2 Copyright (C) 1996-1997 Id Software, Inc.
4 This program is free software; you can redistribute it and/or
5 modify it under the terms of the GNU General Public License
6 as published by the Free Software Foundation; either version 2
7 of the License, or (at your option) any later version.
9 This program is distributed in the hope that it will be useful,
10 but WITHOUT ANY WARRANTY; without even the implied warranty of
11 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
13 See the GNU General Public License for more details.
15 You should have received a copy of the GNU General Public License
16 along with this program; if not, write to the Free Software
17 Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
23 #include "cl_collision.h"
26 dlight_t r_dlight[MAX_DLIGHTS];
29 cvar_t r_modellights = {CVAR_SAVE, "r_modellights", "4"};
30 cvar_t r_vismarklights = {0, "r_vismarklights", "1"};
31 cvar_t r_coronas = {CVAR_SAVE, "r_coronas", "1"};
32 cvar_t gl_flashblend = {CVAR_SAVE, "gl_flashblend", "1"};
34 static rtexture_t *lightcorona;
35 static rtexturepool_t *lighttexturepool;
37 void r_light_start(void)
41 qbyte pixels[32][32][4];
42 lighttexturepool = R_AllocTexturePool();
43 for (y = 0;y < 32;y++)
45 dy = (y - 15.5f) * (1.0f / 16.0f);
46 for (x = 0;x < 32;x++)
48 dx = (x - 15.5f) * (1.0f / 16.0f);
49 a = ((1.0f / (dx * dx + dy * dy + 0.2f)) - (1.0f / (1.0f + 0.2))) * 32.0f / (1.0f / (1.0f + 0.2));
54 pixels[y][x][3] = 255;
57 lightcorona = R_LoadTexture2D(lighttexturepool, "lightcorona", 32, 32, &pixels[0][0][0], TEXTYPE_RGBA, TEXF_PRECACHE, NULL);
60 void r_light_shutdown(void)
62 lighttexturepool = NULL;
66 void r_light_newmap(void)
69 for (i = 0;i < 256;i++)
70 d_lightstylevalue[i] = 264; // normal light value
73 void R_Light_Init(void)
75 Cvar_RegisterVariable(&r_modellights);
76 Cvar_RegisterVariable(&r_vismarklights);
77 Cvar_RegisterVariable(&r_coronas);
78 Cvar_RegisterVariable(&gl_flashblend);
79 R_RegisterModule("R_Light", r_light_start, r_light_shutdown, r_light_newmap);
87 void R_UpdateLights(void)
92 // 'm' is normal light, 'a' is no light, 'z' is double bright
93 i = (int)(cl.time * 10);
94 for (j = 0;j < MAX_LIGHTSTYLES;j++)
96 if (!cl_lightstyle || !cl_lightstyle[j].length)
98 d_lightstylevalue[j] = 256;
101 k = i % cl_lightstyle[j].length;
102 k = cl_lightstyle[j].map[k] - 'a';
104 d_lightstylevalue[j] = k;
110 if (!r_dynamic.integer || !cl_dlights)
113 for (i = 0;i < MAX_DLIGHTS;i++)
115 if (cl_dlights[i].radius > 0)
117 R_RTLight_UpdateFromDLight(&cl_dlights[i].rtlight, &cl_dlights[i], false);
118 // FIXME: use pointer instead of copy
119 r_dlight[r_numdlights++] = cl_dlights[i];
120 c_dlights++; // count every dlight in use
125 void R_DrawCoronas(void)
128 float cscale, scale, viewdist, dist;
130 if (!r_coronas.integer)
132 R_Mesh_Matrix(&r_identitymatrix);
133 viewdist = DotProduct(r_vieworigin, r_viewforward);
134 if (r_shadow_realtime_world.integer)
136 for (lnum = 0, light = r_shadow_worldlightchain;light;light = light->next, lnum++)
138 if (light->rtlight.corona * r_coronas.value > 0 && (r_shadow_debuglight.integer < 0 || r_shadow_debuglight.integer == lnum) && (dist = (DotProduct(light->rtlight.shadoworigin, r_viewforward) - viewdist)) >= 24.0f && CL_TraceLine(light->rtlight.shadoworigin, r_vieworigin, NULL, NULL, true, NULL, SUPERCONTENTS_SOLID) == 1)
140 cscale = light->rtlight.corona * r_coronas.value * 0.25f;
141 scale = light->rtlight.radius * 0.25f;
