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

Comparing ray/src/common/bsdf_m.c (file contents):
Revision 3.5 by greg, Sat Feb 19 23:42:09 2011 UTC vs.
Revision 3.32 by greg, Wed Apr 8 02:41:02 2015 UTC

#	Line 11 \| Line 11 \| static const char RCSid[] = "$Id$";
11		*
12		*/
13
14	+	#define _USE_MATH_DEFINES
15		#include "rtio.h"
15	–	#include <stdlib.h>
16		#include <math.h>
17		#include <ctype.h>
18		#include "ezxml.h"
#	Line 28 \| Line 28 \| static const char RCSid[] = "$Id$";
28		#define RC_INTERR (-4)
29		#define RC_MEMERR (-5)
30
31	<	#define MAXLATS 46 /* maximum number of latitudes */
32	<
33	<	/* BSDF angle specification */
34	<	typedef struct {
35	<	char name[64]; /* basis name */
36	<	int nangles; /* total number of directions */
37	<	struct {
38	<	float tmin; /* starting theta */
39	<	int nphis; /* number of phis (0 term) */
40	<	} lat[MAXLATS+1]; /* latitudes */
41	<	} ANGLE_BASIS;
42	<
43	<	#define MAXABASES 7 /* limit on defined bases */
44	<
45	<	static ANGLE_BASIS abase_list[MAXABASES] = {
31	>	ANGLE_BASIS abase_list[MAXABASES] = {
32		{
33		"LBNL/Klems Full", 145,
34	<	{ {-5., 1},
34	>	{ {0., 1},
35		{5., 8},
36		{15., 16},
37		{25., 20},
#	Line 57 \| Line 43 \| static ANGLE_BASIS abase_list[MAXABASES] = {
43		{90., 0} }
44		}, {
45		"LBNL/Klems Half", 73,
46	<	{ {-6.5, 1},
46	>	{ {0., 1},
47		{6.5, 8},
48		{19.5, 12},
49		{32.5, 16},
#	Line 67 \| Line 53 \| static ANGLE_BASIS abase_list[MAXABASES] = {
53		{90., 0} }
54		}, {
55		"LBNL/Klems Quarter", 41,
56	<	{ {-9., 1},
56	>	{ {0., 1},
57		{9., 8},
58		{27., 12},
59		{46., 12},
#	Line 76 \| Line 62 \| static ANGLE_BASIS abase_list[MAXABASES] = {
62		}
63		};
64
65	<	static int nabases = 3; /* current number of defined bases */
65	>	int nabases = 3; /* current number of defined bases */
66
67	+	C_COLOR mtx_RGB_prim[3]; /* our RGB primaries */
68	+	float mtx_RGB_coef[3]; /* corresponding Y coefficients */
69	+
70	+	enum {mtx_Y, mtx_X, mtx_Z}; /* matrix components (mtx_Y==0) */
71	+
72	+	/* check if two real values are near enough to equal */
73		static int
74		fequal(double a, double b)
75		{
76	<	if (b != .0)
76	>	if (b != 0)
77		a = a/b - 1.;
78		return (a <= 1e-6) & (a >= -1e-6);
79		}
80
81	<	/* returns the name of the given tag */
90	<	#ifdef ezxml_name
91	<	#undef ezxml_name
92	<	static char *
93	<	ezxml_name(ezxml_t xml)
94	<	{
95	<	if (xml == NULL)
96	<	return NULL;
97	<	return xml->name;
98	<	}
99	<	#endif
100	<
101	<	/* returns the given tag's character content or empty string if none */
102	<	#ifdef ezxml_txt
103	<	#undef ezxml_txt
104	<	static char *
105	<	ezxml_txt(ezxml_t xml)
106	<	{
107	<	if (xml == NULL)
108	<	return "";
109	<	return xml->txt;
110	<	}
111	<	#endif
112	<
113	<	/* Convert error to standard BSDF code */
81	>	/* convert error to standard BSDF code */
82		static SDError
83		convert_errcode(int ec)
84		{
#	Line 131 \| Line 99 \| convert_errcode(int ec)
99		return SDEunknown;
100		}
101
102	<	/* Allocate a BSDF matrix of the given size */
102	>	/* allocate a BSDF matrix of the given size */
103		static SDMat *
104		SDnewMatrix(int ni, int no)
105		{
#	Line 155 \| Line 123 \| SDnewMatrix(int ni, int no)
123		}
124
125		/* Free a BSDF matrix */
126	<	#define SDfreeMatrix free
126	>	void
127	>	SDfreeMatrix(void *ptr)
128	>	{
129	>	SDMat mp = (SDMat )ptr;
130
131	<	/* get vector for this angle basis index */
132	<	static int
133	<	ab_getvec(FVECT v, int ndx, double randX, void *p)
131	>	if (mp->chroma != NULL) free(mp->chroma);
132	>	free(ptr);
133	>	}
134	>
135	>	/* compute square of real value */
