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

Comparing ray/src/rt/ambient.c (file contents):
Revision 2.70 by greg, Thu Sep 22 02:15:56 2011 UTC vs.
Revision 2.121 by greg, Mon Jan 29 19:24:00 2024 UTC

#	Line 1 \| Line 1
1	–	#ifndef lint
1		static const char RCSid[] = "$Id$";
3	–	#endif
2		/*
3		* ambient.c - routines dealing with ambient (inter-reflected) component.
4		*
#	Line 14 \| Line 12 \| static const char RCSid[] = "$Id$";
12		#include "platform.h"
13		#include "ray.h"
14		#include "otypes.h"
15	+	#include "otspecial.h"
16		#include "resolu.h"
17		#include "ambient.h"
18		#include "random.h"
19	+	#include "pmapamb.h"
20
21		#ifndef OCTSCALE
22		#define OCTSCALE 1.0 /* ceil((valid rad.)/(cube size)) */
23		#endif
24
25	–	extern char shm_boundary; / memory sharing boundary */
26	–
25		#ifndef MAXASET
26		#define MAXASET 4095 /* maximum number of elements in ambient set */
27		#endif
#	Line 37 \| Line 35 \| *static AMBTREE atrunk; / our ambient trunk node /*
35		static FILE ambfp = NULL; / ambient file pointer */
36		static int nunflshed = 0; /* number of unflushed ambient values */
37
40	–	#ifndef SORT_THRESH
41	–	#ifdef SMLMEM
42	–	#define SORT_THRESH ((3L<<20)/sizeof(AMBVAL))
43	–	#else
44	–	#define SORT_THRESH ((9L<<20)/sizeof(AMBVAL))
45	–	#endif
46	–	#endif
47	–	#ifndef SORT_INTVL
48	–	#define SORT_INTVL (SORT_THRESH<<1)
49	–	#endif
50	–	#ifndef MAX_SORT_INTVL
51	–	#define MAX_SORT_INTVL (SORT_INTVL<<6)
52	–	#endif
53	–
38		static double avsum = 0.; /* computed ambient value sum (log) */
39		static unsigned int navsum = 0; /* number of values in avsum */
40		static unsigned int nambvals = 0; /* total number of indirect values */
41		static unsigned int nambshare = 0; /* number of values from file */
58	–	static unsigned long ambclock = 0; /* ambient access clock */
59	–	static unsigned long lastsort = 0; /* time of last value sort */
60	–	static long sortintvl = SORT_INTVL; /* time until next sort */
42		static FILE ambinp = NULL; / auxiliary file for input */
43		static long lastpos = -1; /* last flush position */
44
64	–	#define MAXACLOCK (1L<<30) /* clock turnover value */
65	–	/*
66	–	* Track access times unless we are sharing ambient values
67	–	* through memory on a multiprocessor, when we want to avoid
68	–	* claiming our own memory (copy on write). Go ahead anyway
69	–	* if more than two thirds of our values are unshared.
70	–	* Compile with -Dtracktime=0 to turn this code off.
71	–	*/
72	–	#ifndef tracktime
73	–	#define tracktime (shm_boundary == NULL \|\| nambvals > 3*nambshare)
74	–	#endif
75	–
45		#define AMBFLUSH (BUFSIZ/AMBVALSIZ)
46
47	<	#define newambval() (AMBVAL *)malloc(sizeof(AMBVAL))
48	<	#define freeav(av) free((void *)av);
47	>	#define AVSIZE (sizeof(AMBVAL)-sizeof(SCOLOR)+sizeof(COLORV)*NCSAMP)
48	>	#define newambval() (AMBVAL *)malloc(AVSIZE)
49
50	<	static void initambfile(int creat);
50	>	#define tfunc(x0, x, x1) (((x)-(x0))/((x1)-(x0)))
51	>
52	>	static void initambfile(int cre8);
53		static void avsave(AMBVAL *av);
54		static AMBVAL avstore(AMBVAL aval);
55		static AMBTREE *newambtree(void);
56		static void freeambtree(AMBTREE *atp);
57
58	<	typedef void unloadtf_t(void *);
58	>	typedef void unloadtf_t(AMBVAL *);
59		static unloadtf_t avinsert;
60	<	static unloadtf_t av2list;
60	>	static unloadtf_t avfree;
61		static void unloadatree(AMBTREE at, unloadtf_t f);
62
63	<	static int aposcmp(const void avp1, const void avp2);
93	<	static int avlmemi(AMBVAL *avaddr);
94	<	static void sortambvals(int always);
63	>	static void sortambvals(void);
64
65	+	static int plugaleak(RAY r, AMBVAL ap, FVECT anorm, double ang);
66	+	static double sumambient(SCOLOR acol, RAY *r, FVECT rn, int al,
67	+	AMBTREE *at, FVECT c0, double s);
68	+	static int makeambient(SCOLOR acol, RAY *r, FVECT rn, int al);
69	+	static int extambient(SCOLOR cr, AMBVAL *ap, FVECT pv, FVECT nv,
70	+	FVECT uvw[3]);
71	+
72		#ifdef F_SETLKW
73		static void aflock(int typ);
74		#endif
75
76
77	<	extern void
77	>	void
78		setambres( /* set ambient resolution */
79		int ar
80		)
#	Line 107 \| Line 83 \| *setambres( / set ambient resolution /*
83		/* set min & max radii */
84		if (ar <= 0) {
85		minarad = 0;
86	<	maxarad = thescene.cusize / 2.0;
86	>	maxarad = thescene.cusize*0.2;
87		} else {
88		minarad = thescene.cusize / ar;
89	<	maxarad = 64 * minarad; /* heuristic */
90	<	if (maxarad > thescene.cusize / 2.0)
91	<	maxarad = thescene.cusize / 2.0;
89	>	maxarad = 64.0 * minarad; /* heuristic */
90	>	if (maxarad > thescene.cusize*0.2)
91	>	maxarad = thescene.cusize*0.2;
92		}
93		if (minarad <= FTINY)
94	<	minarad = 10*FTINY;
94	>	minarad = 10.0*FTINY;
95		if (maxarad <= minarad)
96	<	maxarad = 64 * minarad;
96	>	maxarad = 64.0 * minarad;
97		}
98
99
100	<	extern void
100	>	void
101		setambacc( /* set ambient accuracy */
102		double newa
