[ViewVC] Diff of: radiance/ray/src/rt/ambient.c

Comparing ray/src/rt/ambient.c (file contents):
Revision 1.11 by greg, Fri Sep 7 08:17:42 1990 UTC vs.
Revision 1.17 by greg, Thu Aug 29 11:13:14 1991 UTC

#	Line 1 \| Line 1
1	<	/* Copyright (c) 1986 Regents of the University of California */
1	>	/* Copyright (c) 1991 Regents of the University of California */
2
3		#ifndef lint
4		static char SCCSid[] = "$SunId$ LBL";
#	Line 19 \| Line 19 \| static char SCCSid[] = "$SunId$ LBL";
19
20		#include "otypes.h"
21
22	+	#include "ambient.h"
23	+
24		#include "random.h"
25
26		#define OCTSCALE 0.5 /* ceil((valid rad.)/(cube size)) */
27
28	+	typedef struct ambtree {
29	+	AMBVAL alist; / ambient value list */
30	+	struct ambtree kid; / 8 child nodes */
31	+	} AMBTREE; /* ambient octree */
32	+
33		extern CUBE thescene; /* contains space boundaries */
34
28	–	extern COLOR ambval; /* global ambient component */
29	–	extern double ambacc; /* ambient accuracy */
30	–	extern int ambres; /* ambient resolution */
31	–	extern int ambdiv; /* number of divisions for calculation */
32	–	extern int ambssamp; /* number of super-samples */
33	–	extern int ambounce; /* number of ambient bounces */
34	–	extern char amblist[]; / ambient include/exclude list */
35	–	extern int ambincl; /* include == 1, exclude == 0 */
36	–
35		#define MAXASET 511 /* maximum number of elements in ambient set */
36		OBJECT ambset[MAXASET+1]={0}; /* ambient include/exclude set */
37
38		double maxarad; /* maximum ambient radius */
39		double minarad; /* minimum ambient radius */
40
43	–	typedef struct ambval {
44	–	FVECT pos; /* position in space */
45	–	FVECT dir; /* normal direction */
46	–	int lvl; /* recursion level of parent ray */
47	–	float weight; /* weight of parent ray */
48	–	COLOR val; /* computed ambient value */
49	–	float rad; /* validity radius */
50	–	struct ambval next; / next in list */
51	–	} AMBVAL; /* ambient value */
52	–
53	–	typedef struct ambtree {
54	–	AMBVAL alist; / ambient value list */
55	–	struct ambtree kid; / 8 child nodes */
56	–	} AMBTREE; /* ambient octree */
57	–
58	–	typedef struct {
59	–	float k; /* error contribution per sample */
60	–	COLOR v; /* ray sum */
61	–	int n; /* number of samples */
62	–	short t, p; /* theta, phi indices */
63	–	} AMBSAMP; /* ambient sample */
64	–
41		static AMBTREE atrunk; /* our ambient trunk node */
42
43		static FILE ambfp = NULL; / ambient file pointer */
#	Line 70 \| Line 46 \| *static FILE ambfp = NULL; /* ambient file pointer /*
46
47		#define newambtree() (AMBTREE *)calloc(8, sizeof(AMBTREE))
48
73	–	double sumambient(), doambient(), makeambient();
49
75	–
50		setambient(afile) /* initialize calculation */
51		char *afile;
52		{
#	Line 126 \| Line 100 \| COLOR acol;
100		register RAY *r;
101		{
102		static int rdepth = 0; /* ambient recursion */
103	<	double wsum;
103	>	double d;
104
131	–	rdepth++; /* increment level */
132	–
105		if (ambdiv <= 0) /* no ambient calculation */
