if (!ptype->looks.shader)
{
/*okay, so no shader, generate a shader that matches the legacy/shaderless mode*/
switch(ptype->looks.blendmode)
{
case BM_BLEND:
default:
namepostfix = "_blend";
defaultshader =
"{\n"
"program defaultsprite\n"
"nomipmaps\n"
"{\n"
"map $diffuse\n"
"blendfunc blend\n"
"rgbgen vertex\n"
"alphagen vertex\n"
"}\n"
"polygonoffset\n"
"}\n"
;
break;
case BM_BLENDCOLOUR:
namepostfix = "_bc";
defaultshader =
"{\n"
"program defaultsprite\n"
"nomipmaps\n"
"{\n"
"map $diffuse\n"
"blendfunc GL_SRC_COLOR GL_ONE_MINUS_SRC_COLOR\n"
"rgbgen vertex\n"
"alphagen vertex\n"
"}\n"
"polygonoffset\n"
"}\n"
;
break;
case BM_ADD:
namepostfix = "_add";
defaultshader =
"{\n"
"program defaultsprite\n"
"nomipmaps\n"
"{\n"
"map $diffuse\n"
"blendfunc GL_SRC_ALPHA GL_ONE\n"
"rgbgen vertex\n"
"alphagen vertex\n"
"}\n"
"polygonoffset\n"
"}\n"
;
break;
case BM_INVMODA:
namepostfix = "_invmoda";
defaultshader =
"{\n"
"program defaultsprite\n"
"nomipmaps\n"
"{\n"
"map $diffuse\n"
"blendfunc GL_ZERO GL_ONE_MINUS_SRC_ALPHA\n"
"rgbgen vertex\n"
"alphagen vertex\n"
"}\n"
"polygonoffset\n"
"}\n"
;
break;
case BM_INVMODC:
namepostfix = "_invmodc";
defaultshader =
"{\n"
"program defaultsprite\n"
"nomipmaps\n"
"{\n"
"map $diffuse\n"
"blendfunc GL_ZERO GL_ONE_MINUS_SRC_COLOR\n"
"rgbgen vertex\n"
"alphagen vertex\n"
"}\n"
"polygonoffset\n"
"}\n"
;
break;
case BM_SUBTRACT:
namepostfix = "_sub";
defaultshader =
"{\n"
"program defaultsprite\n"
"nomipmaps\n"
"{\n"
"map $diffuse\n"
"blendfunc GL_SRC_ALPHA GL_ONE_MINUS_SRC_COLOR\n"
"rgbgen vertex\n"
"alphagen vertex\n"
"}\n"
"polygonoffset\n"
"}\n"
;
break;
}
memset(&tn, 0, sizeof(tn));
tn.base = R_LoadHiResTexture(ptype->texname, "particles", 0);
if (!TEXVALID(tn.base))
{
/*okay, so the texture they specified wasn't valid either. use a fully default one*/
//note that this could get messy if you depend upon vid_restart to reload your effect without re-execing it after.
ptype->s1 = 0;
ptype->t1 = 0;
ptype->s2 = 1;
ptype->t2 = 1;
ptype->randsmax = 1;
if (ptype->looks.type == PT_BEAM)
{
/*untextured beams get a single continuous blob*/
ptype->looks.shader = R_RegisterShader(va("beam%s", namepostfix), SUF_NONE, defaultshader);
TEXASSIGNF(tn.base, beamtexture);
}
else if (ptype->looks.type == PT_SPARKFAN)
{
/*untextured beams get a single continuous blob*/
ptype->looks.shader = R_RegisterShader(va("fan%s", namepostfix), SUF_NONE, defaultshader);
TEXASSIGNF(tn.base, ptritexture);
}
else if (strstr(ptype->texname, "glow") || strstr(ptype->texname, "ball") || ptype->looks.type == PT_TEXTUREDSPARK)
{
/*sparks and special names get a nice circular texture.
as these are fully default, we can basically discard the texture name in the shader, and get better batching*/
ptype->looks.shader = R_RegisterShader(va("ball%s", namepostfix), SUF_NONE, defaultshader);
TEXASSIGNF(tn.base, balltexture);
}
else
{
/*anything else gets a fuzzy texture*/
ptype->looks.shader = R_RegisterShader(va("default%s", namepostfix), SUF_NONE, defaultshader);
TEXASSIGNF(tn.base, explosiontexture);
}
}
else
{
/*texture looks good, make a shader, and give it the texture as a diffuse stage*/
ptype->looks.shader = R_RegisterShader(va("%s%s", ptype->texname, namepostfix), SUF_NONE, defaultshader);
}
R_BuildDefaultTexnums(&tn, ptype->looks.shader);
}
}
static void P_ResetToDefaults(part_type_t *ptype)
{
particle_t *parts;
skytris_t *st;
part_type_t *torun;
char tnamebuf[sizeof(ptype->name)];
// go with a lazy clear of list.. mark everything as DEAD and let
// the beam rendering handle removing nodes
beamseg_t *beamsegs = ptype->beams;
while (beamsegs)
{
beamsegs->flags |= BS_DEAD;
beamsegs = beamsegs->next;
}
// forget any particles before its wiped
while (ptype->particles)
{
parts = ptype->particles->next;
ptype->particles->next = free_particles;
free_particles = ptype->particles;
ptype->particles = parts;
}
// if we're in the runstate loop through and remove from linked list
if (ptype->state & PS_INRUNLIST)
{
if (part_run_list == ptype)
part_run_list = part_run_list->nexttorun;
else
{
for (torun = part_run_list; torun != NULL; torun = torun->nexttorun)
{
if (torun->nexttorun == ptype)
torun->nexttorun = torun->nexttorun->nexttorun;
}
}
}
//some things need to be preserved before we clear everything.
beamsegs = ptype->beams;
st = ptype->skytris;
strcpy(tnamebuf, ptype->name);
//free uneeded info
if (ptype->ramp)
BZ_Free(ptype->ramp);
if (ptype->models)
BZ_Free(ptype->models);
//reset everything we're too lazy to specifically set
memset(ptype, 0, sizeof(*ptype));
//now set any non-0 defaults.
ptype->beams = beamsegs;
ptype->skytris = st;
strcpy(ptype->name, tnamebuf);
ptype->assoc=P_INVALID;
ptype->inwater = P_INVALID;
ptype->cliptype = P_INVALID;
ptype->emit = P_INVALID;
ptype->alpha = 1;
ptype->alphachange = 1;
ptype->clipbounce = 0.8;
ptype->colorindex = -1;
ptype->rotationstartmin = -M_PI; //start with a random angle
ptype->rotationstartrand = M_PI-ptype->rotationstartmin;
ptype->spawnchance = 1;
ptype->dl_time = 5000;
VectorSet(ptype->dl_rgb, 1, 1, 1);
ptype->randsmax = 1;
ptype->s2 = 1;
ptype->t2 = 1;
}
//Uses FTE's multiline console stuff.
//This is the function that loads the effect descriptions (via console).
static void P_ParticleEffect_f(void)
{
char *var, *value;
char *buf;
qboolean settype = false;
qboolean setalphadelta = false;
qboolean setbeamlen = false;
part_type_t *ptype;
int pnum, assoc;
char *config = part_parsenamespace;
if (Cmd_Argc()!=2)
{
if (!strcmp(Cmd_Argv(1), "namespace"))
{
Q_strncpyz(part_parsenamespace, Cmd_Argv(2), sizeof(part_parsenamespace));
if (Cmd_Argc() >= 4)
part_parseweak = atoi(Cmd_Argv(3));
return;
}
Con_Printf("No name for particle effect\n");
return;
}
buf = Cbuf_GetNext(Cmd_ExecLevel, false);
while (*buf && *buf <= ' ')
buf++; //no whitespace please.
if (*buf != '{')
{
Cbuf_InsertText(buf, Cmd_ExecLevel, true);
Con_Printf("This is a multiline command and should be used within config files\n");
return;
}
var = Cmd_Argv(1);
if (*var == '+')
ptype = P_GetParticleType(config, var+1);
else
ptype = P_GetParticleType(config, var);
//'weak' configs do not replace 'strong' configs
if (!pe_script_enabled || (part_parseweak && ptype->loaded))
{
int depth = 1;
while(1)
{
buf = Cbuf_GetNext(Cmd_ExecLevel, false);
if (!*buf)
return;
while (*buf && *buf <= ' ')
buf++; //no whitespace please.
if (*buf == '{')
depth++;
else if (*buf == '}')
{
if (--depth == 0)
break;
}
}
return;
}
if (*var == '+')
{
if (ptype->loaded)
{
int i, parenttype;
char newname[256];
for (i = 0; i < 64; i++)
{
parenttype = ptype - part_type;
snprintf(newname, sizeof(newname), "+%i%s", i, var);
ptype = P_GetParticleType(config, newname);
if (!ptype->loaded)
{
if (part_type[parenttype].assoc != P_INVALID)
Con_Printf("warning: assoc on particle chain %s overridden\n", var+1);
part_type[parenttype].assoc = ptype - part_type;
break;
}
}
if (i == 64)
{
Con_Printf("Too many duplicate names, gave up\n");
return;
}
}
}
else
{
if (ptype->loaded)
{
assoc = ptype->assoc;
while (assoc != P_INVALID && assoc < FALLBACKBIAS)
{
if (*part_type[assoc].name == '+')
{
part_type[assoc].loaded = false;
assoc = part_type[assoc].assoc;
}
else
break;
}
}
}
if (!ptype)
{
Con_Printf("Bad name\n");
return;
}
P_SetModified();
pnum = ptype-part_type;
P_ResetToDefaults(ptype);
while(1)
{
buf = Cbuf_GetNext(Cmd_ExecLevel, false);
if (!*buf)
{
Con_Printf("Unexpected end of buffer with effect %s\n", ptype->name);
return;
}
while (*buf && *buf <= ' ')
buf++; //no whitespace please.
if (*buf == '}')
break;
Cmd_TokenizeString(buf, true, true);
var = Cmd_Argv(0);
value = Cmd_Argv(1);
// TODO: switch this mess to some sort of binary tree to increase
// parse speed
if (!strcmp(var, "shader"))
{
Q_strncpyz(ptype->texname, ptype->name, sizeof(ptype->texname));
buf = Cbuf_GetNext(Cmd_ExecLevel, true);
while (*buf && *buf <= ' ')
buf++; //no leading whitespace please.
if (*buf == '{')
{
int nest = 1;
char *str = BZ_Malloc(3);
int slen = 2;
str[0] = '{';
str[1] = '\n';
str[2] = 0;
while(nest)
{
buf = Cbuf_GetNext(Cmd_ExecLevel, true);
if (!*buf)
{
Con_Printf("Unexpected end of buffer with effect %s\n", ptype->name);
break;
}
while (*buf && *buf <= ' ')
buf++; //no leading whitespace please.
if (*buf == '}')
--nest;
if (*buf == '{')
nest++;
str = BZ_Realloc(str, slen + strlen(buf) + 2);
strcpy(str + slen, buf);
slen += strlen(str + slen);
str[slen++] = '\n';
}
str[slen] = 0;
R_RegisterShader(ptype->texname, SUF_NONE, str);
BZ_Free(str);
}
else
Cbuf_InsertText(buf, Cmd_ExecLevel, true);
}
else if (!strcmp(var, "texture"))
Q_strncpyz(ptype->texname, value, sizeof(ptype->texname));
else if (!strcmp(var, "tcoords"))
{
float tscale;
tscale = atof(Cmd_Argv(5));
if (tscale < 0)
tscale = 1;
ptype->s1 = atof(value)/tscale;
ptype->t1 = atof(Cmd_Argv(2))/tscale;
ptype->s2 = atof(Cmd_Argv(3))/tscale;
ptype->t2 = atof(Cmd_Argv(4))/tscale;
ptype->randsmax = atoi(Cmd_Argv(6));
ptype->texsstride = atof(Cmd_Argv(7));
if (ptype->randsmax < 1 || ptype->texsstride == 0)
ptype->randsmax = 1;
}
else if (!strcmp(var, "rotationstart"))
{
ptype->rotationstartmin = atof(value)*M_PI/180;
if (Cmd_Argc()>2)
ptype->rotationstartrand = atof(Cmd_Argv(2))*M_PI/180-ptype->rotationstartmin;
else
ptype->rotationstartrand = 0;
}
else if (!strcmp(var, "rotationspeed"))
{
ptype->rotationmin = atof(value)*M_PI/180;
if (Cmd_Argc()>2)
ptype->rotationrand = atof(Cmd_Argv(2))*M_PI/180-ptype->rotationmin;
else
ptype->rotationrand = 0;
}
else if (!strcmp(var, "beamtexstep"))
{
ptype->rotationstartmin = 1/atof(value);
ptype->rotationstartrand = 0;
setbeamlen = true;
}
else if (!strcmp(var, "beamtexspeed"))
{
ptype->rotationmin = atof(value);
}
else if (!strcmp(var, "scale"))
{
ptype->scale = atof(value);
if (Cmd_Argc()>2)
ptype->scalerand = atof(Cmd_Argv(2)) - ptype->scale;
}
else if (!strcmp(var, "scalerand"))
ptype->scalerand = atof(value);
else if (!strcmp(var, "scalefactor"))
ptype->looks.scalefactor = atof(value);
else if (!strcmp(var, "scaledelta"))
ptype->scaledelta = atof(value);
else if (!strcmp(var, "step"))
{
ptype->count = 1/atof(value);
if (Cmd_Argc()>2)
ptype->countrand = 1/atof(Cmd_Argv(2));
}
else if (!strcmp(var, "count"))
{
ptype->count = atof(value);
if (Cmd_Argc()>2)
ptype->countrand = atof(Cmd_Argv(2));
if (Cmd_Argc()>3)
ptype->countextra = atof(Cmd_Argv(3));
}
else if (!strcmp(var, "alpha"))
ptype->alpha = atof(value);
else if (!strcmp(var, "alphachange"))
{
Con_DPrintf("alphachange is deprechiated, use alphadelta\n");
ptype->alphachange = atof(value);
}
else if (!strcmp(var, "alphadelta"))
{
ptype->alphachange = atof(value);
setalphadelta = true;
}
else if (!strcmp(var, "die"))
{
ptype->die = atof(value);
if (Cmd_Argc()>2)
ptype->randdie = atof(Cmd_Argv(2)) - ptype->die;
}
else if (!strcmp(var, "diesubrand"))
ptype->randdie = atof(value);
else if (!strcmp(var, "randomvel"))
{
ptype->randomvel = atof(value);
if (Cmd_Argc()>3)
{
ptype->randomvelvertbias = atof(Cmd_Argv(2));
ptype->randomvelvert = atof(Cmd_Argv(3));
ptype->randomvelvert -= ptype->randomvelvertbias; /*make vert be the total range*/
ptype->randomvelvert /= 2; /*vert is actually +/- 1, not 0 to 1, so rescale it*/
ptype->randomvelvertbias += ptype->randomvelvert; /*and bias must be centered to the range*/
}
else if (Cmd_Argc()>2)
{
ptype->randomvelvert = atof(Cmd_Argv(2));
ptype->randomvelvertbias = 0;
}
else
{
ptype->randomvelvert = ptype->randomvel;
ptype->randomvelvertbias = 0;
}
}
else if (!strcmp(var, "veladd"))
ptype->veladd = atof(value);
else if (!strcmp(var, "orgadd"))
ptype->orgadd = atof(value);
else if (!strcmp(var, "friction"))
{
ptype->friction[2] = ptype->friction[1] = ptype->friction[0] = atof(value);
if (Cmd_Argc()>3)
{
ptype->friction[2] = atof(Cmd_Argv(3));
ptype->friction[1] = atof(Cmd_Argv(2));
}
else if (Cmd_Argc()>2)
{
ptype->friction[2] = atof(Cmd_Argv(2));
}
}
else if (!strcmp(var, "gravity"))
ptype->gravity = atof(value);
else if (!strcmp(var, "clipbounce"))
ptype->clipbounce = atof(value);
else if (!strcmp(var, "assoc"))
{
assoc = CheckAssosiation(config, value, pnum); //careful - this can realloc all the particle types
ptype = &part_type[pnum];
ptype->assoc = assoc;
}
else if (!strcmp(var, "inwater"))
{
// the underwater effect switch should only occur for
// 1 level so the standard assoc check works
assoc = CheckAssosiation(config, value, pnum);
ptype = &part_type[pnum];
ptype->inwater = assoc;
}
else if (!strcmp(var, "model"))
{
ptype->models = BZ_Realloc(ptype->models, sizeof(partmodels_t)*(ptype->nummodels+1));
Q_strncpyz(ptype->models[ptype->nummodels].name, Cmd_Argv(1), sizeof(ptype->models[ptype->nummodels].name));
ptype->models[ptype->nummodels].framestart = atof(Cmd_Argv(2));
ptype->models[ptype->nummodels].frameend = atof(Cmd_Argv(3));
ptype->models[ptype->nummodels].framerate = atof(Cmd_Argv(4));
ptype->models[ptype->nummodels].alpha = atof(Cmd_Argv(5));
ptype->nummodels++;
}
else if (!strcmp(var, "colorindex"))
{
if (Cmd_Argc()>2)
ptype->colorrand = atof(Cmd_Argv(2));
ptype->colorindex = atoi(value);
}
else if (!strcmp(var, "colorrand"))
ptype->colorrand = atoi(value); // now obsolete
else if (!strcmp(var, "citracer"))
ptype->flags |= PT_CITRACER;
else if (!strcmp(var, "red"))
ptype->rgb[0] = atof(value)/255;
else if (!strcmp(var, "green"))
ptype->rgb[1] = atof(value)/255;
else if (!strcmp(var, "blue"))
ptype->rgb[2] = atof(value)/255;
else if (!strcmp(var, "rgb"))
{
ptype->rgb[0] = ptype->rgb[1] = ptype->rgb[2] = atof(value)/255;
if (Cmd_Argc()>3)
{
ptype->rgb[1] = atof(Cmd_Argv(2))/255;
ptype->rgb[2] = atof(Cmd_Argv(3))/255;
}
}
else if (!strcmp(var, "reddelta"))
{
ptype->rgbchange[0] = atof(value)/255;
if (!ptype->rgbchangetime)
ptype->rgbchangetime = ptype->die;
}
else if (!strcmp(var, "greendelta"))
{
ptype->rgbchange[1] = atof(value)/255;
if (!ptype->rgbchangetime)
ptype->rgbchangetime = ptype->die;
}
else if (!strcmp(var, "bluedelta"))
{
ptype->rgbchange[2] = atof(value)/255;
if (!ptype->rgbchangetime)
ptype->rgbchangetime = ptype->die;
}
else if (!strcmp(var, "rgbdelta"))
{
ptype->rgbchange[0] = ptype->rgbchange[1] = ptype->rgbchange[2] = atof(value)/255;
if (Cmd_Argc()>3)
{
ptype->rgbchange[1] = atof(Cmd_Argv(2))/255;
ptype->rgbchange[2] = atof(Cmd_Argv(3))/255;
}
if (!ptype->rgbchangetime)
ptype->rgbchangetime = ptype->die;
}
else if (!strcmp(var, "rgbdeltatime"))
ptype->rgbchangetime = atof(value);
else if (!strcmp(var, "redrand"))
ptype->rgbrand[0] = atof(value)/255;
else if (!strcmp(var, "greenrand"))
ptype->rgbrand[1] = atof(value)/255;
else if (!strcmp(var, "bluerand"))
ptype->rgbrand[2] = atof(value)/255;
else if (!strcmp(var, "rgbrand"))
{
ptype->rgbrand[0] = ptype->rgbrand[1] = ptype->rgbrand[2] = atof(value)/255;
if (Cmd_Argc()>3)
{
ptype->rgbrand[1] = atof(Cmd_Argv(2))/255;
ptype->rgbrand[2] = atof(Cmd_Argv(3))/255;
}
}
else if (!strcmp(var, "rgbrandsync"))
{
ptype->rgbrandsync[0] = ptype->rgbrandsync[1] = ptype->rgbrandsync[2] = atof(value);
if (Cmd_Argc()>3)
{
ptype->rgbrandsync[1] = atof(Cmd_Argv(2));
ptype->rgbrandsync[2] = atof(Cmd_Argv(3));
}
}
else if (!strcmp(var, "redrandsync"))
ptype->rgbrandsync[0] = atof(value);
else if (!strcmp(var, "greenrandsync"))
ptype->rgbrandsync[1] = atof(value);
else if (!strcmp(var, "bluerandsync"))
ptype->rgbrandsync[2] = atof(value);
else if (!strcmp(var, "stains"))
ptype->stainonimpact = atof(value);
else if (!strcmp(var, "blend"))
{
if (!strcmp(value, "add"))
ptype->looks.blendmode = BM_ADD;
else if (!strcmp(value, "subtract"))
ptype->looks.blendmode = BM_SUBTRACT;
else if (!strcmp(value, "invmoda") || !strcmp(value, "invmod"))
ptype->looks.blendmode = BM_INVMODA;
else if (!strcmp(value, "invmodc"))
ptype->looks.blendmode = BM_INVMODC;
else if (!strcmp(value, "blendcolour") || !strcmp(value, "blendcolor"))
ptype->looks.blendmode = BM_BLENDCOLOUR;
else
ptype->looks.blendmode = BM_BLEND;
}
else if (!strcmp(var, "spawnmode"))
{
if (!strcmp(value, "circle"))
ptype->spawnmode = SM_CIRCLE;
else if (!strcmp(value, "ball"))
ptype->spawnmode = SM_BALL;
else if (!strcmp(value, "spiral"))
ptype->spawnmode = SM_SPIRAL;
else if (!strcmp(value, "tracer"))
ptype->spawnmode = SM_TRACER;
else if (!strcmp(value, "telebox"))
ptype->spawnmode = SM_TELEBOX;
else if (!strcmp(value, "lavasplash"))
ptype->spawnmode = SM_LAVASPLASH;
else if (!strcmp(value, "uniformcircle"))
ptype->spawnmode = SM_UNICIRCLE;
else if (!strcmp(value, "syncfield"))
ptype->spawnmode = SM_FIELD;
else if (!strcmp(value, "distball"))
ptype->spawnmode = SM_DISTBALL;
else
ptype->spawnmode = SM_BOX;
if (Cmd_Argc()>2)
{
if (Cmd_Argc()>3)
ptype->spawnparam2 = atof(Cmd_Argv(3));
ptype->spawnparam1 = atof(Cmd_Argv(2));
}
}
else if (!strcmp(var, "type"))
{
if (!strcmp(value, "beam"))
ptype->looks.type = PT_BEAM;
else if (!strcmp(value, "spark"))
ptype->looks.type = PT_SPARK;
else if (!strcmp(value, "sparkfan") || !strcmp(value, "trianglefan"))
ptype->looks.type = PT_SPARKFAN;
else if (!strcmp(value, "texturedspark"))
ptype->looks.type = PT_TEXTUREDSPARK;
else if (!strcmp(value, "decal") || !strcmp(value, "cdecal"))
ptype->looks.type = PT_CDECAL;
else if (!strcmp(value, "udecal"))
ptype->looks.type = PT_UDECAL;
else
ptype->looks.type = PT_NORMAL;
settype = true;
}
else if (!strcmp(var, "isbeam"))
{
Con_DPrintf("isbeam is deprechiated, use type beam\n");
ptype->looks.type = PT_BEAM;
}
else if (!strcmp(var, "spawntime"))
ptype->spawntime = atof(value);
else if (!strcmp(var, "spawnchance"))
ptype->spawnchance = atof(value);
else if (!strcmp(var, "cliptype"))
{
assoc = P_AllocateParticleType(config, value);//careful - this can realloc all the particle types
ptype = &part_type[pnum];
ptype->cliptype = assoc;
}
else if (!strcmp(var, "clipcount"))
ptype->clipcount = atof(value);
else if (!strcmp(var, "emit"))
{
assoc = P_AllocateParticleType(config, value);//careful - this can realloc all the particle types
ptype = &part_type[pnum];
ptype->emit = assoc;
}
else if (!strcmp(var, "emitinterval"))
ptype->emittime = atof(value);
else if (!strcmp(var, "emitintervalrand"))
ptype->emitrand = atof(value);
else if (!strcmp(var, "emitstart"))
ptype->emitstart = atof(value);
// old names
else if (!strcmp(var, "areaspread"))
{
Con_DPrintf("areaspread is deprechiated, use spawnorg\n");
ptype->areaspread = atof(value);
}
else if (!strcmp(var, "areaspreadvert"))
{
Con_DPrintf("areaspreadvert is deprechiated, use spawnorg\n");
ptype->areaspreadvert = atof(value);
}
else if (!strcmp(var, "offsetspread"))
{
Con_DPrintf("offsetspread is deprechiated, use spawnvel\n");
ptype->spawnvel = atof(value);
}
else if (!strcmp(var, "offsetspreadvert"))
{
Con_DPrintf("offsetspreadvert is deprechiated, use spawnvel\n");
ptype->spawnvelvert = atof(value);
}
// current names
else if (!strcmp(var, "spawnorg"))
{
ptype->areaspreadvert = ptype->areaspread = atof(value);
if (Cmd_Argc()>2)
ptype->areaspreadvert = atof(Cmd_Argv(2));
}
else if (!strcmp(var, "spawnvel"))
{
ptype->spawnvelvert = ptype->spawnvel = atof(value);
if (Cmd_Argc()>2)
ptype->spawnvelvert = atof(Cmd_Argv(2));
}
// spawn mode param fields
else if (!strcmp(var, "spawnparam1"))
ptype->spawnparam1 = atof(value);
else if (!strcmp(var, "spawnparam2"))
ptype->spawnparam2 = atof(value);
/* else if (!strcmp(var, "spawnparam3"))
ptype->spawnparam3 = atof(value); */
else if (!strcmp(var, "up"))
ptype->offsetup = atof(value);
else if (!strcmp(var, "rampmode"))
{
if (!strcmp(value, "none"))
ptype->rampmode = RAMP_NONE;
else if (!strcmp(value, "absolute"))
{
Con_DPrintf("'rampmode absolute' is deprechiated, use 'rampmode nearest'\n");
ptype->rampmode = RAMP_NEAREST;
}
else if (!strcmp(value, "nearest"))
ptype->rampmode = RAMP_NEAREST;
else if (!strcmp(value, "lerp")) //don't use the name 'linear'. ramps are there to avoid linear...