103		)
104		{
105	<	double ambdiff;
106	<
107	<	if (newa < 0.0)
108	<	newa = 0.0;
109	<	ambdiff = fabs(newa - ambacc);
110	<	if (ambdiff >= .01 && (ambacc = newa) > FTINY && nambvals > 0)
111	<	sortambvals(1); /* rebuild tree */
105	>	static double olda; /* remember previous setting here */
106	>
107	>	newa *= (newa > 0);
108	>	if (fabs(newa - olda) >= .05*(newa + olda)) {
109	>	ambacc = newa;
110	>	if (ambacc > FTINY && nambvals > 0)
111	>	sortambvals(); /* rebuild tree */
112	>	}
113		}
114
115
116	<	extern void
116	>	void
117		setambient(void) /* initialize calculation */
118		{
119		int readonly = 0;
#	Line 162 \| Line 139 \| *setambient(void) / initialize calculation /*
139		initambfile(0); /* file exists */
140		lastpos = ftell(ambfp);
141		while (readambval(&amb, ambfp))
142	<	avinsert(avstore(&amb));
142	>	avstore(&amb);
143		nambshare = nambvals; /* share loaded values */
144		if (readonly) {
145		sprintf(errmsg,
#	Line 182 \| Line 159 \| *setambient(void) / initialize calculation /*
159		(flen - lastpos)/AMBVALSIZ);
160		error(WARNING, errmsg);
161		fseek(ambfp, lastpos, SEEK_SET);
185	–	#ifndef _WIN32 /* XXX we need a replacement for that one */
162		ftruncate(fileno(ambfp), (off_t)lastpos);
187	–	#endif
163		}
164		} else if ((ambfp = fopen(ambfile, "w+")) != NULL) {
165		initambfile(1); /* else create new file */
#	Line 200 \| Line 175 \| *setambient(void) / initialize calculation /*
175		}
176
177
178	<	extern void
178	>	void
179		ambdone(void) /* close ambient file and free memory */
180		{
181		if (ambfp != NULL) { /* close ambient file */
#	Line 214 \| Line 189 \| *ambdone(void) / close ambient file and free memory**
189		lastpos = -1;
190		}
191		/* free ambient tree */
192	<	unloadatree(&atrunk, free);
192	>	unloadatree(&atrunk, avfree);
193		/* reset state variables */
194		avsum = 0.;
195		navsum = 0;
196		nambvals = 0;
197		nambshare = 0;
223	–	ambclock = 0;
224	–	lastsort = 0;
225	–	sortintvl = SORT_INTVL;
198		}
199
200
201	<	extern void
201	>	void
202		ambnotify( /* record new modifier */
203		OBJECT obj
204		)
#	Line 256 \| Line 228 \| *ambnotify( / record new modifier /*
228		}
229
230
231	<	extern void
231	>	void
232		multambient( /* compute ambient component & multiply by coef. */
233	<	COLOR aval,
233	>	SCOLOR aval,
234		RAY *r,
235		FVECT nrm
236		)
237		{
238	+	static double logAvgAbsorp = 1;
239		static int rdepth = 0; /* ambient recursion */
240	<	COLOR acol;
240	>	SCOLOR acol, caustic;
241	>	int i, ok;
242		double d, l;
243
244	+	/* PMAP: Factor in ambient from photon map, if enabled and ray is
245	+	* ambient. Return as all ambient components accounted for, else
246	+	* continue. */
247	+	if (ambPmap(aval, r, rdepth))
248	+	return;
249	+
250	+	if (logAvgAbsorp > 0) /* exclude in -aw to avoid growth */
251	+	logAvgAbsorp = log(1.-AVGREFL);
252	+
253	+	/* PMAP: Factor in specular-diffuse ambient (caustics) from photon
254	+	* map, if enabled and ray is primary, else caustic is zero. Continue
255	+	* with RADIANCE ambient calculation */
256	+	{/* XXX TEMPORARY */
257	+	COLOR pmc;
258	+	scolor_color(pmc, aval);
259	+	ambPmapCaustic(pmc, r, rdepth);
260	+	setscolor(caustic, colval(pmc,RED), colval(pmc,GRN), colval(pmc,BLU));
261	+	}
262		if (ambdiv <= 0) /* no ambient calculation */
263		goto dumbamb;
264		/* check number of bounces */
#	Line 278 \| Line 270 \| *multambient( / compute ambient component & multiply**
270		goto dumbamb;
271
272		if (ambacc <= FTINY) { /* no ambient storage */
273	<	copycolor(acol, aval);
273	>	FVECT uvd[2];
274	>	float dgrad[2], *dgp = NULL;
275	>
276	>	if (nrm != r->ron && DOT(nrm,r->ron) < 0.9999)
277	>	dgp = dgrad; /* compute rotational grad. */
278	>	copyscolor(acol, aval);
279		rdepth++;
280	<	d = doambient(acol, r, r->rweight, NULL, NULL);
280	>	ok = doambient(acol, r, r->rweight,
281	>	uvd, NULL, NULL, dgp, NULL);
282		rdepth--;
283	<	if (d <= FTINY)
283	>	if (!ok)
284		goto dumbamb;
285	<	copycolor(aval, acol);
285	>	if ((ok > 0) & (dgp != NULL)) { /* apply texture */
286	>	FVECT v1;
287	>	VCROSS(v1, r->ron, nrm);
288	>	d = 1.0;
289	>	for (i = 3; i--; )
290	>	d += v1[i] * (dgp[0]uvd[0][i] + dgp[1]uvd[1][i]);
291	>	if (d >= 0.05)
292	>	scalescolor(acol, d);
293	>	}
294	>	copyscolor(aval, acol);
295	>
296	>	/* PMAP: add in caustic */
297	>	saddscolor(aval, caustic);
298		return;
299		}
290	–
291	–	if (tracktime) /* sort to minimize thrashing */
292	–	sortambvals(0);
300		/* interpolate ambient value */
301	<	setcolor(acol, 0.0, 0.0, 0.0);
301	>	scolorblack(acol);
302		d = sumambient(acol, r, nrm, rdepth,
303		&atrunk, thescene.cuorg, thescene.cusize);
304	+
305		if (d > FTINY) {
306	<	d = 1.0/d;
307	<	scalecolor(acol, d);
308	<	multcolor(aval, acol);
306	>	scalescolor(acol, 1.0/d);
307	>	smultscolor(aval, acol);
308	>
309	>	/* PMAP: add in caustic */
