[ViewVC] Diff of: radiance/ray/src/common/bsdf

Comparing ray/src/common/bsdf_t.c (file contents):
Revision 3.6 by greg, Sun Apr 24 19:39:21 2011 UTC vs.
Revision 3.20 by greg, Sun Aug 21 22:38:12 2011 UTC

#	Line 10 \| Line 10 \| static const char RCSid[] = "$Id$";
10		*
11		*/
12
13	+	#define _USE_MATH_DEFINES
14		#include "rtio.h"
15		#include <stdlib.h>
16		#include <math.h>
#	Line 24 \| Line 25 \| *typedef int SDtreCallback(float val, const double cmi**
25		double csiz, void *cptr);
26
27		/* reference width maximum (1.0) */
28	+	static const unsigned iwbits = sizeof(unsigned)*4;
29		static const unsigned iwmax = (1<<(sizeof(unsigned)*4))-1;
30	+	/* maximum cumulative value */
31	+	static const unsigned cumlmax = ~0;
32	+	/* constant z-vector */
33	+	static const FVECT zvec = {.0, .0, 1.};
34
35		/* Struct used for our distribution-building callback */
36		typedef struct {
31	–	int wmin; /* minimum square size so far */
32	–	int wmax; /* maximum square size */
37		int nic; /* number of input coordinates */
38	<	int alen; /* current array length */
39	<	int nall; /* number of allocated entries */
38	>	unsigned alen; /* current array length */
39	>	unsigned nall; /* number of allocated entries */
40	>	unsigned wmin; /* minimum square size so far */
41	>	unsigned wmax; /* maximum square size */
42		struct outdir_s {
43		unsigned hent; /* entering Hilbert index */
44		int wid; /* this square size */
#	Line 57 \| Line 63 \| SDnewNode(int nd, int lg)
63		}
64		if (lg < 0) {
65		st = (SDNode *)malloc(sizeof(SDNode) +
66	<	((1<<nd) - 1)*sizeof(st->u.t[0]));
67	<	if (st != NULL)
62	<	memset(st->u.t, 0, sizeof(st->u.t[0])<<nd);
63	<	} else
64	<	st = (SDNode *)malloc(sizeof(SDNode) +
65	<	((1 << ndlg) - 1)sizeof(st->u.v[0]));
66	<
67	<	if (st == NULL) {
68	<	if (lg < 0)
66	>	sizeof(st->u.t[0])*((1<<nd) - 1));
67	>	if (st == NULL) {
68		sprintf(SDerrorDetail,
69		"Cannot allocate %d branch BSDF tree", 1<<nd);
70	<	else
70	>	return NULL;
71	>	}
72	>	memset(st->u.t, 0, sizeof(st->u.t[0])<<nd);
73	>	} else {
74	>	st = (SDNode *)malloc(sizeof(SDNode) +
75	>	sizeof(st->u.v[0])((1 << ndlg) - 1));
76	>	if (st == NULL) {
77		sprintf(SDerrorDetail,
78		"Cannot allocate %d BSDF leaves", 1 << nd*lg);
79	<	return NULL;
79	>	return NULL;
80	>	}
81		}
82		st->ndim = nd;
83		st->log2GR = lg;
#	Line 82 \| Line 88 \| SDnewNode(int nd, int lg)
88		static void
89		SDfreeTre(SDNode *st)
90		{
91	<	int i;
91	>	int n;
92
93		if (st == NULL)
94		return;
95	<	for (i = (st->log2GR < 0) << st->ndim; i--; )
96	<	SDfreeTre(st->u.t[i]);
97	<	free((void *)st);
95	>	for (n = (st->log2GR < 0) << st->ndim; n--; )
96	>	SDfreeTre(st->u.t[n]);
97	>	free(st);
98		}
99
100		/* Free a variable-resolution BSDF */
#	Line 103 \| Line 109 \| *SDFreeBTre(void p)**
109		free(sdt);
110		}
111
112	+	/* Fill branch's worth of grid values from subtree */
113	+	static void
114	+	fill_grid_branch(float dptr, const float sptr, int nd, int shft)
115	+	{
116	+	unsigned n = 1 << (shft-1);
117	+
118	+	if (!--nd) { /* end on the line */
119	+	memcpy(dptr, sptr, sizeof(dptr)n);
120	+	return;
121	+	}
122	+	while (n--) /* recurse on each slice */
123	+	fill_grid_branch(dptr + (n << shft*nd),
124	+	sptr + (n << (shft-1)*nd), nd, shft);
125	+	}
126	+
127	+	/* Get pointer at appropriate offset for the given branch */
128	+	static float *
129	+	grid_branch_start(SDNode *st, int n)
130	+	{
131	+	unsigned skipsiz = 1 << (st->log2GR - 1);
132	+	float *vptr = st->u.v;
133	+	int i;
134	+
135	+	for (i = st->ndim; i--; skipsiz <<= st->log2GR)
136	+	if (1<<i & n)
137	+	vptr += skipsiz;
138	+	return vptr;
139	+	}
140	+
141	+	/* Simplify (consolidate) a tree by flattening uniform depth regions */
142	+	static SDNode *
143	+	SDsimplifyTre(SDNode *st)