106		goto dumbamb;
107		/* check number of bounces */
108	<	if (rdepth > ambounce)
108	>	if (rdepth >= ambounce)
109		goto dumbamb;
110		/* check ambient list */
111		if (ambincl != -1 && r->ro != NULL &&
#	Line 141 \| Line 113 \| *register RAY r;**
113		goto dumbamb;
114
115		if (ambacc <= FTINY) { /* no ambient storage */
116	<	if (doambient(acol, r) == 0.0)
116	>	rdepth++;
117	>	d = doambient(acol, r, r->rweight, NULL, NULL);
118	>	rdepth--;
119	>	if (d == 0.0)
120		goto dumbamb;
121	<	goto done;
121	>	return;
122		}
123		/* get ambient value */
124		setcolor(acol, 0.0, 0.0, 0.0);
125	<	wsum = sumambient(acol, r, &atrunk, thescene.cuorg, thescene.cusize);
126	<	if (wsum > FTINY)
127	<	scalecolor(acol, 1.0/wsum);
128	<	else if (makeambient(acol, r) == 0.0)
129	<	goto dumbamb;
130	<	goto done;
131	<
125	>	d = sumambient(acol, r, rdepth,
126	>	&atrunk, thescene.cuorg, thescene.cusize);
127	>	if (d > FTINY)
128	>	scalecolor(acol, 1.0/d);
129	>	else {
130	>	d = makeambient(acol, r, rdepth++);
131	>	rdepth--;
132	>	}
133	>	if (d > FTINY)
134	>	return;
135		dumbamb: /* return global value */
136		copycolor(acol, ambval);
159	–	done: /* must finish here! */
160	–	rdepth--;
137		}
138
139
140		double
141	<	sumambient(acol, r, at, c0, s) /* get interpolated ambient value */
141	>	sumambient(acol, r, al, at, c0, s) /* get interpolated ambient value */
142		COLOR acol;
143		register RAY *r;
144	+	int al;
145		AMBTREE *at;
146		FVECT c0;
147		double s;
#	Line 180 \| Line 157 \| double s;
157		wsum = 0.0;
158		for (av = at->alist; av != NULL; av = av->next) {
159		/*
160	<	* Ray strength test.
160	>	* Ambient level test.
161		*/
162	<	if (av->lvl > r->rlvl \|\| av->weight < r->rweight-FTINY)
162	>	if (av->lvl > al \|\| av->weight < r->rweight-FTINY)
163		continue;
164		/*
165		* Ambient radius test.
#	Line 209 \| Line 186 \| double s;
186		for (j = 0; j < 3; j++)
187		d += (r->rop[j] - av->pos[j]) *
188		(av->dir[j] + r->ron[j]);
189	<	if (d < -minarad)
189	>	if (d0.5 < -minaradambacc)
190		continue;
191		/*
192		* Jittering final test reduces image artifacts.
#	Line 223 \| Line 200 \| double s;
200		else
201		wt = 1.0 / wt;
202		wsum += wt;
203	<	copycolor(ct, av->val);
203	>	extambient(ct, av, r->rop, r->ron);
204		scalecolor(ct, wt);
205		addcolor(acol, ct);
206		}
#	Line 242 \| Line 219 \| double s;
219		break;
220		}
221		if (j == 3)
222	<	wsum += sumambient(acol, r, at->kid+i, ck0, s);
222	>	wsum += sumambient(acol, r, al, at->kid+i, ck0, s);
223		}
224		return(wsum);
225		}
226
227
228		double
229	<	makeambient(acol, r) /* make a new ambient value */
229	>	makeambient(acol, r, al) /* make a new ambient value */
230		COLOR acol;
231		register RAY *r;
232	+	int al;
233		{
234		AMBVAL amb;
235	<
236	<	amb.rad = doambient(acol, r); /* compute ambient */
235	>	FVECT gp, gd;
236	>	/* compute weight */
237	>	amb.weight = pow(AVGREFL, (double)al);
238	>	if (r->rweight < 0.2amb.weight) / heuristic */
239	>	amb.weight = r->rweight;