ptype->rampmode = RAMP_LERP;
else //if (!strcmp(value, "delta"))
ptype->rampmode = RAMP_DELTA;
}
else if (!strcmp(var, "rampindexlist"))
{ // better not use this with delta ramps...
int cidx, i;
i = 1;
while (i < Cmd_Argc())
{
ptype->ramp = BZ_Realloc(ptype->ramp, sizeof(ramp_t)*(ptype->rampindexes+1));
cidx = atoi(Cmd_Argv(i));
ptype->ramp[ptype->rampindexes].alpha = cidx > 255 ? 0.5 : 1;
cidx = (cidx & 0xff) * 3;
ptype->ramp[ptype->rampindexes].rgb[0] = host_basepal[cidx] * (1/255.0);
ptype->ramp[ptype->rampindexes].rgb[1] = host_basepal[cidx+1] * (1/255.0);
ptype->ramp[ptype->rampindexes].rgb[2] = host_basepal[cidx+2] * (1/255.0);
ptype->ramp[ptype->rampindexes].scale = ptype->scale;
ptype->rampindexes++;
i++;
}
}
else if (!strcmp(var, "rampindex"))
{
int cidx;
ptype->ramp = BZ_Realloc(ptype->ramp, sizeof(ramp_t)*(ptype->rampindexes+1));
cidx = atoi(value);
ptype->ramp[ptype->rampindexes].alpha = cidx > 255 ? 0.5 : 1;
if (Cmd_Argc() > 2) // they gave alpha
ptype->ramp[ptype->rampindexes].alpha *= atof(Cmd_Argv(2));
cidx = (cidx & 0xff) * 3;
ptype->ramp[ptype->rampindexes].rgb[0] = host_basepal[cidx] * (1/255.0);
ptype->ramp[ptype->rampindexes].rgb[1] = host_basepal[cidx+1] * (1/255.0);
ptype->ramp[ptype->rampindexes].rgb[2] = host_basepal[cidx+2] * (1/255.0);
if (Cmd_Argc() > 3) // they gave scale
ptype->ramp[ptype->rampindexes].scale = atof(Cmd_Argv(3));
else
ptype->ramp[ptype->rampindexes].scale = ptype->scale;
ptype->rampindexes++;
}
else if (!strcmp(var, "ramp"))
{
ptype->ramp = BZ_Realloc(ptype->ramp, sizeof(ramp_t)*(ptype->rampindexes+1));
ptype->ramp[ptype->rampindexes].rgb[0] = atof(value)/255;
if (Cmd_Argc()>3) //seperate rgb
{
ptype->ramp[ptype->rampindexes].rgb[1] = atof(Cmd_Argv(2))/255;
ptype->ramp[ptype->rampindexes].rgb[2] = atof(Cmd_Argv(3))/255;
if (Cmd_Argc()>4) //have we alpha and scale changes?
{
ptype->ramp[ptype->rampindexes].alpha = atof(Cmd_Argv(4));
if (Cmd_Argc()>5) //have we scale changes?
ptype->ramp[ptype->rampindexes].scale = atof(Cmd_Argv(5));
else
ptype->ramp[ptype->rampindexes].scale = ptype->scaledelta;
}
else
{
ptype->ramp[ptype->rampindexes].alpha = ptype->alpha;
ptype->ramp[ptype->rampindexes].scale = ptype->scaledelta;
}
}
else //they only gave one value
{
ptype->ramp[ptype->rampindexes].rgb[1] = ptype->ramp[ptype->rampindexes].rgb[0];
ptype->ramp[ptype->rampindexes].rgb[2] = ptype->ramp[ptype->rampindexes].rgb[0];
ptype->ramp[ptype->rampindexes].alpha = ptype->alpha;
ptype->ramp[ptype->rampindexes].scale = ptype->scaledelta;
}
ptype->rampindexes++;
}
else if (!strcmp(var, "perframe"))
ptype->flags |= PT_INVFRAMETIME;
else if (!strcmp(var, "averageout"))
ptype->flags |= PT_AVERAGETRAIL;
else if (!strcmp(var, "nostate"))
ptype->flags |= PT_NOSTATE;
else if (!strcmp(var, "nospreadfirst"))
ptype->flags |= PT_NOSPREADFIRST;
else if (!strcmp(var, "nospreadlast"))
ptype->flags |= PT_NOSPREADLAST;
else if (!strcmp(var, "sound"))
{
Q_strncpyz(ptype->soundname, value, sizeof(ptype->soundname));
ptype->soundvol = atof(Cmd_Argv(2));
if (!ptype->soundvol)
ptype->soundvol = 1;
ptype->soundattn = atof(Cmd_Argv(3));
if (!ptype->soundattn)
ptype->soundattn = 1;
ptype->soundpitch = atof(Cmd_Argv(4));
if (!ptype->soundpitch)
ptype->soundpitch = 100;
ptype->sounddelay = atof(Cmd_Argv(5));
if (!ptype->sounddelay)
ptype->sounddelay = 0;
}
else if (!strcmp(var, "lightradius"))
ptype->dl_radius = atof(value);
else if (!strcmp(var, "lightradiusfade"))
ptype->dl_decay[3] = atof(value);
else if (!strcmp(var, "lightrgb"))
{
ptype->dl_rgb[0] = atof(value);
ptype->dl_rgb[1] = atof(Cmd_Argv(2));
ptype->dl_rgb[2] = atof(Cmd_Argv(3));
}
else if (!strcmp(var, "lightrgbfade"))
{
ptype->dl_decay[0] = atof(value);
ptype->dl_decay[1] = atof(Cmd_Argv(2));
ptype->dl_decay[2] = atof(Cmd_Argv(3));
}
else if (!strcmp(var, "lighttime"))
ptype->dl_time = atof(value);
else if (!strcmp(var, "lightcubemap"))
ptype->dl_cubemapnum = atoi(value);
else if (!strcmp(var, "spawnstain"))
{
ptype->stain_radius = atof(value);
ptype->stain_rgb[0] = atof(Cmd_Argv(2));
ptype->stain_rgb[1] = atof(Cmd_Argv(3));
ptype->stain_rgb[2] = atof(Cmd_Argv(4));
}
else
Con_DPrintf("%s is not a recognised particle type field (in %s)\n", var, ptype->name);
}
ptype->looks.invscalefactor = 1-ptype->looks.scalefactor;
ptype->loaded = part_parseweak?1:2;
if (ptype->clipcount < 1)
ptype->clipcount = 1;
//if there is a chance that it moves
if (ptype->randomvel || ptype->gravity || ptype->veladd || ptype->spawnvel || ptype->spawnvelvert)
ptype->flags |= PT_VELOCITY;
//if it has friction
if (ptype->friction[0] || ptype->friction[1] || ptype->friction[2])
ptype->flags |= PT_FRICTION;
if (!settype)
{
if (ptype->looks.type == PT_NORMAL && !*ptype->texname)
{
if (ptype->scale)
{
ptype->looks.type = PT_SPARKFAN;
Con_DPrintf("effect %s lacks a texture. assuming type sparkfan.\n", ptype->name);
}
else
{
ptype->looks.type = PT_SPARK;
Con_DPrintf("effect %s lacks a texture. assuming type spark.\n", ptype->name);
}
}
else if (ptype->looks.type == PT_SPARK)
{
if (*ptype->texname)
ptype->looks.type = PT_TEXTUREDSPARK;
else if (ptype->scale)
ptype->looks.type = PT_SPARKFAN;
}
}
if (ptype->looks.type == PT_BEAM && !setbeamlen)
ptype->rotationstartmin = 1/128.0;
// use old behavior if not using alphadelta
if (!setalphadelta)
ptype->alphachange = (-ptype->alphachange / ptype->die) * ptype->alpha;
if (ptype->rampmode && !ptype->ramp)
{
ptype->rampmode = RAMP_NONE;
Con_Printf("Particle type %s has a ramp mode but no ramp\n", ptype->name);
}
else if (ptype->ramp && !ptype->rampmode)
{
Con_Printf("Particle type %s has a ramp but no ramp mode\n", ptype->name);
}
P_LoadTexture(ptype, true);
r_plooksdirty = true;
}
qboolean PScript_Query(int typenum, int body, char *outstr, int outstrlen)
{
int i;
part_type_t *ptype = &part_type[typenum];
if (typenum < 0 || typenum >= numparticletypes)
return false;
if (body == 0)
{
Q_strncpyz(outstr, ptype->name, outstrlen);
return true;
}
if (body == 1)
{
*outstr = 0;
if (!ptype->loaded)
return true;
Q_strncatz(outstr, va("//this functionality is incomplete\n"), outstrlen);
for (i = 0; i < ptype->nummodels; i++)
{
Q_strncatz(outstr, va("model %s %g %g %g %g\n", ptype->models[i].name, ptype->models[i].framestart, ptype->models[i].frameend, ptype->models[i].framerate, ptype->models[i].alpha), outstrlen);
}
if (*ptype->texname)
Q_strncatz(outstr, va("texture %s\n", ptype->texname), outstrlen);
if (ptype->count)
Q_strncatz(outstr, va("count %g\n", ptype->count), outstrlen);
if (ptype->rgb[0] || ptype->rgb[1] || ptype->rgb[2])
Q_strncatz(outstr, va("rgb %g %g %g\n", ptype->rgb[0]*255, ptype->rgb[1]*255, ptype->rgb[2]*255), outstrlen);
if (ptype->rgbrand[0] || ptype->rgbrand[1] || ptype->rgbrand[2])
Q_strncatz(outstr, va("rgbrand %g %g %g\n", ptype->rgbrand[0]*255, ptype->rgbrand[1]*255, ptype->rgbrand[2]*255), outstrlen);
if (ptype->rgbrandsync[0] || ptype->rgbrandsync[1] || ptype->rgbrandsync[2])
Q_strncatz(outstr, va("rgbrandsync %g %g %g\n", ptype->rgbrandsync[0], ptype->rgbrandsync[1], ptype->rgbrandsync[2]), outstrlen);
if (ptype->rgbchange[0] || ptype->rgbchange[1] || ptype->rgbchange[2])
Q_strncatz(outstr, va("rgbchange %g %g %g\n", ptype->rgbchange[0]*255, ptype->rgbchange[1]*255, ptype->rgbchange[2]*255), outstrlen);
if (ptype->rgbchangetime)
Q_strncatz(outstr, va("rgbchangetime %g\n", ptype->rgbchangetime), outstrlen);
if (ptype->colorindex)
Q_strncatz(outstr, va("colorindex %i\n", ptype->colorindex), outstrlen);
if (ptype->colorrand)
Q_strncatz(outstr, va("colorrand %i\n", ptype->colorrand), outstrlen);
if (ptype->alpha)
Q_strncatz(outstr, va("alpha %g\n", ptype->alpha), outstrlen);
if (ptype->alpharand)
Q_strncatz(outstr, va("alpharand %g\n", ptype->alpharand), outstrlen);
if (ptype->alphachange)
Q_strncatz(outstr, va("alphadelta %g\n", ptype->alphachange), outstrlen);
if (ptype->scale || ptype->scalerand)
Q_strncatz(outstr, va("scale %g %g\n", ptype->scale, ptype->scale+ptype->scalerand), outstrlen);
// if (ptype->looks.scalefactor)
Q_strncatz(outstr, va("scalefactor %g\n", ptype->looks.scalefactor), outstrlen);
if (ptype->scaledelta)
Q_strncatz(outstr, va("scaledelta %g\n", ptype->scaledelta), outstrlen);
if (ptype->die || ptype->randdie)
Q_strncatz(outstr, va("die %g %g\n", ptype->die, ptype->die+ptype->randdie), outstrlen);
if (ptype->randomvel || ptype->randomvelvert || ptype->randomvelvertbias)
Q_strncatz(outstr, va("randomvel %g %g %g\n", ptype->randomvel, ptype->randomvelvertbias - ptype->randomvelvert, ptype->randomvelvertbias + ptype->randomvelvert), outstrlen);
if (ptype->veladd)
Q_strncatz(outstr, va("veladd %g\n", ptype->veladd), outstrlen);
if (ptype->orgadd)
Q_strncatz(outstr, va("orgadd %g\n", ptype->orgadd), outstrlen);
if (ptype->spawnvel || ptype->spawnvelvert)
Q_strncatz(outstr, va("spawnvel %g %g\n", ptype->spawnvel, ptype->spawnvelvert), outstrlen);
if (ptype->assoc != P_INVALID)
Q_strncatz(outstr, va("assoc \"%s\"\n", part_type[ptype->assoc].name), outstrlen);
Q_strncatz(outstr, va("tcoords %g %g %g %g %g %i %g\n", ptype->s1, ptype->t1, ptype->s2, ptype->t2, 1.0f, ptype->randsmax, ptype->texsstride), outstrlen);
Q_strncatz(outstr, va("rotationstart %g %g\n", ptype->rotationstartmin*180/M_PI, (ptype->rotationstartmin+ptype->rotationstartrand)*180/M_PI), outstrlen);
Q_strncatz(outstr, va("rotationspeed %g %g\n", ptype->rotationmin*180/M_PI, (ptype->rotationmin+ptype->rotationrand)*180/M_PI), outstrlen);
if (ptype->soundvol)
Q_strncatz(outstr, va("sound \"%s\" %g %g %g %g\n", ptype->soundname, ptype->soundvol, ptype->soundattn, ptype->soundpitch, ptype->sounddelay), outstrlen);
if (ptype->dl_radius)
{
Q_strncatz(outstr, va("lightradius %g\n", ptype->dl_radius), outstrlen);
Q_strncatz(outstr, va("lightradiusfade %g\n", ptype->dl_decay[3]), outstrlen);
Q_strncatz(outstr, va("lightrgb %g %g %g\n", ptype->dl_rgb[0], ptype->dl_rgb[1], ptype->dl_rgb[2]), outstrlen);
Q_strncatz(outstr, va("lightrgbfade %g %g %g\n", ptype->dl_decay[0], ptype->dl_decay[1], ptype->dl_decay[2]), outstrlen);
Q_strncatz(outstr, va("lighttime %g\n", ptype->dl_time), outstrlen);
Q_strncatz(outstr, va("lightshadows %g\n", (ptype->flags & PT_NODLSHADOW)?0.0f:1.0f), outstrlen);
Q_strncatz(outstr, va("lightcubemap %i\n", ptype->dl_cubemapnum), outstrlen);
}
if (ptype->stain_radius)
Q_strncatz(outstr, va("spawnstain %g %g %g %g\n", ptype->stain_radius, ptype->stain_rgb[0], ptype->stain_rgb[1], ptype->stain_rgb[2]), outstrlen);
return true;
#if 0
plooks_t *slooks; //shared looks, so state switches don't apply between particles so much
plooks_t looks;
float spawntime; //time limit for trails
float spawnchance; //if < 0, particles might not spawn so many
float scaledelta;
int countextra;
float count;
float countrand;
int cliptype;
int inwater;
float clipcount;
int emit;
float emittime;
float emitrand;
float emitstart;
float areaspread;
float areaspreadvert;
float spawnparam1;
float spawnparam2;
/* float spawnparam3; */
float offsetup; // make this into a vec3_t later with dir, possibly for mdls
enum {
SM_BOX, //box = even spread within the area
SM_CIRCLE, //circle = around edge of a circle
SM_BALL, //ball = filled sphere
SM_SPIRAL, //spiral = spiral trail
SM_TRACER, //tracer = tracer trail
SM_TELEBOX, //telebox = q1-style telebox
SM_LAVASPLASH, //lavasplash = q1-style lavasplash
SM_UNICIRCLE, //unicircle = uniform circle
SM_FIELD, //field = synced field (brightfield, etc)
SM_DISTBALL // uneven distributed ball
} spawnmode;
float gravity;
vec3_t friction;
float clipbounce;
int stainonimpact;
vec3_t stain_rgb;
float stain_radius;
enum {RAMP_NONE, RAMP_DELTA, RAMP_ABSOLUTE} rampmode;
int rampindexes;
ramp_t *ramp;
int loaded;
particle_t *particles;
clippeddecal_t *clippeddecals;
beamseg_t *beams;
skytris_t *skytris;
struct part_type_s *nexttorun;
unsigned int flags;
#define PT_CITRACER 0x008 // Q1-style tracer behavior for colorindex
#define PT_INVFRAMETIME 0x010 // apply inverse frametime to count (causes emits to be per frame)
#define PT_AVERAGETRAIL 0x020 // average trail points from start to end, useful with t_lightning, etc
#define PT_NOSTATE 0x040 // don't use trailstate for this emitter (careful with assoc...)
