[ViewVC] Diff of: radiance/ray/src/rt/m

Comparing ray/src/rt/m_bsdf.c (file contents):
Revision 2.32 by greg, Sat Feb 18 19:12:49 2017 UTC vs.
Revision 2.67 by greg, Tue Dec 7 23:49:50 2021 UTC

#	Line 8 \| Line 8 \| static const char RCSid[] = "$Id$";
8		#include "copyright.h"
9
10		#include "ray.h"
11	+	#include "otypes.h"
12		#include "ambient.h"
13		#include "source.h"
14		#include "func.h"
#	Line 18 \| Line 19 \| static const char RCSid[] = "$Id$";
19		/*
20		* Arguments to this material include optional diffuse colors.
21		* String arguments include the BSDF and function files.
22	<	* A non-zero thickness causes the strange but useful behavior
22	>	* For the MAT_BSDF type, a non-zero thickness causes the useful behavior
23		* of translating transmitted rays this distance beneath the surface
24		* (opposite the surface normal) to bypass any intervening geometry.
25		* Translation only affects scattered, non-source-directed samples.
26		* A non-zero thickness has the further side-effect that an unscattered
27	<	* (view) ray will pass right through our material if it has any
28	<	* non-diffuse transmission, making the BSDF surface invisible. This
29	<	* shows the proxied geometry instead. Thickness has the further
30	<	* effect of turning off reflection on the hidden side so that rays
30	<	* heading in the opposite direction pass unimpeded through the BSDF
27	>	* (view) ray will pass right through our material, making the BSDF
28	>	* surface invisible and showing the proxied geometry instead. Thickness
29	>	* has the further effect of turning off reflection on the reverse side so
30	>	* rays heading in the opposite direction pass unimpeded through the BSDF
31		* surface. A paired surface may be placed on the opposide side of
32		* the detail geometry, less than this thickness away, if a two-way
33		* proxy is desired. Note that the sign of the thickness is important.
#	Line 36 \| Line 36 \| static const char RCSid[] = "$Id$";
36		* hides geometry in front of the surface when rays hit from behind,
37		* and applies only the transmission and backside reflectance properties.
38		* Reflection is ignored on the hidden side, as those rays pass through.
39	+	* For the MAT_ABSDF type, we check for a strong "through" component.
40	+	* Such a component will cause direct rays to pass through unscattered.
41	+	* A separate test prevents over-counting by dropping samples that are
42	+	* too close to this "through" direction. BSDFs with such a through direction
43	+	* will also have a view component, meaning they are somewhat see-through.
44	+	* A MAT_BSDF type with zero thickness behaves the same as a MAT_ABSDF
45	+	* type with no strong through component.
46		* The "up" vector for the BSDF is given by three variables, defined
47		* (along with the thickness) by the named function file, or '.' if none.
48		* Together with the surface normal, this defines the local coordinate
#	Line 43 \| Line 50 \| static const char RCSid[] = "$Id$";
50		* We do not reorient the surface, so if the BSDF has no back-side
51		* reflectance and none is given in the real arguments, a BSDF surface
52		* with zero thickness will appear black when viewed from behind
53	<	* unless backface visibility is off.
53	>	* unless backface visibility is on, when it becomes invisible.
54		* The diffuse arguments are added to components in the BSDF file,
55		* not multiplied. However, patterns affect this material as a multiplier
56		* on everything except non-diffuse reflection.
57		*
58	+	* Arguments for MAT_ABSDF are:
59	+	* 5+ BSDFfile ux uy uz funcfile transform
60	+	* 0
61	+	* 0\|3\|6\|9 rdf gdf bdf
62	+	* rdb gdb bdb
63	+	* rdt gdt bdt
64	+	*
65		* Arguments for MAT_BSDF are:
66		* 6+ thick BSDFfile ux uy uz funcfile transform
67		* 0
#	Line 59 \| Line 73 \| static const char RCSid[] = "$Id$";
73		/*
74		* Note that our reverse ray-tracing process means that the positions
75		* of incoming and outgoing vectors may be reversed in our calls
76	<	* to the BSDF library. This is fine, since the bidirectional nature
76	>	* to the BSDF library. This is usually fine, since the bidirectional nature
77		* of the BSDF (that's what the 'B' stands for) means it all works out.