136	>	static double sq(double x) { return x*x; }
137	>
138	>	/* Get vector for this angle basis index (front exiting) */
139	>	int
140	>	fo_getvec(FVECT v, double ndxr, void *p)
141		{
142	<	ANGLE_BASIS ab = (ANGLE_BASIS )p;
142	>	ANGLE_BASIS ab = (ANGLE_BASIS )p;
143	>	int ndx = (int)ndxr;
144	>	double randX = ndxr - ndx;
145		double rx[2];
146		int li;
147	<	double pol, azi, d;
147	>	double azi, d;
148
149	<	if ((ndx < 0) \| (ndx >= ab->nangles))
149	>	if ((ndxr < 0) \| (ndx >= ab->nangles))
150		return RC_FAIL;
151		for (li = 0; ndx >= ab->lat[li].nphis; li++)
152		ndx -= ab->lat[li].nphis;
153		SDmultiSamp(rx, 2, randX);
154	<	pol = M_PI/180.( (1.-rx[0])ab->lat[li].tmin +
155	<	rx[0]*ab->lat[li+1].tmin );
154	>	d = (1. - randX)sq(cos(M_PI/180.ab->lat[li].tmin)) +
155	>	randXsq(cos(M_PI/180.ab->lat[li+1].tmin));
156	>	v[2] = d = sqrt(d); /* cos(pol) */
157		azi = 2.M_PI(ndx + rx[1] - .5)/ab->lat[li].nphis;
177	–	v[2] = d = cos(pol);
158		d = sqrt(1. - dd); / sin(pol) */
159		v[0] = cos(azi)*d;
160		v[1] = sin(azi)*d;
161		return RC_GOOD;
162		}
163
164	<	/* get index corresponding to the given vector */
165	<	static int
166	<	ab_getndx(const FVECT v, void *p)
164	>	/* Get index corresponding to the given vector (front exiting) */
165	>	int
166	>	fo_getndx(const FVECT v, void *p)
167		{
168	<	ANGLE_BASIS ab = (ANGLE_BASIS )p;
168	>	ANGLE_BASIS ab = (ANGLE_BASIS )p;
169		int li, ndx;
170	<	double pol, azi, d;
170	>	double pol, azi;
171
172		if (v == NULL)
173		return -1;
174	<	if ((v[2] < .0) \| (v[2] > 1.0))
174	>	if ((v[2] < 0) \| (v[2] > 1.))
175		return -1;
176	<	pol = 180.0/M_PI*acos(v[2]);
176	>	pol = 180.0/M_PI*Acos(v[2]);
177		azi = 180.0/M_PI*atan2(v[1], v[0]);
178		if (azi < 0.0) azi += 360.0;
179		for (li = 1; ab->lat[li].tmin <= pol; li++)
#	Line 207 \| Line 187 \| *ab_getndx(const FVECT v, void p)**
187		return ndx;
188		}
189
190	<	/* compute square of real value */
191	<	static double sq(double x) { return x*x; }
192	<
213	<	/* get projected solid angle for this angle basis index */
214	<	static double
215	<	ab_getohm(int ndx, void *p)
190	>	/* Get projected solid angle for this angle basis index (universal) */
191	>	double
192	>	io_getohm(int ndx, void *p)
193		{
194		static int last_li = -1;
195		static double last_ohm;
#	Line 227 \| Line 204 \| *ab_getohm(int ndx, void p)**
204		if (li == last_li) /* cached latitude? */
205		return last_ohm;
206		last_li = li;
230	–	theta1 = M_PI/180. * ab->lat[li+1].tmin;
231	–	if (ab->lat[li].nphis == 1) /* special case */
232	–	return last_ohm = M_PI*(1. - sq(cos(theta1)));
207		theta = M_PI/180. * ab->lat[li].tmin;
208	+	theta1 = M_PI/180. * ab->lat[li+1].tmin;
209		return last_ohm = M_PI*(sq(cos(theta)) - sq(cos(theta1))) /
210		(double)ab->lat[li].nphis;
211		}
212
213	<	/* get reverse vector for this angle basis index */
214	<	static int
215	<	ab_getvecR(FVECT v, int ndx, double randX, void *p)
213	>	/* Get vector for this angle basis index (back incident) */
214	>	int
215	>	bi_getvec(FVECT v, double ndxr, void *p)
216		{
217	<	int na = ((ANGLE_BASIS )p).nangles;
243	<
244	<	if (!ab_getvec(v, ndx, randX, p))
217	>	if (!fo_getvec(v, ndxr, p))
218		return RC_FAIL;
219
220		v[0] = -v[0];
#	Line 251 \| Line 224 \| *ab_getvecR(FVECT v, int ndx, double randX, void p)**
224		return RC_GOOD;
225		}
226
227	<	/* get index corresponding to the reverse vector */
228	<	static int
229	<	ab_getndxR(const FVECT v, void *p)
227	>	/* Get index corresponding to the vector (back incident) */
228	>	int