#define PT_NOSPREADFIRST 0x080 // don't randomize org/vel for first generated particle
#define PT_NOSPREADLAST 0x100 // don't randomize org/vel for last generated particle
#endif
}
return false;
}
static void P_ExportAllEffects_f(void)
{
char effect[8192];
int i;
vfsfile_t *outf;
char fname[64] = "particles/export.cfg";
FS_CreatePath("particles/", FS_GAMEONLY);
outf = FS_OpenVFS(fname, "wb", FS_GAMEONLY);
if (!outf)
{
FS_NativePath(fname, FS_GAMEONLY, effect, sizeof(effect));
Con_Printf("Unable to open file %s\n", effect);
return;
}
for (i = 0; i < numparticletypes; i++)
{
PScript_Query(i, 0, effect, sizeof(effect));
VFS_PUTS(outf, "r_part ");
VFS_PUTS(outf, effect);
VFS_PUTS(outf, "\n{\n");
PScript_Query(i, 1, effect, sizeof(effect));
VFS_PUTS(outf, effect);
VFS_PUTS(outf, "}\n");
}
VFS_CLOSE(outf);
FS_NativePath(fname, FS_GAMEONLY, effect, sizeof(effect));
Con_Printf("Written %s\n", effect);
}
#if _DEBUG
// R_BeamInfo_f - debug junk
static void P_BeamInfo_f (void)
{
beamseg_t *bs;
int i, j, k, l, m;
i = 0;
for (bs = free_beams; bs; bs = bs->next)
i++;
Con_Printf("%i free beams\n", i);
for (i = 0; i < numparticletypes; i++)
{
m = l = k = j = 0;
for (bs = part_type[i].beams; bs; bs = bs->next)
{
if (!bs->p)
k++;
if (bs->flags & BS_DEAD)
l++;
if (bs->flags & BS_LASTSEG)
m++;
j++;
}
if (j)
Con_Printf("Type %i = %i NULL p, %i DEAD, %i LASTSEG, %i total\n", i, k, l, m, j);
}
}
static void P_PartInfo_f (void)
{
particle_t *p;
part_type_t *ptype;
int i, j;
i = 0;
for (p = free_particles; p; p = p->next)
i++;
Con_Printf("%i free particles\n", i);
for (i = 0; i < numparticletypes; i++)
{
j = 0;
for (p = part_type[i].particles; p; p = p->next)
j++;
if (j)
{
Con_Printf("Type %s = %i total\n", part_type[i].name, j);
if (!(part_type[i].state & PS_INRUNLIST))
Con_Printf(" NOT RUNNING\n");
}
}
Con_Printf("Running effects:\n");
// maintain run list
for (ptype = part_run_list; ptype; ptype = ptype->nexttorun)
{
j = 0;
for (p = ptype->particles; p; p = p->next)
j++;
Con_Printf("Type %s = %i total\n", ptype->name, j);
}
Con_Printf("End of list\n");
}
#endif
void FinishParticleType(part_type_t *ptype)
{
//if there is a chance that it moves
if (ptype->randomvel || ptype->gravity || ptype->veladd || ptype->spawnvel || ptype->spawnvelvert)
ptype->flags |= PT_VELOCITY;
//if it has friction
if (ptype->friction[0] || ptype->friction[1] || ptype->friction[2])
ptype->flags |= PT_FRICTION;
P_LoadTexture(ptype, true);
if (ptype->die == 9999)
{
if (ptype->alphachange)
ptype->die = (ptype->alpha+ptype->alpharand)/-ptype->alphachange;
else
ptype->die = 15;
}
if (ptype->looks.scalefactor > 1 && !ptype->looks.invscalefactor)
{
ptype->scale *= ptype->looks.scalefactor;
ptype->scalerand *= ptype->looks.scalefactor;
/*too lazy to go through ramps*/
ptype->looks.scalefactor = 1;
}
if (ptype->looks.type == PT_TEXTUREDSPARK)
ptype->looks.stretch *= 0.04;
}
static void P_ImportEffectInfo_f(void)
{
part_type_t *ptype = NULL;
int parenttype;
char *file, *line;
char arg[8][1024];
int args = 0;
char *config = "effectinfo";
FS_LoadFile("effectinfo.txt", (void**)&file);
if (!file)
{
Con_Printf("effectinfo.txt not found\n");
return;
}
line = file;
for (;;)
{
if (!*line)
break;
if (args == 8)
{
Con_Printf("Too many args!\n");
args--;
}
line = COM_StringParse(line, com_token, sizeof(com_token), false, false);
if (!line)
break;
Q_strncpyz(arg[args], com_token, sizeof(arg[args]));
args++;
if (*com_token == '\n')
args--;
else if (*line)
continue;
if (args <= 0)
continue;
if (!strcmp(arg[0], "effect"))
{
char newname[64];
int i;
if (ptype)
{
if (ptype->looks.type == PT_CDECAL)
ptype->scale *= 0.25;
FinishParticleType(ptype);
}
ptype = P_GetParticleType(config, arg[1]);
if (ptype->loaded)
{
for (i = 0; i < 64; i++)
{
parenttype = ptype - part_type;
snprintf(newname, sizeof(newname), "%i+%s", i, arg[1]);
ptype = P_GetParticleType(config, newname);
if (!ptype->loaded)
{
part_type[parenttype].assoc = ptype - part_type;
break;
}
}
if (i == 64)
{
Con_Printf("Too many duplicate names, gave up\n");
break;
}
}
// P_ResetToDefaults(ptype);
ptype->loaded = part_parseweak?1:2;
ptype->scale = 1;
ptype->alpha = 0;
ptype->alpharand = 1;
ptype->alphachange = -1;
ptype->die = 9999;
strcpy(ptype->texname, "particles/particlefont");
ptype->rgb[0] = 1;
ptype->rgb[1] = 1;
ptype->rgb[2] = 1;
ptype->spawnmode = SM_BOX;
ptype->spawnchance = 1;
ptype->randsmax = 1;
ptype->looks.scalefactor = 2;
ptype->looks.invscalefactor = 0;
ptype->looks.type = PT_NORMAL;
ptype->looks.blendmode = BM_BLEND;
ptype->looks.stretch = 1;
ptype->dl_time = 100;
}
else if (!ptype)
{
Con_Printf("Bad effectinfo file\n");
break;
}
else if (!strcmp(arg[0], "countabsolute") && args == 2)
ptype->countextra = atof(arg[1]);
else if (!strcmp(arg[0], "count") && args == 2)
ptype->count = atof(arg[1]);
else if (!strcmp(arg[0], "type") && args == 2)
{
if (!strcmp(arg[1], "decal") || !strcmp(arg[1], "cdecal"))
{
ptype->looks.type = PT_CDECAL;
ptype->looks.blendmode = BM_INVMODC;
}
else if (!strcmp(arg[1], "udecal"))
{
ptype->looks.type = PT_UDECAL;
ptype->looks.blendmode = BM_INVMODC;
}
else if (!strcmp(arg[1], "alphastatic"))
{
ptype->looks.type = PT_NORMAL;
ptype->looks.blendmode = BM_BLEND;
}
else if (!strcmp(arg[1], "static"))
{
ptype->looks.type = PT_NORMAL;
ptype->looks.blendmode = BM_ADD;
}
else if (!strcmp(arg[1], "smoke"))
{
ptype->looks.type = PT_NORMAL;
ptype->looks.blendmode = BM_ADD;
}
else if (!strcmp(arg[1], "spark"))
{
ptype->looks.type = PT_TEXTUREDSPARK;
ptype->looks.blendmode = BM_ADD;
}
else if (!strcmp(arg[1], "bubble"))
{
ptype->looks.type = PT_NORMAL;
ptype->looks.blendmode = BM_ADD;
}
else if (!strcmp(arg[1], "blood"))
{
ptype->looks.type = PT_NORMAL;
ptype->looks.blendmode = BM_INVMODC;
ptype->gravity = 800*1;
}
else if (!strcmp(arg[1], "beam"))
{
ptype->looks.type = PT_BEAM;
ptype->looks.blendmode = BM_ADD;
}
else if (!strcmp(arg[1], "snow"))
{
ptype->looks.type = PT_NORMAL;
ptype->looks.blendmode = BM_ADD;
//should have some sort of wind/flutter with it
}
else
{
Con_Printf("effectinfo type %s not supported\n", arg[1]);
}
}
else if (!strcmp(arg[0], "tex") && args == 3)
{
int mini = atoi(arg[1]);
int maxi = atoi(arg[2]);
/*number range between 0 and 63*/
ptype->s1 = 1/8.0 * (mini & 7);
ptype->s2 = 1/8.0 * (1+(mini & 7));
ptype->t1 = 1/8.0 * (mini>>3);
ptype->t2 = 1/8.0 * (1+(mini>>3));
ptype->texsstride = 1/8.0;
ptype->randsmax = (maxi - mini);
if (ptype->randsmax < 1)
ptype->randsmax = 1;
}
else if (!strcmp(arg[0], "size") && args == 3)
{
float s1 = atof(arg[1]), s2 = atof(arg[2]);
ptype->scale = s1 * 4;
ptype->scalerand = (s2-s1) * 4;
}
else if (!strcmp(arg[0], "sizeincrease") && args == 2)
ptype->scaledelta = atof(arg[1]) * 4;
else if (!strcmp(arg[0], "color") && args == 3)
{
unsigned int rgb1 = strtoul(arg[1], NULL, 0), rgb2 = strtoul(arg[2], NULL, 0);
int i;
for (i = 0; i < 3; i++)
{
ptype->rgb[i] = ((rgb1>>(16-i*8)) & 0xff)/255.0;
ptype->rgbrand[i] = (int)(((rgb2>>(16-i*8)) & 0xff) - ((rgb1>>(16-i*8)) & 0xff))/255.0;
ptype->rgbrandsync[i] = 1;
}
}
else if (!strcmp(arg[0], "alpha") && args == 4)
{
float a1 = atof(arg[1]), a2 = atof(arg[2]), f = atof(arg[3]);
ptype->alpha = a1/255;
ptype->alpharand = (a2-a1)/255;
ptype->alphachange = -f/255;
}
else if (!strcmp(arg[0], "velocityoffset") && args == 4)
; /*a 3d world-coord addition*/
else if (!strcmp(arg[0], "velocityjitter") && args == 4)
{
ptype->spawnvel = (atof(arg[1]) + atof(arg[2]))*0.5;
ptype->spawnvelvert = atof(arg[3]);
}
else if (!strcmp(arg[0], "originoffset") && args == 4)
{ /*a 3d world-coord addition*/
ptype->orgbias[0] = atof(arg[1]);
ptype->orgbias[1] = atof(arg[2]);
ptype->orgbias[2] = atof(arg[3]);
}
else if (!strcmp(arg[0], "originjitter") && args == 4)
{
ptype->areaspread = (atof(arg[1]) + atof(arg[2]))*0.5;
ptype->areaspreadvert = atof(arg[3]);
}
else if (!strcmp(arg[0], "gravity") && args == 2)
{
ptype->gravity = 800*atof(arg[1]);
}
else if (!strcmp(arg[0], "bounce") && args == 2)
{
ptype->clipbounce = atof(arg[1]);
ptype->cliptype = ptype - part_type;
}
else if (!strcmp(arg[0], "airfriction") && args == 2)
ptype->friction[2] = ptype->friction[1] = ptype->friction[0] = atof(arg[1]);
else if (!strcmp(arg[0], "liquidfriction") && args == 2)
;
else if (!strcmp(arg[0], "underwater") && args == 1)
ptype->flags |= PT_TRUNDERWATER;
else if (!strcmp(arg[0], "notunderwater") && args == 1)
ptype->flags |= PT_TROVERWATER;
else if (!strcmp(arg[0], "velocitymultiplier") && args == 2)
ptype->veladd = atof(arg[1]);
else if (!strcmp(arg[0], "trailspacing") && args == 2)
ptype->count = 1 / atof(arg[1]);
else if (!strcmp(arg[0], "time") && args == 3)
{
ptype->die = atof(arg[1]);
ptype->randdie = atof(arg[2]) - ptype->die;
if (ptype->randdie < 0)
{
ptype->die = atof(arg[2]);
ptype->randdie = atof(arg[1]) - ptype->die;
}
}
else if (!strcmp(arg[0], "stretchfactor") && args == 2)
ptype->looks.stretch = atof(arg[1]);
else if (!strcmp(arg[0], "blend") && args == 2)
{
if (!strcmp(arg[1], "invmod"))
ptype->looks.blendmode = BM_INVMODC;
else if (!strcmp(arg[1], "alpha"))
ptype->looks.blendmode = BM_BLEND;
else if (!strcmp(arg[1], "add"))
ptype->looks.blendmode = BM_ADD;
else
Con_Printf("effectinfo 'blend %s' not supported\n", arg[1]);
}
else if (!strcmp(arg[0], "orientation") && args == 2)
{
if (!strcmp(arg[1], "billboard"))
ptype->looks.type = PT_NORMAL;
else if (!strcmp(arg[1], "spark"))
ptype->looks.type = PT_TEXTUREDSPARK;
else if (!strcmp(arg[1], "oriented")) //FIXME: not sure this points the right way. also, its double-sided in dp.
ptype->looks.type = PT_UDECAL;
else if (!strcmp(arg[1], "beam"))
ptype->looks.type = PT_BEAM;
else
Con_Printf("effectinfo 'orientation %s' not supported\n", arg[1]);
}
else if (!strcmp(arg[0], "lightradius") && args == 2)
ptype->dl_radius = atof(arg[1]);
else if (!strcmp(arg[0], "lightradiusfade") && args == 2)
ptype->dl_decay[3] = atof(arg[1]);
else if (!strcmp(arg[0], "lightcolor") && args == 4)
{
ptype->dl_rgb[0] = atof(arg[1]);
ptype->dl_rgb[1] = atof(arg[2]);
ptype->dl_rgb[2] = atof(arg[3]);
}
else if (!strcmp(arg[0], "lighttime") && args == 2)
ptype->dl_time = atof(arg[1]);
else if (!strcmp(arg[0], "lightshadow") && args == 2)
ptype->flags = (ptype->flags & ~PT_NODLSHADOW) | (!atoi(arg[1])?PT_NODLSHADOW:0);
else if (!strcmp(arg[0], "lightcubemapnum") && args == 2)
ptype->dl_cubemapnum = atoi(arg[1]);
#if 1
else if (!strcmp(arg[0], "staincolor") && args == 3)
Con_DPrintf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
else if (!strcmp(arg[0], "stainalpha") && args == 3)
Con_DPrintf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
else if (!strcmp(arg[0], "stainsize") && args == 3)
Con_DPrintf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
else if (!strcmp(arg[0], "staintex") && args == 3)
Con_DPrintf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
else if (!strcmp(arg[0], "stainless") && args == 2)
Con_DPrintf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
else if (!strcmp(arg[0], "rotate") && args == 3)
Con_DPrintf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
else if (!strcmp(arg[0], "rotate") && args == 5)
Con_DPrintf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
#endif
else
Con_Printf("Particle effect token not recognised, or invalid args: %s %s %s %s %s %s\n", arg[0], args<2?"":arg[1], args<3?"":arg[2], args<4?"":arg[3], args<5?"":arg[4], args<6?"":arg[5]);
args = 0;
}
if (ptype)
{
if (ptype->looks.type == PT_CDECAL)
ptype->scale *= 0.25;
FinishParticleType(ptype);
}
FS_FreeFile(file);
r_plooksdirty = true;
}
/*
===============
R_InitParticles
===============
*/
static qboolean PScript_InitParticles (void)
{
int i;
if (r_numparticles) //already inited
return true;
buildsintable();
i = COM_CheckParm ("-particles");
if (i)
{
r_numparticles = (int)(Q_atoi(com_argv[i+1]));
}
else
{
r_numparticles = MAX_PARTICLES;
}
r_numbeams = MAX_BEAMSEGS;
r_numdecals = MAX_DECALS;
r_numtrailstates = MAX_TRAILSTATES;
particles = (particle_t *)
BZ_Malloc (r_numparticles * sizeof(particle_t));
beams = (beamseg_t *)
BZ_Malloc (r_numbeams * sizeof(beamseg_t));
decals = (clippeddecal_t *)
BZ_Malloc (r_numdecals * sizeof(clippeddecal_t));
trailstates = (trailstate_t *)
BZ_Malloc (r_numtrailstates * sizeof(trailstate_t));
memset(trailstates, 0, r_numtrailstates * sizeof(trailstate_t));
ts_cycle = 0;
Cmd_AddCommand("pointfile", P_ReadPointFile_f); //load the leak info produced from qbsp into the particle system to show a line. :)
Cmd_AddCommand("r_part", P_ParticleEffect_f);
pe_script_enabled = true;
Cmd_AddCommand("r_exportbuiltinparticles", P_ExportBuiltinSet_f);
Cmd_AddCommand("r_importeffectinfo", P_ImportEffectInfo_f);
Cmd_AddCommand("r_exportalleffects", P_ExportAllEffects_f);
#if _DEBUG
Cmd_AddCommand("r_partinfo", P_PartInfo_f);
Cmd_AddCommand("r_beaminfo", P_BeamInfo_f);
#endif
pt_pointfile = P_AllocateParticleType("", "PT_POINTFILE");
pe_default = P_AllocateParticleType("", "PE_DEFAULT");
pe_size2 = P_AllocateParticleType("", "PE_SIZE2");
pe_size3 = P_AllocateParticleType("", "PE_SIZE3");
pe_defaulttrail = P_AllocateParticleType("", "PE_DEFAULTTRAIL");
Cvar_Hook(&r_particledesc, R_ParticleDesc_Callback);
Cvar_ForceCallback(&r_particledesc);
for (i = 0; i < (BUFFERVERTS>>2)*6; i += 6)
{
pscriptquadindexes[i+0] = ((i/6)<<2)+0;
pscriptquadindexes[i+1] = ((i/6)<<2)+1;
pscriptquadindexes[i+2] = ((i/6)<<2)+2;
pscriptquadindexes[i+3] = ((i/6)<<2)+0;
pscriptquadindexes[i+4] = ((i/6)<<2)+2;
pscriptquadindexes[i+5] = ((i/6)<<2)+3;
}
pscriptmesh.xyz_array = pscriptverts;
pscriptmesh.st_array = pscripttexcoords;
pscriptmesh.colors4f_array[0] = pscriptcolours;
pscriptmesh.indexes = pscriptquadindexes;
for (i = 0; i < BUFFERVERTS; i++)
{
pscripttriindexes[i] = i;
}
pscripttmesh.xyz_array = pscriptverts;
pscripttmesh.st_array = pscripttexcoords;
pscripttmesh.colors4f_array[0] = pscriptcolours;
pscripttmesh.indexes = pscripttriindexes;
return true;
}
static void PScript_Shutdown (void)
{
pe_script_enabled = false;
if (fallback)
fallback->ShutdownParticles();
Cvar_Unhook(&r_particledesc);
Cmd_RemoveCommand("pointfile"); //load the leak info produced from qbsp into the particle system to show a line. :)
Cmd_RemoveCommand("r_exportbuiltinparticles");
Cmd_RemoveCommand("r_importeffectinfo");
#if _DEBUG
Cmd_RemoveCommand("r_partinfo");
Cmd_RemoveCommand("r_beaminfo");
#endif
while(loadedconfigs)
{
pcfg_t *cfg;
cfg = loadedconfigs;
loadedconfigs = cfg->next;
Z_Free(cfg);
}
while (numparticletypes > 0)
{
numparticletypes--;
if (part_type[numparticletypes].models)
BZ_Free(part_type[numparticletypes].models);
if (part_type[numparticletypes].ramp)
BZ_Free(part_type[numparticletypes].ramp);
}
BZ_Free (part_type);
part_type = NULL;
part_run_list = NULL;
fallback = NULL;
BZ_Free (particles);
BZ_Free (beams);
BZ_Free (decals);
BZ_Free (trailstates);
r_numparticles = 0;
}
/*
===============
P_ClearParticles
===============
*/
static void PScript_ClearParticles (void)
{
int i;
if (fallback)
fallback->ClearParticles();
free_particles = &particles[0];
for (i=0 ;i<r_numparticles ; i++)
particles[i].next = &particles[i+1];
particles[r_numparticles-1].next = NULL;
free_decals = &decals[0];
for (i=0 ;i<r_numdecals ; i++)
decals[i].next = &decals[i+1];
decals[r_numdecals-1].next = NULL;
free_beams = &beams[0];
for (i=0 ;i<r_numbeams ; i++)
{
beams[i].p = NULL;
beams[i].flags = BS_DEAD;
beams[i].next = &beams[i+1];
}
beams[r_numbeams-1].next = NULL;
particletime = cl.time;
for (i = 0; i < numparticletypes; i++)
{
P_LoadTexture(&part_type[i], false);
}
for (i = 0; i < numparticletypes; i++)
{
part_type[i].clippeddecals = NULL;
part_type[i].particles = NULL;
part_type[i].beams = NULL;
part_type[i].skytris = NULL;
}
}
static void P_ExportBuiltinSet_f(void)
{
char *efname = Cmd_Argv(1);
char *file = NULL;
int i;
if (!*efname)
{
Con_Printf("Please name the built in effect (faithful, spikeset, tsshaft, minimal or highfps)\n");
return;
}
for (i = 0; partset_list[i].name; i++)
{
if (!stricmp(efname, partset_list[i].name))
{
file = *partset_list[i].data;
if (file)
{
COM_WriteFile(va("particles/%s.cfg", efname), file, strlen(file));
Con_Printf("Written particles/%s.cfg\n", efname);
}
else
Con_Printf("nothing to export\n");
return;
}
}
Con_Printf("'%s' is not a built in particle set\n", efname);
}
static qboolean P_LoadParticleSet(char *name, qboolean implicit)
{
char *file;
int i;
int restrictlevel = Cmd_FromGamecode() ? RESTRICT_SERVER : RESTRICT_LOCAL;
pcfg_t *cfg;
if (!*name)
return false;
//protect against configs being loaded multiple times. this can easily happen with namespaces (especially if an effect is missing).