144	+	{
145	+	int match, n;
146	+
147	+	if (st == NULL) /* check for invalid tree */
148	+	return NULL;
149	+	if (st->log2GR >= 0) /* grid just returns unaltered */
150	+	return st;
151	+	match = 1; /* check if grids below match */
152	+	for (n = 0; n < 1<<st->ndim; n++) {
153	+	if ((st->u.t[n] = SDsimplifyTre(st->u.t[n])) == NULL)
154	+	return NULL; /* propogate error up call stack */
155	+	match &= (st->u.t[n]->log2GR == st->u.t[0]->log2GR);
156	+	}
157	+	if (match && (match = st->u.t[0]->log2GR) >= 0) {
158	+	SDNode *stn = SDnewNode(st->ndim, match + 1);
159	+	if (stn == NULL) /* out of memory? */
160	+	return st;
161	+	/* transfer values to new grid */
162	+	for (n = 1 << st->ndim; n--; )
163	+	fill_grid_branch(grid_branch_start(stn, n),
164	+	st->u.t[n]->u.v, stn->ndim, stn->log2GR);
165	+	SDfreeTre(st); /* free old tree */
166	+	st = stn; /* return new one */
167	+	}
168	+	return st;
169	+	}
170	+
171	+	/* Find smallest leaf in tree */
172	+	static double
173	+	SDsmallestLeaf(const SDNode *st)
174	+	{
175	+	if (st->log2GR < 0) { /* tree branches */
176	+	double lmin = 1.;
177	+	int n;
178	+	for (n = 1<<st->ndim; n--; ) {
179	+	double lsiz = SDsmallestLeaf(st->u.t[n]);
180	+	if (lsiz < lmin)
181	+	lmin = lsiz;
182	+	}
183	+	return .5*lmin;
184	+	}
185	+	/* leaf grid width */
186	+	return 1. / (double)(1 << st->log2GR);
187	+	}
188	+
189		/* Add up N-dimensional hypercube array values over the given box */
190		static double
191	<	SDiterSum(const float va, int nd, int siz, const int imin, const int *imax)
191	>	SDiterSum(const float va, int nd, int shft, const int imin, const int *imax)
192		{
193	+	const unsigned skipsiz = 1 << --nd*shft;
194		double sum = .0;
111	–	unsigned skipsiz = 1;
195		int i;
196	<
197	<	for (i = nd; --i > 0; )
198	<	skipsiz *= siz;
196	>
197	>	va += imin skipsiz;
198	>
199		if (skipsiz == 1)
200		for (i = imin; i < imax; i++)
201	<	sum += va[i];
201	>	sum += *va++;
202		else
203	<	for (i = imin; i < imax; i++)
204	<	sum += SDiterSum(va + i*skipsiz,
122	<	nd-1, siz, imin+1, imax+1);
203	>	for (i = imin; i < imax; i++, va += skipsiz)
204	>	sum += SDiterSum(va, nd, shft, imin+1, imax+1);
205		return sum;
206		}
207
#	Line 127 \| Line 209 \| *SDiterSum(const float va, int nd, int siz, const int**
209		static double
210		SDavgTreBox(const SDNode st, const double bmin, const double *bmax)
211		{
130	–	int imin[SD_MAXDIM], imax[SD_MAXDIM];
212		unsigned n;
213		int i;
214
#	Line 137 \| Line 218 \| *SDavgTreBox(const SDNode st, const double bmin, cons*
218		for (i = st->ndim; i--; ) {
219		if (bmin[i] >= 1.)
220		return .0;
221	<	if (bmax[i] <= .0)
221	>	if (bmax[i] <= 0)
222		return .0;
223		if (bmin[i] >= bmax[i])
224		return .0;
#	Line 145 \| Line 226 \| *SDavgTreBox(const SDNode st, const double bmin, cons*
226		if (st->log2GR < 0) { /* iterate on subtree */
227		double sum = .0, wsum = 1e-20;
228		double sbmin[SD_MAXDIM], sbmax[SD_MAXDIM], w;
148	–
229		for (n = 1 << st->ndim; n--; ) {
230		w = 1.;
231		for (i = st->ndim; i--; ) {
#	Line 157 \| Line 237 \| *SDavgTreBox(const SDNode st, const double bmin, cons*
237		}
238		if (sbmin[i] < .0) sbmin[i] = .0;
239		if (sbmax[i] > 1.) sbmax[i] = 1.;
240	+	if (sbmin[i] >= sbmax[i]) {
241	+	w = .0;
242	+	break;
243	+	}
244		w *= sbmax[i] - sbmin[i];
245		}
246		if (w > 1e-10) {
#	Line 165 \| Line 249 \| *SDavgTreBox(const SDNode st, const double bmin, cons*
249		}
250		}
251		return sum / wsum;
252	+	} else { /* iterate over leaves */
253	+	int imin[SD_MAXDIM], imax[SD_MAXDIM];
254	+
255	+	n = 1;
256	+	for (i = st->ndim; i--; ) {
257	+	imin[i] = (bmin[i] <= 0) ? 0 :
258	+	(int)((1 << st->log2GR)*bmin[i]);
259	+	imax[i] = (bmax[i] >= 1.) ? (1 << st->log2GR) :
260	+	(int)((1 << st->log2GR)*bmax[i] + .999999);