240	>	/* compute ambient */
241	>	amb.rad = doambient(acol, r, amb.weight, gp, gd);
242		if (amb.rad == 0.0)
243		return(0.0);
244		/* store it */
245		VCOPY(amb.pos, r->rop);
246		VCOPY(amb.dir, r->ron);
247	<	amb.lvl = r->rlvl;
265	<	amb.weight = r->rweight;
247	>	amb.lvl = al;
248		copycolor(amb.val, acol);
249	+	VCOPY(amb.gpos, gp);
250	+	VCOPY(amb.gdir, gd);
251		/* insert into tree */
252		avinsert(&amb, &atrunk, thescene.cuorg, thescene.cusize);
253		avsave(&amb); /* write to file */
#	Line 271 \| Line 255 \| *register RAY r;**
255		}
256
257
258	<	double
259	<	doambient(acol, r) /* compute ambient component */
260	<	COLOR acol;
261	<	register RAY *r;
258	>	extambient(cr, ap, pv, nv) /* extrapolate value at pv, nv */
259	>	COLOR cr;
260	>	register AMBVAL *ap;
261	>	FVECT pv, nv;
262		{
263	<	extern int ambcmp();
264	<	extern double sin(), cos(), sqrt();
265	<	double phi, xd, yd, zd;
282	<	double b, b2;
283	<	register AMBSAMP *div;
284	<	AMBSAMP dnew;
285	<	RAY ar;
286	<	FVECT ux, uy;
287	<	double arad;
288	<	int ndivs, nt, np, ns, ne, i, j;
289	<	register int k;
263	>	FVECT v1, v2;
264	>	register int i;
265	>	double d;
266
267	<	setcolor(acol, 0.0, 0.0, 0.0);
268	<	/* set number of divisions */
269	<	nt = sqrt(ambdiv * r->rweight * 0.5) + 0.5;
270	<	np = 2 * nt;
271	<	ndivs = nt * np;
272	<	/* check first */
273	<	if (ndivs == 0 \|\| rayorigin(&ar, r, AMBIENT, 0.5) < 0)
274	<	return(0.0);
275	<	/* set number of super-samples */
276	<	ns = ambssamp * r->rweight + 0.5;
277	<	if (ns > 0) {
302	<	div = (AMBSAMP )malloc(ndivssizeof(AMBSAMP));
303	<	if (div == NULL)
304	<	error(SYSTEM, "out of memory in doambient");
267	>	d = 1.0; /* zeroeth order */
268	>	/* gradient due to translation */
269	>	for (i = 0; i < 3; i++)
270	>	d += ap->gpos[i]*(pv[i]-ap->pos[i]);
271	>	/* gradient due to rotation */
272	>	VCOPY(v1, ap->dir);
273	>	fcross(v2, v1, nv);
274	>	d += DOT(ap->gdir, v2);
275	>	if (d <= 0.0) {
276	>	setcolor(cr, 0.0, 0.0, 0.0);
277	>	return;
278		}
279	<	/* make axes */
280	<	uy[0] = uy[1] = uy[2] = 0.0;
308	<	for (k = 0; k < 3; k++)
309	<	if (r->ron[k] < 0.6 && r->ron[k] > -0.6)
310	<	break;
311	<	uy[k] = 1.0;
312	<	fcross(ux, r->ron, uy);
313	<	normalize(ux);
314	<	fcross(uy, ux, r->ron);
315	<	/* sample divisions */
316	<	arad = 0.0;
317	<	ne = 0;
318	<	for (i = 0; i < nt; i++)
319	<	for (j = 0; j < np; j++) {
320	<	rayorigin(&ar, r, AMBIENT, 0.5); /* pretested */
321	<	zd = sqrt((i+frandom())/nt);
322	<	phi = 2.0PI (j+frandom())/np;
323	<	xd = cos(phi) * zd;
324	<	yd = sin(phi) * zd;
325	<	zd = sqrt(1.0 - zd*zd);
326	<	for (k = 0; k < 3; k++)
327	<	ar.rdir[k] = xdux[k]+yduy[k]+zd*r->ron[k];
328	<	rayvalue(&ar);
329	<	if (ar.rot < FHUGE)
330	<	arad += 1.0 / ar.rot;
331	<	if (ns > 0) { /* save division */
332	<	div[ne].k = 0.0;
333	<	copycolor(div[ne].v, ar.rcol);
334	<	div[ne].n = 0;
335	<	div[ne].t = i; div[ne].p = j;
336	<	/* sum errors */
337	<	b = bright(ar.rcol);
338	<	if (i > 0) { /* from above */