310	>	saddscolor(aval, caustic);
311		return;
312		}
313	+
314		rdepth++; /* need to cache new value */
315	<	d = makeambient(acol, r, nrm, rdepth-1);
315	>	ok = makeambient(acol, r, nrm, rdepth-1);
316		rdepth--;
317	<	if (d > FTINY) {
318	<	multcolor(aval, acol); /* got new value */
317	>
318	>	if (ok) {
319	>	smultscolor(aval, acol); /* computed new value */
320	>
321	>	/* PMAP: add in caustic */
322	>	saddscolor(aval, caustic);
323		return;
324		}
325	+
326		dumbamb: /* return global value */
327		if ((ambvwt <= 0) \| (navsum == 0)) {
328	<	multcolor(aval, ambval);
328	>	smultcolor(aval, ambval);
329	>
330	>	/* PMAP: add in caustic */
331	>	saddscolor(aval, caustic);
332		return;
333		}
334	<	l = bright(ambval); /* average in computations */
334	>
335	>	l = bright(ambval); /* average in computations */
336		if (l > FTINY) {
337	<	d = (log(l)*(double)ambvwt + avsum) /
337	>	d = (log(l)(double)ambvwt + avsum + logAvgAbsorpnavsum) /
338		(double)(ambvwt + navsum);
339		d = exp(d) / l;
340	<	scalecolor(aval, d);
341	<	multcolor(aval, ambval); /* apply color of ambval */
340	>	scalescolor(aval, d);
341	>	smultcolor(aval, ambval); /* apply color of ambval */
342		} else {
343	<	d = exp( avsum / (double)navsum );
344	<	scalecolor(aval, d); /* neutral color */
343	>	d = exp( avsum/(double)navsum + logAvgAbsorp );
344	>	scalescolor(aval, d); /* neutral color */
345		}
346		}
347
348
349	<	extern double
350	<	sumambient( /* get interpolated ambient value */
351	<	COLOR acol,
349	>	/* Plug a potential leak where ambient cache value is occluded */
350	>	static int
351	>	plugaleak(RAY r, AMBVAL ap, FVECT anorm, double ang)
352	>	{
353	>	const double cost70sq = 0.1169778; /* cos(70deg)^2 */
354	>	RAY rtst;
355	>	FVECT vdif;
356	>	double normdot, ndotd, nadotd;
357	>	double a, b, c, t[2];
358	>
359	>	ang += 2.PI(ang < 0); /* check direction flags */
360	>	if ( !(ap->corral>>(int)(ang*(16./PI)) & 1) )
361	>	return(0);
362	>	/*
363	>	* Generate test ray, targeting 20 degrees above sample point plane
364	>	* along surface normal from cache position. This should be high
365	>	* enough to miss local geometry we don't really care about.
366	>	*/
367	>	VSUB(vdif, ap->pos, r->rop);
368	>	normdot = DOT(anorm, r->ron);
369	>	ndotd = DOT(vdif, r->ron);
370	>	nadotd = DOT(vdif, anorm);
371	>	a = normdot*normdot - cost70sq;
372	>	b = 2.0(normdotndotd - nadotd*cost70sq);
373	>	c = ndotdndotd - DOT(vdif,vdif)cost70sq;
374	>	if (quadratic(t, a, b, c) != 2)
375	>	return(1); /* should rarely happen */
376	>	if (t[1] <= FTINY)
377	>	return(0); /* should fail behind test */
378	>	rayorigin(&rtst, SHADOW, r, NULL);
379	>	VSUM(rtst.rdir, vdif, anorm, t[1]); /* further dist. > plane */
380	>	rtst.rmax = normalize(rtst.rdir); /* short ray test */
381	>	while (localhit(&rtst, &thescene)) { /* check for occluder */
382	>	OBJREC *m = findmaterial(rtst.ro);
383	>	if (m != NULL && !istransp(m->otype) && !isBSDFproxy(m) &&
384	>	(rtst.clipset == NULL \|\|
385	>	!inset(rtst.clipset, rtst.ro->omod)))
386	>	return(1); /* plug light leak */
387	>	VCOPY(rtst.rorg, rtst.rop); /* skip invisible surface */
388	>	rtst.rmax -= rtst.rot;
389	>	rayclear(&rtst);
390	>	}
391	>	return(0); /* seems we're OK */
392	>	}
393	>
394	>
395	>	static double
396	>	sumambient( /* get interpolated ambient value */
397	>	SCOLOR acol,
398		RAY *r,
399		FVECT rn,
400		int al,
#	Line 336 \| Line 402 \| *sumambient( / get interpolated ambient value /*
402		FVECT c0,
403		double s
404		)
405	<	{
406	<	double d, e1, e2, wt, wsum;
407	<	COLOR ct;
408	<	FVECT ck0;
409	<	int i;
410	<	int j;
411	<	AMBVAL *av;
405	>	{ /* initial limit is 10 degrees plus ambacc radians */
406	>	const double minangle = 10.0 * PI/180.;
407	>	double maxangle = minangle + ambacc;
408	>	double wsum = 0.0;
409	>	FVECT ck0;
410	>	int i, j;
411	>	AMBVAL *av;
412
413	<	wsum = 0.0;
414	<	/* do this node */
413	>	if (at->kid != NULL) { /* sum children first */
414	>	s *= 0.5;
415	>	for (i = 0; i < 8; i++) {
416	>	for (j = 0; j < 3; j++) {
417	>	ck0[j] = c0[j];
418	>	if (1<<j & i)
419	>	ck0[j] += s;
420	>	if (r->rop[j] < ck0[j] - OCTSCALE*s)
421	>	break;
422	>	if (r->rop[j] > ck0[j] + (1.0+OCTSCALE)*s)
423	>	break;
424	>	}
425	>	if (j == 3)
426	>	wsum += sumambient(acol, r, rn, al,
427	>	at->kid+i, ck0, s);
428	>	}
429	>	/* good enough? */
430	>	if ((wsum >= 0.05) & (s*ambacc > minarad))
431	>	return(wsum);
432	>	}
433	>	/* adjust maximum angle */
434	>	if (at->alist != NULL && (at->alist->lvl <= al) & (r->rweight < 0.6))
435	>	maxangle = (maxangle - PI/2.)*pow(r->rweight,0.13) + PI/2.;
436	>	/* sum this node */
437		for (av = at->alist; av != NULL; av = av->next) {
438	<	double rn_dot = -2.0;
439	<	if (tracktime)
440	<	av->latick = ambclock;
438	>	double u, v, d, delta_r2, delta_t2;
439	>	SCOLOR sct;
440	>	FVECT uvw[3];
441		/*
442	<	* Ambient level test.