229	>	bi_getndx(const FVECT v, void *p)
230		{
231		FVECT v2;
232
#	Line 261 \| Line 234 \| *ab_getndxR(const FVECT v, void p)**
234		v2[1] = -v[1];
235		v2[2] = -v[2];
236
237	<	return ab_getndx(v2, p);
237	>	return fo_getndx(v2, p);
238		}
239
240	+	/* Get vector for this angle basis index (back exiting) */
241	+	int
242	+	bo_getvec(FVECT v, double ndxr, void *p)
243	+	{
244	+	if (!fo_getvec(v, ndxr, p))
245	+	return RC_FAIL;
246	+
247	+	v[2] = -v[2];
248	+
249	+	return RC_GOOD;
250	+	}
251	+
252	+	/* Get index corresponding to the vector (back exiting) */
253	+	int
254	+	bo_getndx(const FVECT v, void *p)
255	+	{
256	+	FVECT v2;
257	+
258	+	v2[0] = v[0];
259	+	v2[1] = v[1];
260	+	v2[2] = -v[2];
261	+
262	+	return fo_getndx(v2, p);
263	+	}
264	+
265	+	/* Get vector for this angle basis index (front incident) */
266	+	int
267	+	fi_getvec(FVECT v, double ndxr, void *p)
268	+	{
269	+	if (!fo_getvec(v, ndxr, p))
270	+	return RC_FAIL;
271	+
272	+	v[0] = -v[0];
273	+	v[1] = -v[1];
274	+
275	+	return RC_GOOD;
276	+	}
277	+
278	+	/* Get index corresponding to the vector (front incident) */
279	+	int
280	+	fi_getndx(const FVECT v, void *p)
281	+	{
282	+	FVECT v2;
283	+
284	+	v2[0] = -v[0];
285	+	v2[1] = -v[1];
286	+	v2[2] = v[2];
287	+
288	+	return fo_getndx(v2, p);
289	+	}
290	+
291	+	/* Get color or grayscale value for BSDF for the given direction pair */
292	+	int
293	+	mBSDF_color(float coef[], const SDMat *dp, int i, int o)
294	+	{
295	+	C_COLOR cxy;
296	+
297	+	coef[0] = mBSDF_value(dp, i, o);
298	+	if (dp->chroma == NULL)
299	+	return 1; /* grayscale */
300	+
301	+	c_decodeChroma(&cxy, dp->chroma[o*dp->ninc + i]);
302	+	c_toSharpRGB(&cxy, coef[0], coef);
303	+	coef[0] *= mtx_RGB_coef[0];
304	+	coef[1] *= mtx_RGB_coef[1];
305	+	coef[2] *= mtx_RGB_coef[2];
306	+	return 3; /* RGB color */
307	+	}
308	+
309		/* load custom BSDF angle basis */
310		static int
311		load_angle_basis(ezxml_t wab)
#	Line 295 \| Line 337 \| load_angle_basis(ezxml_t wab)
337		ezxml_child(ezxml_child(wbb,
338		"ThetaBounds"), "UpperTheta")));
339		if (!i)
340	<	abase_list[nabases].lat[i].tmin =
299	<	-abase_list[nabases].lat[i+1].tmin;
340	>	abase_list[nabases].lat[0].tmin = 0;
341		else if (!fequal(atof(ezxml_txt(ezxml_child(ezxml_child(wbb,
342		"ThetaBounds"), "LowerTheta"))),
343		abase_list[nabases].lat[i].tmin)) {
344		sprintf(SDerrorDetail, "Theta values disagree in '%s'",
345	<	abname);
345	>	abname);
346		return RC_DATERR;
347		}
348		abase_list[nabases].nangles +=
#	Line 311 \| Line 352 \| load_angle_basis(ezxml_t wab)
352		(abase_list[nabases].lat[i].nphis == 1 &&
353		abase_list[nabases].lat[i].tmin > FTINY)) {
354		sprintf(SDerrorDetail, "Illegal phi count in '%s'",
355	<	abname);
355	>	abname);
356		return RC_DATERR;
357		}
358		}
#	Line 357 \| Line 398 \| *get_extrema(SDSpectralDF df)**
398
399		/* load BSDF distribution for this wavelength */
400		static int
401	<	load_bsdf_data(SDData *sd, ezxml_t wdb, int rowinc)
401	>	load_bsdf_data(SDData *sd, ezxml_t wdb, int ct, int rowinc)
402		{
403		SDSpectralDF *df;
404		SDMat *dp;
#	Line 366 \| Line 407 \| *load_bsdf_data(SDData sd, ezxml_t wdb, int rowinc)**
407		int i;
408		/* allocate BSDF component */
409		sdata = ezxml_txt(ezxml_child(wdb, "WavelengthDataDirection"));
410	+	if (!sdata)
411	+	return RC_FAIL;
412	+	/*
413	+	* Remember that front and back are reversed from WINDOW 6 orientations
414	+	*/
415		if (!strcasecmp(sdata, "Transmission Front")) {
416	<	if (sd->tf != NULL)
371	<	SDfreeSpectralDF(sd->tf);
372	<	if ((sd->tf = SDnewSpectralDF(1)) == NULL)