261	+	n *= imax[i] - imin[i];
262	+	}
263	+	if (n)
264	+	return SDiterSum(st->u.v, st->ndim,
265	+	st->log2GR, imin, imax) / (double)n;
266		}
267	<	n = 1; /* iterate over leaves */
170	<	for (i = st->ndim; i--; ) {
171	<	imin[i] = (bmin[i] <= .0) ? 0
172	<	: (int)((1 << st->log2GR)*bmin[i]);
173	<	imax[i] = (bmax[i] >= 1.) ? (1 << st->log2GR)
174	<	: (int)((1 << st->log2GR)*bmax[i] + .999999);
175	<	n *= imax[i] - imin[i];
176	<	}
177	<	if (!n)
178	<	return .0;
179	<
180	<	return SDiterSum(st->u.v, st->ndim, 1 << st->log2GR, imin, imax) /
181	<	(double)n;
267	>	return .0;
268		}
269
270		/* Recursive call for SDtraverseTre() */
#	Line 193 \| Line 279 \| *SDdotravTre(const SDNode st, const double pos, int c*
279		/* in branches? */
280		if (st->log2GR < 0) {
281		unsigned skipmask = 0;
196	–
282		csiz *= .5;
283		for (i = st->ndim; i--; )
284		if (1<<i & cmask)
285		if (pos[i] < cmin[i] + csiz)
286	<	for (n = 1 << st->ndim; n--; )
286	>	for (n = 1 << st->ndim; n--; ) {
287		if (n & 1<<i)
288		skipmask \|= 1<<n;
289	+	}
290		else
291	<	for (n = 1 << st->ndim; n--; )
291	>	for (n = 1 << st->ndim; n--; ) {
292		if (!(n & 1<<i))
293		skipmask \|= 1<<n;
294	+	}
295		for (n = 1 << st->ndim; n--; ) {
296		if (1<<n & skipmask)
297		continue;
#	Line 238 \| Line 325 \| *SDdotravTre(const SDNode st, const double pos, int c*
325		clim[i][0] = 0;
326		clim[i][1] = 1 << st->log2GR;
327		}
241	–	/* fill in unused dimensions */
242	–	for (i = SD_MAXDIM; i-- > st->ndim; ) {
243	–	clim[i][0] = 0; clim[i][1] = 1;
244	–	}
328		#if (SD_MAXDIM == 4)
329		bmin[0] = cmin[0] + csiz*clim[0][0];
330		for (cpos[0] = clim[0][0]; cpos[0] < clim[0][1]; cpos[0]++) {
331		bmin[1] = cmin[1] + csiz*clim[1][0];
332		for (cpos[1] = clim[1][0]; cpos[1] < clim[1][1]; cpos[1]++) {
333		bmin[2] = cmin[2] + csiz*clim[2][0];
334	<	for (cpos[2] = clim[2][0]; cpos[2] < clim[2][1]; cpos[2]++) {
335	<	bmin[3] = cmin[3] + csiz*(cpos[3] = clim[3][0]);
334	>	if (st->ndim == 3) {
335	>	cpos[2] = clim[2][0];
336		n = cpos[0];
337	<	for (i = 1; i < st->ndim; i++)
337	>	for (i = 1; i < 3; i++)
338		n = (n << st->log2GR) + cpos[i];
339	<	for ( ; cpos[3] < clim[3][1]; cpos[3]++) {
339	>	for ( ; cpos[2] < clim[2][1]; cpos[2]++) {
340		rval += rv = (*cf)(st->u.v[n++], bmin, csiz, cptr);
341		if (rv < 0)
342		return rv;
343	<	bmin[3] += csiz;
343	>	bmin[2] += csiz;
344		}
345	<	bmin[2] += csiz;
345	>	} else {
346	>	for (cpos[2] = clim[2][0]; cpos[2] < clim[2][1]; cpos[2]++) {
347	>	bmin[3] = cmin[3] + csiz*(cpos[3] = clim[3][0]);
348	>	n = cpos[0];
349	>	for (i = 1; i < 4; i++)
350	>	n = (n << st->log2GR) + cpos[i];
351	>	for ( ; cpos[3] < clim[3][1]; cpos[3]++) {
352	>	rval += rv = (*cf)(st->u.v[n++], bmin, csiz, cptr);
353	>	if (rv < 0)
354	>	return rv;
355	>	bmin[3] += csiz;
356	>	}
357	>	bmin[2] += csiz;
358	>	}
359		}
360		bmin[1] += csiz;
361		}
#	Line 334 \| Line 430 \| *SDlookupTre(const SDNode st, const double pos, doubl*
430		static float
431		SDqueryTre(const SDTre sdt, const FVECT outVec, const FVECT inVec, double hc)
432		{
337	–	static const FVECT zvec = {.0, .0, 1.};
433		FVECT rOutVec;
434		double gridPos[4];
435	<	/* check transmission */
436	<	if (!sdt->isxmit ^ outVec[2] > 0 ^ inVec[2] > 0)
435	>
436	>	switch (sdt->sidef) { /* whose side are you on? */
437	>	case SD_UFRONT:
438	>	if ((outVec[2] < 0) \| (inVec[2] < 0))
439	>	return -1.;
440	>	break;
441	>	case SD_UBACK:
442	>	if ((outVec[2] > 0) \| (inVec[2] > 0))
443	>	return -1.;
444	>	break;
445	>	case SD_XMIT:
446	>	if ((outVec[2] > 0) == (inVec[2] > 0))
447	>	return -1.;
448	>	break;
449	>	default:
450		return -1.;
451	+	}
452		/* convert vector coordinates */
453		if (sdt->st->ndim == 3) {
454	<	spinvector(rOutVec, outVec, zvec, -atan2(inVec[1],inVec[0]));