78		*/
79
#	Line 72 \| Line 86 \| typedef struct {
86		RREAL toloc[3][3]; /* world to local BSDF coords */
87		RREAL fromloc[3][3]; /* local BSDF coords to world */
88		double thick; /* surface thickness */
89	+	COLOR cthru; /* "through" component for MAT_ABSDF */
90	+	COLOR cthru_surr; /* surround for "through" component */
91		SDData sd; / loaded BSDF data */
92		COLOR rdiff; /* diffuse reflection */
93	+	COLOR runsamp; /* BSDF hemispherical reflection */
94		COLOR tdiff; /* diffuse transmission */
95	+	COLOR tunsamp; /* BSDF hemispherical transmission */
96		} BSDFDAT; /* BSDF material data */
97
98		#define cvt_sdcolor(cv, svp) ccy2rgb(&(svp)->spec, (svp)->cieY, cv)
99
100	+	typedef struct {
101	+	double vy; /* brightness (for sorting) */
102	+	FVECT tdir; /* through sample direction (normalized) */
103	+	COLOR vcol; /* BTDF color */
104	+	} PEAKSAMP; /* BTDF peak sample */
105	+
106	+	/* Comparison function to put near-peak values in descending order */
107	+	static int
108	+	cmp_psamp(const void p1, const void p2)
109	+	{
110	+	double diff = ((const PEAKSAMP )p1).vy - ((const PEAKSAMP )p2).vy;
111	+	if (diff > 0) return(-1);
112	+	if (diff < 0) return(1);
113	+	return(0);
114	+	}
115	+
116	+	/* Compute "through" component color for MAT_ABSDF */
117	+	static void
118	+	compute_through(BSDFDAT *ndp)
119	+	{
120	+	#define NDIR2CHECK 29
121	+	static const float dir2check[NDIR2CHECK][2] = {
122	+	{0, 0}, {-0.6, 0}, {0, 0.6},
123	+	{0, -0.6}, {0.6, 0}, {-0.6, 0.6},
124	+	{-0.6, -0.6}, {0.6, 0.6}, {0.6, -0.6},
125	+	{-1.2, 0}, {0, 1.2}, {0, -1.2},
126	+	{1.2, 0}, {-1.2, 1.2}, {-1.2, -1.2},
127	+	{1.2, 1.2}, {1.2, -1.2}, {-1.8, 0},
128	+	{0, 1.8}, {0, -1.8}, {1.8, 0},
129	+	{-1.8, 1.8}, {-1.8, -1.8}, {1.8, 1.8},
130	+	{1.8, -1.8}, {-2.4, 0}, {0, 2.4},
131	+	{0, -2.4}, {2.4, 0},
132	+	};
133	+	PEAKSAMP psamp[NDIR2CHECK];
134	+	SDSpectralDF *dfp;
135	+	FVECT pdir;
136	+	double tomega, srchrad;
137	+	double tomsum, tomsurr;
138	+	COLOR vpeak, vsurr;
139	+	double vypeak;
140	+	int i, ns;
141	+	SDError ec;
142	+
143	+	if (ndp->pr->rod > 0)
144	+	dfp = (ndp->sd->tf != NULL) ? ndp->sd->tf : ndp->sd->tb;
145	+	else
146	+	dfp = (ndp->sd->tb != NULL) ? ndp->sd->tb : ndp->sd->tf;
147	+
148	+	if (dfp == NULL)
149	+	return; /* no specular transmission */
150	+	if (bright(ndp->pr->pcol) <= FTINY)
151	+	return; /* pattern is black, here */
152	+	srchrad = sqrt(dfp->minProjSA); /* else evaluate peak */
153	+	for (i = 0; i < NDIR2CHECK; i++) {
154	+	SDValue sv;
155	+	psamp[i].tdir[0] = -ndp->vray[0] + dir2check[i][0]*srchrad;
156	+	psamp[i].tdir[1] = -ndp->vray[1] + dir2check[i][1]*srchrad;
157	+	psamp[i].tdir[2] = -ndp->vray[2];
158	+	normalize(psamp[i].tdir);
159	+	ec = SDevalBSDF(&sv, ndp->vray, psamp[i].tdir, ndp->sd);
160	+	if (ec)
161	+	goto baderror;
162	+	cvt_sdcolor(psamp[i].vcol, &sv);
163	+	psamp[i].vy = sv.cieY;
164	+	}
165	+	qsort(psamp, NDIR2CHECK, sizeof(PEAKSAMP), cmp_psamp);
166	+	if (psamp[0].vy <= FTINY)
167	+	return; /* zero BTDF here */
168	+	setcolor(vpeak, 0, 0, 0);
169	+	setcolor(vsurr, 0, 0, 0);
170	+	vypeak = tomsum = tomsurr = 0; /* combine top unique values */
171	+	ns = 0;
172	+	for (i = 0; i < NDIR2CHECK; i++) {
173	+	if (i && psamp[i].vy == psamp[i-1].vy)
174	+	continue; /* assume duplicate sample */
175	+
176	+	ec = SDsizeBSDF(&tomega, ndp->vray, psamp[i].tdir,
177	+	SDqueryMin, ndp->sd);
178	+	if (ec)
179	+	goto baderror;
180	+
181	+	scalecolor(psamp[i].vcol, tomega);