442	>	* Ambient level test
443		*/
444	<	if (av->lvl > al) /* list sorted, so this works */
444	>	if (av->lvl > al \|\| /* list sorted, so this works */
445	>	(av->lvl == al) & (av->weight < 0.9*r->rweight))
446		break;
358	–	if (av->weight < 0.9*r->rweight)
359	–	continue;
447		/*
448	<	* Ambient radius test.
448	>	* Direction test using unperturbed normal
449		*/
450	<	VSUB(ck0, av->pos, r->rop);
451	<	e1 = DOT(ck0, ck0) / (av->rad * av->rad);
452	<	if (e1 > ambaccambacc1.21)
450	>	decodedir(uvw[2], av->ndir);
451	>	d = DOT(uvw[2], r->ron);
452	>	if (d <= 0.0) /* >= 90 degrees */
453		continue;
454	+	delta_r2 = 2.0 - 2.0d; / approx. radians^2 */
455	+	if (delta_r2 >= maxangle*maxangle)
456	+	continue;
457		/*
458	<	* Direction test using closest normal.
458	>	* Modified ray behind test
459		*/
460	<	d = DOT(av->dir, r->ron);
461	<	if (rn != r->ron) {
462	<	rn_dot = DOT(av->dir, rn);
373	<	if (rn_dot > 1.0-FTINY)
374	<	rn_dot = 1.0-FTINY;
375	<	if (rn_dot >= d-FTINY) {
376	<	d = rn_dot;
377	<	rn_dot = -2.0;
378	<	}
379	<	}
380	<	e2 = (1.0 - d) * r->rweight;
381	<	if (e2 < 0.0)
382	<	e2 = 0.0;
383	<	else if (e1 + e2 > ambaccambacc1.21)
460	>	VSUB(ck0, r->rop, av->pos);
461	>	d = DOT(ck0, uvw[2]);
462	>	if (d < -minarad*ambacc)
463		continue;
464	+	d /= av->rad[0];
465	+	delta_t2 = d*d;
466	+	if (delta_t2 >= ambacc*ambacc)
467	+	continue;
468		/*
469	<	* Ray behind test.
469	>	* Elliptical radii test based on Hessian
470		*/
471	<	d = 0.0;
472	<	for (j = 0; j < 3; j++)
473	<	d += (r->rop[j] - av->pos[j]) *
474	<	(av->dir[j] + r->ron[j]);
475	<	if (d0.5 < -minaradambacc-.001)
471	>	decodedir(uvw[0], av->udir);
472	>	VCROSS(uvw[1], uvw[2], uvw[0]);
473	>	d = (u = DOT(ck0, uvw[0])) / av->rad[0];
474	>	delta_t2 += d*d;
475	>	d = (v = DOT(ck0, uvw[1])) / av->rad[1];
476	>	delta_t2 += d*d;
477	>	if (delta_t2 >= ambacc*ambacc)
478		continue;
479		/*
480	<	* Jittering final test reduces image artifacts.
480	>	* Test for potential light leak
481		*/
482	<	e1 = sqrt(e1);
398	<	e2 = sqrt(e2);
399	<	wt = e1 + e2;
400	<	if (wt > ambacc(.9+.2urand(9015+samplendx)))
482	>	if (av->corral && plugaleak(r, av, uvw[2], atan2a(v,u)))
483		continue;
484		/*
485	<	* Recompute directional error using perturbed normal
485	>	* Extrapolate value and compute final weight (hat function)
486		*/
487	<	if (rn_dot > 0.0) {
488	<	e2 = sqrt((1.0 - rn_dot)*r->rweight);
489	<	wt = e1 + e2;
490	<	}
491	<	if (wt <= 1e-3)
492	<	wt = 1e3;
493	<	else
412	<	wt = 1.0 / wt;
413	<	wsum += wt;
414	<	extambient(ct, av, r->rop, rn);
415	<	scalecolor(ct, wt);
416	<	addcolor(acol, ct);
487	>	if (!extambient(sct, av, r->rop, rn, uvw))
488	>	continue;
489	>	d = tfunc(maxangle, sqrt(delta_r2), 0.0) *
490	>	tfunc(ambacc, sqrt(delta_t2), 0.0);
491	>	scalescolor(sct, d);
492	>	saddscolor(acol, sct);
493	>	wsum += d;
494		}
418	–	if (at->kid == NULL)
419	–	return(wsum);
420	–	/* do children */
421	–	s *= 0.5;
422	–	for (i = 0; i < 8; i++) {
423	–	for (j = 0; j < 3; j++) {
424	–	ck0[j] = c0[j];
425	–	if (1<<j & i)
426	–	ck0[j] += s;
427	–	if (r->rop[j] < ck0[j] - OCTSCALE*s)
428	–	break;
429	–	if (r->rop[j] > ck0[j] + (1.0+OCTSCALE)*s)
430	–	break;
431	–	}
432	–	if (j == 3)
433	–	wsum += sumambient(acol, r, rn, al,
434	–	at->kid+i, ck0, s);
435	–	}
495		return(wsum);
496		}
497
498
499	<	extern double
499	>	static int
500		makeambient( /* make a new ambient value for storage */
501	<	COLOR acol,
501	>	SCOLOR acol,
502		RAY *r,
503		FVECT rn,
504		int al
505		)
506		{
507		AMBVAL amb;
508	<	FVECT gp, gd;
508	>	FVECT uvw[3];
509		int i;
510
511		amb.weight = 1.0; /* compute weight */
#	Line 454 \| Line 513 \| *makeambient( / make a new ambient value for storage**
513		amb.weight *= AVGREFL;
514		if (r->rweight < 0.1amb.weight) / heuristic override */
515		amb.weight = 1.25*r->rweight;
516	<	setcolor(acol, AVGREFL, AVGREFL, AVGREFL);
516	>	setscolor(acol, AVGREFL, AVGREFL, AVGREFL);
517		/* compute ambient */
518	<	amb.rad = doambient(acol, r, amb.weight, gp, gd);
519	<	if (amb.rad <= FTINY) {
520	<	setcolor(acol, 0.0, 0.0, 0.0);
521	<	return(0.0);
522	<	}
464	<	scalecolor(acol, 1./AVGREFL); /* undo assumed reflectance */