for (cfg = loadedconfigs; cfg; cfg = cfg->next)
{
//already loaded?
if (!strcmp(cfg->name, name))
return false;
}
cfg = Z_Malloc(sizeof(*cfg) + strlen(name));
strcpy(cfg->name, name);
cfg->next = loadedconfigs;
loadedconfigs = cfg;
if (!strcmp(name, "classic"))
{
if (fallback)
fallback->ShutdownParticles();
fallback = &pe_classic;
if (fallback)
{
fallback->InitParticles();
fallback->ClearParticles();
}
return true;
}
for (i = 0; partset_list[i].name; i++)
{
if (!stricmp(name, partset_list[i].name))
{
if (partset_list[i].data)
{
Cbuf_AddText(*partset_list[i].data, RESTRICT_LOCAL);
}
return true;
}
}
if (!strcmp(name, "effectinfo"))
{
P_ImportEffectInfo_f();
return true;
}
FS_LoadFile(va("particles/%s.cfg", name), (void**)&file);
if (!file)
FS_LoadFile(va("%s.cfg", name), (void**)&file);
if (file)
{
Cbuf_AddText(va("\nr_part namespace %s %i\n", name, implicit), restrictlevel);
Cbuf_AddText(file, restrictlevel);
Cbuf_AddText("\nr_part namespace \"\" 0\n", restrictlevel);
FS_FreeFile(file);
}
else
{
if (P_LoadParticleSet("high", true))
Con_Printf(CON_WARNING "Couldn't find particle description %s, loading 'high' instead\n", name);
else
{
Con_Printf(CON_WARNING "Couldn't find particle description %s\n", name);
return false;
}
}
return true;
}
static void R_Particles_KillAllEffects(void)
{
int i;
pcfg_t *cfg;
for (i = 0; i < numparticletypes; i++)
{
*part_type[i].texname = '\0';
part_type[i].scale = 0;
part_type[i].loaded = 0;
if (part_type->ramp)
BZ_Free(part_type->ramp);
part_type->ramp = NULL;
}
// numparticletypes = 0;
// BZ_Free(part_type);
// part_type = NULL;
f_modified_particles = false;
if (fallback)
{
fallback->ShutdownParticles();
fallback = NULL;
}
while(loadedconfigs)
{
cfg = loadedconfigs;
loadedconfigs = cfg->next;
Z_Free(cfg);
}
}
static void R_ParticleDesc_Callback(struct cvar_s *var, char *oldvalue)
{
qboolean first;
char *c;
if (qrenderer == QR_NONE)
return; // don't bother parsing early
R_Particles_KillAllEffects();
first = true;
for (c = COM_ParseStringSet(var->string); com_token[0]; c = COM_ParseStringSet(c))
{
/*set up a default*/
if (first && !*com_token)
strcpy(com_token, "faithful");
P_LoadParticleSet(com_token, false);
first = false;
}
// Cbuf_AddText("r_effect\n", RESTRICT_LOCAL);
//make sure nothing is stale.
CL_RegisterParticles();
}
static void P_ReadPointFile_f (void)
{
vfsfile_t *f;
vec3_t org;
//int r; //unreferenced
int c;
char name[MAX_OSPATH];
char line[1024];
char *s;
COM_StripExtension(cl.worldmodel->name, name, sizeof(name));
strcat(name, ".pts");
f = FS_OpenVFS(name, "rb", FS_GAME);
if (!f)
{
Con_Printf ("couldn't open %s\n", name);
return;
}
P_ClearParticles(); //so overflows arn't as bad.
Con_Printf ("Reading %s...\n", name);
c = 0;
for ( ;; )
{
VFS_GETS(f, line, sizeof(line));
s = COM_Parse(line);
org[0] = atof(com_token);
s = COM_Parse(s);
if (!s)
continue;
org[1] = atof(com_token);
s = COM_Parse(s);
if (!s)
continue;
org[2] = atof(com_token);
if (COM_Parse(s))
continue;
c++;
if (c%8)
continue;
if (!free_particles)
{
Con_Printf ("Not enough free particles\n");
break;
}
P_RunParticleEffectType(org, NULL, 1, pt_pointfile);
}
VFS_CLOSE (f);
Con_Printf ("%i points read\n", c);
}
static void P_AddRainParticles(void)
{
float x;
float y;
static float skipped;
static float lastrendered;
int ptype;
vec3_t org, vdist;
skytris_t *st;
if (!r_part_rain.ival || !r_part_rain_quantity.ival)
{
skipped = true;
return;
}
if (lastrendered < particletime - 0.5)
skipped = true; //we've gone for half a sec without any new rain. This would cause some strange effects, so reset times.
if (skipped)
{
for (ptype = 0; ptype<numparticletypes; ptype++)
{
for (st = part_type[ptype].skytris; st; st = st->next)
{
st->nexttime = particletime;
}
}
}
skipped = false;
lastrendered = particletime;
for (ptype = 0; ptype<numparticletypes; ptype++)
{
if (!part_type[ptype].loaded) //woo, batch skipping.
continue;
for (st = part_type[ptype].skytris; st; st = st->next)
{
if (st->face->visframe != r_framecount)
{
st->nexttime = particletime;
continue;
}
while (st->nexttime < particletime)
{
if (!free_particles)
return;
st->nexttime += 10000/(st->area*r_part_rain_quantity.value);
x = frandom()*frandom();
y = frandom() * (1-x);
VectorMA(st->org, x, st->x, org);
VectorMA(org, y, st->y, org);
VectorSubtract(org, r_refdef.vieworg, vdist);
if (Length(vdist) > (1024+512)*frandom())
continue;
if (st->face->flags & SURF_PLANEBACK)
VectorMA(org, -0.5, st->face->plane->normal, org);
else
VectorMA(org, 0.5, st->face->plane->normal, org);
if (!(cl.worldmodel->funcs.PointContents(cl.worldmodel, NULL, org) & FTECONTENTS_SOLID))
{
if (st->face->flags & SURF_PLANEBACK)
{
vdist[0] = -st->face->plane->normal[0];
vdist[1] = -st->face->plane->normal[1];
vdist[2] = -st->face->plane->normal[2];
P_RunParticleEffectType(org, vdist, 1, ptype);
}
else
P_RunParticleEffectType(org, st->face->plane->normal, 1, ptype);
}
}
}
}
}
static void R_Part_SkyTri(float *v1, float *v2, float *v3, msurface_t *surf, int ptype)
{
float dot;
float xm;
float ym;
float theta;
vec3_t xd;
vec3_t yd;
skytris_t *st;
st = NULL;//Hunk_Alloc(sizeof(skytris_t));
if (!st)
return;
st->next = part_type[ptype].skytris;
VectorCopy(v1, st->org);
VectorSubtract(v2, st->org, st->x);
VectorSubtract(v3, st->org, st->y);
VectorCopy(st->x, xd);
VectorCopy(st->y, yd);
/*
xd[2] = 0; //prevent area from being valid on vertical surfaces
yd[2] = 0;
*/
xm = Length(xd);
ym = Length(yd);
dot = DotProduct(xd, yd);
theta = acos(dot/(xm*ym));
st->area = sin(theta)*xm*ym;
st->nexttime = particletime;
st->face = surf;
if (st->area<=0)
return;//bummer.
part_type[ptype].skytris = st;
}
static void PScript_EmitSkyEffectTris(model_t *mod, msurface_t *fa, int ptype)
{
vec3_t verts[64];
int v1;
int v2;
int v3;
int numverts;
int i, lindex;
float *vec;
if (ptype < 0 || ptype >= numparticletypes)
return;
//
// convert edges back to a normal polygon
//
numverts = 0;
for (i=0 ; i<fa->numedges ; i++)
{
lindex = mod->surfedges[fa->firstedge + i];
if (lindex > 0)
vec = mod->vertexes[mod->edges[lindex].v[0]].position;
else
vec = mod->vertexes[mod->edges[-lindex].v[1]].position;
VectorCopy (vec, verts[numverts]);
numverts++;
if (numverts>=64)
{
Con_Printf("Too many verts on sky surface\n");
return;
}
}
v1 = 0;
v2 = 1;
for (v3 = 2; v3 < numverts; v3++)
{
R_Part_SkyTri(verts[v1], verts[v2], verts[v3], fa, ptype);
v2 = v3;
}
}
// Trailstate functions
static void P_CleanTrailstate(trailstate_t *ts)
{
// clear LASTSEG flag from lastbeam so it can be reused
if (ts->lastbeam)
{
ts->lastbeam->flags &= ~BS_LASTSEG;
ts->lastbeam->flags |= BS_NODRAW;
}
// clean structure
memset(ts, 0, sizeof(trailstate_t));
}
static void PScript_DelinkTrailstate(trailstate_t **tsk)
{
trailstate_t *ts;
trailstate_t *assoc;
if (*tsk == NULL)
return; // not linked to a trailstate
ts = *tsk; // store old pointer
*tsk = NULL; // clear pointer
if (ts->key != tsk)
return; // prevent overwrite
assoc = ts->assoc; // store assoc
P_CleanTrailstate(ts); // clean directly linked trailstate
// clean trailstates assoc linked
while (assoc)
{
ts = assoc->assoc;
P_CleanTrailstate(assoc);
assoc = ts;
}
}
static trailstate_t *P_NewTrailstate(trailstate_t **key)
{
trailstate_t *ts;
// bounds check here in case r_numtrailstates changed
if (ts_cycle >= r_numtrailstates)
ts_cycle = 0;
// get trailstate
ts = trailstates + ts_cycle;
// clear trailstate
P_CleanTrailstate(ts);
// set key
ts->key = key;
// advance index cycle
ts_cycle++;
// return clean trailstate
return ts;
}
#define NUMVERTEXNORMALS 162
static float r_avertexnormals[NUMVERTEXNORMALS][3] = {
#include "anorms.h"
};
static vec2_t avelocities[NUMVERTEXNORMALS];
#define BEAMLENGTH 16
// vec3_t avelocity = {23, 7, 3};
// float partstep = 0.01;
// float timescale = 0.01;
static void PScript_ApplyOrgVel(vec3_t oorg, vec3_t ovel, vec3_t eforg, vec3_t efdir, int pno, int pmax, part_type_t *ptype)
{
vec3_t ofsvec, arsvec;
float k,l,m;
int spawnspc, i=pno, j;
l=0;
j=0;
k=0;
m=0;
spawnspc = 8;
switch (ptype->spawnmode)
{
case SM_UNICIRCLE:
m = pmax;
if (ptype->looks.type == PT_BEAM)
m--;
if (m < 1)
m = 0;
else
m = (M_PI*2)/m;
if (ptype->spawnparam1) /* use for weird shape hacks */
m *= ptype->spawnparam1;
break;
case SM_TELEBOX:
spawnspc = 4;
l = -ptype->areaspreadvert;
case SM_LAVASPLASH:
j = k = -ptype->areaspread;
if (ptype->spawnparam1)
m = ptype->spawnparam1;
else
m = 0.55752; /* default weird number for tele/lavasplash used in vanilla Q1 */
if (ptype->spawnparam2)
spawnspc = (int)ptype->spawnparam2;
break;
case SM_FIELD:
if (!avelocities[0][0])
{
for (j=0 ; j<NUMVERTEXNORMALS*2 ; j++)
avelocities[0][j] = (rand()&255) * 0.01;
}
j = 0;
m = 0;
break;
default: //others don't need intitialisation
break;
}
// randomvel
ovel[0] = crandom()*ptype->randomvel;
ovel[1] = crandom()*ptype->randomvel;
ovel[2] = crandom()*ptype->randomvelvert + ptype->randomvelvertbias;
// handle spawn modes (org/vel)
switch (ptype->spawnmode)
{
case SM_BOX:
ofsvec[0] = crandom();
ofsvec[1] = crandom();
ofsvec[2] = crandom();
arsvec[0] = ofsvec[0]*ptype->areaspread;
arsvec[1] = ofsvec[1]*ptype->areaspread;
arsvec[2] = ofsvec[2]*ptype->areaspreadvert;
break;
case SM_TELEBOX:
ofsvec[0] = k;
ofsvec[1] = j;
ofsvec[2] = l+4;
VectorNormalize(ofsvec);
VectorScale(ofsvec, 1.0-(frandom())*m, ofsvec);
// org is just like the original
arsvec[0] = j + (rand()%spawnspc);
arsvec[1] = k + (rand()%spawnspc);
arsvec[2] = l + (rand()%spawnspc);
// advance telebox loop
j += spawnspc;
if (j >= ptype->areaspread)
{
j = -ptype->areaspread;
k += spawnspc;
if (k >= ptype->areaspread)
{
k = -ptype->areaspread;
l += spawnspc;
if (l >= ptype->areaspreadvert)
l = -ptype->areaspreadvert;
}
}
break;
case SM_LAVASPLASH:
// calc directions, org with temp vector
ofsvec[0] = k + (rand()%spawnspc);
ofsvec[1] = j + (rand()%spawnspc);
ofsvec[2] = 256;
arsvec[0] = ofsvec[0];
arsvec[1] = ofsvec[1];
arsvec[2] = frandom()*ptype->areaspreadvert;
VectorNormalize(ofsvec);
VectorScale(ofsvec, 1.0-(frandom())*m, ofsvec);
// advance splash loop
j += spawnspc;
if (j >= ptype->areaspread)
{
j = -ptype->areaspread;
k += spawnspc;
if (k >= ptype->areaspread)
k = -ptype->areaspread;
}
break;
case SM_UNICIRCLE:
ofsvec[0] = cos(m*i);
ofsvec[1] = sin(m*i);
ofsvec[2] = 0;
VectorScale(ofsvec, ptype->areaspread, arsvec);
break;
case SM_FIELD:
arsvec[0] = cl.time * (avelocities[i][0] + m);
arsvec[1] = cl.time * (avelocities[i][1] + m);
arsvec[2] = cos(arsvec[1]);
ofsvec[0] = arsvec[2]*cos(arsvec[0]);
ofsvec[1] = arsvec[2]*sin(arsvec[0]);
ofsvec[2] = -sin(arsvec[1]);
arsvec[0] = r_avertexnormals[j][0]*ptype->areaspread + ofsvec[0]*BEAMLENGTH;
arsvec[1] = r_avertexnormals[j][1]*ptype->areaspread + ofsvec[1]*BEAMLENGTH;
arsvec[2] = r_avertexnormals[j][2]*ptype->areaspreadvert + ofsvec[2]*BEAMLENGTH;
VectorNormalize(ofsvec);
j++;
if (j >= NUMVERTEXNORMALS)
{
j = 0;
m += 0.1762891; // some BS number to try to "randomize" things
}
break;
case SM_DISTBALL:
{
float rdist;
rdist = ptype->spawnparam2 - crandom()*(1-(crandom() * ptype->spawnparam1));
// this is a strange spawntype, which is based on the fact that
// crandom()*crandom() provides something similar to an exponential
// probability curve
ofsvec[0] = hrandom();
ofsvec[1] = hrandom();
if (ptype->areaspreadvert)
ofsvec[2] = hrandom();
else
ofsvec[2] = 0;
VectorNormalize(ofsvec);
VectorScale(ofsvec, rdist, ofsvec);
arsvec[0] = ofsvec[0]*ptype->areaspread;
arsvec[1] = ofsvec[1]*ptype->areaspread;
arsvec[2] = ofsvec[2]*ptype->areaspreadvert;
}
break;
default: // SM_BALL, SM_CIRCLE
ofsvec[0] = hrandom();
ofsvec[1] = hrandom();
if (ptype->areaspreadvert)
ofsvec[2] = hrandom();
else
ofsvec[2] = 0;
VectorNormalize(ofsvec);
if (ptype->spawnmode != SM_CIRCLE)
VectorScale(ofsvec, frandom(), ofsvec);
arsvec[0] = ofsvec[0]*ptype->areaspread;
arsvec[1] = ofsvec[1]*ptype->areaspread;
arsvec[2] = ofsvec[2]*ptype->areaspreadvert;
break;
}
oorg[0] = eforg[0] + arsvec[0];
oorg[1] = eforg[1] + arsvec[1];
oorg[2] = eforg[2] + arsvec[2] + ptype->offsetup;
// apply arsvec+ofsvec
if (efdir)
{
ovel[0] += efdir[0]*ptype->veladd+ofsvec[0]*ptype->spawnvel;
ovel[1] += efdir[1]*ptype->veladd+ofsvec[1]*ptype->spawnvel;
ovel[2] += efdir[2]*ptype->veladd+ofsvec[2]*ptype->spawnvelvert;
oorg[0] += efdir[0]*ptype->orgadd;
oorg[1] += efdir[1]*ptype->orgadd;
oorg[2] += efdir[2]*ptype->orgadd;
}
else
{
ovel[0] += ofsvec[0]*ptype->spawnvel;
ovel[1] += ofsvec[1]*ptype->spawnvel;
ovel[2] += ofsvec[2]*ptype->spawnvelvert - ptype->veladd;
oorg[2] -= ptype->orgadd;
}
}
static void PScript_EffectSpawned(part_type_t *ptype, vec3_t org, vec3_t dir, int dlkey, float countscale)
{
if (ptype->nummodels)
{
int count = ptype->countextra + countscale*(ptype->count+ptype->countrand*frandom());
int i;
partmodels_t *mod;
if (!ptype->countextra && !ptype->count)
count = countscale;
for (i = 0; i < count; i++)
{
mod = &ptype->models[rand() % ptype->nummodels];
if (!mod->model)
mod->model = Mod_ForName(mod->name, false);
if (mod->model && !mod->model->needload)
{
vec3_t morg, mdir;
PScript_ApplyOrgVel(morg, mdir, org, dir, i, count, ptype);
CL_SpawnSpriteEffect(morg, mdir, mod->model, mod->framestart, (mod->frameend?mod->frameend:(mod->model->numframes - mod->framestart)), mod->framerate?mod->framerate:10, ptype->alpha?ptype->alpha:1, ptype->rotationmin*180/M_PI, ptype->gravity);
}
}
}
if (ptype->dl_radius)
{
dlight_t *dl = CL_NewDlight(dlkey, org, ptype->dl_radius, ptype->dl_time, ptype->dl_rgb[0], ptype->dl_rgb[1], ptype->dl_rgb[2]);
dl->channelfade[0] = ptype->dl_decay[0];
dl->channelfade[1] = ptype->dl_decay[1];
dl->channelfade[2] = ptype->dl_decay[2];
dl->decay = ptype->dl_decay[3];
if (ptype->flags & PT_NODLSHADOW)
dl->flags |= LFLAG_NOSHADOWS;
if (ptype->dl_cubemapnum)
snprintf(dl->cubemapname, sizeof(dl->cubemapname), "cubemaps/%i", ptype->dl_cubemapnum);
}
if (*ptype->soundname)
{
S_StartSound(0, 0, S_PrecacheSound(ptype->soundname), org, ptype->soundvol, ptype->soundattn, ptype->sounddelay, ptype->soundpitch);
}
if (ptype->stain_radius)
Surf_AddStain(org, ptype->stain_rgb[0], ptype->stain_rgb[1], ptype->stain_rgb[2], ptype->stain_radius);
}
int Q1BSP_ClipDecal(vec3_t center, vec3_t normal, vec3_t tangent, vec3_t tangent2, float size, float **out);
static int PScript_RunParticleEffectState (vec3_t org, vec3_t dir, float count, int typenum, trailstate_t **tsk)
{
part_type_t *ptype = &part_type[typenum];
int i, j, k, l, spawnspc;
float m, pcount;
particle_t *p;
beamseg_t *b, *bfirst;
vec3_t ofsvec, arsvec; // offsetspread vec, areaspread vec
trailstate_t *ts;
if (typenum >= FALLBACKBIAS && fallback)
return fallback->RunParticleEffectState(org, dir, count, typenum-FALLBACKBIAS, NULL);
if (typenum < 0 || typenum >= numparticletypes)
return 1;
if (!ptype->loaded)
return 1;
// inwater check, switch only once
if (r_part_contentswitch.ival && ptype->inwater >= 0 && cl.worldmodel)
{
int cont;
cont = cl.worldmodel->funcs.PointContents(cl.worldmodel, NULL, org);
if (cont & FTECONTENTS_FLUID)
ptype = &part_type[ptype->inwater];
}
// eliminate trailstate if flag set
if (ptype->flags & PT_NOSTATE)
tsk = NULL;
// trailstate allocation/deallocation
if (tsk)
{
// if *tsk = NULL get a new one
if (*tsk == NULL)
{
ts = P_NewTrailstate(tsk);
*tsk = ts;
}
else
{
ts = *tsk;
if (ts->key != tsk) // trailstate was overwritten
{
ts = P_NewTrailstate(tsk); // so get a new one
*tsk = ts;
}
}
}
else
ts = NULL;
// get msvc to shut up
j = k = l = 0;
m = 0;
while(ptype)
{
PScript_EffectSpawned(ptype, org, dir, 0, count);
if (ptype->looks.type == PT_CDECAL)
{
clippeddecal_t *d;
int decalcount;
float dist;
vec3_t tangent, t2;
vec3_t vec={0.5, 0.5, 0.5};
float *decverts;
int i;
trace_t tr;
float sb,sw,tb,tw;
vec3_t bestdir;
if (!free_decals)
return 0;
if (!dir || (dir[0] == 0 && dir[1] == 0 && dir[2] == 0))
{
bestdir[0] = 0;
bestdir[1] = 0.73;
bestdir[2] = 0.73;
dist = 1;
for (i = 0; i < 6; i++)
{
if (i >= 3)
{
t2[0] = ((i&3)==0)*8;
t2[1] = ((i&3)==1)*8;