142 R_DrawSprite(GL_ONE, GL_ONE, lightcorona, true, light->rtlight.shadoworigin, r_viewright, r_viewup, scale, -scale, -scale, scale, light->rtlight.color[0] * cscale, light->rtlight.color[1] * cscale, light->rtlight.color[2] * cscale, 1);
146 for (i = 0, light = r_dlight;i < r_numdlights;i++, light++)
148 if (light->corona * r_coronas.value > 0 && (dist = (DotProduct(light->origin, r_viewforward) - viewdist)) >= 24.0f && CL_TraceLine(light->origin, r_vieworigin, NULL, NULL, true, NULL, SUPERCONTENTS_SOLID) == 1)
150 cscale = light->corona * r_coronas.value * 0.25f;
151 scale = light->radius * 0.25f;
152 if (gl_flashblend.integer)
157 R_DrawSprite(GL_ONE, GL_ONE, lightcorona, true, light->origin, r_viewright, r_viewup, scale, -scale, -scale, scale, light->color[0] * cscale, light->color[1] * cscale, light->color[2] * cscale, 1);
163 =============================================================================
167 =============================================================================
170 static int lightpvsbytes;
171 static qbyte lightpvs[(MAX_MAP_LEAFS+7)>>3];
178 static void R_RecursiveMarkLights(entity_render_t *ent, vec3_t lightorigin, dlight_t *light, int bit, int bitindex, mnode_t *node, qbyte *pvs, int pvsbits)
184 // for comparisons to minimum acceptable light
185 while(node->contents >= 0)
187 dist = PlaneDiff(lightorigin, node->plane);
188 if (dist > light->rtlight.lightmap_cullradius)
189 node = node->children[0];
192 if (dist >= -light->rtlight.lightmap_cullradius)
193 R_RecursiveMarkLights(ent, lightorigin, light, bit, bitindex, node->children[0], pvs, pvsbits);
194 node = node->children[1];
198 // check if leaf is visible according to pvs
199 leaf = (mleaf_t *)node;
200 i = leaf->clusterindex;
201 if (leaf->nummarksurfaces && (i >= pvsbits || CHECKPVSBIT(pvs, i)))
203 int *surfacepvsframes, d, impacts, impactt;
204 float sdist, maxdist, dist2, impact[3];
207 maxdist = light->rtlight.lightmap_cullradius2;
208 surfacepvsframes = ent->model->brushq1.surfacepvsframes;
209 for (i = 0;i < leaf->nummarksurfaces;i++)
211 if (surfacepvsframes[leaf->firstmarksurface[i]] != ent->model->brushq1.pvsframecount)
213 surf = ent->model->brushq1.surfaces + leaf->firstmarksurface[i];
214 dist = sdist = PlaneDiff(lightorigin, surf->plane);
215 if (surf->flags & SURF_PLANEBACK)
218 if (dist < -0.25f && !(surf->flags & SURF_LIGHTBOTHSIDES))
222 if (dist2 >= maxdist)
225 VectorCopy(lightorigin, impact);
226 if (surf->plane->type >= 3)
227 VectorMA(impact, -sdist, surf->plane->normal, impact);
229 impact[surf->plane->type] -= sdist;
231 impacts = DotProduct (impact, surf->texinfo->vecs[0]) + surf->texinfo->vecs[0][3] - surf->texturemins[0];
233 d = bound(0, impacts, surf->extents[0] + 16) - impacts;
238 impactt = DotProduct (impact, surf->texinfo->vecs[1]) + surf->texinfo->vecs[1][3] - surf->texturemins[1];
240 d = bound(0, impactt, surf->extents[1] + 16) - impactt;
245 if (surf->dlightframe != r_framecount) // not dynamic until now
247 surf->dlightbits[0] = surf->dlightbits[1] = surf->dlightbits[2] = surf->dlightbits[3] = surf->dlightbits[4] = surf->dlightbits[5] = surf->dlightbits[6] = surf->dlightbits[7] = 0;
248 surf->dlightframe = r_framecount;
249 surf->cached_dlight = true;
251 surf->dlightbits[bitindex] |= bit;
256 void R_MarkLights(entity_render_t *ent)
258 int i, bit, bitindex;
261 if (!gl_flashblend.integer && r_dynamic.integer && ent->model && ent->model->brushq1.num_leafs)
263 for (i = 0, light = r_dlight;i < r_numdlights;i++, light++)
267 Matrix4x4_Transform(&ent->inversematrix, light->origin, lightorigin);
269 if (r_vismarklights.integer && ent->model->brush.FatPVS)