416	>	if (sd->tb == NULL && (sd->tb = SDnewSpectralDF(3)) == NULL)
417		return RC_MEMERR;
418	+	df = sd->tb;
419	+	} else if (!strcasecmp(sdata, "Transmission Back")) {
420	+	if (sd->tf == NULL && (sd->tf = SDnewSpectralDF(3)) == NULL)
421	+	return RC_MEMERR;
422		df = sd->tf;
423		} else if (!strcasecmp(sdata, "Reflection Front")) {
424	<	if (sd->rf != NULL)
377	<	SDfreeSpectralDF(sd->rf);
378	<	if ((sd->rf = SDnewSpectralDF(1)) == NULL)
424	>	if (sd->rb == NULL && (sd->rb = SDnewSpectralDF(3)) == NULL)
425		return RC_MEMERR;
426	<	df = sd->rf;
426	>	df = sd->rb;
427		} else if (!strcasecmp(sdata, "Reflection Back")) {
428	<	if (sd->rb != NULL)
383	<	SDfreeSpectralDF(sd->rb);
384	<	if ((sd->rb = SDnewSpectralDF(1)) == NULL)
428	>	if (sd->rf == NULL && (sd->rf = SDnewSpectralDF(3)) == NULL)
429		return RC_MEMERR;
430	<	df = sd->rb;
430	>	df = sd->rf;
431		} else
432		return RC_FAIL;
433	<	/* XXX should also check "ScatteringDataType" for consistency? */
433	>	/* free previous matrix if any */
434	>	if (df->comp[ct].dist != NULL) {
435	>	SDfreeMatrix(df->comp[ct].dist);
436	>	df->comp[ct].dist = NULL;
437	>	}
438		/* get angle bases */
439		sdata = ezxml_txt(ezxml_child(wdb,"ColumnAngleBasis"));
440		if (!sdata \|\| !*sdata) {
#	Line 421 \| Line 469 \| *load_bsdf_data(SDData sd, ezxml_t wdb, int rowinc)**
469		dp->ib_priv = &abase_list[inbi];
470		dp->ob_priv = &abase_list[outbi];
471		if (df == sd->tf) {
472	<	dp->ib_vec = &ab_getvecR;
473	<	dp->ib_ndx = &ab_getndxR;
474	<	dp->ob_vec = &ab_getvec;
475	<	dp->ob_ndx = &ab_getndx;
472	>	dp->ib_vec = &fi_getvec;
473	>	dp->ib_ndx = &fi_getndx;
474	>	dp->ob_vec = &bo_getvec;
475	>	dp->ob_ndx = &bo_getndx;
476	>	} else if (df == sd->tb) {
477	>	dp->ib_vec = &bi_getvec;
478	>	dp->ib_ndx = &bi_getndx;
479	>	dp->ob_vec = &fo_getvec;
480	>	dp->ob_ndx = &fo_getndx;
481		} else if (df == sd->rf) {
482	<	dp->ib_vec = &ab_getvec;
483	<	dp->ib_ndx = &ab_getndx;
484	<	dp->ob_vec = &ab_getvec;
485	<	dp->ob_ndx = &ab_getndx;
482	>	dp->ib_vec = &fi_getvec;
483	>	dp->ib_ndx = &fi_getndx;
484	>	dp->ob_vec = &fo_getvec;
485	>	dp->ob_ndx = &fo_getndx;
486		} else /* df == sd->rb */ {
487	<	dp->ib_vec = &ab_getvecR;
488	<	dp->ib_ndx = &ab_getndxR;
489	<	dp->ob_vec = &ab_getvecR;
490	<	dp->ob_ndx = &ab_getndxR;
487	>	dp->ib_vec = &bi_getvec;
488	>	dp->ib_ndx = &bi_getndx;
489	>	dp->ob_vec = &bo_getvec;
490	>	dp->ob_ndx = &bo_getndx;
491		}
492	<	dp->ib_ohm = &ab_getohm;
493	<	dp->ob_ohm = &ab_getohm;
494	<	df->comp[0].cspec[0] = c_dfcolor; /* XXX monochrome for now */
495	<	df->comp[0].dist = dp;
443	<	df->comp[0].func = &SDhandleMtx;
492	>	dp->ib_ohm = &io_getohm;
493	>	dp->ob_ohm = &io_getohm;
494	>	df->comp[ct].dist = dp;
495	>	df->comp[ct].func = &SDhandleMtx;
496		/* read BSDF data */
497	<	sdata = ezxml_txt(ezxml_child(wdb,"ScatteringData"));
497	>	sdata = ezxml_txt(ezxml_child(wdb, "ScatteringData"));
498		if (!sdata \|\| !*sdata) {
499		sprintf(SDerrorDetail, "Missing BSDF ScatteringData in '%s'",
500		sd->name);
501		return RC_FORMERR;
502		}
503		for (i = 0; i < dp->ninc*dp->nout; i++) {
504	<	char *sdnext = fskip(sdata);
504	>	char *sdnext = fskip(sdata);
505	>	double val;
506		if (sdnext == NULL) {
507		sprintf(SDerrorDetail,
508		"Bad/missing BSDF ScatteringData in '%s'",
509		sd->name);
510		return RC_FORMERR;
511		}
512	<	while (sdnext && isspace(sdnext))
512	>	while (isspace(*sdnext))
513		sdnext++;
514		if (*sdnext == ',') sdnext++;
515	+	if ((val = atof(sdata)) < 0)
516	+	val = 0; /* don't allow negative values */
517		if (rowinc) {
