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root/radiance/src/rt/virtuals.c
Revision: 1.21
Committed: Mon Aug 5 09:02:42 1991 UTC (34 years, 3 months ago) by greg
Content type: text/plain
Branch: MAIN
Changes since 1.20: +4 -2 lines
Log Message: 
changed fatal error to warning

File Contents

# User Rev Content
1 greg 1.1 /* Copyright (c) 1991 Regents of the University of California */
2    
3     #ifndef lint
4     static char SCCSid[] = "$SunId$ LBL";
5     #endif
6    
7     /*
8     * Routines for simulating virtual light sources
9     * Thus far, we only support planar mirrors.
10     */
11    
12     #include "ray.h"
13    
14 greg 1.7 #include "octree.h"
15    
16 greg 1.3 #include "otypes.h"
17    
18 greg 1.1 #include "source.h"
19    
20 greg 1.7 #include "random.h"
21 greg 1.1
22 greg 1.15 #define MINSAMPLES 5 /* minimum number of pretest samples */
23 greg 1.13 #define STESTMAX 30 /* maximum seeks per sample */
24 greg 1.1
25 greg 1.13
26 greg 1.7 double getdisk();
27    
28 greg 1.1 static OBJECT *vobject; /* virtual source objects */
29     static int nvobjects = 0; /* number of virtual source objects */
30    
31    
32     markvirtuals() /* find and mark virtual sources */
33     {
34     register OBJREC *o;
35     register int i;
36     /* check number of direct relays */
37     if (directrelay <= 0)
38     return;
39     /* find virtual source objects */
40     for (i = 0; i < nobjects; i++) {
41     o = objptr(i);
42 greg 1.3 if (!issurface(o->otype) || o->omod == OVOID)
43 greg 1.1 continue;
44     if (!isvlight(objptr(o->omod)->otype))
45     continue;
46 greg 1.3 if (sfun[o->otype].of == NULL ||
47 greg 1.21 sfun[o->otype].of->getpleq == NULL) {
48     objerror(o,WARNING,"secondary sources not supported");
49     continue;
50     }
51 greg 1.1 if (nvobjects == 0)
52     vobject = (OBJECT *)malloc(sizeof(OBJECT));
53     else
54     vobject = (OBJECT *)realloc((char *)vobject,
55     (unsigned)(nvobjects+1)*sizeof(OBJECT));
56     if (vobject == NULL)
57     error(SYSTEM, "out of memory in addvirtuals");
58     vobject[nvobjects++] = i;
59     }
60     if (nvobjects == 0)
61     return;
62 greg 1.4 #ifdef DEBUG
63     fprintf(stderr, "found %d virtual source objects\n", nvobjects);
64     #endif
65 greg 1.1 /* append virtual sources */
66     for (i = nsources; i-- > 0; )
67 greg 1.7 addvirtuals(i, directrelay);
68 greg 1.1 /* done with our object list */
69     free((char *)vobject);
70     nvobjects = 0;
71     }
72    
73    
74 greg 1.4 addvirtuals(sn, nr) /* add virtuals associated with source */
75     int sn;
76 greg 1.1 int nr;
77     {
78     register int i;
79     /* check relay limit first */
80     if (nr <= 0)
81     return;
82 greg 1.7 if (source[sn].sflags & SSKIP)
83     return;
84 greg 1.1 /* check each virtual object for projection */
85     for (i = 0; i < nvobjects; i++)
86 greg 1.3 /* vproject() calls us recursively */
87 greg 1.4 vproject(objptr(vobject[i]), sn, nr-1);
88 greg 1.1 }
89    
90    
91 greg 1.4 vproject(o, sn, n) /* create projected source(s) if they exist */
92 greg 1.3 OBJREC *o;
93 greg 1.4 int sn;
94 greg 1.3 int n;
95     {
96     register int i;
97     register VSMATERIAL *vsmat;
98     MAT4 proj;
99 greg 1.4 int ns;
100    
101     if (o == source[sn].so) /* objects cannot project themselves */
102     return;
103 greg 1.3 /* get virtual source material */
104     vsmat = sfun[objptr(o->omod)->otype].mf;
105     /* project virtual sources */