t2[2] = ((i&3)==2)*8;
}
else
{
t2[0] = -((i&3)==0)*8;
t2[1] = -((i&3)==1)*8;
t2[2] = -((i&3)==2)*8;
}
VectorSubtract(org, t2, tangent);
VectorAdd(org, t2, t2);
if (cl.worldmodel->funcs.NativeTrace (cl.worldmodel, 0, 0, NULL, tangent, t2, vec3_origin, vec3_origin, MASK_WORLDSOLID, &tr))
{
if (tr.fraction < dist)
{
dist = tr.fraction;
VectorCopy(tr.plane.normal, bestdir);
}
}
}
dir = bestdir;
}
VectorInverse(dir);
VectorNormalize(dir);
VectorNormalize(vec);
CrossProduct(dir, vec, t2);
Matrix4x4_CM_Transform3(Matrix4x4_CM_NewRotation(frandom()*360, dir[0], dir[1], dir[2]), t2, tangent);
CrossProduct(dir, tangent, t2);
sw = ptype->s2 - ptype->s1;
sb = ptype->s1 + sw/2;
tw = ptype->t2 - ptype->t1;
tb = ptype->t1 + tw/2;
m = ptype->scale + frandom() * ptype->scalerand;
sw /= m;
tw /= m;
decalcount = Q1BSP_ClipDecal(org, dir, tangent, t2, m, &decverts);
while(decalcount)
{
if (!free_decals)
break;
d = free_decals;
free_decals = d->next;
d->next = ptype->clippeddecals;
ptype->clippeddecals = d;
VectorCopy((decverts+0*(sizeof(vec3_t)/sizeof(vec_t))), d->vertex[0]);
VectorCopy((decverts+1*(sizeof(vec3_t)/sizeof(vec_t))), d->vertex[1]);
VectorCopy((decverts+2*(sizeof(vec3_t)/sizeof(vec_t))), d->vertex[2]);
for (i = 0; i < 3; i++)
{
VectorSubtract(d->vertex[i], org, vec);
d->texcoords[i][0] = (DotProduct(vec, t2)*sw)+sb;
d->texcoords[i][1] = (DotProduct(vec, tangent)*tw)+tb;
}
d->die = ptype->randdie*frandom();
if (ptype->die)
d->rgba[3] = ptype->alpha + d->die*ptype->alphachange;
else
d->rgba[3] = ptype->alpha;
d->rgba[3] += ptype->alpharand*frandom();
if (ptype->colorindex >= 0)
{
int cidx;
cidx = ptype->colorrand > 0 ? rand() % ptype->colorrand : 0;
cidx = ptype->colorindex + cidx;
if (cidx > 255)
d->rgba[3] = d->rgba[3] / 2; // Hexen 2 style transparency
cidx = (cidx & 0xff) * 3;
d->rgba[0] = host_basepal[cidx] * (1/255.0);
d->rgba[1] = host_basepal[cidx+1] * (1/255.0);
d->rgba[2] = host_basepal[cidx+2] * (1/255.0);
}
else
VectorCopy(ptype->rgb, d->rgba);
vec[2] = frandom();
vec[0] = vec[2]*ptype->rgbrandsync[0] + frandom()*(1-ptype->rgbrandsync[0]);
vec[1] = vec[2]*ptype->rgbrandsync[1] + frandom()*(1-ptype->rgbrandsync[1]);
vec[2] = vec[2]*ptype->rgbrandsync[2] + frandom()*(1-ptype->rgbrandsync[2]);
d->rgba[0] += vec[0]*ptype->rgbrand[0] + ptype->rgbchange[0]*d->die;
d->rgba[1] += vec[1]*ptype->rgbrand[1] + ptype->rgbchange[1]*d->die;
d->rgba[2] += vec[2]*ptype->rgbrand[2] + ptype->rgbchange[2]*d->die;
d->die = particletime + ptype->die - d->die;
decverts += (sizeof(vec3_t)/sizeof(vec_t))*3;
decalcount--;
// maintain run list
if (!(ptype->state & PS_INRUNLIST))
{
ptype->nexttorun = part_run_list;
part_run_list = ptype;
ptype->state |= PS_INRUNLIST;
}
}
if (ptype->assoc < 0)
break;
ptype = &part_type[ptype->assoc];
continue;
}
// init spawn specific variables
b = bfirst = NULL;
spawnspc = 8;
pcount = ptype->countextra + count*(ptype->count+ptype->countrand*frandom());
if (ptype->flags & PT_INVFRAMETIME)
pcount /= host_frametime;
if (ts)
pcount += ts->state2.emittime;
pcount *= r_part_density.value;
switch (ptype->spawnmode)
{
case SM_UNICIRCLE:
m = pcount;
if (ptype->looks.type == PT_BEAM)
m--;
if (m < 1)
m = 0;
else
m = (M_PI*2)/m;
if (ptype->spawnparam1) /* use for weird shape hacks */
m *= ptype->spawnparam1;
break;
case SM_TELEBOX:
spawnspc = 4;
l = -ptype->areaspreadvert;
case SM_LAVASPLASH:
j = k = -ptype->areaspread;
if (ptype->spawnparam1)
m = ptype->spawnparam1;
else
m = 0.55752; /* default weird number for tele/lavasplash used in vanilla Q1 */
if (ptype->spawnparam2)
spawnspc = (int)ptype->spawnparam2;
break;
case SM_FIELD:
if (!avelocities[0][0])
{
for (j=0 ; j<NUMVERTEXNORMALS*2 ; j++)
avelocities[0][j] = (rand()&255) * 0.01;
}
j = 0;
m = 0;
break;
default: //others don't need intitialisation
break;
}
// time limit (for completeness)
if (ptype->spawntime && ts)
{
if (ts->state1.statetime > particletime)
return 0; // timelimit still in effect
ts->state1.statetime = particletime + ptype->spawntime; // record old time
}
// random chance for point effects
if (ptype->spawnchance < frandom())
{
i = ceil(pcount);
break;
}
/*this is a hack, use countextra=1, count=0*/
if (!ptype->die && ptype->count == 1 && ptype->countrand == 0)
{
i = 0;
pcount = 1;
}
// particle spawning loop
for (i = 0; i < pcount; i++)
{
if (!free_particles)
break;
p = free_particles;
if (ptype->looks.type == PT_BEAM)
{
if (!free_beams)
break;
if (b)
{
b = b->next = free_beams;
free_beams = free_beams->next;
}
else
{
b = bfirst = free_beams;
free_beams = free_beams->next;
}
b->texture_s = i; // TODO: FIX THIS NUMBER
b->flags = 0;
b->p = p;
VectorClear(b->dir);
}
free_particles = p->next;
p->next = ptype->particles;
ptype->particles = p;
p->die = ptype->randdie*frandom();
p->scale = ptype->scale+ptype->scalerand*frandom();
if (ptype->die)
p->rgba[3] = ptype->alpha+p->die*ptype->alphachange;
else
p->rgba[3] = ptype->alpha;
p->rgba[3] += ptype->alpharand*frandom();
// p->color = 0;
if (ptype->emittime < 0)
p->state.trailstate = NULL;
else
p->state.nextemit = particletime + ptype->emitstart - p->die;
p->rotationspeed = ptype->rotationmin + frandom()*ptype->rotationrand;
p->angle = ptype->rotationstartmin + frandom()*ptype->rotationstartrand;
p->s1 = ptype->s1;
p->t1 = ptype->t1;
p->s2 = ptype->s2;
p->t2 = ptype->t2;
if (ptype->randsmax!=1)
{
m = ptype->texsstride * (rand()%ptype->randsmax);
p->s1 += m;
p->s2 += m;
}
if (ptype->colorindex >= 0)
{
int cidx;
cidx = ptype->colorrand > 0 ? rand() % ptype->colorrand : 0;
cidx = ptype->colorindex + cidx;
if (cidx > 255)
p->rgba[3] = p->rgba[3] / 2; // Hexen 2 style transparency
cidx = (cidx & 0xff) * 3;
p->rgba[0] = host_basepal[cidx] * (1/255.0);
p->rgba[1] = host_basepal[cidx+1] * (1/255.0);
p->rgba[2] = host_basepal[cidx+2] * (1/255.0);
}
else
VectorCopy(ptype->rgb, p->rgba);
// use org temporarily for rgbsync
p->org[2] = frandom();
p->org[0] = p->org[2]*ptype->rgbrandsync[0] + frandom()*(1-ptype->rgbrandsync[0]);
p->org[1] = p->org[2]*ptype->rgbrandsync[1] + frandom()*(1-ptype->rgbrandsync[1]);
p->org[2] = p->org[2]*ptype->rgbrandsync[2] + frandom()*(1-ptype->rgbrandsync[2]);
p->rgba[0] += p->org[0]*ptype->rgbrand[0] + ptype->rgbchange[0]*p->die;
p->rgba[1] += p->org[1]*ptype->rgbrand[1] + ptype->rgbchange[1]*p->die;
p->rgba[2] += p->org[2]*ptype->rgbrand[2] + ptype->rgbchange[2]*p->die;
// randomvel
p->vel[0] = crandom()*ptype->randomvel;
p->vel[1] = crandom()*ptype->randomvel;
p->vel[2] = crandom()*ptype->randomvelvert + ptype->randomvelvertbias;
// handle spawn modes (org/vel)
switch (ptype->spawnmode)
{
case SM_BOX:
ofsvec[0] = crandom();
ofsvec[1] = crandom();
ofsvec[2] = crandom();
arsvec[0] = ofsvec[0]*ptype->areaspread;
arsvec[1] = ofsvec[1]*ptype->areaspread;
arsvec[2] = ofsvec[2]*ptype->areaspreadvert;
break;
case SM_TELEBOX:
ofsvec[0] = k;
ofsvec[1] = j;
ofsvec[2] = l+4;
VectorNormalize(ofsvec);
VectorScale(ofsvec, 1.0-(frandom())*m, ofsvec);
// org is just like the original
arsvec[0] = j + (rand()%spawnspc);
arsvec[1] = k + (rand()%spawnspc);
arsvec[2] = l + (rand()%spawnspc);
// advance telebox loop
j += spawnspc;
if (j >= ptype->areaspread)
{
j = -ptype->areaspread;
k += spawnspc;
if (k >= ptype->areaspread)
{
k = -ptype->areaspread;
l += spawnspc;
if (l >= ptype->areaspreadvert)
l = -ptype->areaspreadvert;
}
}
break;
case SM_LAVASPLASH:
// calc directions, org with temp vector
ofsvec[0] = k + (rand()%spawnspc);
ofsvec[1] = j + (rand()%spawnspc);
ofsvec[2] = 256;
arsvec[0] = ofsvec[0];
arsvec[1] = ofsvec[1];
arsvec[2] = frandom()*ptype->areaspreadvert;
VectorNormalize(ofsvec);
VectorScale(ofsvec, 1.0-(frandom())*m, ofsvec);
// advance splash loop
j += spawnspc;
if (j >= ptype->areaspread)
{
j = -ptype->areaspread;
k += spawnspc;
if (k >= ptype->areaspread)
k = -ptype->areaspread;
}
break;
case SM_UNICIRCLE:
ofsvec[0] = cos(m*i);
ofsvec[1] = sin(m*i);
ofsvec[2] = 0;
VectorScale(ofsvec, ptype->areaspread, arsvec);
break;
case SM_FIELD:
arsvec[0] = cl.time * (avelocities[i][0] + m);
arsvec[1] = cl.time * (avelocities[i][1] + m);
arsvec[2] = cos(arsvec[1]);
ofsvec[0] = arsvec[2]*cos(arsvec[0]);
ofsvec[1] = arsvec[2]*sin(arsvec[0]);
ofsvec[2] = -sin(arsvec[1]);
arsvec[0] = r_avertexnormals[j][0]*ptype->areaspread + ofsvec[0]*BEAMLENGTH;
arsvec[1] = r_avertexnormals[j][1]*ptype->areaspread + ofsvec[1]*BEAMLENGTH;
arsvec[2] = r_avertexnormals[j][2]*ptype->areaspreadvert + ofsvec[2]*BEAMLENGTH;
VectorNormalize(ofsvec);
j++;
if (j >= NUMVERTEXNORMALS)
{
j = 0;
m += 0.1762891; // some BS number to try to "randomize" things
}
break;
case SM_DISTBALL:
{
float rdist;
rdist = ptype->spawnparam2 - crandom()*(1-(crandom() * ptype->spawnparam1));
// this is a strange spawntype, which is based on the fact that
// crandom()*crandom() provides something similar to an exponential
// probability curve
ofsvec[0] = hrandom();
ofsvec[1] = hrandom();
if (ptype->areaspreadvert)
ofsvec[2] = hrandom();
else
ofsvec[2] = 0;
VectorNormalize(ofsvec);
VectorScale(ofsvec, rdist, ofsvec);
arsvec[0] = ofsvec[0]*ptype->areaspread;
arsvec[1] = ofsvec[1]*ptype->areaspread;
arsvec[2] = ofsvec[2]*ptype->areaspreadvert;
}
break;
default: // SM_BALL, SM_CIRCLE
ofsvec[0] = hrandom();
ofsvec[1] = hrandom();
if (ptype->areaspreadvert)
ofsvec[2] = hrandom();
else
ofsvec[2] = 0;
VectorNormalize(ofsvec);
if (ptype->spawnmode != SM_CIRCLE)
VectorScale(ofsvec, frandom(), ofsvec);
arsvec[0] = ofsvec[0]*ptype->areaspread;
arsvec[1] = ofsvec[1]*ptype->areaspread;
arsvec[2] = ofsvec[2]*ptype->areaspreadvert;
break;
}
p->org[0] = org[0] + arsvec[0];
p->org[1] = org[1] + arsvec[1];
p->org[2] = org[2] + arsvec[2] + ptype->offsetup;
// apply arsvec+ofsvec
if (dir)
{
p->vel[0] += dir[0]*ptype->veladd+ofsvec[0]*ptype->spawnvel;
p->vel[1] += dir[1]*ptype->veladd+ofsvec[1]*ptype->spawnvel;
p->vel[2] += dir[2]*ptype->veladd+ofsvec[2]*ptype->spawnvelvert;
p->org[0] += dir[0]*ptype->orgadd;
p->org[1] += dir[1]*ptype->orgadd;
p->org[2] += dir[2]*ptype->orgadd;
}
else
{
p->vel[0] += ofsvec[0]*ptype->spawnvel;
p->vel[1] += ofsvec[1]*ptype->spawnvel;
p->vel[2] += ofsvec[2]*ptype->spawnvelvert - ptype->veladd;
p->org[2] -= ptype->orgadd;
}
VectorAdd(p->org, ptype->orgbias, p->org);
p->die = particletime + ptype->die - p->die;
}
// update beam list
if (ptype->looks.type == PT_BEAM)
{
if (b)
{
// update dir for bfirst for certain modes since it will never get updated
switch (ptype->spawnmode)
{
case SM_UNICIRCLE:
// kinda hackish here, assuming ofsvec contains the point at i-1
arsvec[0] = cos(m*(i-2));
arsvec[1] = sin(m*(i-2));
arsvec[2] = 0;
VectorSubtract(ofsvec, arsvec, bfirst->dir);
VectorNormalize(bfirst->dir);
break;
default:
break;
}
b->flags |= BS_NODRAW;
b->next = ptype->beams;
ptype->beams = bfirst;
}
}
// save off emit times in trailstate
if (ts)
ts->state2.emittime = pcount - i;
// maintain run list
if (!(ptype->state & PS_INRUNLIST))
{
ptype->nexttorun = part_run_list;
part_run_list = ptype;
ptype->state |= PS_INRUNLIST;
}
// go to next associated effect
if (ptype->assoc < 0)
break;
// new trailstate
if (ts)
{
tsk = &(ts->assoc);
// if *tsk = NULL get a new one
if (*tsk == NULL)
{
ts = P_NewTrailstate(tsk);
*tsk = ts;
}
else
{
ts = *tsk;
if (ts->key != tsk) // trailstate was overwritten
{
ts = P_NewTrailstate(tsk); // so get a new one
*tsk = ts;
}
}
}
ptype = &part_type[ptype->assoc];
}
return 0;
}
static int PScript_RunParticleEffectTypeString (vec3_t org, vec3_t dir, float count, char *name)
{
int type = P_FindParticleType(name);
if (type < 0)
return 1;
return P_RunParticleEffectType(org, dir, count, type);
}
/*
===============
P_RunParticleEffect
===============
*/
static void PScript_RunParticleEffect (vec3_t org, vec3_t dir, int color, int count)
{
int ptype;
ptype = P_FindParticleType(va("pe_%i", color));
if (P_RunParticleEffectType(org, dir, count, ptype))
{
if (count > 130 && part_type[pe_size3].loaded)
{
part_type[pe_size3].colorindex = color & ~0x7;
part_type[pe_size3].colorrand = 8;
P_RunParticleEffectType(org, dir, count, pe_size3);
}
else if (count > 20 && part_type[pe_size2].loaded)
{
part_type[pe_size2].colorindex = color & ~0x7;
part_type[pe_size2].colorrand = 8;
P_RunParticleEffectType(org, dir, count, pe_size2);
}
else if (part_type[pe_default].loaded || !fallback)
{
part_type[pe_default].colorindex = color & ~0x7;
part_type[pe_default].colorrand = 8;
P_RunParticleEffectType(org, dir, count, pe_default);
}
else
fallback->RunParticleEffect(org, dir, color, count);
}
}
//h2 stylie
static void PScript_RunParticleEffect2 (vec3_t org, vec3_t dmin, vec3_t dmax, int color, int effect, int count)
{
int i, j;
float num;
float invcount;
vec3_t nvel;
int ptype = P_FindParticleType(va("pe2_%i_%i", effect, color));
if (ptype < 0)
{
ptype = P_FindParticleType(va("pe2_%i", effect));
if (ptype < 0)
ptype = pe_default;
part_type[ptype].colorindex = color;
}
invcount = 1/part_type[ptype].count; // using this to get R_RPET to always spawn 1
count = count * part_type[ptype].count;
for (i=0 ; i<count ; i++)
{
if (!free_particles)
return;
for (j=0 ; j<3 ; j++)
{
num = rand() / (float)RAND_MAX;
nvel[j] = dmin[j] + ((dmax[j] - dmin[j]) * num);
}
P_RunParticleEffectType(org, nvel, invcount, ptype);
}
}
/*
===============
P_RunParticleEffect3
===============
*/
//h2 stylie
static void PScript_RunParticleEffect3 (vec3_t org, vec3_t box, int color, int effect, int count)
{
int i, j;
vec3_t nvel;
float num;
float invcount;
int ptype = P_FindParticleType(va("pe3_%i_%i", effect, color));
if (ptype < 0)
{
ptype = P_FindParticleType(va("pe3_%i", effect));
if (ptype < 0)
ptype = pe_default;
part_type[ptype].colorindex = color;
}
invcount = 1/part_type[ptype].count; // using this to get R_RPET to always spawn 1
count = count * part_type[ptype].count;
for (i=0 ; i<count ; i++)
{
if (!free_particles)
return;
for (j=0 ; j<3 ; j++)
{
num = rand() / (float)RAND_MAX;
nvel[j] = (box[j] * num * 2) - box[j];
}
P_RunParticleEffectType(org, nvel, invcount, ptype);
}
}
/*
===============
P_RunParticleEffect4
===============
*/
//h2 stylie
static void PScript_RunParticleEffect4 (vec3_t org, float radius, int color, int effect, int count)
{
int i, j;
vec3_t nvel;
float num;
float invcount;
int ptype = P_FindParticleType(va("pe4_%i_%i", effect, color));
if (ptype < 0)
{
ptype = P_FindParticleType(va("pe4_%i", effect));
if (ptype < 0)
ptype = pe_default;
part_type[ptype].colorindex = color;
}
invcount = 1/part_type[ptype].count; // using this to get R_RPET to always spawn 1
count = count * part_type[ptype].count;
for (i=0 ; i<count ; i++)
{
if (!free_particles)
return;
for (j=0 ; j<3 ; j++)
{
num = rand() / (float)RAND_MAX;
nvel[j] = (radius * num * 2) - radius;
}
P_RunParticleEffectType(org, nvel, invcount, ptype);
}
}
static void PScript_RunParticleCube(int ptype, vec3_t minb, vec3_t maxb, vec3_t dir_min, vec3_t dir_max, float count, int colour, qboolean gravity, float jitter)
{
vec3_t org;
int i, j;
float num;
float invcount;
if (ptype < 0)
ptype = P_FindParticleType(va("te_cube%s_%i", gravity?"_g":"", colour));
if (ptype < 0)
{
ptype = P_FindParticleType(va("te_cube%s", gravity?"_g":""));
if (ptype < 0)
ptype = pe_default;
part_type[ptype].colorindex = colour;
}
invcount = 1/part_type[ptype].count; // using this to get R_RPET to always spawn 1
count = count * part_type[ptype].count;
for (i=0 ; i<count ; i++)
{
if (!free_particles)
return;
for (j=0 ; j<3 ; j++)
{
num = rand() / (float)RAND_MAX;
org[j] = minb[j] + num*(maxb[j]-minb[j]);
}
P_RunParticleEffectType(org, dir_min, invcount, ptype);
}
}
static void PScript_RunParticleWeather(vec3_t minb, vec3_t maxb, vec3_t dir, float count, int colour, char *efname)
{
vec3_t org;
int i, j;
float num;
float invcount;
int ptype = P_FindParticleType(va("te_%s_%i", efname, colour));
if (ptype < 0)
{
ptype = P_FindParticleType(va("te_%s", efname));
if (ptype < 0)
ptype = pe_default;
part_type[ptype].colorindex = colour;
}
invcount = 1/part_type[ptype].count; // using this to get R_RPET to always spawn 1