518		int r = i/dp->nout;
519	<	int c = i - c*dp->nout;
520	<	mBSDF_value(dp,r,c) = atof(sdata);
519	>	int c = i - r*dp->nout;
520	>	mBSDF_value(dp,r,c) = val;
521		} else
522	<	dp->bsdf[i] = atof(sdata);
522	>	dp->bsdf[i] = val;
523		sdata = sdnext;
524		}
525	<	return get_extrema(df);
525	>	return (ct == mtx_Y) ? get_extrema(df) : RC_GOOD;
526		}
527
528	<	/* Subtract minimum (diffuse) scattering amount from BSDF */
528	>	/* copy our RGB (x,y) primary chromaticities */
529	>	static void
530	>	copy_RGB_prims(C_COLOR cspec[])
531	>	{
532	>	if (mtx_RGB_coef[1] < .001) { /* need to initialize */
533	>	int i = 3;
534	>	while (i--) {
535	>	float rgb[3];
536	>	rgb[0] = rgb[1] = rgb[2] = .0f;
537	>	rgb[i] = 1.f;
538	>	mtx_RGB_coef[i] = c_fromSharpRGB(rgb, &mtx_RGB_prim[i]);
539	>	}
540	>	}
541	>	memcpy(cspec, mtx_RGB_prim, sizeof(mtx_RGB_prim));
542	>	}
543	>
544	>	/* encode chromaticity if XYZ -- reduce to one channel in any case */
545	>	static SDSpectralDF *
546	>	encode_chroma(SDSpectralDF *df)
547	>	{
548	>	SDMat mpx, mpy, *mpz;
549	>	int n;
550	>
551	>	if (df == NULL \|\| df->ncomp != 3)
552	>	return df;
553	>
554	>	mpy = (SDMat *)df->comp[mtx_Y].dist;
555	>	if (mpy == NULL) {
556	>	free(df);
557	>	return NULL;
558	>	}
559	>	mpx = (SDMat *)df->comp[mtx_X].dist;
560	>	mpz = (SDMat *)df->comp[mtx_Z].dist;
561	>	if (mpx == NULL \|\| (mpx->ninc != mpy->ninc) \| (mpx->nout != mpy->nout))
562	>	goto done;
563	>	if (mpz == NULL \|\| (mpz->ninc != mpy->ninc) \| (mpz->nout != mpy->nout))
564	>	goto done;
565	>	mpy->chroma = (C_CHROMA )malloc(sizeof(C_CHROMA)mpy->ninc*mpy->nout);
566	>	if (mpy->chroma == NULL)
567	>	goto done; /* XXX punt */
568	>	/* encode chroma values */
569	>	for (n = mpy->ninc*mpy->nout; n--; ) {
570	>	const double sum = mpx->bsdf[n] + mpy->bsdf[n] + mpz->bsdf[n];
571	>	C_COLOR cxy;
572	>	if (sum > .0)
573	>	c_cset(&cxy, mpx->bsdf[n]/sum, mpy->bsdf[n]/sum);
574	>	else
575	>	c_cset(&cxy, 1./3., 1./3.);
576	>	mpy->chroma[n] = c_encodeChroma(&cxy);
577	>	}
578	>	done: /* free X & Z channels */
579	>	if (mpx != NULL) SDfreeMatrix(mpx);
580	>	if (mpz != NULL) SDfreeMatrix(mpz);
581	>	if (mpy->chroma == NULL) /* grayscale after all? */
582	>	df->comp[0].cspec[0] = c_dfcolor;
583	>	else /* else copy RGB primaries */
584	>	copy_RGB_prims(df->comp[0].cspec);
585	>	df->ncomp = 1; /* return resized struct */
586	>	return (SDSpectralDF *)realloc(df, sizeof(SDSpectralDF));
587	>	}
588	>
589	>	/* subtract minimum (diffuse) scattering amount from BSDF */
590		static double
591	<	subtract_min(SDMat *sm)
591	>	subtract_min(C_COLOR cs, SDMat sm)
592		{
593	<	float minv = sm->bsdf[0];
594	<	int n = sm->ninc*sm->nout;
595	<	int i;
593	>	const int ncomp = 1 + 2*(sm->chroma != NULL);
594	>	float min_coef[3], ymin, coef[3];
595	>	int i, o, c;
596
597	<	for (i = n; --i; )
598	<	if (sm->bsdf[i] < minv)
599	<	minv = sm->bsdf[i];
600	<	for (i = n; i--; )
601	<	sm->bsdf[i] -= minv;
597	>	min_coef[0] = min_coef[1] = min_coef[2] = FHUGE;
598	>	for (i = 0; i < sm->ninc; i++)
599	>	for (o = 0; o < sm->nout; o++) {
600	>	c = mBSDF_color(coef, sm, i, o);
601	>	while (c--)
602	>	if (coef[c] < min_coef[c])
603	>	min_coef[c] = coef[c];
604	>	}
605	>	ymin = 0;
606	>	for (c = ncomp; c--; )
607	>	ymin += min_coef[c];
608	>	if (ymin <= .01/M_PI) /* not worth bothering about? */
609	>	return .0;
610	>	if (ncomp == 1) { /* subtract grayscale minimum */
611	>	for (i = sm->ninc*sm->nout; i--; )
612	>	sm->bsdf[i] -= ymin;
613	>	*cs = c_dfcolor;
614	>	return M_PI*ymin;
615	>	}
616	>	/* else subtract colored minimum */