106     for (i = 0; i < vsmat->nproj; i++)
107 greg 1.4 if ((*vsmat->vproj)(proj, o, &source[sn], i))
108     if ((ns = makevsrc(o, sn, proj)) >= 0) {
109 greg 1.17 source[ns].sa.sv.pn = i;
110 greg 1.4 #ifdef DEBUG
111 greg 1.6 virtverb(ns, stderr);
112 greg 1.4 #endif
113 greg 1.3 addvirtuals(ns, n);
114 greg 1.4 }
115 greg 1.3 }
116    
117    
118 greg 1.4 int
119     makevsrc(op, sn, pm) /* make virtual source if reasonable */
120 greg 1.1 OBJREC *op;
121 greg 1.4 register int sn;
122 greg 1.1 MAT4 pm;
123     {
124 greg 1.9 FVECT nsloc, nsnorm, ocent, v;
125     double maxrad2, d;
126 greg 1.3 int nsflags;
127 greg 1.1 SPOT theirspot, ourspot;
128     register int i;
129 greg 1.3
130 greg 1.6 nsflags = source[sn].sflags | (SVIRTUAL|SSPOT|SFOLLOW);
131 greg 1.1 /* get object center and max. radius */
132 greg 1.6 maxrad2 = getdisk(ocent, op, sn);
133     if (maxrad2 <= FTINY) /* too small? */
134     return(-1);
135 greg 1.1 /* get location and spot */
136 greg 1.4 if (source[sn].sflags & SDISTANT) { /* distant source */
137     if (source[sn].sflags & SPROX)
138 greg 1.5 return(-1); /* should never get here! */
139 greg 1.4 multv3(nsloc, source[sn].sloc, pm);
140 greg 1.17 normalize(nsloc);
141 greg 1.6 VCOPY(ourspot.aim, ocent);
142     ourspot.siz = PI*maxrad2;
143     ourspot.flen = 0.;
144 greg 1.4 if (source[sn].sflags & SSPOT) {
145     multp3(theirspot.aim, source[sn].sl.s->aim, pm);
146 greg 1.19 d = sqrt(dist2(ourspot.aim, theirspot.aim));
147     d = sqrt(source[sn].sl.s->siz/PI) + d*source[sn].ss;
148     theirspot.siz = PI*d*d;
149     ourspot.flen = theirspot.flen = source[sn].sl.s->flen;
150 greg 1.9 d = ourspot.siz;
151 greg 1.6 if (!commonbeam(&ourspot, &theirspot, nsloc))
152 greg 1.9 return(-1); /* no overlap */
153     if (ourspot.siz < d-FTINY) { /* it shrunk */
154     d = beamdisk(v, op, &ourspot, nsloc);
155     if (d <= FTINY)
156     return(-1);
157     if (d < maxrad2) {
158     maxrad2 = d;
159     VCOPY(ocent, v);
160     }
161     }
162 greg 1.1 }
163     } else { /* local source */
164 greg 1.4 multp3(nsloc, source[sn].sloc, pm);
165 greg 1.6 for (i = 0; i < 3; i++)
166     ourspot.aim[i] = ocent[i] - nsloc[i];
167 greg 1.9 if ((d = normalize(ourspot.aim)) == 0.)
168 greg 1.6 return(-1); /* at source!! */
169 greg 1.9 if (source[sn].sflags & SPROX && d > source[sn].sl.prox)
170 greg 1.6 return(-1); /* too far away */
171     ourspot.flen = 0.;
172 greg 1.19 d = (sqrt(maxrad2) + source[sn].ss) / d;
173     if (d < 1.-FTINY)
174     ourspot.siz = 2.*PI*(1. - sqrt(1.-d*d));
175 greg 1.14 else
176     nsflags &= ~SSPOT;
177 greg 1.4 if (source[sn].sflags & SSPOT) {
178     copystruct(&theirspot, source[sn].sl.s);
179     multv3(theirspot.aim, source[sn].sl.s->aim, pm);
180 greg 1.17 normalize(theirspot.aim);
181 greg 1.14 if (nsflags & SSPOT) {
182     ourspot.flen = theirspot.flen;
183     d = ourspot.siz;
184     if (!commonspot(&ourspot, &theirspot, nsloc))
185     return(-1); /* no overlap */
186     } else {
187     nsflags |= SSPOT;
188     copystruct(&ourspot, &theirspot);
189     d = 2.*ourspot.siz;
190     }
191 greg 1.9 if (ourspot.siz < d-FTINY) { /* it shrunk */
192     d = spotdisk(v, op, &ourspot, nsloc);
193     if (d <= FTINY)
194     return(-1);
195     if (d < maxrad2) {
196     maxrad2 = d;
197     VCOPY(ocent, v);
198     }
199     }
200 greg 1.1 }
201 greg 1.4 if (source[sn].sflags & SFLAT) { /* behind source? */
202     multv3(nsnorm, source[sn].snorm, pm);