count = count * part_type[ptype].count;
for (i=0 ; i<count ; i++)
{
if (!free_particles)
return;
for (j=0 ; j<3 ; j++)
{
num = rand() / (float)RAND_MAX;
org[j] = minb[j] + num*(maxb[j]-minb[j]);
}
P_RunParticleEffectType(org, dir, invcount, ptype);
}
}
static void P_ParticleTrailDraw (vec3_t startpos, vec3_t end, part_type_t *ptype, trailstate_t **tsk, int dlkey)
{
vec3_t vec, vstep, right, up, start;
float len;
int tcount;
particle_t *p;
beamseg_t *b;
beamseg_t *bfirst;
trailstate_t *ts;
int count;
float veladd = -ptype->veladd;
float randvel = ptype->randomvel;
float randvelvert = ptype->randomvelvert;
float step;
float stop;
float tdegree = 2.0*M_PI/256; /* MSVC whine */
float sdegree = 0;
float nrfirst, nrlast;
VectorCopy(startpos, start);
// eliminate trailstate if flag set
if (ptype->flags & PT_NOSTATE)
tsk = NULL;
// trailstate allocation/deallocation
if (tsk)
{
// if *tsk = NULL get a new one
if (*tsk == NULL)
{
ts = P_NewTrailstate(tsk);
*tsk = ts;
}
else
{
ts = *tsk;
if (ts->key != tsk) // trailstate was overwritten
{
ts = P_NewTrailstate(tsk); // so get a new one
*tsk = ts;
}
}
}
else
ts = NULL;
PScript_EffectSpawned(ptype, start, vec3_origin, dlkey, 1);
if (ptype->assoc>=0)
{
if (ts)
P_ParticleTrail(start, end, ptype->assoc, dlkey, &(ts->assoc));
else
P_ParticleTrail(start, end, ptype->assoc, dlkey, NULL);
}
if (r_part_contentswitch.ival && (ptype->flags & (PT_TRUNDERWATER | PT_TROVERWATER)) && cl.worldmodel)
{
int cont;
cont = cl.worldmodel->funcs.PointContents(cl.worldmodel, NULL, startpos);
if ((ptype->flags & PT_TROVERWATER) && (cont & FTECONTENTS_FLUID))
return;
if ((ptype->flags & PT_TRUNDERWATER) && !(cont & FTECONTENTS_FLUID))
return;
}
// time limit for trails
if (ptype->spawntime && ts)
{
if (ts->state1.statetime > particletime)
return; // timelimit still in effect
ts->state1.statetime = particletime + ptype->spawntime; // record old time
ts = NULL; // clear trailstate so we don't save length/lastseg
}
// random chance for trails
if (ptype->spawnchance < frandom())
return; // don't spawn but return success
if (!ptype->die)
ts = NULL;
// use ptype step to calc step vector and step size
step = 1/ptype->count;
if (step < 0.01)
step = 0.01;
VectorSubtract (end, start, vec);
len = VectorNormalize (vec);
if (ptype->flags & PT_AVERAGETRAIL)
{
float tavg;
// mangle len/step to get last point to be at end
tavg = len / step;
tavg = tavg / ceil(tavg);
step *= tavg;
len += step;
}
VectorScale(vec, step, vstep);
// add offset
start[2] += ptype->offsetup;
// spawn mode precalculations
if (ptype->spawnmode == SM_SPIRAL)
{
VectorVectors(vec, right, up);
// precalculate degree of rotation
if (ptype->spawnparam1)
tdegree = 2.0*M_PI/ptype->spawnparam1; /* distance per rotation inversed */
sdegree = ptype->spawnparam2*(M_PI/180);
}
else if (ptype->spawnmode == SM_CIRCLE)
{
VectorVectors(vec, right, up);
}
// store last stop here for lack of a better solution besides vectors
if (ts)
{
ts->state2.laststop = stop = ts->state2.laststop + len; //when to stop
len = ts->state1.lastdist;
}
else
{
stop = len;
len = 0;
}
// len = ts->lastdist/step;
// len = (len - (int)len)*step;
// VectorMA (start, -len, vec, start);
if (ptype->flags & PT_NOSPREADFIRST)
nrfirst = len + step*1.5;
else
nrfirst = len;
if (ptype->flags & PT_NOSPREADLAST)
nrlast = stop;
else
nrlast = stop + step;
b = bfirst = NULL;
if (len < stop)
count = (stop-len) / step;
else
{
count = 0;
step = 0;
VectorClear(vstep);
}
count += ptype->countextra;
while (count-->0)//len < stop)
{
len += step;
if (!free_particles)
{
len = stop;
break;
}
p = free_particles;
if (ptype->looks.type == PT_BEAM)
{
if (!free_beams)
{
len = stop;
break;
}
if (b)
{
b = b->next = free_beams;
free_beams = free_beams->next;
}
else
{
b = bfirst = free_beams;
free_beams = free_beams->next;
}
b->texture_s = len; // not sure how to calc this
b->flags = 0;
b->p = p;
VectorCopy(vec, b->dir);
}
free_particles = p->next;
p->next = ptype->particles;
ptype->particles = p;
p->die = ptype->randdie*frandom();
p->scale = ptype->scale+ptype->scalerand*frandom();
if (ptype->die)
p->rgba[3] = ptype->alpha+p->die*ptype->alphachange;
else
p->rgba[3] = ptype->alpha;
p->rgba[3] += ptype->alpharand*frandom();
// p->color = 0;
// if (ptype->spawnmode == SM_TRACER)
if (ptype->spawnparam1)
tcount = (int)(len * ptype->count / ptype->spawnparam1);
else
tcount = (int)(len * ptype->count);
if (ptype->colorindex >= 0)
{
int cidx;
cidx = ptype->colorrand > 0 ? rand() % ptype->colorrand : 0;
if (ptype->flags & PT_CITRACER) // colorindex behavior as per tracers in std Q1
cidx += ((tcount & 4) << 1);
cidx = ptype->colorindex + cidx;
if (cidx > 255)
p->rgba[3] = p->rgba[3] / 2;
cidx = (cidx & 0xff) * 3;
p->rgba[0] = host_basepal[cidx] * (1/255.0);
p->rgba[1] = host_basepal[cidx+1] * (1/255.0);
p->rgba[2] = host_basepal[cidx+2] * (1/255.0);
}
else
VectorCopy(ptype->rgb, p->rgba);
// use org temporarily for rgbsync
p->org[2] = frandom();
p->org[0] = p->org[2]*ptype->rgbrandsync[0] + frandom()*(1-ptype->rgbrandsync[0]);
p->org[1] = p->org[2]*ptype->rgbrandsync[1] + frandom()*(1-ptype->rgbrandsync[1]);
p->org[2] = p->org[2]*ptype->rgbrandsync[2] + frandom()*(1-ptype->rgbrandsync[2]);
p->rgba[0] += p->org[0]*ptype->rgbrand[0] + ptype->rgbchange[0]*p->die;
p->rgba[1] += p->org[1]*ptype->rgbrand[1] + ptype->rgbchange[1]*p->die;
p->rgba[2] += p->org[2]*ptype->rgbrand[2] + ptype->rgbchange[2]*p->die;
VectorClear (p->vel);
if (ptype->emittime < 0)
p->state.trailstate = NULL; // init trailstate
else
p->state.nextemit = particletime + ptype->emitstart - p->die;
p->rotationspeed = ptype->rotationmin + frandom()*ptype->rotationrand;
p->angle = ptype->rotationstartmin + frandom()*ptype->rotationstartrand;
p->s1 = ptype->s1;
p->t1 = ptype->t1;
p->s2 = ptype->s2;
p->t2 = ptype->t2;
if (ptype->randsmax!=1)
{
float offs;
offs = ptype->texsstride * (rand()%ptype->randsmax);
p->s1 += offs;
p->s2 += offs;
while (p->s1 >= 1)
{
p->s1 -= 1;
p->s2 -= 1;
p->t1 += ptype->texsstride;
p->t2 += ptype->texsstride;
}
}
if (len < nrfirst || len >= nrlast)
{
// no offset or areaspread for these particles...
p->vel[0] = vec[0]*veladd+crandom()*randvel;
p->vel[1] = vec[1]*veladd+crandom()*randvel;
p->vel[2] = vec[2]*veladd+crandom()*randvelvert;
VectorCopy(start, p->org);
}
else
{
switch(ptype->spawnmode)
{
case SM_TRACER:
if (tcount & 1)
{
p->vel[0] = vec[1]*ptype->spawnvel;
p->vel[1] = -vec[0]*ptype->spawnvel;
p->org[0] = vec[1]*ptype->areaspread;
p->org[1] = -vec[0]*ptype->areaspread;
}
else
{
p->vel[0] = -vec[1]*ptype->spawnvel;
p->vel[1] = vec[0]*ptype->spawnvel;
p->org[0] = -vec[1]*ptype->areaspread;
p->org[1] = vec[0]*ptype->areaspread;
}
p->vel[0] += vec[0]*veladd+crandom()*randvel;
p->vel[1] += vec[1]*veladd+crandom()*randvel;
p->vel[2] = vec[2]*veladd+crandom()*randvelvert;
p->org[0] += start[0];
p->org[1] += start[1];
p->org[2] = start[2];
break;
case SM_SPIRAL:
{
float tsin, tcos;
float tright, tup;
tcos = cos(len*tdegree+sdegree);
tsin = sin(len*tdegree+sdegree);
tright = tcos*ptype->areaspread;
tup = tsin*ptype->areaspread;
p->org[0] = start[0] + right[0]*tright + up[0]*tup;
p->org[1] = start[1] + right[1]*tright + up[1]*tup;
p->org[2] = start[2] + right[2]*tright + up[2]*tup;
tright = tcos*ptype->spawnvel;
tup = tsin*ptype->spawnvel;
p->vel[0] = vec[0]*veladd+crandom()*randvel + right[0]*tright + up[0]*tup;
p->vel[1] = vec[1]*veladd+crandom()*randvel + right[1]*tright + up[1]*tup;
p->vel[2] = vec[2]*veladd+crandom()*randvelvert + right[2]*tright + up[2]*tup;
}
break;
// TODO: directionalize SM_BALL/SM_CIRCLE/SM_DISTBALL
case SM_BALL:
p->org[0] = crandom();
p->org[1] = crandom();
p->org[2] = crandom();
VectorNormalize(p->org);
VectorScale(p->org, frandom(), p->org);
p->vel[0] = vec[0]*veladd+crandom()*randvel + p->org[0]*ptype->spawnvel;
p->vel[1] = vec[1]*veladd+crandom()*randvel + p->org[1]*ptype->spawnvel;
p->vel[2] = vec[2]*veladd+crandom()*randvelvert + p->org[2]*ptype->spawnvelvert;
p->org[0] = p->org[0]*ptype->areaspread + start[0];
p->org[1] = p->org[1]*ptype->areaspread + start[1];
p->org[2] = p->org[2]*ptype->areaspreadvert + start[2];
break;
case SM_CIRCLE:
{
float tsin, tcos;
tcos = cos(len*tdegree)*ptype->areaspread;
tsin = sin(len*tdegree)*ptype->areaspread;
p->org[0] = start[0] + right[0]*tcos + up[0]*tsin + vstep[0] * (len*tdegree);
p->org[1] = start[1] + right[1]*tcos + up[1]*tsin + vstep[1] * (len*tdegree);
p->org[2] = start[2] + right[2]*tcos + up[2]*tsin + vstep[2] * (len*tdegree)*50;
tcos = cos(len*tdegree)*ptype->spawnvel;
tsin = sin(len*tdegree)*ptype->spawnvel;
p->vel[0] = vec[0]*veladd+crandom()*randvel + right[0]*tcos + up[0]*tsin;
p->vel[1] = vec[1]*veladd+crandom()*randvel + right[1]*tcos + up[1]*tsin;
p->vel[2] = vec[2]*veladd+crandom()*randvelvert + right[2]*tcos + up[2]*tsin;
}
break;
case SM_DISTBALL:
{
float rdist;
rdist = ptype->spawnparam2 - crandom()*(1-(crandom() * ptype->spawnparam1));
// this is a strange spawntype, which is based on the fact that
// crandom()*crandom() provides something similar to an exponential
// probability curve
p->org[0] = crandom();
p->org[1] = crandom();
p->org[2] = crandom();
VectorNormalize(p->org);
VectorScale(p->org, rdist, p->org);
p->vel[0] = vec[0]*veladd+crandom()*randvel + p->org[0]*ptype->spawnvel;
p->vel[1] = vec[1]*veladd+crandom()*randvel + p->org[1]*ptype->spawnvel;
p->vel[2] = vec[2]*veladd+crandom()*randvelvert + p->org[2]*ptype->spawnvelvert;
p->org[0] = p->org[0]*ptype->areaspread + start[0];
p->org[1] = p->org[1]*ptype->areaspread + start[1];
p->org[2] = p->org[2]*ptype->areaspreadvert + start[2];
}
break;
default:
p->org[0] = crandom();
p->org[1] = crandom();
p->org[2] = crandom();
p->vel[0] = vec[0]*veladd+crandom()*randvel + p->org[0]*ptype->spawnvel;
p->vel[1] = vec[1]*veladd+crandom()*randvel + p->org[1]*ptype->spawnvel;
p->vel[2] = vec[2]*veladd+crandom()*randvelvert + p->org[2]*ptype->spawnvelvert;
p->org[0] = p->org[0]*ptype->areaspread + start[0];
p->org[1] = p->org[1]*ptype->areaspread + start[1];
p->org[2] = p->org[2]*ptype->areaspreadvert + start[2];
break;
}
if (ptype->orgadd)
{
p->org[0] += vec[0]*ptype->orgadd;
p->org[1] += vec[1]*ptype->orgadd;
p->org[2] += vec[2]*ptype->orgadd;
}
VectorAdd(p->org, ptype->orgbias, p->org);
}
VectorAdd (start, vstep, start);
if (ptype->countrand)
{
float rstep = frandom() / ptype->countrand;
VectorMA(start, rstep, vec, start);
step += rstep;
}
p->die = particletime + ptype->die - p->die;
}
if (ts)
{
ts->state1.lastdist = len;
// update beamseg list
if (ptype->looks.type == PT_BEAM)
{
if (b)
{
if (ptype->beams)
{
if (ts->lastbeam)
{
b->next = ts->lastbeam->next;
ts->lastbeam->next = bfirst;
ts->lastbeam->flags &= ~BS_LASTSEG;
}
else
{
b->next = ptype->beams;
ptype->beams = bfirst;
}
}
else
{
ptype->beams = bfirst;
b->next = NULL;
}
b->flags |= BS_LASTSEG;
ts->lastbeam = b;
}
if ((!free_particles || !free_beams) && ts->lastbeam)
{
ts->lastbeam->flags &= ~BS_LASTSEG;
ts->lastbeam->flags |= BS_NODRAW;
ts->lastbeam = NULL;
}
}
}
else if (ptype->looks.type == PT_BEAM)
{
if (b)
{
b->flags |= BS_NODRAW;
b->next = ptype->beams;
ptype->beams = bfirst;
}
}
// maintain run list
if (!(ptype->state & PS_INRUNLIST))
{
ptype->nexttorun = part_run_list;
part_run_list = ptype;
ptype->state |= PS_INRUNLIST;
}
return;
}
static int PScript_ParticleTrail (vec3_t startpos, vec3_t end, int type, int dlkey, trailstate_t **tsk)
{
part_type_t *ptype = &part_type[type];
// TODO: fallback particle system won't have a decent trailstate which will mess up
// high fps trails
if (type >= FALLBACKBIAS && fallback)
return fallback->ParticleTrail(startpos, end, type-FALLBACKBIAS, dlkey, NULL);
if (type < 0 || type >= numparticletypes)
return 1; //bad value
if (!ptype->loaded)
return 1;
// inwater check, switch only once
if (r_part_contentswitch.ival && ptype->inwater >= 0 && cl.worldmodel)
{
int cont;
cont = cl.worldmodel->funcs.PointContents(cl.worldmodel, NULL, startpos);
if (cont & FTECONTENTS_FLUID)
ptype = &part_type[ptype->inwater];
}
P_ParticleTrailDraw (startpos, end, ptype, tsk, dlkey);
return 0;
}
static void PScript_ParticleTrailIndex (vec3_t start, vec3_t end, int color, int crnd, trailstate_t **tsk)
{
part_type[pe_defaulttrail].colorindex = color;
part_type[pe_defaulttrail].colorrand = crnd;
P_ParticleTrail(start, end, pe_defaulttrail, 0, tsk);
}
static vec3_t pright, pup;
static float pframetime;
static void GL_DrawTexturedParticle(int count, particle_t **plist, plooks_t *type)
{
particle_t *p;
float x,y;
float scale;
while (count--)
{
p = *plist++;
if (pscriptmesh.numvertexes >= BUFFERVERTS-4)
{
pscriptmesh.numindexes = pscriptmesh.numvertexes/4*6;
BE_DrawMesh_Single(type->shader, &pscriptmesh, NULL, &type->shader->defaulttextures, 0);
pscriptmesh.numvertexes = 0;
}
if (type->scalefactor == 1)
scale = p->scale*0.25;
else
{
scale = (p->org[0] - r_origin[0])*vpn[0] + (p->org[1] - r_origin[1])*vpn[1]
+ (p->org[2] - r_origin[2])*vpn[2];
scale = (scale*p->scale)*(type->invscalefactor) + p->scale * (type->scalefactor*250);
if (scale < 20)
scale = 0.25;
else
scale = 0.25 + scale * 0.001;
}
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+0]);
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+1]);
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+2]);
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+3]);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+0], p->s1, p->t1);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+1], p->s1, p->t2);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+2], p->s2, p->t2);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+3], p->s2, p->t1);
if (p->angle)
{
x = sin(p->angle)*scale;
y = cos(p->angle)*scale;
pscriptverts[pscriptmesh.numvertexes+0][0] = p->org[0] - x*pright[0] - y*pup[0];
pscriptverts[pscriptmesh.numvertexes+0][1] = p->org[1] - x*pright[1] - y*pup[1];
pscriptverts[pscriptmesh.numvertexes+0][2] = p->org[2] - x*pright[2] - y*pup[2];
pscriptverts[pscriptmesh.numvertexes+1][0] = p->org[0] - y*pright[0] + x*pup[0];
pscriptverts[pscriptmesh.numvertexes+1][1] = p->org[1] - y*pright[1] + x*pup[1];
pscriptverts[pscriptmesh.numvertexes+1][2] = p->org[2] - y*pright[2] + x*pup[2];
pscriptverts[pscriptmesh.numvertexes+2][0] = p->org[0] + x*pright[0] + y*pup[0];
pscriptverts[pscriptmesh.numvertexes+2][1] = p->org[1] + x*pright[1] + y*pup[1];
pscriptverts[pscriptmesh.numvertexes+2][2] = p->org[2] + x*pright[2] + y*pup[2];
pscriptverts[pscriptmesh.numvertexes+3][0] = p->org[0] + y*pright[0] - x*pup[0];
pscriptverts[pscriptmesh.numvertexes+3][1] = p->org[1] + y*pright[1] - x*pup[1];
pscriptverts[pscriptmesh.numvertexes+3][2] = p->org[2] + y*pright[2] - x*pup[2];
}
else
{
VectorMA(p->org, -scale, pup, pscriptverts[pscriptmesh.numvertexes+0]);
VectorMA(p->org, -scale, pright, pscriptverts[pscriptmesh.numvertexes+1]);
VectorMA(p->org, scale, pup, pscriptverts[pscriptmesh.numvertexes+2]);
VectorMA(p->org, scale, pright, pscriptverts[pscriptmesh.numvertexes+3]);
}
pscriptmesh.numvertexes += 4;
}
if (pscriptmesh.numvertexes)
{
pscriptmesh.numindexes = pscriptmesh.numvertexes/4*6;
BE_DrawMesh_Single(type->shader, &pscriptmesh, NULL, &type->shader->defaulttextures, 0);
pscriptmesh.numvertexes = 0;
}
}
static void GL_DrawTrifanParticle(int count, particle_t **plist, plooks_t *type)
{
particle_t *p;
vec3_t v, cr, o2;
float scale;
while (count--)
{
p = *plist++;
if (pscripttmesh.numvertexes >= BUFFERVERTS-3)
{
pscripttmesh.numindexes = pscripttmesh.numvertexes;
BE_DrawMesh_Single(type->shader, &pscripttmesh, NULL, &type->shader->defaulttextures, 0);
pscripttmesh.numvertexes = 0;
}
scale = (p->org[0] - r_origin[0])*vpn[0] + (p->org[1] - r_origin[1])*vpn[1]
+ (p->org[2] - r_origin[2])*vpn[2];
scale = (scale*p->scale)*(type->invscalefactor) + p->scale * (type->scalefactor*250);
if (scale < 20)
scale = 0.05;
else
scale = 0.05 + scale * 0.0001;
Vector4Copy(p->rgba, pscriptcolours[pscripttmesh.numvertexes+0]);