518	>	i = doambient(acol, r, amb.weight,
519	>	uvw, amb.rad, amb.gpos, amb.gdir, &amb.corral);
520	>	scalescolor(acol, 1./AVGREFL); /* undo assumed reflectance */
521	>	if (i <= 0 \|\| amb.rad[0] <= FTINY) /* no Hessian or zero radius */
522	>	return(i);
523		/* store value */
524		VCOPY(amb.pos, r->rop);
525	<	VCOPY(amb.dir, r->ron);
525	>	amb.ndir = encodedir(r->ron);
526	>	amb.udir = encodedir(uvw[0]);
527		amb.lvl = al;
528	<	copycolor(amb.val, acol);
470	<	VCOPY(amb.gpos, gp);
471	<	VCOPY(amb.gdir, gd);
528	>	copyscolor(amb.val, acol);
529		/* insert into tree */
530		avsave(&amb); /* and save to file */
531	<	if (rn != r->ron)
532	<	extambient(acol, &amb, r->rop, rn); /* texture */
533	<	return(amb.rad);
531	>	if (rn != r->ron) { /* texture */
532	>	VCOPY(uvw[2], r->ron);
533	>	extambient(acol, &amb, r->rop, rn, uvw);
534	>	}
535	>	return(1);
536		}
537
538
539	<	extern void
539	>	static int
540		extambient( /* extrapolate value at pv, nv */
541	<	COLOR cr,
541	>	SCOLOR scr,
542		AMBVAL *ap,
543		FVECT pv,
544	<	FVECT nv
544	>	FVECT nv,
545	>	FVECT uvw[3]
546		)
547		{
548	<	FVECT v1;
548	>	const double min_d = 0.05;
549	>	const double max_d = 20.;
550	>	static FVECT my_uvw[3];
551	>	FVECT v1;
552	>	int i;
553	>	double d = 1.0; /* zeroeth order */
554	>
555	>	if (uvw == NULL) { /* need local coordinates? */
556	>	decodedir(my_uvw[2], ap->ndir);
557	>	decodedir(my_uvw[0], ap->udir);
558	>	VCROSS(my_uvw[1], my_uvw[2], my_uvw[0]);
559	>	uvw = my_uvw;
560	>	}
561	>	for (i = 3; i--; ) /* gradient due to translation */
562	>	d += (pv[i] - ap->pos[i]) *
563	>	(ap->gpos[0]uvw[0][i] + ap->gpos[1]uvw[1][i]);
564	>
565	>	VCROSS(v1, uvw[2], nv); /* gradient due to rotation */
566	>	for (i = 3; i--; )
567	>	d += v1[i] * (ap->gdir[0]uvw[0][i] + ap->gdir[1]uvw[1][i]);
568	>
569	>	if (d < min_d) /* clamp min/max scaling */
570	>	d = min_d;
571	>	else if (d > max_d)
572	>	d = max_d;
573	>	copyscolor(scr, ap->val);
574	>	scalescolor(scr, d);
575	>	return(d > min_d);
576	>	}
577	>
578	>
579	>	static void
580	>	avinsert( /* insert ambient value in our tree */
581	>	AMBVAL *av
582	>	)
583	>	{
584	>	AMBTREE *at;
585	>	AMBVAL *ap;
586	>	AMBVAL avh;
587	>	FVECT ck0;
588	>	double s;
589	>	int branch;
590		int i;
490	–	double d;
591
592	<	d = 1.0; /* zeroeth order */
593	<	/* gradient due to translation */
594	<	for (i = 0; i < 3; i++)
595	<	d += ap->gpos[i]*(pv[i]-ap->pos[i]);
596	<	/* gradient due to rotation */
597	<	VCROSS(v1, ap->dir, nv);
598	<	d += DOT(ap->gdir, v1);
599	<	if (d <= 0.0) {
600	<	setcolor(cr, 0.0, 0.0, 0.0);
601	<	return;
592	>	if (av->rad[0] <= FTINY)
593	>	error(CONSISTENCY, "zero ambient radius in avinsert");
594	>	at = &atrunk;
595	>	VCOPY(ck0, thescene.cuorg);
596	>	s = thescene.cusize;
597	>	while (s(OCTSCALE/2) > av->rad[1]ambacc) {
598	>	if (at->kid == NULL)
599	>	if ((at->kid = newambtree()) == NULL)
600	>	error(SYSTEM, "out of memory in avinsert");
601	>	s *= 0.5;
602	>	branch = 0;
603	>	for (i = 0; i < 3; i++)
604	>	if (av->pos[i] > ck0[i] + s) {
605	>	ck0[i] += s;
606	>	branch \|= 1 << i;
607	>	}
608	>	at = at->kid + branch;
609		}
610	<	copycolor(cr, ap->val);
611	<	scalecolor(cr, d);
610	>	avh.next = at->alist; /* order by increasing level */
611	>	for (ap = &avh; ap->next != NULL; ap = ap->next)
612	>	if ( ap->next->lvl > av->lvl \|\|
613	>	(ap->next->lvl == av->lvl) &
614	>	(ap->next->weight <= av->weight) )
615	>	break;
616	>	av->next = ap->next;
617	>	ap->next = (AMBVAL*)av;
618	>	at->alist = avh.next;
619		}
620
621
#	Line 520 \| Line 634 \| *initambfile( / initialize ambient file /*
634		if (mybuf == NULL)
635		mybuf = (char *)bmalloc(BUFSIZ+8);
636		setbuf(ambfp, mybuf);
637	+	retry:
638		if (cre8) { /* new file */
639		newheader("RADIANCE", ambfp);
640		fprintf(ambfp, "%s -av %g %g %g -aw %d -ab %d -aa %g ",
#	Line 528 \| Line 643 \| *initambfile( / initialize ambient file /*
643		ambvwt, ambounce, ambacc);
644		fprintf(ambfp, "-ad %d -as %d -ar %d ",
645		ambdiv, ambssamp, ambres);
646	+	fprintf(ambfp, "-dr %d -ds %g -dt %g -dc %g ", directrelay,
647	+	srcsizerat, shadthresh, shadcert);
648	+	fprintf(ambfp, "-ss %g -st %g -lr %d -lw %g ", specjitter,