617	>	for (i = 0; i < sm->ninc; i++)
618	>	for (o = 0; o < sm->nout; o++) {
619	>	C_COLOR cxy;
620	>	c = mBSDF_color(coef, sm, i, o);
621	>	while (c--)
622	>	coef[c] = (coef[c] - min_coef[c]) /
623	>	mtx_RGB_coef[c];
624	>	if (c_fromSharpRGB(coef, &cxy) > 1e-5)
625	>	sm->chroma[o*sm->ninc + i] = c_encodeChroma(&cxy);
626	>	mBSDF_value(sm,i,o) -= ymin;
627	>	}
628	>	/* return colored minimum */
629	>	for (i = 3; i--; )
630	>	coef[i] = min_coef[i]/mtx_RGB_coef[i];
631	>	c_fromSharpRGB(coef, cs);
632
633	<	return minvM_PI; / be sure to include multiplier */
633	>	return M_PI*ymin;
634		}
635
636	<	/* Extract and separate diffuse portion of BSDF */
637	<	static void
636	>	/* Extract and separate diffuse portion of BSDF & convert color */
637	>	static SDSpectralDF *
638		extract_diffuse(SDValue dv, SDSpectralDF df)
639		{
494	–	int n;
640
641	+	df = encode_chroma(df); /* reduce XYZ to Y + chroma */
642		if (df == NULL \|\| df->ncomp <= 0) {
643		dv->spec = c_dfcolor;
644		dv->cieY = .0;
645	<	return;
645	>	return df;
646		}
647	<	dv->spec = df->comp[0].cspec[0];
648	<	dv->cieY = subtract_min((SDMat *)df->comp[0].dist);
649	<	/* in case of multiple components */
504	<	for (n = df->ncomp; --n; ) {
505	<	double ymin = subtract_min((SDMat *)df->comp[n].dist);
506	<	c_cmix(&dv->spec, dv->cieY, &dv->spec, ymin, &df->comp[n].cspec[0]);
507	<	dv->cieY += ymin;
508	<	}
509	<	df->maxHemi -= dv->cieY; /* adjust minimum hemispherical */
647	>	/* subtract minimum value */
648	>	dv->cieY = subtract_min(&dv->spec, (SDMat *)df->comp[0].dist);
649	>	df->maxHemi -= dv->cieY; /* adjust maximum hemispherical */
650		/* make sure everything is set */
651		c_ccvt(&dv->spec, C_CSXY+C_CSSPEC);
652	+	return df;
653		}
654
655		/* Load a BSDF matrix from an open XML file */
656		SDError
657		SDloadMtx(SDData *sd, ezxml_t wtl)
658		{
659	<	ezxml_t wld, wdb;
660	<	int rowIn;
661	<	struct BSDF_data *dp;
662	<	char *txt;
663	<	int rval;
523	<
659	>	ezxml_t wld, wdb;
660	>	int rowIn;
661	>	char *txt;
662	>	int rval;
663	>	/* basic checks and data ordering */
664		txt = ezxml_txt(ezxml_child(ezxml_child(wtl,
665		"DataDefinition"), "IncidentDataStructure"));
666		if (txt == NULL \|\| !*txt) {
#	Line 539 \| Line 679 \| *SDloadMtx(SDData sd, ezxml_t wtl)**
679		sd->name);
680		return SDEsupport;
681		}
682	<	/* get angle basis */
683	<	rval = load_angle_basis(ezxml_child(ezxml_child(wtl,
684	<	"DataDefinition"), "AngleBasis"));
685	<	if (rval < 0)
686	<	return convert_errcode(rval);
687	<	/* load BSDF components */
682	>	/* get angle bases */
683	>	for (wld = ezxml_child(ezxml_child(wtl, "DataDefinition"), "AngleBasis");
684	>	wld != NULL; wld = wld->next) {
685	>	rval = load_angle_basis(wld);
686	>	if (rval < 0)
687	>	return convert_errcode(rval);
688	>	}
689	>	/* load BSDF components */
690		for (wld = ezxml_child(wtl, "WavelengthData");
691		wld != NULL; wld = wld->next) {
692	<	if (strcasecmp(ezxml_txt(ezxml_child(wld,"Wavelength")),
693	<	"Visible"))
694	<	continue; /* just visible for now */
692	>	const char *cnm = ezxml_txt(ezxml_child(wld,"Wavelength"));
693	>	int ct = -1;
694	>	if (!strcasecmp(cnm, "Visible"))
695	>	ct = mtx_Y;
696	>	else if (!strcasecmp(cnm, "CIE-X"))
697	>	ct = mtx_X;
698	>	else if (!strcasecmp(cnm, "CIE-Z"))
699	>	ct = mtx_Z;
700	>	else
701	>	continue;
702		for (wdb = ezxml_child(wld, "WavelengthDataBlock");
703		wdb != NULL; wdb = wdb->next)
704	<	if ((rval = load_bsdf_data(sd, wdb, rowIn)) < 0)
704	>	if ((rval = load_bsdf_data(sd, wdb, ct, rowIn)) < 0)
705		return convert_errcode(rval);
706		}