454	>	spinvector(rOutVec, outVec, zvec, -atan2(-inVec[1],-inVec[0]));
455		gridPos[0] = .5 - .5sqrt(inVec[0]inVec[0] + inVec[1]*inVec[1]);
456		SDdisk2square(gridPos+1, rOutVec[0], rOutVec[1]);
457		} else if (sdt->st->ndim == 4) {
#	Line 383 \| Line 492 \| *build_scaffold(float val, const double cmin, double c**
492		sp->wmax = wid;
493		if (sp->alen >= sp->nall) { /* need more space? */
494		struct outdir_s *ndarr;
495	<	sp->nall += 8192;
495	>	sp->nall += 1024;
496		ndarr = (struct outdir_s *)realloc(sp->darr,
497		sizeof(struct outdir_s)*sp->nall);
498	<	if (ndarr == NULL)
498	>	if (ndarr == NULL) {
499	>	sprintf(SDerrorDetail,
500	>	"Cannot grow scaffold to %u entries", sp->nall);
501		return -1; /* abort build */
502	+	}
503		sp->darr = ndarr;
504		}
505		/* find Hilbert entry index */
506		bmin[0] = cmin[0]*(double)iwmax + .5;
507		bmin[1] = cmin[1]*(double)iwmax + .5;
508	<	bmax[0] = bmin[0] + wid;
509	<	bmax[1] = bmin[1] + wid;
510	<	hilbert_box_vtx(2, sizeof(bitmask_t), sizeof(unsigned)*4,
511	<	1, bmin, bmax);
400	<	sp->darr[sp->alen].hent = hilbert_c2i(2, sizeof(unsigned)*4, bmin);
508	>	bmax[0] = bmin[0] + wid-1;
509	>	bmax[1] = bmin[1] + wid-1;
510	>	hilbert_box_vtx(2, sizeof(bitmask_t), iwbits, 1, bmin, bmax);
511	>	sp->darr[sp->alen].hent = hilbert_c2i(2, iwbits, bmin);
512		sp->darr[sp->alen].wid = wid;
513		sp->darr[sp->alen].bsdf = val;
514		sp->alen++; /* on to the next entry */
#	Line 408 \| Line 519 \| *build_scaffold(float val, const double cmin, double c**
519		static int
520		sscmp(const void p1, const void p2)
521		{
522	<	return (int)(((const struct outdir_s )p1).hent -
523	<	((const struct outdir_s )p2).hent);
522	>	unsigned h1 = ((const struct outdir_s )p1).hent;
523	>	unsigned h2 = ((const struct outdir_s )p2).hent;
524	>
525	>	if (h1 > h2)
526	>	return 1;
527	>	if (h1 < h2)
528	>	return -1;
529	>	return 0;
530		}
531
532		/* Create a new cumulative distribution for the given input direction */
533		static SDTreCDst *
534		make_cdist(const SDTre sdt, const double pos)
535		{
419	–	const unsigned cumlmax = ~0;
536		SDdistScaffold myScaffold;
537		SDTreCDst *cd;
538		struct outdir_s *sp;
#	Line 427 \| Line 543 \| *make_cdist(const SDTre sdt, const double pos)*
543		myScaffold.wmax = 0;
544		myScaffold.nic = sdt->st->ndim - 2;
545		myScaffold.alen = 0;
546	<	myScaffold.nall = 8192;
546	>	myScaffold.nall = 512;
547		myScaffold.darr = (struct outdir_s )malloc(sizeof(struct outdir_s)
548		myScaffold.nall);
549		if (myScaffold.darr == NULL)
#	Line 442 \| Line 558 \| *make_cdist(const SDTre sdt, const double pos)*
558		cd = (SDTreCDst *)malloc(sizeof(SDTreCDst) +
559		sizeof(cd->carr[0])*myScaffold.alen);
560		if (cd == NULL) {
561	+	sprintf(SDerrorDetail,
562	+	"Cannot allocate %u entry cumulative distribution",
563	+	myScaffold.alen);
564		free(myScaffold.darr);
565		return NULL;
566		}
567	+	cd->isodist = (myScaffold.nic == 1);
568		/* sort the distribution */
569		qsort(myScaffold.darr, cd->calen = myScaffold.alen,
570		sizeof(struct outdir_s), &sscmp);
571
572		/* record input range */
573	<	scale = (double)myScaffold.wmin / iwmax;
573	>	scale = myScaffold.wmin / (double)iwmax;
574		for (i = myScaffold.nic; i--; ) {
575	<	cd->clim[i][0] = floor(pos[i]/scale + .5) * scale;
575	>	cd->clim[i][0] = floor(pos[i]/scale) * scale;
576		cd->clim[i][1] = cd->clim[i][0] + scale;
577		}
578	+	if (cd->isodist) { /* avoid issue in SDqueryTreProjSA() */
579	+	cd->clim[1][0] = cd->clim[0][0];
580	+	cd->clim[1][1] = cd->clim[0][1];
581	+	}
582		cd->max_psa = myScaffold.wmax / (double)iwmax;
583		cd->max_psa = cd->max_psa M_PI;
584	<	cd->isxmit = sdt->isxmit;
584	>	cd->sidef = sdt->sidef;
585		cd->cTotal = 1e-20; /* compute directional total */