649	+	specthresh, maxdepth, minweight);
650	+	fprintf(ambfp, "-cw %g %g -cs %d ", WLPART[3], WLPART[0], NCSAMP);
651		if (octname != NULL)
652		fputs(octname, ambfp);
653	<	fputc('\n', ambfp);
653	>	fputc('\n', ambfp); /* end of command line, not header! */
654		fprintf(ambfp, "SOFTWARE= %s\n", VersionID);
655		fputnow(ambfp);
656	+	AMB_CNDX = CNDX; /* use current spectral sampling */
657	+	AMB_WLPART = WLPART;
658	+	fputwlsplit(WLPART, ambfp);
659	+	fputncomp(NCSAMP, ambfp);
660		fputformat(AMBFMT, ambfp);
661		fputc('\n', ambfp);
662		putambmagic(ambfp);
663	<	} else if (checkheader(ambfp, AMBFMT, NULL) < 0 \|\| !hasambmagic(ambfp))
664	<	error(USER, "bad ambient file");
663	>	} else if (getheader(ambfp, amb_headline, NULL) < 0 \|\| !hasambmagic(ambfp)) {
664	>	#ifndef F_SETLKW
665	>	static int ntries = 0;
666	>	if (++ntries < 4 && ftell(ambfp) == 0) {
667	>	sleep(2);
668	>	goto retry;
669	>	}
670	>	#endif
671	>	error(USER, "bad/incompatible ambient file");
672	>	}
673	>	if ((AMB_CNDX != CNDX) \| (AMB_WLPART != WLPART)) {
674	>	if (setspectrsamp(AMB_CNDX, AMB_WLPART) < 0)
675	>	error(USER, "bad wavelength sampling in ambient file");
676	>	if (AMB_CNDX[3] == CNDX[3] && FABSEQ(AMB_WLPART[0],WLPART[0]) &&
677	>	FABSEQ(AMB_WLPART[3],WLPART[3])) {
678	>	AMB_CNDX = CNDX;
679	>	AMB_WLPART = WLPART; /* just the same */
680	>	} else
681	>	error(WARNING, "different ambient file wavelength sampling");
682	>	}
683		}
684
685
#	Line 546 \| Line 688 \| *avsave( / insert and save an ambient value /*
688		AMBVAL *av
689		)
690		{
691	<	avinsert(avstore(av));
691	>	avstore(av);
692		if (ambfp == NULL)
693		return;
694		if (writambval(av, ambfp) < 0)
#	Line 561 \| Line 703 \| writerr:
703
704
705		static AMBVAL *
706	<	avstore( /* allocate memory and store aval */
706	>	avstore( /* allocate memory and save aval */
707		AMBVAL *aval
708		)
709		{
#	Line 570 \| Line 712 \| *avstore( / allocate memory and store aval /*
712
713		if ((av = newambval()) == NULL)
714		error(SYSTEM, "out of memory in avstore");
715	<	av = aval;
574	<	av->latick = ambclock;
715	>	memcpy(av, aval, AVSIZE); /* AVSIZE <= sizeof(AMBVAL) */
716		av->next = NULL;
717		nambvals++;
718	<	d = bright(av->val);
718	>	d = pbright(av->val);
719		if (d > FTINY) { /* add to log sum for averaging */
720		avsum += log(d);
721		navsum++;
722		}
723	+	avinsert(av); /* insert in our cache tree */
724		return(av);
725		}
726
#	Line 605 \| Line 747 \| *newambtree(void) / allocate 8 ambient tree structs**
747		}
748		atp = atfreelist;
749		atfreelist = atp->kid;
750	<	memset((char )atp, '\0', 8sizeof(AMBTREE));
750	>	memset(atp, 0, 8*sizeof(AMBTREE));
751		return(atp);
752		}
753
#	Line 621 \| Line 763 \| *freeambtree( / free 8 ambient tree structs /*
763
764
765		static void
624	–	avinsert( /* insert ambient value in our tree */
625	–	void *av
626	–	)
627	–	{
628	–	AMBTREE *at;
629	–	AMBVAL *ap;
630	–	AMBVAL avh;
631	–	FVECT ck0;
632	–	double s;
633	–	int branch;
634	–	int i;
635	–
636	–	if (((AMBVAL*)av)->rad <= FTINY)
637	–	error(CONSISTENCY, "zero ambient radius in avinsert");
638	–	at = &atrunk;
639	–	VCOPY(ck0, thescene.cuorg);
640	–	s = thescene.cusize;
641	–	while (s(OCTSCALE/2) > ((AMBVAL)av)->rad*ambacc) {
642	–	if (at->kid == NULL)
643	–	if ((at->kid = newambtree()) == NULL)
644	–	error(SYSTEM, "out of memory in avinsert");
645	–	s *= 0.5;
646	–	branch = 0;
647	–	for (i = 0; i < 3; i++)
648	–	if (((AMBVAL*)av)->pos[i] > ck0[i] + s) {
649	–	ck0[i] += s;
650	–	branch \|= 1 << i;
651	–	}
652	–	at = at->kid + branch;
653	–	}
654	–	avh.next = at->alist; /* order by increasing level */
655	–	for (ap = &avh; ap->next != NULL; ap = ap->next)
656	–	if (ap->next->lvl >= ((AMBVAL*)av)->lvl)
657	–	break;
658	–	((AMBVAL*)av)->next = ap->next;
659	–	ap->next = (AMBVAL*)av;
660	–	at->alist = avh.next;
661	–	}
662	–
663	–
664	–	static void
766		unloadatree( /* unload an ambient value tree */
767		AMBTREE *at,
768		unloadtf_t *f
#	Line 672 \| Line 773 \| *unloadatree( / unload an ambient value tree /*
773		/* transfer values at this node */
774		for (av = at->alist; av != NULL; av = at->alist) {
775		at->alist = av->next;