339	<	b2 = bright(div[ne-np].v) - b;
340	<	b2 = b2 0.25;
341	<	div[ne].k += b2;
342	<	div[ne].n++;
343	<	div[ne-np].k += b2;
344	<	div[ne-np].n++;
345	<	}
346	<	if (j > 0) { /* from behind */
347	<	b2 = bright(div[ne-1].v) - b;
348	<	b2 = b2 0.25;
349	<	div[ne].k += b2;
350	<	div[ne].n++;
351	<	div[ne-1].k += b2;
352	<	div[ne-1].n++;
353	<	}
354	<	if (j == np-1) { /* around */
355	<	b2 = bright(div[ne-(np-1)].v) - b;
356	<	b2 = b2 0.25;
357	<	div[ne].k += b2;
358	<	div[ne].n++;
359	<	div[ne-(np-1)].k += b2;
360	<	div[ne-(np-1)].n++;
361	<	}
362	<	ne++;
363	<	} else
364	<	addcolor(acol, ar.rcol);
365	<	}
366	<	for (k = 0; k < ne; k++) { /* compute errors */
367	<	if (div[k].n > 1)
368	<	div[k].k /= div[k].n;
369	<	div[k].n = 1;
370	<	}
371	<	/* sort the divisions */
372	<	qsort(div, ne, sizeof(AMBSAMP), ambcmp);
373	<	/* skim excess */
374	<	while (ne > ns) {
375	<	ne--;
376	<	addcolor(acol, div[ne].v);
377	<	}
378	<	/* super-sample */
379	<	for (i = ns; i > 0; i--) {
380	<	rayorigin(&ar, r, AMBIENT, 0.5); /* pretested */
381	<	zd = sqrt((div[0].t+frandom())/nt);
382	<	phi = 2.0PI (div[0].p+frandom())/np;
383	<	xd = cos(phi) * zd;
384	<	yd = sin(phi) * zd;
385	<	zd = sqrt(1.0 - zd*zd);
386	<	for (k = 0; k < 3; k++)
387	<	ar.rdir[k] = xdux[k]+yduy[k]+zd*r->ron[k];
388	<	rayvalue(&ar);
389	<	if (ar.rot < FHUGE)
390	<	arad += 1.0 / ar.rot;
391	<	/* recompute error */
392	<	copycolor(dnew.v, div[0].v);
393	<	addcolor(dnew.v, ar.rcol);
394	<	dnew.n = div[0].n + 1;
395	<	dnew.t = div[0].t; dnew.p = div[0].p;
396	<	b2 = bright(dnew.v)/dnew.n - bright(ar.rcol);
397	<	b2 = b2b2 + div[0].k(div[0].n*div[0].n);
398	<	dnew.k = b2/(dnew.n*dnew.n);
399	<	/* reinsert */
400	<	for (k = 0; k < ne-1 && dnew.k < div[k+1].k; k++)
401	<	copystruct(&div[k], &div[k+1]);
402	<	copystruct(&div[k], &dnew);
403	<
404	<	if (ne >= i) { /* extract darkest division */
405	<	ne--;
406	<	if (div[ne].n > 1)
407	<	scalecolor(div[ne].v, 1.0/div[ne].n);
408	<	addcolor(acol, div[ne].v);
409	<	}
410	<	}
411	<	scalecolor(acol, 1.0/ndivs);
412	<	if (arad <= FTINY)
413	<	arad = FHUGE;
414	<	else
415	<	arad = (ndivs+ns) / arad / sqrt(r->rweight);
416	<	if (arad > maxarad)
417	<	arad = maxarad;
418	<	else if (arad < minarad)
419	<	arad = minarad;
420	<	if (ns > 0)
421	<	free((char *)div);
422	<	return(arad);
423	<	}
424	<
425	<
426	<	static int
427	<	ambcmp(d1, d2) /* decreasing order */
428	<	AMBSAMP d1, d2;
429	<	{
430	<	if (d1->k < d2->k)
431	<	return(1);
432	<	if (d1->k > d2->k)
433	<	return(-1);
434	<	return(0);
279	>	copycolor(cr, ap->val);
280	>	scalecolor(cr, d);
281		}
282
283

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Comparing ray/src/rt/ambient.c (file contents): Revision 1.11 by greg, Fri Sep 7 08:17:42 1990 UTC vs. Revision 1.17 by greg, Thu Aug 29 11:13:14 1991 UTC

Diff Legend

Comparing ray/src/rt/ambient.c (file contents):
Revision 1.11 by greg, Fri Sep 7 08:17:42 1990 UTC vs.
Revision 1.17 by greg, Thu Aug 29 11:13:14 1991 UTC