586		sp = myScaffold.darr;
587		for (i = myScaffold.alen; i--; sp++)
#	Line 466 \| Line 590 \| *make_cdist(const SDTre sdt, const double pos)*
590		scale = (double)cumlmax / cd->cTotal;
591		sp = myScaffold.darr;
592		for (i = 0; i < cd->calen; i++, sp++) {
593	+	cd->carr[i].hndx = sp->hent;
594		cd->carr[i].cuml = scale*cursum + .5;
595		cursum += sp->bsdf * (double)sp->wid * sp->wid;
596		}
#	Line 483 \| Line 608 \| *SDgetTreCDist(const FVECT inVec, SDComponent sdc)**
608		{
609		const SDTre *sdt;
610		double inCoord[2];
486	–	int vflags;
611		int i;
612		SDTreCDst cd, cdlast;
613		/* check arguments */
#	Line 498 \| Line 622 \| *SDgetTreCDist(const FVECT inVec, SDComponent sdc)**
622		return NULL; /* should be internal error */
623		cdlast = NULL; /* check for direction in cache list */
624		for (cd = (SDTreCDst *)sdc->cdList; cd != NULL;
625	<	cdlast = cd, cd = (SDTreCDst *)cd->next) {
625	>	cdlast = cd, cd = cd->next) {
626		for (i = sdt->st->ndim - 2; i--; )
627		if ((cd->clim[i][0] > inCoord[i]) \|
628		(inCoord[i] >= cd->clim[i][1]))
#	Line 510 \| Line 634 \| *SDgetTreCDist(const FVECT inVec, SDComponent sdc)**
634		cdlast = cd = make_cdist(sdt, inCoord);
635		if (cdlast != NULL) { /* move entry to head of cache list */
636		cdlast->next = cd->next;
637	<	cd->next = sdc->cdList;
637	>	cd->next = (SDTreCDst *)sdc->cdList;
638		sdc->cdList = (SDCDst *)cd;
639		}
640		return (SDCDst )cd; / ready to go */
#	Line 531 \| Line 655 \| *SDqueryTreProjSA(double psa, const FVECT v1, const RR**
655		const SDTre sdt = (SDTre )sdc->dist;
656		double hcube[SD_MAXDIM];
657		if (SDqueryTre(sdt, v1, v2, hcube) < 0) {
658	<	if (qflags == SDqueryVal)
659	<	*psa = M_PI;
536	<	return SDEnone;
658	>	strcpy(SDerrorDetail, "Bad call to SDqueryTreProjSA");
659	>	return SDEinternal;
660		}
661		myPSA[0] = hcube[sdt->st->ndim];
662		myPSA[1] = myPSA[0] = myPSA[0] M_PI;
#	Line 571 \| Line 694 \| SDsampTreCDist(FVECT ioVec, double randX, const SDCDst
694		{
695		const unsigned nBitsC = 4*sizeof(bitmask_t);
696		const unsigned nExtraBits = 8*(sizeof(bitmask_t)-sizeof(unsigned));
574	–	const unsigned maxval = ~0;
697		const SDTreCDst cd = (const SDTreCDst )cdp;
698	<	const unsigned target = randX*maxval;
698	>	const unsigned target = randX*cumlmax;
699		bitmask_t hndx, hcoord[2];
700	<	double gpos[3];
700	>	double gpos[3], rotangle;
701		int i, iupper, ilower;
702		/* check arguments */
703		if ((ioVec == NULL) \| (cd == NULL))
704		return SDEargument;
705	+	if (ioVec[2] > 0) {
706	+	if (!(cd->sidef & SD_UFRONT))
707	+	return SDEargument;
708	+	} else if (!(cd->sidef & SD_UBACK))
709	+	return SDEargument;
710		/* binary search to find position */
711		ilower = 0; iupper = cd->calen;
712		while ((i = (iupper + ilower) >> 1) != ilower)
713	<	if ((long)target >= (long)cd->carr[i].cuml)
713	>	if (target >= cd->carr[i].cuml)
714		ilower = i;
715		else
716		iupper = i;
717		/* localize random position */
718	<	randX = (randX*maxval - cd->carr[ilower].cuml) /
718	>	randX = (randX*cumlmax - cd->carr[ilower].cuml) /
719		(double)(cd->carr[iupper].cuml - cd->carr[ilower].cuml);
720		/* index in longer Hilbert curve */
721		hndx = (randXcd->carr[iupper].hndx + (1.-randX)cd->carr[ilower].hndx)
#	Line 599 \| Line 726 \| SDsampTreCDist(FVECT ioVec, double randX, const SDCDst
726		gpos[i] = ((double)hcoord[i] + rand()*(1./(RAND_MAX+.5))) /
727		(double)((bitmask_t)1 << nBitsC);
728		SDsquare2disk(gpos, gpos[0], gpos[1]);
729	+	/* compute Z-coordinate */
730		gpos[2] = 1. - gpos[0]gpos[0] - gpos[1]gpos[1];
731		if (gpos[2] > 0) /* paranoia, I hope */
732		gpos[2] = sqrt(gpos[2]);
733	<	if (ioVec[2] > 0 ^ !cd->isxmit)
733	>	/* emit from back? */
734	>	if (ioVec[2] > 0 ^ cd->sidef != SD_XMIT)
735		gpos[2] = -gpos[2];