270 lightpvsbytes = ent->model->brush.FatPVS(ent->model, lightorigin, 0, lightpvs, sizeof(lightpvs));
271 R_RecursiveMarkLights(ent, lightorigin, light, bit, bitindex, ent->model->brushq1.nodes + ent->model->brushq1.hulls[0].firstclipnode, lightpvs, min(lightpvsbytes * 8, ent->model->brush.num_pvsclusters));
277 =============================================================================
281 =============================================================================
284 void R_CompleteLightPoint(vec3_t ambientcolor, vec3_t diffusecolor, vec3_t diffusenormal, const vec3_t p, int dynamic, const mleaf_t *leaf)
286 VectorClear(diffusecolor);
287 VectorClear(diffusenormal);
289 if (!r_fullbright.integer && cl.worldmodel && cl.worldmodel->brush.LightPoint)
291 ambientcolor[0] = ambientcolor[1] = ambientcolor[2] = r_ambient.value * (2.0f / 128.0f);
292 cl.worldmodel->brush.LightPoint(cl.worldmodel, p, ambientcolor, diffusecolor, diffusenormal);
295 VectorSet(ambientcolor, 1, 1, 1);
297 // FIXME: this .lights related stuff needs to be ported into the Mod_Q1BSP code
298 if (cl.worldmodel->brushq1.numlights)
304 for (i = 0;i < cl.worldmodel->brushq1.numlights;i++)
306 sl = cl.worldmodel->brushq1.lights + i;
307 if (d_lightstylevalue[sl->style] > 0)
309 VectorSubtract (p, sl->origin, v);
310 f = ((1.0f / (DotProduct(v, v) * sl->falloff + sl->distbias)) - sl->subtract);
311 if (f > 0 && CL_TraceLine(p, sl->origin, NULL, NULL, false, NULL, SUPERCONTENTS_SOLID) == 1)
313 f *= d_lightstylevalue[sl->style] * (1.0f / 65536.0f);
314 VectorMA(ambientcolor, f, sl->light, ambientcolor);
325 // FIXME: this really should handle dlights as diffusecolor/diffusenormal somehow
326 for (i = 0;i < r_numdlights;i++)
328 light = r_dlight + i;
329 VectorSubtract(p, light->origin, v);
330 f = DotProduct(v, v);
331 if (f < light->rtlight.lightmap_cullradius2 && CL_TraceLine(p, light->origin, NULL, NULL, false, NULL, SUPERCONTENTS_SOLID) == 1)
333 f = (1.0f / (f + LIGHTOFFSET)) - light->rtlight.lightmap_subtract;
334 VectorMA(ambientcolor, f, light->rtlight.lightmap_light, ambientcolor);
345 // how much this light would contribute to ambient if replaced
350 // used for choosing only the brightest lights
355 static int nearlights;
356 static nearlight_t nearlight[MAX_DLIGHTS];
358 int R_LightModel(float *ambient4f, float *diffusecolor, float *diffusenormal, const entity_render_t *ent, float colorr, float colorg, float colorb, float colora, int worldcoords)
360 int i, j, maxnearlights;
361 float v[3], f, mscale, stylescale, intensity, ambientcolor[3], tempdiffusenormal[3];
367 maxnearlights = r_modellights.integer;
368 ambient4f[0] = ambient4f[1] = ambient4f[2] = r_ambient.value * (2.0f / 128.0f);
369 VectorClear(diffusecolor);
370 VectorClear(diffusenormal);
371 if (r_fullbright.integer || (ent->effects & EF_FULLBRIGHT))
374 VectorSet(ambient4f, 1, 1, 1);
377 else if (r_shadow_realtime_world.integer && r_shadow_realtime_world_lightmaps.value <= 0)
381 if (cl.worldmodel && cl.worldmodel->brush.LightPoint)
383 cl.worldmodel->brush.LightPoint(cl.worldmodel, ent->origin, ambient4f, diffusecolor, tempdiffusenormal);
384 Matrix4x4_Transform3x3(&ent->inversematrix, tempdiffusenormal, diffusenormal);
385 VectorNormalize(diffusenormal);
388 VectorSet(ambient4f, 1, 1, 1);
391 // scale of the model's coordinate space, to alter light attenuation to match
392 // make the mscale squared so it can scale the squared distance results
393 mscale = ent->scale * ent->scale;
394 // FIXME: no support for .lights on non-Q1BSP?