776	+	av->next = NULL;
777		(*f)(av);
778		}
779		if (at->kid == NULL)
#	Line 683 \| Line 785 \| *unloadatree( / unload an ambient value tree /*
785		}
786
787
686	–	static struct avl {
687	–	AMBVAL *p;
688	–	unsigned long t;
689	–	} avlist1; / ambient value list with ticks */
690	–	static AMBVAL *avlist2; / memory positions for sorting */
691	–	static int i_avlist; /* index for lists */
692	–
693	–	static int alatcmp(const void av1, const void av2);
694	–
788		static void
789	<	av2list(
697	<	void *av
698	<	)
789	>	avfree(AMBVAL *av)
790		{
791	<	#ifdef DEBUG
701	<	if (i_avlist >= nambvals)
702	<	error(CONSISTENCY, "too many ambient values in av2list1");
703	<	#endif
704	<	avlist1[i_avlist].p = avlist2[i_avlist] = (AMBVAL*)av;
705	<	avlist1[i_avlist++].t = ((AMBVAL*)av)->latick;
791	>	free(av);
792		}
793
794
795	<	static int
796	<	alatcmp( /* compare ambient values for MRA */
711	<	const void *av1,
712	<	const void *av2
713	<	)
795	>	static void
796	>	sortambvals(void) /* resort ambient values */
797		{
798	<	long lc = ((struct avl )av2)->t - ((struct avl )av1)->t;
716	<	return(lc<0 ? -1 : lc>0 ? 1 : 0);
717	<	}
798	>	AMBTREE oldatrunk = atrunk;
799
800	<
801	<	/* GW NOTE 2002/10/3:
802	<	* I used to compare AMBVAL pointers, but found that this was the
722	<	* cause of a serious consistency error with gcc, since the optimizer
723	<	* uses some dangerous trick in pointer subtraction that
724	<	* assumes pointers differ by exact struct size increments.
725	<	*/
726	<	static int
727	<	aposcmp( /* compare ambient value positions */
728	<	const void *avp1,
729	<	const void *avp2
730	<	)
731	<	{
732	<	long diff = (char const )avp1 - (char * const *)avp2;
733	<	if (diff < 0)
734	<	return(-1);
735	<	return(diff > 0);
800	>	atrunk.alist = NULL;
801	>	atrunk.kid = NULL;
802	>	unloadatree(&oldatrunk, avinsert);
803		}
804
738	–	#if 1
739	–	static int
740	–	avlmemi( /* find list position from address */
741	–	AMBVAL *avaddr
742	–	)
743	–	{
744	–	AMBVAL **avlpp;
805
746	–	avlpp = (AMBVAL *)bsearch((char )&avaddr, (char *)avlist2,
747	–	nambvals, sizeof(AMBVAL *), aposcmp);
748	–	if (avlpp == NULL)
749	–	error(CONSISTENCY, "address not found in avlmemi");
750	–	return(avlpp - avlist2);
751	–	}
752	–	#else
753	–	#define avlmemi(avaddr) ((AMBVAL *)bsearch((char )&avaddr,(char *)avlist2, \
754	–	nambvals,sizeof(AMBVAL *),aposcmp) - avlist2)
755	–	#endif
756	–
757	–
758	–	static void
759	–	sortambvals( /* resort ambient values */
760	–	int always
761	–	)
762	–	{
763	–	AMBTREE oldatrunk;
764	–	AMBVAL tav, tap, pnext;
765	–	int i, j;
766	–	/* see if it's time yet */
767	–	if (!always && (ambclock++ < lastsort+sortintvl \|\|
768	–	nambvals < SORT_THRESH))
769	–	return;
770	–	/*
771	–	* The idea here is to minimize memory thrashing
772	–	* in VM systems by improving reference locality.
773	–	* We do this by periodically sorting our stored ambient
774	–	* values in memory in order of most recently to least
775	–	* recently accessed. This ordering was chosen so that new
776	–	* ambient values (which tend to be less important) go into
777	–	* higher memory with the infrequently accessed values.
778	–	* Since we expect our values to need sorting less
779	–	* frequently as the process continues, we double our
780	–	* waiting interval after each call.
781	–	* This routine is also called by setambacc() with
782	–	* the "always" parameter set to 1 so that the ambient
783	–	* tree will be rebuilt with the new accuracy parameter.
784	–	*/
785	–	if (tracktime) { /* allocate pointer arrays to sort */
786	–	avlist2 = (AMBVAL *)malloc(nambvalssizeof(AMBVAL *));
787	–	avlist1 = (struct avl )malloc(nambvalssizeof(struct avl));
788	–	} else {
789	–	avlist2 = NULL;
790	–	avlist1 = NULL;
791	–	}
792	–	if (avlist1 == NULL) { /* no time tracking -- rebuild tree? */
793	–	if (avlist2 != NULL)
794	–	free((void *)avlist2);
795	–	if (always) { /* rebuild without sorting */
796	–	oldatrunk = atrunk;
797	–	atrunk.alist = NULL;
798	–	atrunk.kid = NULL;
799	–	unloadatree(&oldatrunk, avinsert);
800	–	}
801	–	} else { /* sort memory by last access time */
802	–	/*
803	–	* Sorting memory is tricky because it isn't contiguous.