736	<	VCOPY(ioVec, gpos);
736	>	if (cd->isodist) { /* rotate isotropic result */
737	>	rotangle = atan2(-ioVec[1],-ioVec[0]);
738	>	VCOPY(ioVec, gpos);
739	>	spinvector(ioVec, ioVec, zvec, rotangle);
740	>	} else
741	>	VCOPY(ioVec, gpos);
742		return SDEnone;
743		}
744
745	+	/* Advance pointer to the next non-white character in the string (or nul) */
746	+	static int
747	+	next_token(char **spp)
748	+	{
749	+	while (isspace(**spp))
750	+	++*spp;
751	+	return **spp;
752	+	}
753	+
754	+	/* Advance pointer past matching token (or any token if c==0) */
755	+	#define eat_token(spp,c) (next_token(spp)==(c) ^ !(c) ? ((spp))++ : 0)
756	+
757	+	/* Count words from this point in string to '}' */
758	+	static int
759	+	count_values(char *cp)
760	+	{
761	+	int n = 0;
762	+
763	+	while (next_token(&cp) != '}' && *cp) {
764	+	while (!isspace(cp) & (cp != ',') & (*cp != '}'))
765	+	if (!*++cp)
766	+	break;
767	+	++n;
768	+	eat_token(&cp, ',');
769	+	}
770	+	return n;
771	+	}
772	+
773	+	/* Load an array of real numbers, returning total */
774	+	static int
775	+	load_values(char *spp, float va, int n)
776	+	{
777	+	float *v = va;
778	+	char *svnext;
779	+
780	+	while (n-- > 0 && (svnext = fskip(*spp)) != NULL) {
781	+	v++ = atof(spp);
782	+	*spp = svnext;
783	+	eat_token(spp, ',');
784	+	}
785	+	return v - va;
786	+	}
787	+
788	+	/* Load BSDF tree data */
789	+	static SDNode *
790	+	load_tree_data(char **spp, int nd)
791	+	{
792	+	SDNode *st;
793	+	int n;
794	+
795	+	if (!eat_token(spp, '{')) {
796	+	strcpy(SDerrorDetail, "Missing '{' in tensor tree");
797	+	return NULL;
798	+	}
799	+	if (next_token(spp) == '{') { /* tree branches */
800	+	st = SDnewNode(nd, -1);
801	+	if (st == NULL)
802	+	return NULL;
803	+	for (n = 0; n < 1<<nd; n++)
804	+	if ((st->u.t[n] = load_tree_data(spp, nd)) == NULL) {
805	+	SDfreeTre(st);
806	+	return NULL;
807	+	}
808	+	} else { /* else load value grid */
809	+	int bsiz;
810	+	n = count_values(spp); / see how big the grid is */
811	+	for (bsiz = 0; bsiz < 8*sizeof(size_t); bsiz += nd)
812	+	if (1<<bsiz == n)
813	+	break;
814	+	if (bsiz >= 8*sizeof(size_t)) {
815	+	strcpy(SDerrorDetail, "Illegal value count in tensor tree");
816	+	return NULL;
817	+	}
818	+	st = SDnewNode(nd, bsiz/nd);
819	+	if (st == NULL)
820	+	return NULL;
821	+	if (load_values(spp, st->u.v, n) != n) {
822	+	strcpy(SDerrorDetail, "Real format error in tensor tree");
823	+	SDfreeTre(st);
824	+	return NULL;
825	+	}
826	+	}
827	+	if (!eat_token(spp, '}')) {
828	+	strcpy(SDerrorDetail, "Missing '}' in tensor tree");
829	+	SDfreeTre(st);
830	+	return NULL;
831	+	}
832	+	eat_token(spp, ',');
833	+	return st;
834	+	}
835	+
836	+	/* Compute min. proj. solid angle and max. direct hemispherical scattering */
837	+	static SDError
838	+	get_extrema(SDSpectralDF *df)
839	+	{
840	+	SDNode st = ((SDTre *)df->comp[0].dist).st;
841	+	double stepWidth, dhemi, bmin[4], bmax[4];
842	+
843	+	stepWidth = SDsmallestLeaf(st);
844	+	df->minProjSA = M_PIstepWidthstepWidth;
845	+	if (stepWidth < .03125)
846	+	stepWidth = .03125; /* 1/32 resolution good enough */
847	+	df->maxHemi = .0;
848	+	if (st->ndim == 3) { /* isotropic BSDF */
849	+	bmin[1] = bmin[2] = .0;
850	+	bmax[1] = bmax[2] = 1.;
851	+	for (bmin[0] = .0; bmin[0] < .5-FTINY; bmin[0] += stepWidth) {
852	+	bmax[0] = bmin[0] + stepWidth;
853	+	dhemi = SDavgTreBox(st, bmin, bmax);
854	+	if (dhemi > df->maxHemi)
855	+	df->maxHemi = dhemi;
856	+	}
857	+	} else if (st->ndim == 4) { /* anisotropic BSDF */
858	+	bmin[2] = bmin[3] = .0;
859	+	bmax[2] = bmax[3] = 1.;
860	+	for (bmin[0] = .0; bmin[0] < 1.-FTINY; bmin[0] += stepWidth) {
861	+	bmax[0] = bmin[0] + stepWidth;
862	+	for (bmin[1] = .0; bmin[1] < 1.-FTINY; bmin[1] += stepWidth) {
863	+	bmax[1] = bmin[1] + stepWidth;