203 greg 1.17 normalize(nsnorm);
204 greg 1.20 if (nsflags & SSPOT && !checkspot(&ourspot, nsnorm))
205 greg 1.5 return(-1);
206 greg 1.1 }
207     }
208 greg 1.7 /* pretest visibility */
209     nsflags = vstestvis(nsflags, op, ocent, maxrad2, sn);
210     if (nsflags & SSKIP)
211     return(-1); /* obstructed */
212     /* it all checks out, so make it */
213 greg 1.6 if ((i = newsource()) < 0)
214 greg 1.1 goto memerr;
215 greg 1.6 source[i].sflags = nsflags;
216     VCOPY(source[i].sloc, nsloc);
217 greg 1.3 if (nsflags & SFLAT)
218 greg 1.6 VCOPY(source[i].snorm, nsnorm);
219     source[i].ss = source[sn].ss; source[i].ss2 = source[sn].ss2;
220 greg 1.14 if (nsflags & SSPOT) {
221     if ((source[i].sl.s = (SPOT *)malloc(sizeof(SPOT))) == NULL)
222     goto memerr;
223     copystruct(source[i].sl.s, &ourspot);
224     }
225 greg 1.3 if (nsflags & SPROX)
226 greg 1.6 source[i].sl.prox = source[sn].sl.prox;
227 greg 1.17 source[i].sa.sv.sn = sn;
228 greg 1.6 source[i].so = op;
229     return(i);
230 greg 1.1 memerr:
231     error(SYSTEM, "out of memory in makevsrc");
232     }
233    
234    
235 greg 1.6 double
236     getdisk(oc, op, sn) /* get visible object disk */
237     FVECT oc;
238     OBJREC *op;
239     register int sn;
240     {
241     double rad2, roffs, offs, d, rd, rdoto;
242     FVECT rnrm, nrm;
243     /* first, use object getdisk function */
244 greg 1.9 rad2 = getmaxdisk(oc, op);
245 greg 1.6 if (!(source[sn].sflags & SVIRTUAL))
246     return(rad2); /* all done for normal source */
247     /* check for correct side of relay surface */
248 greg 1.9 roffs = getplaneq(rnrm, source[sn].so);
249 greg 1.6 rd = DOT(rnrm, source[sn].sloc); /* source projection */
250     if (!(source[sn].sflags & SDISTANT))
251     rd -= roffs;
252     d = DOT(rnrm, oc) - roffs; /* disk distance to relay plane */
253     if ((d > 0.) ^ (rd > 0.))
254     return(rad2); /* OK if opposite sides */
255     if (d*d >= rad2)
256 greg 1.9 return(0.); /* no relay is possible */
257 greg 1.6 /* we need a closer look */
258 greg 1.9 offs = getplaneq(nrm, op);
259 greg 1.6 rdoto = DOT(rnrm, nrm);
260     if (d*d >= rad2*(1.-rdoto*rdoto))
261     return(0.); /* disk entirely on projection side */
262     /* should shrink disk but I'm lazy */
263     return(rad2);
264     }
265    
266    
267 greg 1.7 int
268     vstestvis(f, o, oc, or2, sn) /* pretest source visibility */
269     int f; /* virtual source flags */
270     OBJREC *o; /* relay object */
271     FVECT oc; /* relay object center */
272     double or2; /* relay object radius squared */
273     register int sn; /* target source number */
274 greg 1.1 {
275 greg 1.7 RAY sr;
276     FVECT onorm;
277     FVECT offsdir;
278     double or, d;
279 greg 1.8 int infront;
280 greg 1.16 int stestlim, ssn;
281 greg 1.11 int nhit, nok;
282 greg 1.7 register int i, n;
283     /* return if pretesting disabled */
284     if (vspretest <= 0)
285     return(f);
286     /* get surface normal */
287 greg 1.9 getplaneq(onorm, o);
288 greg 1.7 /* set number of rays to sample */
289 greg 1.8 if (source[sn].sflags & SDISTANT) {
290 greg 1.7 n = (2./3.*PI*PI)*or2/(thescene.cusize*thescene.cusize)*
291     vspretest + .5;
292 greg 1.8 infront = DOT(onorm, source[sn].sloc) > 0.;
293     } else {
294     for (i = 0; i < 3; i++)
295     offsdir[i] = source[sn].sloc[i] - oc[i];
296 greg 1.20 d = DOT(offsdir,offsdir);
297     if (d <= FTINY)
298     n = 2.*PI * vspretest + .5;