804	–	* We have to sort an array of pointers by MRA and also
805	–	* by memory position. We then copy values in "loops"
806	–	* to minimize memory hits. Nevertheless, we will visit
807	–	* everyone at least twice, and this is an expensive process
808	–	* when we're thrashing, which is when we need to do it.
809	–	*/
810	–	#ifdef DEBUG
811	–	sprintf(errmsg, "sorting %u ambient values at ambclock=%lu...",
812	–	nambvals, ambclock);
813	–	eputs(errmsg);
814	–	#endif
815	–	i_avlist = 0;
816	–	unloadatree(&atrunk, av2list); /* empty current tree */
817	–	#ifdef DEBUG
818	–	if (i_avlist < nambvals)
819	–	error(CONSISTENCY, "missing ambient values in sortambvals");
820	–	#endif
821	–	qsort((char *)avlist1, nambvals, sizeof(struct avl), alatcmp);
822	–	qsort((char )avlist2, nambvals, sizeof(AMBVAL ), aposcmp);
823	–	for (i = 0; i < nambvals; i++) {
824	–	if (avlist1[i].p == NULL)
825	–	continue;
826	–	tap = avlist2[i];
827	–	tav = *tap;
828	–	for (j = i; (pnext = avlist1[j].p) != tap;
829	–	j = avlmemi(pnext)) {
830	–	(avlist2[j]) = pnext;
831	–	avinsert(avlist2[j]);
832	–	avlist1[j].p = NULL;
833	–	}
834	–	*(avlist2[j]) = tav;
835	–	avinsert(avlist2[j]);
836	–	avlist1[j].p = NULL;
837	–	}
838	–	free((void *)avlist1);
839	–	free((void *)avlist2);
840	–	/* compute new sort interval */
841	–	sortintvl = ambclock - lastsort;
842	–	if (sortintvl >= MAX_SORT_INTVL/2)
843	–	sortintvl = MAX_SORT_INTVL;
844	–	else
845	–	sortintvl <<= 1; /* wait twice as long next */
846	–	#ifdef DEBUG
847	–	eputs("done\n");
848	–	#endif
849	–	}
850	–	if (ambclock >= MAXACLOCK)
851	–	ambclock = MAXACLOCK/2;
852	–	lastsort = ambclock;
853	–	}
854	–
855	–
806		#ifdef F_SETLKW
807
808		static void
#	Line 864 \| Line 814 \| *aflock( / lock/unlock ambient file /*
814
815		if (typ == fls.l_type) /* already called? */
816		return;
817	+
818		fls.l_type = typ;
819	<	if (fcntl(fileno(ambfp), F_SETLKW, &fls) < 0)
820	<	error(SYSTEM, "cannot (un)lock ambient file");
819	>	do
820	>	if (fcntl(fileno(ambfp), F_SETLKW, &fls) != -1)
821	>	return;
822	>	while (errno == EINTR);
823	>
824	>	error(SYSTEM, "cannot (un)lock ambient file");
825		}
826
827
828	<	extern int
828	>	int
829		ambsync(void) /* synchronize ambient file */
830		{
831		long flen;
#	Line 885 \| Line 840 \| *ambsync(void) / synchronize ambient file /*
840		if ((flen = lseek(fileno(ambfp), (off_t)0, SEEK_END)) < 0)
841		goto seekerr;
842		if ((n = flen - lastpos) > 0) { /* file has grown */
843	<	if (ambinp == NULL) { /* use duplicate filedes */
844	<	ambinp = fdopen(dup(fileno(ambfp)), "r");
843	>	if (ambinp == NULL) { /* get new file pointer */
844	>	ambinp = fopen(ambfile, "rb");
845		if (ambinp == NULL)
846	<	error(SYSTEM, "fdopen failed in ambsync");
846	>	error(SYSTEM, "fopen failed in ambsync");
847		}
848		if (fseek(ambinp, lastpos, SEEK_SET) < 0)
849		goto seekerr;
#	Line 900 \| Line 855 \| *ambsync(void) / synchronize ambient file /*
855		error(WARNING, errmsg);
856		break;
857		}
858	<	avinsert(avstore(&avs));
858	>	avstore(&avs);
859		n -= AMBVALSIZ;
860		}
861	<	lastpos = flen - n;
862	<	/*** seek always as safety measure
863	<	if (n) **/ / alignment */
909	<	if (lseek(fileno(ambfp), (off_t)lastpos, SEEK_SET) < 0)
910	<	goto seekerr;
861	>	lastpos = flen - n; /* check alignment */
862	>	if (n && lseek(fileno(ambfp), (off_t)lastpos, SEEK_SET) < 0)
863	>	goto seekerr;
864		}
865		n = fflush(ambfp); /* calls write() at last */
866	<	if (n != EOF)
914	<	lastpos += (long)nunflshed*AMBVALSIZ;
915	<	else if ((lastpos = lseek(fileno(ambfp), (off_t)0, SEEK_CUR)) < 0)
916	<	goto seekerr;
917	<
866	>	lastpos += (long)nunflshed*AMBVALSIZ;
867		aflock(F_UNLCK); /* release file */
868		nunflshed = 0;
869		return(n);
870		seekerr:
871		error(SYSTEM, "seek failed in ambsync");
872	<	return -1; /* pro forma return */
872	>	return(EOF); /* pro forma return */
873		}
874
875	<	#else
875	>	#else /* ! F_SETLKW */
876
877	<	extern int
877	>	int
878		ambsync(void) /* flush ambient file */
879		{
880		if (ambfp == NULL)
#	Line 934 \| Line 883 \| *ambsync(void) / flush ambient file /*
883		return(fflush(ambfp));
884		}
885
886	<	#endif
886	>	#endif /* ! F_SETLKW */

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Comparing ray/src/rt/ambient.c (file contents): Revision 2.70 by greg, Thu Sep 22 02:15:56 2011 UTC vs. Revision 2.121 by greg, Mon Jan 29 19:24:00 2024 UTC

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Comparing ray/src/rt/ambient.c (file contents):
Revision 2.70 by greg, Thu Sep 22 02:15:56 2011 UTC vs.
Revision 2.121 by greg, Mon Jan 29 19:24:00 2024 UTC