864	+	dhemi = SDavgTreBox(st, bmin, bmax);
865	+	if (dhemi > df->maxHemi)
866	+	df->maxHemi = dhemi;
867	+	}
868	+	}
869	+	} else
870	+	return SDEinternal;
871	+	/* correct hemispherical value */
872	+	df->maxHemi *= M_PI;
873	+	return SDEnone;
874	+	}
875	+
876	+	/* Load BSDF distribution for this wavelength */
877	+	static SDError
878	+	load_bsdf_data(SDData *sd, ezxml_t wdb, int ndim)
879	+	{
880	+	SDSpectralDF *df;
881	+	SDTre *sdt;
882	+	char *sdata;
883	+	/* allocate BSDF component */
884	+	sdata = ezxml_txt(ezxml_child(wdb, "WavelengthDataDirection"));
885	+	if (!sdata)
886	+	return SDEnone;
887	+	/*
888	+	* Remember that front and back are reversed from WINDOW 6 orientations
889	+	*/
890	+	if (!strcasecmp(sdata, "Transmission")) {
891	+	if (sd->tf != NULL)
892	+	SDfreeSpectralDF(sd->tf);
893	+	if ((sd->tf = SDnewSpectralDF(1)) == NULL)
894	+	return SDEmemory;
895	+	df = sd->tf;
896	+	} else if (!strcasecmp(sdata, "Reflection Front")) {
897	+	if (sd->rb != NULL) /* note back-front reversal */
898	+	SDfreeSpectralDF(sd->rb);
899	+	if ((sd->rb = SDnewSpectralDF(1)) == NULL)
900	+	return SDEmemory;
901	+	df = sd->rb;
902	+	} else if (!strcasecmp(sdata, "Reflection Back")) {
903	+	if (sd->rf != NULL) /* note front-back reversal */
904	+	SDfreeSpectralDF(sd->rf);
905	+	if ((sd->rf = SDnewSpectralDF(1)) == NULL)
906	+	return SDEmemory;
907	+	df = sd->rf;
908	+	} else
909	+	return SDEnone;
910	+	/* XXX should also check "ScatteringDataType" for consistency? */
911	+	/* get angle bases */
912	+	sdata = ezxml_txt(ezxml_child(wdb,"AngleBasis"));
913	+	if (!sdata \|\| strcasecmp(sdata, "LBNL/Shirley-Chiu")) {
914	+	sprintf(SDerrorDetail, "%s angle basis for BSDF '%s'",
915	+	!sdata ? "Missing" : "Unsupported", sd->name);
916	+	return !sdata ? SDEformat : SDEsupport;
917	+	}
918	+	/* allocate BSDF tree */
919	+	sdt = (SDTre *)malloc(sizeof(SDTre));
920	+	if (sdt == NULL)
921	+	return SDEmemory;
922	+	if (df == sd->rf)
923	+	sdt->sidef = SD_UFRONT;
924	+	else if (df == sd->rb)
925	+	sdt->sidef = SD_UBACK;
926	+	else
927	+	sdt->sidef = SD_XMIT;
928	+	sdt->st = NULL;
929	+	df->comp[0].cspec[0] = c_dfcolor; /* XXX monochrome for now */
930	+	df->comp[0].dist = sdt;
931	+	df->comp[0].func = &SDhandleTre;
932	+	/* read BSDF data */
933	+	sdata = ezxml_txt(ezxml_child(wdb, "ScatteringData"));
934	+	if (!sdata \|\| !next_token(&sdata)) {
935	+	sprintf(SDerrorDetail, "Missing BSDF ScatteringData in '%s'",
936	+	sd->name);
937	+	return SDEformat;
938	+	}
939	+	sdt->st = load_tree_data(&sdata, ndim);
940	+	if (sdt->st == NULL)
941	+	return SDEformat;
942	+	if (next_token(&sdata)) { /* check for unconsumed characters */
943	+	sprintf(SDerrorDetail,
944	+	"Extra characters at end of ScatteringData in '%s'",
945	+	sd->name);
946	+	return SDEformat;
947	+	}
948	+	/* flatten branches where possible */
949	+	sdt->st = SDsimplifyTre(sdt->st);
950	+	if (sdt->st == NULL)
951	+	return SDEinternal;
952	+	return get_extrema(df); /* compute global quantities */
953	+	}
954	+
955	+	/* Find minimum value in tree */
956	+	static float
957	+	SDgetTreMin(const SDNode *st)
958	+	{
959	+	float vmin = FHUGE;
960	+	int n;
961	+
962	+	if (st->log2GR < 0) {
963	+	for (n = 1<<st->ndim; n--; ) {
964	+	float v = SDgetTreMin(st->u.t[n]);
965	+	if (v < vmin)
966	+	vmin = v;
967	+	}
968	+	} else {
969	+	for (n = 1<<(st->ndim*st->log2GR); n--; )
970	+	if (st->u.v[n] < vmin)
971	+	vmin = st->u.v[n];
972	+	}
973	+	return vmin;
974	+	}
975	+
976	+	/* Subtract the given value from all tree nodes */
977	+	static void
978	+	SDsubtractTreVal(SDNode *st, float val)
979	+	{
980	+	int n;
981	+
982	+	if (st->log2GR < 0) {
983	+	for (n = 1<<st->ndim; n--; )
984	+	SDsubtractTreVal(st->u.t[n], val);
985	+	} else {