Vector4Copy(p->rgba, pscriptcolours[pscripttmesh.numvertexes+1]);
Vector4Copy(p->rgba, pscriptcolours[pscripttmesh.numvertexes+2]);
Vector2Set(pscripttexcoords[pscripttmesh.numvertexes+0], p->s1, p->t1);
Vector2Set(pscripttexcoords[pscripttmesh.numvertexes+1], p->s1, p->t2);
Vector2Set(pscripttexcoords[pscripttmesh.numvertexes+2], p->s2, p->t1);
VectorMA(p->org, -scale, p->vel, o2);
VectorSubtract(r_refdef.vieworg, o2, v);
CrossProduct(v, p->vel, cr);
VectorNormalize(cr);
VectorCopy(p->org, pscriptverts[pscripttmesh.numvertexes+0]);
VectorMA(o2, -p->scale, cr, pscriptverts[pscripttmesh.numvertexes+1]);
VectorMA(o2, p->scale, cr, pscriptverts[pscripttmesh.numvertexes+2]);
pscripttmesh.numvertexes += 3;
}
if (pscripttmesh.numvertexes)
{
pscripttmesh.numindexes = pscripttmesh.numvertexes;
BE_DrawMesh_Single(type->shader, &pscripttmesh, NULL, &type->shader->defaulttextures, 0);
pscripttmesh.numvertexes = 0;
}
}
static void R_AddLineSparkParticle(int count, particle_t **plist, plooks_t *type)
{
/*
particle_t *p;
while (count--)
{
p = *plist++;
if (cl_numstrisvert+2 > cl_maxstrisvert)
{
cl_maxstrisvert+=64*2;
cl_strisvertv = BZ_Realloc(cl_strisvertv, sizeof(*cl_strisvertv)*cl_maxstrisvert);
cl_strisvertt = BZ_Realloc(cl_strisvertt, sizeof(*cl_strisvertt)*cl_maxstrisvert);
cl_strisvertc = BZ_Realloc(cl_strisvertc, sizeof(*cl_strisvertc)*cl_maxstrisvert);
}
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+0]);
VectorCopy(p->rgba, cl_strisvertc[cl_numstrisvert+1]);
cl_strisvertc[cl_numstrisvert+1][3] = 0;
Vector2Set(cl_strisvertt[cl_numstrisvert+0], p->s1, p->t1);
Vector2Set(cl_strisvertt[cl_numstrisvert+1], p->s2, p->t2);
VectorCopy(p->org, cl_strisvertv[cl_numstrisvert+0]);
VectorMA(p->org, -1/10, p->vel, cl_strisvertv[cl_numstrisvert+1]);
if (cl_numstrisidx+2 > cl_maxstrisidx)
{
cl_maxstrisidx += 64*2;
cl_strisidx = BZ_Realloc(cl_strisidx, sizeof(*cl_strisidx)*cl_maxstrisidx);
}
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 1;
cl_numstrisvert += 2;
t->numvert += 2;
t->numidx += 2;
}
*/
}
static void R_AddTSparkParticle(scenetris_t *t, particle_t *p, plooks_t *type)
{
vec3_t v, cr, o2;
float scale;
if (cl_numstrisvert+4 > cl_maxstrisvert)
{
cl_maxstrisvert+=64*4;
cl_strisvertv = BZ_Realloc(cl_strisvertv, sizeof(*cl_strisvertv)*cl_maxstrisvert);
cl_strisvertt = BZ_Realloc(cl_strisvertt, sizeof(*cl_strisvertt)*cl_maxstrisvert);
cl_strisvertc = BZ_Realloc(cl_strisvertc, sizeof(*cl_strisvertc)*cl_maxstrisvert);
}
if (type->scalefactor == 1)
scale = p->scale*0.25;
else
{
scale = (p->org[0] - r_origin[0])*vpn[0] + (p->org[1] - r_origin[1])*vpn[1]
+ (p->org[2] - r_origin[2])*vpn[2];
scale = (scale*p->scale)*(type->invscalefactor) + p->scale * (type->scalefactor*250);
if (scale < 20)
scale = 0.25;
else
scale = 0.25 + scale * 0.001;
}
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+0]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+1]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+2]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+3]);
Vector2Set(cl_strisvertt[cl_numstrisvert+0], p->s1, p->t1);
Vector2Set(cl_strisvertt[cl_numstrisvert+1], p->s1, p->t2);
Vector2Set(cl_strisvertt[cl_numstrisvert+2], p->s2, p->t2);
Vector2Set(cl_strisvertt[cl_numstrisvert+3], p->s2, p->t1);
if (type->stretch)
{
VectorMA(p->org, type->stretch, p->vel, o2);
VectorMA(p->org, -type->stretch, p->vel, v);
VectorSubtract(r_refdef.vieworg, v, v);
}
else
{
VectorMA(p->org, 0.1, p->vel, o2);
VectorSubtract(r_refdef.vieworg, p->org, v);
}
CrossProduct(v, p->vel, cr);
VectorNormalize(cr);
VectorMA(p->org, -p->scale/2, cr, cl_strisvertv[cl_numstrisvert+0]);
VectorMA(p->org, p->scale/2, cr, cl_strisvertv[cl_numstrisvert+1]);
VectorSubtract(r_refdef.vieworg, o2, v);
CrossProduct(v, p->vel, cr);
VectorNormalize(cr);
VectorMA(o2, p->scale/2, cr, cl_strisvertv[cl_numstrisvert+2]);
VectorMA(o2, -p->scale/2, cr, cl_strisvertv[cl_numstrisvert+3]);
if (cl_numstrisidx+6 > cl_maxstrisidx)
{
cl_maxstrisidx += 64*6;
cl_strisidx = BZ_Realloc(cl_strisidx, sizeof(*cl_strisidx)*cl_maxstrisidx);
}
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 1;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 2;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 2;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 3;
cl_numstrisvert += 4;
t->numvert += 4;
t->numidx += 6;
}
static void GL_DrawTexturedSparkParticle(int count, particle_t **plist, plooks_t *type)
{
particle_t *p;
vec3_t v, cr, o2;
while (count--)
{
p = *plist++;
if (pscriptmesh.numvertexes >= BUFFERVERTS-4)
{
pscriptmesh.numindexes = pscriptmesh.numvertexes/4*6;
BE_DrawMesh_Single(type->shader, &pscriptmesh, NULL, &type->shader->defaulttextures, 0);
pscriptmesh.numvertexes = 0;
}
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+0]);
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+1]);
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+2]);
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+3]);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+0], p->s1, p->t1);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+1], p->s1, p->t2);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+2], p->s2, p->t2);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+3], p->s2, p->t1);
if (type->stretch)
{
VectorMA(p->org, type->stretch, p->vel, o2);
VectorMA(p->org, -type->stretch, p->vel, v);
VectorSubtract(r_refdef.vieworg, v, v);
}
else
{
VectorMA(p->org, 0.1, p->vel, o2);
VectorSubtract(r_refdef.vieworg, p->org, v);
}
CrossProduct(v, p->vel, cr);
VectorNormalize(cr);
VectorMA(p->org, -p->scale/2, cr, pscriptverts[pscriptmesh.numvertexes+0]);
VectorMA(p->org, p->scale/2, cr, pscriptverts[pscriptmesh.numvertexes+1]);
VectorSubtract(r_refdef.vieworg, o2, v);
CrossProduct(v, p->vel, cr);
VectorNormalize(cr);
VectorMA(o2, p->scale/2, cr, pscriptverts[pscriptmesh.numvertexes+2]);
VectorMA(o2, -p->scale/2, cr, pscriptverts[pscriptmesh.numvertexes+3]);
pscriptmesh.numvertexes += 4;
}
if (pscriptmesh.numvertexes)
{
pscriptmesh.numindexes = pscriptmesh.numvertexes/4*6;
BE_DrawMesh_Single(type->shader, &pscriptmesh, NULL, &type->shader->defaulttextures, 0);
pscriptmesh.numvertexes = 0;
}
}
static void GL_DrawParticleBeam(int count, beamseg_t **blist, plooks_t *type)
{
beamseg_t *b;
vec3_t v;
vec3_t cr;
beamseg_t *c;
particle_t *p;
particle_t *q;
float ts;
while(count--)
{
b = *blist++;
if (pscriptmesh.numvertexes >= BUFFERVERTS-4)
{
pscriptmesh.numindexes = pscriptmesh.numvertexes/4*6;
BE_DrawMesh_Single(type->shader, &pscriptmesh, NULL, &type->shader->defaulttextures, 0);
pscriptmesh.numvertexes = 0;
}
c = b->next;
q = c->p;
if (!q)
continue;
p = b->p;
// q->rgba[3] = 1;
// p->rgba[3] = 1;
VectorSubtract(r_refdef.vieworg, q->org, v);
VectorNormalize(v);
CrossProduct(c->dir, v, cr);
VectorNormalize(cr);
ts = c->texture_s*q->angle + particletime*q->rotationspeed;
Vector4Copy(q->rgba, pscriptcolours[pscriptmesh.numvertexes+0]);
Vector4Copy(q->rgba, pscriptcolours[pscriptmesh.numvertexes+1]);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+0], ts, p->t1);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+1], ts, p->t2);
VectorMA(q->org, -q->scale, cr, pscriptverts[pscriptmesh.numvertexes+0]);
VectorMA(q->org, q->scale, cr, pscriptverts[pscriptmesh.numvertexes+1]);
VectorSubtract(r_refdef.vieworg, p->org, v);
VectorNormalize(v);
CrossProduct(b->dir, v, cr); // replace with old p->dir?
VectorNormalize(cr);
ts = b->texture_s*p->angle + particletime*p->rotationspeed;
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+2]);
Vector4Copy(p->rgba, pscriptcolours[pscriptmesh.numvertexes+3]);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+2], ts, p->t2);
Vector2Set(pscripttexcoords[pscriptmesh.numvertexes+3], ts, p->t1);
VectorMA(p->org, p->scale, cr, pscriptverts[pscriptmesh.numvertexes+2]);
VectorMA(p->org, -p->scale, cr, pscriptverts[pscriptmesh.numvertexes+3]);
pscriptmesh.numvertexes += 4;
}
if (pscriptmesh.numvertexes)
{
pscriptmesh.numindexes = pscriptmesh.numvertexes/4*6;
BE_DrawMesh_Single(type->shader, &pscriptmesh, NULL, &type->shader->defaulttextures, 0);
pscriptmesh.numvertexes = 0;
}
}
static void R_AddClippedDecal(scenetris_t *t, clippeddecal_t *d, plooks_t *type)
{
if (cl_numstrisvert+4 > cl_maxstrisvert)
{
cl_maxstrisvert+=64*4;
cl_strisvertv = BZ_Realloc(cl_strisvertv, sizeof(*cl_strisvertv)*cl_maxstrisvert);
cl_strisvertt = BZ_Realloc(cl_strisvertt, sizeof(*cl_strisvertt)*cl_maxstrisvert);
cl_strisvertc = BZ_Realloc(cl_strisvertc, sizeof(*cl_strisvertc)*cl_maxstrisvert);
}
Vector4Copy(d->rgba, cl_strisvertc[cl_numstrisvert+0]);
Vector4Copy(d->rgba, cl_strisvertc[cl_numstrisvert+1]);
Vector4Copy(d->rgba, cl_strisvertc[cl_numstrisvert+2]);
Vector2Copy(d->texcoords[0], cl_strisvertt[cl_numstrisvert+0]);
Vector2Copy(d->texcoords[1], cl_strisvertt[cl_numstrisvert+1]);
Vector2Copy(d->texcoords[2], cl_strisvertt[cl_numstrisvert+2]);
VectorCopy(d->vertex[0], cl_strisvertv[cl_numstrisvert+0]);
VectorCopy(d->vertex[1], cl_strisvertv[cl_numstrisvert+1]);
VectorCopy(d->vertex[2], cl_strisvertv[cl_numstrisvert+2]);
if (cl_numstrisidx+3 > cl_maxstrisidx)
{
cl_maxstrisidx += 64*3;
cl_strisidx = BZ_Realloc(cl_strisidx, sizeof(*cl_strisidx)*cl_maxstrisidx);
}
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 1;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 2;
cl_numstrisvert += 3;
t->numvert += 3;
t->numidx += 3;
}
static void R_AddUnclippedDecal(scenetris_t *t, particle_t *p, plooks_t *type)
{
float x, y;
vec3_t sdir, tdir;
if (cl_numstrisvert+4 > cl_maxstrisvert)
{
cl_maxstrisvert+=64*4;
cl_strisvertv = BZ_Realloc(cl_strisvertv, sizeof(*cl_strisvertv)*cl_maxstrisvert);
cl_strisvertt = BZ_Realloc(cl_strisvertt, sizeof(*cl_strisvertt)*cl_maxstrisvert);
cl_strisvertc = BZ_Realloc(cl_strisvertc, sizeof(*cl_strisvertc)*cl_maxstrisvert);
}
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+0]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+1]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+2]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+3]);
Vector2Set(cl_strisvertt[cl_numstrisvert+0], p->s1, p->t1);
Vector2Set(cl_strisvertt[cl_numstrisvert+1], p->s1, p->t2);
Vector2Set(cl_strisvertt[cl_numstrisvert+2], p->s2, p->t2);
Vector2Set(cl_strisvertt[cl_numstrisvert+3], p->s2, p->t1);
// if (p->vel[1] == 1)
{
VectorSet(sdir, 1, 0, 0);
VectorSet(tdir, 0, 1, 0);
}
if (p->angle)
{
x = sin(p->angle)*p->scale;
y = cos(p->angle)*p->scale;
cl_strisvertv[cl_numstrisvert+0][0] = p->org[0] - x*sdir[0] - y*tdir[0];
cl_strisvertv[cl_numstrisvert+0][1] = p->org[1] - x*sdir[1] - y*tdir[1];
cl_strisvertv[cl_numstrisvert+0][2] = p->org[2] - x*sdir[2] - y*tdir[2];
cl_strisvertv[cl_numstrisvert+1][0] = p->org[0] - y*sdir[0] + x*tdir[0];
cl_strisvertv[cl_numstrisvert+1][1] = p->org[1] - y*sdir[1] + x*tdir[1];
cl_strisvertv[cl_numstrisvert+1][2] = p->org[2] - y*sdir[2] + x*tdir[2];
cl_strisvertv[cl_numstrisvert+2][0] = p->org[0] + x*sdir[0] + y*tdir[0];
cl_strisvertv[cl_numstrisvert+2][1] = p->org[1] + x*sdir[1] + y*tdir[1];
cl_strisvertv[cl_numstrisvert+2][2] = p->org[2] + x*sdir[2] + y*tdir[2];
cl_strisvertv[cl_numstrisvert+3][0] = p->org[0] + y*sdir[0] - x*tdir[0];
cl_strisvertv[cl_numstrisvert+3][1] = p->org[1] + y*sdir[1] - x*tdir[1];
cl_strisvertv[cl_numstrisvert+3][2] = p->org[2] + y*sdir[2] - x*tdir[2];
}
else
{
VectorMA(p->org, -p->scale, tdir, cl_strisvertv[cl_numstrisvert+0]);
VectorMA(p->org, -p->scale, sdir, cl_strisvertv[cl_numstrisvert+1]);
VectorMA(p->org, p->scale, tdir, cl_strisvertv[cl_numstrisvert+2]);
VectorMA(p->org, p->scale, sdir, cl_strisvertv[cl_numstrisvert+3]);
}
if (cl_numstrisidx+6 > cl_maxstrisidx)
{
cl_maxstrisidx += 64*6;
cl_strisidx = BZ_Realloc(cl_strisidx, sizeof(*cl_strisidx)*cl_maxstrisidx);
}
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 1;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 2;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 2;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 3;
cl_numstrisvert += 4;
t->numvert += 4;
t->numidx += 6;
}
static void R_AddTexturedParticle(scenetris_t *t, particle_t *p, plooks_t *type)
{
float scale, x, y;
if (cl_numstrisvert+4 > cl_maxstrisvert)
{
cl_maxstrisvert+=64*4;
cl_strisvertv = BZ_Realloc(cl_strisvertv, sizeof(*cl_strisvertv)*cl_maxstrisvert);
cl_strisvertt = BZ_Realloc(cl_strisvertt, sizeof(*cl_strisvertt)*cl_maxstrisvert);
cl_strisvertc = BZ_Realloc(cl_strisvertc, sizeof(*cl_strisvertc)*cl_maxstrisvert);
}
if (type->scalefactor == 1)
scale = p->scale*0.25;
else
{
scale = (p->org[0] - r_origin[0])*vpn[0] + (p->org[1] - r_origin[1])*vpn[1]
+ (p->org[2] - r_origin[2])*vpn[2];
scale = (scale*p->scale)*(type->invscalefactor) + p->scale * (type->scalefactor*250);
if (scale < 20)
scale = 0.25;
else
scale = 0.25 + scale * 0.001;
}
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+0]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+1]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+2]);
Vector4Copy(p->rgba, cl_strisvertc[cl_numstrisvert+3]);
Vector2Set(cl_strisvertt[cl_numstrisvert+0], p->s1, p->t1);
Vector2Set(cl_strisvertt[cl_numstrisvert+1], p->s1, p->t2);
Vector2Set(cl_strisvertt[cl_numstrisvert+2], p->s2, p->t2);
Vector2Set(cl_strisvertt[cl_numstrisvert+3], p->s2, p->t1);
if (p->angle)
{
x = sin(p->angle)*scale;
y = cos(p->angle)*scale;
cl_strisvertv[cl_numstrisvert+0][0] = p->org[0] - x*pright[0] - y*pup[0];
cl_strisvertv[cl_numstrisvert+0][1] = p->org[1] - x*pright[1] - y*pup[1];
cl_strisvertv[cl_numstrisvert+0][2] = p->org[2] - x*pright[2] - y*pup[2];
cl_strisvertv[cl_numstrisvert+1][0] = p->org[0] - y*pright[0] + x*pup[0];
cl_strisvertv[cl_numstrisvert+1][1] = p->org[1] - y*pright[1] + x*pup[1];
cl_strisvertv[cl_numstrisvert+1][2] = p->org[2] - y*pright[2] + x*pup[2];
cl_strisvertv[cl_numstrisvert+2][0] = p->org[0] + x*pright[0] + y*pup[0];
cl_strisvertv[cl_numstrisvert+2][1] = p->org[1] + x*pright[1] + y*pup[1];
cl_strisvertv[cl_numstrisvert+2][2] = p->org[2] + x*pright[2] + y*pup[2];
cl_strisvertv[cl_numstrisvert+3][0] = p->org[0] + y*pright[0] - x*pup[0];
cl_strisvertv[cl_numstrisvert+3][1] = p->org[1] + y*pright[1] - x*pup[1];
cl_strisvertv[cl_numstrisvert+3][2] = p->org[2] + y*pright[2] - x*pup[2];
}
else
{
VectorMA(p->org, -scale, pup, cl_strisvertv[cl_numstrisvert+0]);
VectorMA(p->org, -scale, pright, cl_strisvertv[cl_numstrisvert+1]);
VectorMA(p->org, scale, pup, cl_strisvertv[cl_numstrisvert+2]);
VectorMA(p->org, scale, pright, cl_strisvertv[cl_numstrisvert+3]);
}
if (cl_numstrisidx+6 > cl_maxstrisidx)
{
cl_maxstrisidx += 64*6;
cl_strisidx = BZ_Realloc(cl_strisidx, sizeof(*cl_strisidx)*cl_maxstrisidx);
}
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 1;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 2;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 0;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 2;
cl_strisidx[cl_numstrisidx++] = (cl_numstrisvert - t->firstvert) + 3;
cl_numstrisvert += 4;
t->numvert += 4;
t->numidx += 6;
}
static void PScript_DrawParticleTypes (void)
{
void (*sparklineparticles)(int count, particle_t **plist, plooks_t *type)=R_AddLineSparkParticle;
void (*sparkfanparticles)(int count, particle_t **plist, plooks_t *type)=GL_DrawTrifanParticle;
void (*sparktexturedparticles)(int count, particle_t **plist, plooks_t *type)=GL_DrawTexturedSparkParticle;
qboolean (*tr) (vec3_t start, vec3_t end, vec3_t impact, vec3_t normal);
void *pdraw, *bdraw;
void (*tdraw)(scenetris_t *t, particle_t *p, plooks_t *type);
vec3_t oldorg;
vec3_t stop, normal;
part_type_t *type, *lastvalidtype;
particle_t *p, *kill;
clippeddecal_t *d, *dkill;
ramp_t *ramp;
float grav;
vec3_t friction;
scenetris_t *scenetri;
float dist;
particle_t *kill_list, *kill_first; //the kill list is to stop particles from being freed and reused whilst still in this loop
//which is bad because beams need to find out when particles died. Reuse can do wierd things.