707	<	/* separate diffuse components */
708	<	extract_diffuse(&sd->rLambFront, sd->rf);
709	<	extract_diffuse(&sd->rLambBack, sd->rb);
710	<	extract_diffuse(&sd->tLamb, sd->tf);
711	<	/* return success */
707	>	/* separate diffuse components */
708	>	sd->rf = extract_diffuse(&sd->rLambFront, sd->rf);
709	>	sd->rb = extract_diffuse(&sd->rLambBack, sd->rb);
710	>	if (sd->tf != NULL)
711	>	sd->tf = extract_diffuse(&sd->tLamb, sd->tf);
712	>	if (sd->tb != NULL)
713	>	sd->tb = extract_diffuse(&sd->tLamb, sd->tb);
714	>	/* return success */
715		return SDEnone;
716		}
717
718		/* Get Matrix BSDF value */
719		static int
720		SDgetMtxBSDF(float coef[SDmaxCh], const FVECT outVec,
721	<	const FVECT inVec, const void *dist)
721	>	const FVECT inVec, SDComponent *sdc)
722		{
723	<	const SDMat dp = (const SDMat )dist;
723	>	const SDMat *dp;
724		int i_ndx, o_ndx;
725	+	/* check arguments */
726	+	if ((coef == NULL) \| (outVec == NULL) \| (inVec == NULL) \| (sdc == NULL)
727	+	\|\| (dp = (SDMat *)sdc->dist) == NULL)
728	+	return 0;
729		/* get angle indices */
730		i_ndx = mBSDF_incndx(dp, inVec);
731		o_ndx = mBSDF_outndx(dp, outVec);
#	Line 580 \| Line 736 \| SDgetMtxBSDF(float coef[SDmaxCh], const FVECT outVec,
736		}
737		if ((i_ndx < 0) \| (o_ndx < 0))
738		return 0; /* nothing from this component */
739	<	coef[0] = mBSDF_value(dp, i_ndx, o_ndx);
740	<	return 1; /* XXX monochrome for now */
739	>
740	>	return mBSDF_color(coef, dp, i_ndx, o_ndx);
741		}
742
743	<	/* Query solid angle for vector */
743	>	/* Query solid angle for vector(s) */
744		static SDError
745	<	SDqueryMtxProjSA(double psa, const FVECT vec, int qflags, const void dist)
745	>	SDqueryMtxProjSA(double psa, const FVECT v1, const RREAL v2,
746	>	int qflags, SDComponent *sdc)
747		{
748	<	const SDMat dp = (const SDMat )dist;
748	>	const SDMat *dp;
749		double inc_psa, out_psa;
750		/* check arguments */
751	<	if ((psa == NULL) \| (vec == NULL) \| (dp == NULL))
751	>	if ((psa == NULL) \| (v1 == NULL) \| (sdc == NULL) \|\|
752	>	(dp = (SDMat *)sdc->dist) == NULL)
753		return SDEargument;
754	+	if (v2 == NULL)
755	+	v2 = v1;
756		/* get projected solid angles */
757	<	inc_psa = mBSDF_incohm(dp, mBSDF_incndx(dp, vec));
758	<	out_psa = mBSDF_outohm(dp, mBSDF_outndx(dp, vec));
757	>	out_psa = mBSDF_outohm(dp, mBSDF_outndx(dp, v1));
758	>	inc_psa = mBSDF_incohm(dp, mBSDF_incndx(dp, v2));
759	>	if ((v1 != v2) & (out_psa <= 0) & (inc_psa <= 0)) {
760	>	inc_psa = mBSDF_outohm(dp, mBSDF_outndx(dp, v2));
761	>	out_psa = mBSDF_incohm(dp, mBSDF_incndx(dp, v1));
762	>	}
763
764		switch (qflags) { /* record based on flag settings */
601	–	case SDqueryVal:
602	–	psa[0] = .0;
603	–	/* fall through */
765		case SDqueryMax:
766		if (inc_psa > psa[0])
767		psa[0] = inc_psa;
#	Line 608 \| Line 769 \| *SDqueryMtxProjSA(double psa, const FVECT vec, int qfl**
769		psa[0] = out_psa;
770		break;
771		case SDqueryMin+SDqueryMax:
772	<	if (inc_psa > psa[0])
772	>	if (inc_psa > psa[1])
773		psa[1] = inc_psa;
774	<	if (out_psa > psa[0])
774	>	if (out_psa > psa[1])
775		psa[1] = out_psa;
776		/* fall through */
777	+	case SDqueryVal:
778	+	if (qflags == SDqueryVal)
779	+	psa[0] = M_PI;
780	+	/* fall through */
781		case SDqueryMin:
782	<	if ((inc_psa > .0) & (inc_psa < psa[0]))
782	>	if ((inc_psa > 0) & (inc_psa < psa[0]))
783		psa[0] = inc_psa;
784	<	if ((out_psa > .0) & (out_psa < psa[0]))
784	>	if ((out_psa > 0) & (out_psa < psa[0]))
785		psa[0] = out_psa;
786		break;
787		}
788		/* make sure it's legal */
789	<	return (psa[0] <= .0) ? SDEinternal : SDEnone;