986	+	for (n = 1<<(st->ndim*st->log2GR); n--; )
987	+	if ((st->u.v[n] -= val) < 0)
988	+	st->u.v[n] = .0f;
989	+	}
990	+	}
991	+
992	+	/* Subtract minimum value from BSDF */
993	+	static double
994	+	subtract_min(SDNode *st)
995	+	{
996	+	float vmin;
997	+	/* be sure to skip unused portion */
998	+	if (st->ndim == 3) {
999	+	int n;
1000	+	vmin = 1./M_PI;
1001	+	if (st->log2GR < 0) {
1002	+	for (n = 0; n < 8; n += 2) {
1003	+	float v = SDgetTreMin(st->u.t[n]);
1004	+	if (v < vmin)
1005	+	vmin = v;
1006	+	}
1007	+	} else if (st->log2GR) {
1008	+	for (n = 1 << (3*st->log2GR - 1); n--; )
1009	+	if (st->u.v[n] < vmin)
1010	+	vmin = st->u.v[n];
1011	+	} else
1012	+	vmin = st->u.v[0];
1013	+	} else /* anisotropic covers entire tree */
1014	+	vmin = SDgetTreMin(st);
1015	+
1016	+	if (vmin <= FTINY)
1017	+	return .0;
1018	+
1019	+	SDsubtractTreVal(st, vmin);
1020	+
1021	+	return M_PI * vmin; /* return hemispherical value */
1022	+	}
1023	+
1024	+	/* Extract and separate diffuse portion of BSDF */
1025	+	static void
1026	+	extract_diffuse(SDValue dv, SDSpectralDF df)
1027	+	{
1028	+	int n;
1029	+
1030	+	if (df == NULL \|\| df->ncomp <= 0) {
1031	+	dv->spec = c_dfcolor;
1032	+	dv->cieY = .0;
1033	+	return;
1034	+	}
1035	+	dv->spec = df->comp[0].cspec[0];
1036	+	dv->cieY = subtract_min(((SDTre )df->comp[0].dist).st);
1037	+	/* in case of multiple components */
1038	+	for (n = df->ncomp; --n; ) {
1039	+	double ymin = subtract_min(((SDTre )df->comp[n].dist).st);
1040	+	c_cmix(&dv->spec, dv->cieY, &dv->spec, ymin, &df->comp[n].cspec[0]);
1041	+	dv->cieY += ymin;
1042	+	}
1043	+	df->maxHemi -= dv->cieY; /* adjust maximum hemispherical */
1044	+	/* make sure everything is set */
1045	+	c_ccvt(&dv->spec, C_CSXY+C_CSSPEC);
1046	+	}
1047	+
1048		/* Load a variable-resolution BSDF tree from an open XML file */
1049		SDError
1050		SDloadTre(SDData *sd, ezxml_t wtl)
1051		{
1052	<	return SDEsupport;
1052	>	SDError ec;
1053	>	ezxml_t wld, wdb;
1054	>	int rank;
1055	>	char *txt;
1056	>	/* basic checks and tensor rank */
1057	>	txt = ezxml_txt(ezxml_child(ezxml_child(wtl,
1058	>	"DataDefinition"), "IncidentDataStructure"));
1059	>	if (txt == NULL \|\| !*txt) {
1060	>	sprintf(SDerrorDetail,
1061	>	"BSDF \"%s\": missing IncidentDataStructure",
1062	>	sd->name);
1063	>	return SDEformat;
1064	>	}
1065	>	if (!strcasecmp(txt, "TensorTree3"))
1066	>	rank = 3;
1067	>	else if (!strcasecmp(txt, "TensorTree4"))
1068	>	rank = 4;
1069	>	else {
1070	>	sprintf(SDerrorDetail,
1071	>	"BSDF \"%s\": unsupported IncidentDataStructure",
1072	>	sd->name);
1073	>	return SDEsupport;
1074	>	}
1075	>	/* load BSDF components */
1076	>	for (wld = ezxml_child(wtl, "WavelengthData");
1077	>	wld != NULL; wld = wld->next) {
1078	>	if (strcasecmp(ezxml_txt(ezxml_child(wld,"Wavelength")),
1079	>	"Visible"))
1080	>	continue; /* just visible for now */
1081	>	for (wdb = ezxml_child(wld, "WavelengthDataBlock");
1082	>	wdb != NULL; wdb = wdb->next)
1083	>	if ((ec = load_bsdf_data(sd, wdb, rank)) != SDEnone)
1084	>	return ec;
1085	>	}
1086	>	/* separate diffuse components */
1087	>	extract_diffuse(&sd->rLambFront, sd->rf);
1088	>	extract_diffuse(&sd->rLambBack, sd->rb);
1089	>	extract_diffuse(&sd->tLamb, sd->tf);
1090	>	/* return success */
1091	>	return SDEnone;
1092		}
1093
1094		/* Variable resolution BSDF methods */

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Comparing ray/src/common/bsdf_t.c (file contents): Revision 3.6 by greg, Sun Apr 24 19:39:21 2011 UTC vs. Revision 3.20 by greg, Sun Aug 21 22:38:12 2011 UTC

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Comparing ray/src/common/bsdf_t.c (file contents):
Revision 3.6 by greg, Sun Apr 24 19:39:21 2011 UTC vs.
Revision 3.20 by greg, Sun Aug 21 22:38:12 2011 UTC