//remember that they're not drawn instantly either.
beamseg_t *b, *bkill;
int traces=r_particle_tracelimit.ival;
int rampind;
static float oldtime;
RSpeedMark();
if (r_plooksdirty)
{
int i, j;
for (i = 0; i < numparticletypes; i++)
{
//set the fallback
part_type[i].slooks = &part_type[i].looks;
for (j = i-1; j-- > 0;)
{
if (!memcmp(&part_type[i].looks, &part_type[j].looks, sizeof(plooks_t)))
{
part_type[i].slooks = part_type[j].slooks;
break;
}
}
}
r_plooksdirty = false;
CL_RegisterParticles();
}
#if 1
pframetime = cl.time - oldtime;
if (pframetime < 0)
pframetime = 0;
oldtime = cl.time;
#else
pframetime = host_frametime;
if (cl.paused || r_secondaryview || r_refdef.recurse)
pframetime = 0;
#endif
VectorScale (vup, 1.5, pup);
VectorScale (vright, 1.5, pright);
#ifdef Q2BSPS
if (cl.worldmodel->fromgame == fg_quake2 || cl.worldmodel->fromgame == fg_quake3)
tr = Q2TraceLineN;
else
#endif
tr = TraceLineN;
kill_list = kill_first = NULL;
if (r_part_sparks_textured.ival < 0)
sparktexturedparticles = NULL;
else if (!r_part_sparks_textured.ival)
sparktexturedparticles = sparklineparticles;
if (r_part_sparks_trifan.ival < 0)
sparkfanparticles = NULL;
else if (!r_part_sparks_trifan.ival)
sparkfanparticles = sparklineparticles;
if (r_part_sparks.ival < 0)
sparklineparticles = NULL;
else if (!r_part_sparks.ival)
{
sparktexturedparticles = NULL;
sparkfanparticles = NULL;
sparklineparticles = NULL;
}
for (type = part_run_list, lastvalidtype = NULL; type != NULL; type = type->nexttorun)
{
if (type->clippeddecals)
{
if (cl_numstris && cl_stris[cl_numstris-1].shader == type->looks.shader && cl_stris[cl_numstris-1].flags == (BEF_NODLIGHT|BEF_NOSHADOWS))
scenetri = &cl_stris[cl_numstris-1];
else
{
if (cl_numstris == cl_maxstris)
{
cl_maxstris+=8;
cl_stris = BZ_Realloc(cl_stris, sizeof(*cl_stris)*cl_maxstris);
}
scenetri = &cl_stris[cl_numstris++];
scenetri->shader = type->looks.shader;
scenetri->flags = BEF_NODLIGHT|BEF_NOSHADOWS;
scenetri->firstidx = cl_numstrisidx;
scenetri->firstvert = cl_numstrisvert;
scenetri->numvert = 0;
scenetri->numidx = 0;
}
for ( ;; )
{
dkill = type->clippeddecals;
if (dkill && dkill->die < particletime)
{
type->clippeddecals = dkill->next;
dkill->next = free_decals;
free_decals = dkill;
continue;
}
break;
}
for (d=type->clippeddecals ; d ; d=d->next)
{
for ( ;; )
{
dkill = d->next;
if (dkill && dkill->die < particletime)
{
d->next = dkill->next;
dkill->next = free_decals;
free_decals = dkill;
continue;
}
break;
}
switch (type->rampmode)
{
case RAMP_NEAREST:
rampind = (int)(type->rampindexes * (type->die - (d->die - particletime)) / type->die);
if (rampind >= type->rampindexes)
rampind = type->rampindexes - 1;
ramp = type->ramp + rampind;
VectorCopy(ramp->rgb, d->rgba);
d->rgba[3] = ramp->alpha;
break;
case RAMP_LERP:
{
float frac = (type->rampindexes * (type->die - (d->die - particletime)) / type->die);
int s1, s2;
s1 = min(type->rampindexes-1, frac);
s2 = min(type->rampindexes-1, s1+1);
frac -= s1;
VectorInterpolate(type->ramp[s1].rgb, frac, type->ramp[s2].rgb, d->rgba);
FloatInterpolate(type->ramp[s1].alpha, frac, type->ramp[s2].alpha, d->rgba[3]);
}
break;
case RAMP_DELTA: //particle ramps
ramp = type->ramp + (int)(type->rampindexes * (type->die - (d->die - particletime)) / type->die);
VectorMA(d->rgba, pframetime, ramp->rgb, d->rgba);
d->rgba[3] -= pframetime*ramp->alpha;
break;
case RAMP_NONE: //particle changes acording to it's preset properties.
if (particletime < (d->die-type->die+type->rgbchangetime))
{
d->rgba[0] += pframetime*type->rgbchange[0];
d->rgba[1] += pframetime*type->rgbchange[1];
d->rgba[2] += pframetime*type->rgbchange[2];
}
d->rgba[3] += pframetime*type->alphachange;
}
R_AddClippedDecal(scenetri, d, type->slooks);
}
}
bdraw = NULL;
pdraw = NULL;
tdraw = NULL;
// set drawing methods by type and cvars and hope branch
// prediction takes care of the rest
switch(type->looks.type)
{
case PT_BEAM:
if (r_part_beams.ival <= 0)
bdraw = NULL;
else
bdraw = GL_DrawParticleBeam;
break;
case PT_CDECAL:
break;
case PT_UDECAL:
tdraw = R_AddUnclippedDecal;
break;
case PT_NORMAL:
pdraw = GL_DrawTexturedParticle;
tdraw = R_AddTexturedParticle;
break;
case PT_SPARK:
pdraw = sparklineparticles;
break;
case PT_SPARKFAN:
pdraw = sparkfanparticles;
break;
case PT_TEXTUREDSPARK:
pdraw = sparktexturedparticles;
tdraw = R_AddTSparkParticle;
break;
}
if (!tdraw || type->looks.shader->sort == SHADER_SORT_BLEND)
scenetri = NULL;
else if (cl_numstris && cl_stris[cl_numstris-1].shader == type->looks.shader && cl_stris[cl_numstris-1].flags == (BEF_NODLIGHT|BEF_NOSHADOWS))
scenetri = &cl_stris[cl_numstris-1];
else
{
if (cl_numstris == cl_maxstris)
{
cl_maxstris+=8;
cl_stris = BZ_Realloc(cl_stris, sizeof(*cl_stris)*cl_maxstris);
}
scenetri = &cl_stris[cl_numstris++];
scenetri->shader = type->looks.shader;
scenetri->firstidx = cl_numstrisidx;
scenetri->firstvert = cl_numstrisvert;
scenetri->flags = BEF_NODLIGHT|BEF_NOSHADOWS;
scenetri->numvert = 0;
scenetri->numidx = 0;
}
if (!type->die)
{
while ((p=type->particles))
{
if (scenetri)
{
tdraw(scenetri, p, type->slooks);
}
else if (pdraw)
RQ_AddDistReorder(pdraw, p, type->slooks, p->org);
// make sure emitter runs at least once
if (type->emit >= 0 && type->emitstart <= 0)
P_RunParticleEffectType(p->org, p->vel, 1, type->emit);
// make sure stain effect runs
if (type->stainonimpact && r_bloodstains.ival)
{
if (traces-->0&&tr(oldorg, p->org, stop, normal))
{
Surf_AddStain(stop, (p->rgba[1]*-10+p->rgba[2]*-10),
(p->rgba[0]*-10+p->rgba[2]*-10),
(p->rgba[0]*-10+p->rgba[1]*-10),
30*p->rgba[3]*type->stainonimpact);
}
}
type->particles = p->next;
// p->next = free_particles;
// free_particles = p;
p->next = kill_list;
kill_list = p;
if (!kill_first) // branch here is probably faster than list traversal later
kill_first = p;
}
if (type->beams)
{
b = type->beams;
}
while ((b=type->beams) && (b->flags & BS_DEAD))
{
type->beams = b->next;
b->next = free_beams;
free_beams = b;
}
while (b)
{
if (!(b->flags & BS_NODRAW))
{
// no BS_NODRAW implies b->next != NULL
// BS_NODRAW should imply b->next == NULL or b->next->flags & BS_DEAD
VectorCopy(b->next->p->org, stop);
VectorCopy(b->p->org, oldorg);
VectorSubtract(stop, oldorg, b->next->dir);
VectorNormalize(b->next->dir);
if (bdraw)
{
VectorAdd(stop, oldorg, stop);
VectorScale(stop, 0.5, stop);
RQ_AddDistReorder(bdraw, b, type->slooks, stop);
}
}
// clean up dead entries ahead of current
for ( ;; )
{
bkill = b->next;
if (bkill && (bkill->flags & BS_DEAD))
{
b->next = bkill->next;
bkill->next = free_beams;
free_beams = bkill;
continue;
}
break;
}
b->flags |= BS_DEAD;
b = b->next;
}
goto endtype;
}
//kill off early ones.
if (type->emittime < 0)
{
for ( ;; )
{
kill = type->particles;
if (kill && kill->die < particletime)
{
P_DelinkTrailstate(&kill->state.trailstate);
type->particles = kill->next;
kill->next = kill_list;
kill_list = kill;
if (!kill_first)
kill_first = kill;
continue;
}
break;
}
}
else
{
for ( ;; )
{
kill = type->particles;
if (kill && kill->die < particletime)
{
type->particles = kill->next;
kill->next = kill_list;
kill_list = kill;
if (!kill_first)
kill_first = kill;
continue;
}
break;
}
}
grav = type->gravity*pframetime;
friction[0] = 1 - type->friction[0]*pframetime;
friction[1] = 1 - type->friction[1]*pframetime;
friction[2] = 1 - type->friction[2]*pframetime;
for (p=type->particles ; p ; p=p->next)
{
if (type->emittime < 0)
{
for ( ;; )
{
kill = p->next;
if (kill && kill->die < particletime)
{
P_DelinkTrailstate(&kill->state.trailstate);
p->next = kill->next;
kill->next = kill_list;
kill_list = kill;
if (!kill_first)
kill_first = kill;
continue;
}
break;
}
}
else
{
for ( ;; )
{
kill = p->next;
if (kill && kill->die < particletime)
{
p->next = kill->next;
kill->next = kill_list;
kill_list = kill;
if (!kill_first)
kill_first = kill;
continue;
}
break;
}
}
VectorCopy(p->org, oldorg);
if (type->flags & PT_VELOCITY)
{
p->org[0] += p->vel[0]*pframetime;
p->org[1] += p->vel[1]*pframetime;
p->org[2] += p->vel[2]*pframetime;
if (type->flags & PT_FRICTION)
{
p->vel[0] *= friction[0];
p->vel[1] *= friction[1];
p->vel[2] *= friction[2];
}
p->vel[2] -= grav;
}
p->angle += p->rotationspeed*pframetime;
switch (type->rampmode)
{
case RAMP_NEAREST:
rampind = (int)(type->rampindexes * (type->die - (p->die - particletime)) / type->die);
if (rampind >= type->rampindexes)
rampind = type->rampindexes - 1;
ramp = type->ramp + rampind;
VectorCopy(ramp->rgb, p->rgba);
p->rgba[3] = ramp->alpha;
p->scale = ramp->scale;
break;
case RAMP_LERP:
{
float frac = (type->rampindexes * (type->die - (p->die - particletime)) / type->die);
int s1, s2;
s1 = min(type->rampindexes-1, frac);
s2 = min(type->rampindexes-1, s1+1);
frac -= s1;
VectorInterpolate(type->ramp[s1].rgb, frac, type->ramp[s2].rgb, p->rgba);
FloatInterpolate(type->ramp[s1].alpha, frac, type->ramp[s2].alpha, p->rgba[3]);
FloatInterpolate(type->ramp[s1].scale, frac, type->ramp[s2].scale, p->scale);
}
break;
case RAMP_DELTA: //particle ramps
rampind = (int)(type->rampindexes * (type->die - (p->die - particletime)) / type->die);
if (rampind >= type->rampindexes)
rampind = type->rampindexes - 1;
ramp = type->ramp + rampind;
VectorMA(p->rgba, pframetime, ramp->rgb, p->rgba);
p->rgba[3] -= pframetime*ramp->alpha;
p->scale += pframetime*ramp->scale;
break;
case RAMP_NONE: //particle changes acording to it's preset properties.
if (particletime < (p->die-type->die+type->rgbchangetime))
{
p->rgba[0] += pframetime*type->rgbchange[0];
p->rgba[1] += pframetime*type->rgbchange[1];
p->rgba[2] += pframetime*type->rgbchange[2];
}
p->rgba[3] += pframetime*type->alphachange;
p->scale += pframetime*type->scaledelta;
}
if (type->emit >= 0)
{
if (type->emittime < 0)
P_ParticleTrail(oldorg, p->org, type->emit, 0, &p->state.trailstate);
else if (p->state.nextemit < particletime)
{
p->state.nextemit = particletime + type->emittime + frandom()*type->emitrand;
P_RunParticleEffectType(p->org, p->vel, 1, type->emit);
}
}
if (type->cliptype>=0 && r_bouncysparks.ival)
{
if (traces-->0&&tr(oldorg, p->org, stop, normal))
{
if (type->stainonimpact && r_bloodstains.ival)
Surf_AddStain(stop, p->rgba[1]*-10+p->rgba[2]*-10,
p->rgba[0]*-10+p->rgba[2]*-10,
p->rgba[0]*-10+p->rgba[1]*-10,
30*p->rgba[3]);
if (part_type + type->cliptype == type)
{ //bounce
dist = DotProduct(p->vel, normal) * (-1-(rand()/(float)0x7fff)/2);
VectorMA(p->vel, dist, normal, p->vel);
VectorCopy(stop, p->org);
p->vel[0] *= type->clipbounce;
p->vel[1] *= type->clipbounce;
p->vel[2] *= type->clipbounce;
if (!*type->texname && Length(p->vel)<1000*pframetime && type->looks.type == PT_NORMAL)
{
p->die = -1;
continue;
}
}
else
{
p->die = -1;
VectorNormalize(p->vel);
if (type->clipbounce)
{
VectorScale(normal, type->clipbounce, normal);
P_RunParticleEffectType(stop, normal, type->clipcount/part_type[type->cliptype].count, type->cliptype);
}
else
P_RunParticleEffectType(stop, p->vel, type->clipcount/part_type[type->cliptype].count, type->cliptype);
continue;
}
}
}
else if (type->stainonimpact && r_bloodstains.ival)
{
if (traces-->0&&tr(oldorg, p->org, stop, normal))
{
if (type->stainonimpact < 0)
Surf_AddStain(stop, (p->rgba[0]*-1),
(p->rgba[1]*-1),
(p->rgba[2]*-1),
p->scale*-type->stainonimpact);
else
Surf_AddStain(stop, (p->rgba[1]*-10+p->rgba[2]*-10),
(p->rgba[0]*-10+p->rgba[2]*-10),
(p->rgba[0]*-10+p->rgba[1]*-10),
30*p->rgba[3]*type->stainonimpact);
p->die = -1;
continue;
}
}
if (scenetri)
{
tdraw(scenetri, p, type->slooks);
}
else if (pdraw)
RQ_AddDistReorder((void*)pdraw, p, type->slooks, p->org);
}
// beams are dealt with here
// kill early entries
for ( ;; )
{
bkill = type->beams;
if (bkill && (bkill->flags & BS_DEAD || bkill->p->die < particletime) && !(bkill->flags & BS_LASTSEG))
{
type->beams = bkill->next;
bkill->next = free_beams;
free_beams = bkill;
continue;
}
break;
}
b = type->beams;
if (b)
{
for ( ;; )
{
if (b->next)
{
// mark dead entries
if (b->flags & (BS_LASTSEG|BS_DEAD|BS_NODRAW))
{
// kill some more dead entries
for ( ;; )
{
bkill = b->next;
if (bkill && (bkill->flags & BS_DEAD) && !(bkill->flags & BS_LASTSEG))
{
b->next = bkill->next;
bkill->next = free_beams;
free_beams = bkill;
continue;
}
break;
}
if (!bkill) // have to check so we don't hit NULL->next
continue;
}
else
{
if (!(b->next->flags & BS_DEAD))
{
VectorCopy(b->next->p->org, stop);
VectorCopy(b->p->org, oldorg);
VectorSubtract(stop, oldorg, b->next->dir);
VectorNormalize(b->next->dir);
if (bdraw)
{
VectorAdd(stop, oldorg, stop);
VectorScale(stop, 0.5, stop);
RQ_AddDistReorder(bdraw, b, type->slooks, stop);
}
}
if (b->p->die < particletime)
b->flags |= BS_DEAD;
}
}
else
{
if (b->p->die < particletime) // end of the list check
b->flags |= BS_DEAD;
break;
}
if (b->p->die < particletime)
b->flags |= BS_DEAD;
b = b->next;
}
}
endtype:
// delete from run list if necessary
if (!type->particles && !type->beams && !type->clippeddecals)
{
if (!lastvalidtype)
part_run_list = type->nexttorun;
else
lastvalidtype->nexttorun = type->nexttorun;
type->state &= ~PS_INRUNLIST;
}
else
lastvalidtype = type;
}
RSpeedEnd(RSPEED_PARTICLES);
// lazy delete for particles is done here
if (kill_list)
{
kill_first->next = free_particles;
free_particles = kill_list;
}
particletime += pframetime;
}
/*
===============
R_DrawParticles
===============
*/
static void PScript_DrawParticles (void)
{
P_AddRainParticles();
PScript_DrawParticleTypes();
if (fallback)
fallback->DrawParticles();
}
particleengine_t pe_script =
{
"script",
"fte",
PScript_FindParticleType,
PScript_Query,
PScript_RunParticleEffectTypeString,
PScript_ParticleTrail,
PScript_RunParticleEffectState,
PScript_RunParticleWeather,
PScript_RunParticleCube,
PScript_RunParticleEffect,
PScript_RunParticleEffect2,
PScript_RunParticleEffect3,
PScript_RunParticleEffect4,
PScript_ParticleTrailIndex,
PScript_EmitSkyEffectTris,
PScript_InitParticles,
PScript_Shutdown,
PScript_DelinkTrailstate,
PScript_ClearParticles,
PScript_DrawParticles
};
#endif
#endif