396 for (i = 0;i < ent->numentlights;i++)
398 sl = cl.worldmodel->brushq1.lights + ent->entlights[i];
399 stylescale = d_lightstylevalue[sl->style] * (1.0f / 65536.0f);
400 VectorSubtract (ent->origin, sl->origin, v);
401 f = ((1.0f / (DotProduct(v, v) * sl->falloff + sl->distbias)) - sl->subtract) * stylescale;
402 VectorScale(sl->light, f, ambientcolor);
403 intensity = DotProduct(ambientcolor, ambientcolor);
406 if (nearlights < maxnearlights)
410 for (j = 0;j < maxnearlights;j++)
412 if (nearlight[j].intensity < intensity)
414 if (nearlight[j].intensity > 0)
415 VectorAdd(ambient4f, nearlight[j].ambientlight, ambient4f);
420 if (j >= maxnearlights)
422 // this light is less significant than all others,
425 VectorAdd(ambient4f, ambientcolor, ambient4f);
430 nl->intensity = intensity;
431 // transform the light into the model's coordinate system
433 VectorCopy(sl->origin, nl->origin);
435 Matrix4x4_Transform(&ent->inversematrix, sl->origin, nl->origin);
436 // integrate mscale into falloff, for maximum speed
437 nl->falloff = sl->falloff * mscale;
438 VectorCopy(ambientcolor, nl->ambientlight);
439 nl->light[0] = sl->light[0] * stylescale * colorr * 4.0f;
440 nl->light[1] = sl->light[1] * stylescale * colorg * 4.0f;
441 nl->light[2] = sl->light[2] * stylescale * colorb * 4.0f;
442 nl->subtract = sl->subtract;
443 nl->offset = sl->distbias;
446 if (!r_shadow_realtime_dlight.integer)
448 for (i = 0;i < r_numdlights;i++)
450 light = r_dlight + i;
451 VectorCopy(light->origin, v);
452 if (v[0] < ent->mins[0]) v[0] = ent->mins[0];if (v[0] > ent->maxs[0]) v[0] = ent->maxs[0];
453 if (v[1] < ent->mins[1]) v[1] = ent->mins[1];if (v[1] > ent->maxs[1]) v[1] = ent->maxs[1];
454 if (v[2] < ent->mins[2]) v[2] = ent->mins[2];if (v[2] > ent->maxs[2]) v[2] = ent->maxs[2];
455 VectorSubtract (v, light->origin, v);
456 if (DotProduct(v, v) < light->rtlight.lightmap_cullradius2)
458 if (CL_TraceLine(ent->origin, light->origin, NULL, NULL, false, NULL, SUPERCONTENTS_SOLID) != 1)
460 VectorSubtract (ent->origin, light->origin, v);
461 f = ((1.0f / (DotProduct(v, v) + LIGHTOFFSET)) - light->rtlight.lightmap_subtract);
462 VectorScale(light->rtlight.lightmap_light, f, ambientcolor);
463 intensity = DotProduct(ambientcolor, ambientcolor);
466 if (nearlights < maxnearlights)
470 for (j = 0;j < maxnearlights;j++)
472 if (nearlight[j].intensity < intensity)
474 if (nearlight[j].intensity > 0)
475 VectorAdd(ambient4f, nearlight[j].ambientlight, ambient4f);
480 if (j >= maxnearlights)
482 // this light is less significant than all others,
485 VectorAdd(ambient4f, ambientcolor, ambient4f);
490 nl->intensity = intensity;
491 // transform the light into the model's coordinate system
493 VectorCopy(light->origin, nl->origin);
496 Matrix4x4_Transform(&ent->inversematrix, light->origin, nl->origin);
498 Con_Printf("%i %s : %f %f %f : %f %f %f\n%f %f %f %f\n%f %f %f %f\n%f %f %f %f\n%f %f %f %f\n"
499 , rd - r_dlight, ent->model->name
500 , light->origin[0], light->origin[1], light->origin[2]
501 , nl->origin[0], nl->origin[1], nl->origin[2]
502 , ent->inversematrix.m[0][0], ent->inversematrix.m[0][1], ent->inversematrix.m[0][2], ent->inversematrix.m[0][3]
503 , ent->inversematrix.m[1][0], ent->inversematrix.m[1][1], ent->inversematrix.m[1][2], ent->inversematrix.m[1][3]