789	>	return (psa[0] <= 0) ? SDEinternal : SDEnone;
790		}
791
792		/* Compute new cumulative distribution from BSDF */
#	Line 659 \| Line 824 \| *make_cdist(SDMatCDst cd, const FVECT inVec, SDMat dp*
824		static const SDCDst *
825		SDgetMtxCDist(const FVECT inVec, SDComponent *sdc)
826		{
827	<	SDMat dp = (SDMat )sdc->dist;
827	>	SDMat *dp;
828		int reverse;
829		SDMatCDst myCD;
830		SDMatCDst cd, cdlast;
831		/* check arguments */
832	<	if ((inVec == NULL) \| (dp == NULL))
832	>	if ((inVec == NULL) \| (sdc == NULL) \|\|
833	>	(dp = (SDMat *)sdc->dist) == NULL)
834		return NULL;
835		memset(&myCD, 0, sizeof(myCD));
836		myCD.indx = mBSDF_incndx(dp, inVec);
#	Line 683 \| Line 849 \| *SDgetMtxCDist(const FVECT inVec, SDComponent sdc)**
849		reverse = 1;
850		}
851		cdlast = NULL; /* check for it in cache list */
852	<	for (cd = (SDMatCDst *)sdc->cdList;
853	<	cd != NULL; cd = (SDMatCDst *)cd->next) {
852	>	for (cd = (SDMatCDst *)sdc->cdList; cd != NULL;
853	>	cdlast = cd, cd = cd->next)
854		if (cd->indx == myCD.indx && (cd->calen == myCD.calen) &
855		(cd->ob_priv == myCD.ob_priv) &
856		(cd->ob_vec == myCD.ob_vec))
857		break;
692	–	cdlast = cd;
693	–	}
858		if (cd == NULL) { /* need to allocate new entry */
859		cd = (SDMatCDst *)malloc(sizeof(SDMatCDst) +
860	<	myCD.calen*sizeof(myCD.carr[0]));
860	>	sizeof(myCD.carr[0])*myCD.calen);
861		if (cd == NULL)
862		return NULL;
863		cd = myCD; / compute cumulative distribution */
#	Line 705 \| Line 869 \| *SDgetMtxCDist(const FVECT inVec, SDComponent sdc)**
869		}
870		if (cdlast != NULL) { /* move entry to head of cache list */
871		cdlast->next = cd->next;
872	<	cd->next = sdc->cdList;
872	>	cd->next = (SDMatCDst *)sdc->cdList;
873		sdc->cdList = (SDCDst *)cd;
874		}
875		return (SDCDst )cd; / ready to go */
#	Line 713 \| Line 877 \| *SDgetMtxCDist(const FVECT inVec, SDComponent sdc)**
877
878		/* Sample cumulative distribution */
879		static SDError
880	<	SDsampMtxCDist(FVECT outVec, double randX, const SDCDst *cdp)
880	>	SDsampMtxCDist(FVECT ioVec, double randX, const SDCDst *cdp)
881		{
882		const unsigned maxval = ~0;
883		const SDMatCDst mcd = (const SDMatCDst )cdp;
884		const unsigned target = randX*maxval;
885		int i, iupper, ilower;
886		/* check arguments */
887	<	if ((outVec == NULL) \| (mcd == NULL))
887	>	if ((ioVec == NULL) \| (mcd == NULL))
888		return SDEargument;
889		/* binary search to find index */
890		ilower = 0; iupper = mcd->calen;
891		while ((i = (iupper + ilower) >> 1) != ilower)
892	<	if ((long)target >= (long)mcd->carr[i])
892	>	if (target >= mcd->carr[i])
893		ilower = i;
894		else
895		iupper = i;
#	Line 733 \| Line 897 \| SDsampMtxCDist(FVECT outVec, double randX, const SDCDs
897		randX = (randX*maxval - mcd->carr[ilower]) /
898		(double)(mcd->carr[iupper] - mcd->carr[ilower]);
899		/* convert index to vector */
900	<	if ((*mcd->ob_vec)(outVec, i, randX, mcd->ob_priv))
900	>	if ((*mcd->ob_vec)(ioVec, i+randX, mcd->ob_priv))
901		return SDEnone;
902	<	strcpy(SDerrorDetail, "BSDF sampling fault");
902	>	strcpy(SDerrorDetail, "Matrix BSDF sampling fault");
903		return SDEinternal;
904		}
905

Diff Legend

-–
+Removed lines
-+
+Added lines
-<
+Changed lines
->
+Changed lines

Comparing ray/src/common/bsdf_m.c (file contents): Revision 3.5 by greg, Sat Feb 19 23:42:09 2011 UTC vs. Revision 3.32 by greg, Wed Apr 8 02:41:02 2015 UTC

Diff Legend

Comparing ray/src/common/bsdf_m.c (file contents):
Revision 3.5 by greg, Sat Feb 19 23:42:09 2011 UTC vs.
Revision 3.32 by greg, Wed Apr 8 02:41:02 2015 UTC