299     else
300     n = 2.*PI * (1.-sqrt(1./(1.+or2/d)))*vspretest + .5;
301 greg 1.8 infront = DOT(onorm, offsdir) > 0.;
302     }
303 greg 1.13 if (n < MINSAMPLES) n = MINSAMPLES;
304 greg 1.9 #ifdef DEBUG
305     fprintf(stderr, "pretesting source %d in object %s with %d rays\n",
306     sn, o->oname, n);
307     #endif
308 greg 1.7 /* sample */
309 greg 1.8 or = sqrt(or2);
310 greg 1.16 stestlim = n*STESTMAX;
311     ssn = 0;
312 greg 1.11 nhit = nok = 0;
313 greg 1.7 while (n-- > 0) {
314 greg 1.8 /* get sample point */
315     do {
316 greg 1.16 if (ssn >= stestlim) {
317 greg 1.9 #ifdef DEBUG
318     fprintf(stderr, "\ttoo hard to hit\n");
319     #endif
320 greg 1.8 return(f); /* too small a target! */
321 greg 1.9 }
322 greg 1.8 for (i = 0; i < 3; i++)
323     offsdir[i] = or*(1. -
324 greg 1.16 2.*urand(urind(931*i+5827,ssn)));
325     ssn++;
326 greg 1.8 for (i = 0; i < 3; i++)
327     sr.rorg[i] = oc[i] + offsdir[i];
328     d = DOT(offsdir,onorm);
329     if (infront)
330     for (i = 0; i < 3; i++) {
331     sr.rorg[i] -= (d-.0001)*onorm[i];
332     sr.rdir[i] = -onorm[i];
333     }
334     else
335     for (i = 0; i < 3; i++) {
336     sr.rorg[i] -= (d+.0001)*onorm[i];
337     sr.rdir[i] = onorm[i];
338     }
339     rayorigin(&sr, NULL, PRIMARY, 1.0);
340     } while (!(*ofun[o->otype].funp)(o, &sr));
341     /* check against source */
342 greg 1.7 samplendx++;
343 greg 1.9 if (srcray(&sr, NULL, sn) == 0.)
344 greg 1.7 continue;
345     sr.revf = srcvalue;
346     rayvalue(&sr);
347     if (bright(sr.rcol) <= FTINY)
348     continue;
349 greg 1.11 nok++;
350 greg 1.7 /* check against obstructions */
351 greg 1.18 rayclear(&sr);
352     sr.revf = raytrace;
353 greg 1.7 rayvalue(&sr);
354 greg 1.11 if (bright(sr.rcol) > FTINY)
355     nhit++;
356     if (nhit > 0 && nhit < nok) {
357 greg 1.9 #ifdef DEBUG
358 greg 1.11 fprintf(stderr, "\tpartially occluded\n");
359 greg 1.9 #endif
360 greg 1.11 return(f); /* need to shadow test */
361     }
362 greg 1.1 }
363 greg 1.9 if (nhit == 0) {
364     #ifdef DEBUG
365     fprintf(stderr, "\t0%% hit rate\n");
366     #endif
367 greg 1.7 return(f | SSKIP); /* 0% hit rate: totally occluded */
368 greg 1.9 }
369     #ifdef DEBUG
370     fprintf(stderr, "\t100%% hit rate\n");
371     #endif
372     return(f & ~SFOLLOW); /* 100% hit rate: no occlusion */
373 greg 1.1 }
374 greg 1.7
375 greg 1.4
376     #ifdef DEBUG
377 greg 1.6 virtverb(sn, fp) /* print verbose description of virtual source */
378     register int sn;
379 greg 1.4 FILE *fp;
380     {
381     register int i;
382    
383     fprintf(fp, "%s virtual source %d in %s %s\n",
384 greg 1.6 source[sn].sflags & SDISTANT ? "distant" : "local",
385     sn, ofun[source[sn].so->otype].funame,
386     source[sn].so->oname);
387 greg 1.4 fprintf(fp, "\tat (%f,%f,%f)\n",
388 greg 1.6 source[sn].sloc[0], source[sn].sloc[1], source[sn].sloc[2]);
389 greg 1.4 fprintf(fp, "\tlinked to source %d (%s)\n",
390 greg 1.17 source[sn].sa.sv.sn, source[source[sn].sa.sv.sn].so->oname);
391 greg 1.6 if (source[sn].sflags & SFOLLOW)
392 greg 1.4 fprintf(fp, "\talways followed\n");
393     else
394     fprintf(fp, "\tnever followed\n");
395 greg 1.6 if (!(source[sn].sflags & SSPOT))
396 greg 1.4 return;
397     fprintf(fp, "\twith spot aim (%f,%f,%f) and size %f\n",
398 greg 1.6 source[sn].sl.s->aim[0], source[sn].sl.s->aim[1],
399     source[sn].sl.s->aim[2], source[sn].sl.s->siz);
400 greg 1.4 }
401     #endif