504 , ent->inversematrix.m[2][0], ent->inversematrix.m[2][1], ent->inversematrix.m[2][2], ent->inversematrix.m[2][3]
505 , ent->inversematrix.m[3][0], ent->inversematrix.m[3][1], ent->inversematrix.m[3][2], ent->inversematrix.m[3][3]);
508 // integrate mscale into falloff, for maximum speed
509 nl->falloff = mscale;
510 VectorCopy(ambientcolor, nl->ambientlight);
511 nl->light[0] = light->rtlight.lightmap_light[0] * colorr * 4.0f;
512 nl->light[1] = light->rtlight.lightmap_light[1] * colorg * 4.0f;
513 nl->light[2] = light->rtlight.lightmap_light[2] * colorb * 4.0f;
514 nl->subtract = light->rtlight.lightmap_subtract;
515 nl->offset = LIGHTOFFSET;
520 ambient4f[0] *= colorr;
521 ambient4f[1] *= colorg;
522 ambient4f[2] *= colorb;
523 ambient4f[3] = colora;
524 diffusecolor[0] *= colorr;
525 diffusecolor[1] *= colorg;
526 diffusecolor[2] *= colorb;
527 return nearlights != 0 || DotProduct(diffusecolor, diffusecolor) > 0;
530 void R_LightModel_CalcVertexColors(const float *ambientcolor4f, const float *diffusecolor, const float *diffusenormal, int numverts, const float *vertex3f, const float *normal3f, float *color4f)
532 int i, j, usediffuse;
533 float color[4], v[3], dot, dist2, f, dnormal[3];
535 usediffuse = DotProduct(diffusecolor, diffusecolor) > 0;
536 // negate the diffuse normal to avoid the need to negate the
537 // dotproduct on each vertex
538 VectorNegate(diffusenormal, dnormal);
540 VectorNormalize(dnormal);
541 // directional shading code here
542 for (i = 0;i < numverts;i++, vertex3f += 3, normal3f += 3, color4f += 4)
544 VectorCopy4(ambientcolor4f, color);
546 // silly directional diffuse shading
549 dot = DotProduct(normal3f, dnormal);
551 VectorMA(color, dot, diffusecolor, color);
554 // pretty good lighting
555 for (j = 0, nl = &nearlight[0];j < nearlights;j++, nl++)
557 VectorSubtract(vertex3f, nl->origin, v);
558 // first eliminate negative lighting (back side)
559 dot = DotProduct(normal3f, v);
562 // we'll need this again later to normalize the dotproduct
563 dist2 = DotProduct(v,v);
564 // do the distance attenuation math
565 f = (1.0f / (dist2 * nl->falloff + nl->offset)) - nl->subtract;
568 // we must divide dot by sqrt(dist2) to compensate for
569 // the fact we did not normalize v before doing the
570 // dotproduct, the result is in the range 0 to 1 (we
571 // eliminated negative numbers already)
572 f *= dot / sqrt(dist2);
573 // blend in the lighting
574 VectorMA(color, f, nl->light, color);
578 VectorCopy4(color, color4f);
582 void R_UpdateEntLights(entity_render_t *ent)
587 if (r_shadow_realtime_world.integer && r_shadow_realtime_world_lightmaps.value <= 0)
589 VectorSubtract(ent->origin, ent->entlightsorigin, v);
590 if (ent->entlightsframe != (r_framecount - 1) || (realtime > ent->entlightstime && DotProduct(v,v) >= 1.0f))
592 ent->entlightstime = realtime + 0.1;
593 VectorCopy(ent->origin, ent->entlightsorigin);
594 ent->numentlights = 0;
596 for (i = 0, sl = cl.worldmodel->brushq1.lights;i < cl.worldmodel->brushq1.numlights && ent->numentlights < MAXENTLIGHTS;i++, sl++)
597 if (CL_TraceLine(ent->origin, sl->origin, NULL, NULL, false, NULL, SUPERCONTENTS_SOLID) == 1)
598 ent->entlights[ent->numentlights++] = i;
600 ent->entlightsframe = r_framecount;