182	+	/* not part of peak? */
183	+	if (tomega > 1.5*dfp->minProjSA \|\|
184	+	vypeak > 8.psamp[i].vyns) {
185	+	if (!i) return; /* abort */
186	+	addcolor(vsurr, psamp[i].vcol);
187	+	tomsurr += tomega;
188	+	continue;
189	+	}
190	+	addcolor(vpeak, psamp[i].vcol);
191	+	tomsum += tomega;
192	+	vypeak += psamp[i].vy;
193	+	++ns;
194	+	}
195	+	if (tomsurr <= FTINY) /* no surround implies no peak */
196	+	return;
197	+	if ((vypeak/ns - (ndp->vray[2] > 0 ? ndp->sd->tLambFront.cieY
198	+	: ndp->sd->tLambBack.cieY)(1./PI))tomsum < .0005)
199	+	return; /* < 0.05% transmission */
200	+	copycolor(ndp->cthru, vpeak); /* already scaled by omega */
201	+	multcolor(ndp->cthru, ndp->pr->pcol); /* modify by pattern */
202	+	scalecolor(vsurr, 1./tomsurr); /* surround is avg. BTDF */
203	+	copycolor(ndp->cthru_surr, vsurr);
204	+	multcolor(ndp->cthru_surr, ndp->pr->pcol);
205	+	return;
206	+	baderror:
207	+	objerror(ndp->mp, USER, transSDError(ec));
208	+	#undef NDIR2CHECK
209	+	}
210	+
211		/* Jitter ray sample according to projected solid angle and specjitter */
212		static void
213		bsdf_jitter(FVECT vres, BSDFDAT *ndp, double sr_psa)
#	Line 93 \| Line 222 \| *bsdf_jitter(FVECT vres, BSDFDAT ndp, double sr_psa)**
222		normalize(vres);
223		}
224
225	<	/* Evaluate BSDF for direct component, returning true if OK to proceed */
225	>	/* Get BSDF specular for direct component, returning true if OK to proceed */
226		static int
227	<	direct_bsdf_OK(COLOR cval, FVECT ldir, double omega, BSDFDAT *ndp)
227	>	direct_specular_OK(COLOR cval, FVECT ldir, double omega, BSDFDAT *ndp)
228		{
229	<	int nsamp, ok = 0;
230	<	FVECT vsrc, vsmp, vjit;
231	<	double tomega;
229	>	int nsamp = 1;
230	>	int scnt = 0;
231	>	FVECT vsrc, vjit;
232	>	double tomega, tomega2;
233		double sf, tsr, sd[2];
234		COLOR csmp, cdiff;
235		double diffY;
236		SDValue sv;
237		SDError ec;
238		int i;
239	+	/* in case we fail */
240	+	setcolor(cval, 0, 0, 0);
241		/* transform source direction */
242		if (SDmapDir(vsrc, ndp->toloc, ldir) != SDEnone)
243		return(0);
#	Line 121 \| Line 253 \| direct_bsdf_OK(COLOR cval, FVECT ldir, double omega, B
253		return(0); /* all diffuse */
254		sv = ndp->sd->rLambBack;
255		break;
256	<	default:
256	>	case 1:
257		if ((ndp->sd->tf == NULL) & (ndp->sd->tb == NULL))
258		return(0); /* all diffuse */
259	<	sv = ndp->sd->tLamb;
259	>	sv = ndp->sd->tLambFront;
260		break;
261	+	case 2:
262	+	if ((ndp->sd->tf == NULL) & (ndp->sd->tb == NULL))
263	+	return(0); /* all diffuse */
264	+	sv = ndp->sd->tLambBack;
265	+	break;
266		}
267	<	if ((sv.cieY *= 1./PI) > FTINY) {
268	<	diffY = sv.cieY;
267	>	if (sv.cieY > FTINY) {
268	>	diffY = sv.cieY *= 1./PI;
269		cvt_sdcolor(cdiff, &sv);
270		} else {
271	<	diffY = .0;
272	<	setcolor(cdiff, .0, .0, .0);
271	>	diffY = 0;
272	>	setcolor(cdiff, 0, 0, 0);
273		}
274	<	/* assign number of samples */
274	>	/* check indirect over-counting */
275	>	if ((vsrc[2] > 0) ^ (ndp->vray[2] > 0) && bright(ndp->cthru) > FTINY) {
276	>	double dx = vsrc[0] + ndp->vray[0];
277	>	double dy = vsrc[1] + ndp->vray[1];
278	>	SDSpectralDF *dfp = (ndp->pr->rod > 0) ?
279	>	((ndp->sd->tf != NULL) ? ndp->sd->tf : ndp->sd->tb) :
280	>	((ndp->sd->tb != NULL) ? ndp->sd->tb : ndp->sd->tf) ;
281	>
282	>	tomega = omega*fabs(vsrc[2]);
283	>	if (dxdx + dydy <= (2.54./PI)(tomega + dfp->minProjSA +
284	>	2.sqrt(tomegadfp->minProjSA))) {
285	>	if (bright(ndp->cthru_surr) <= FTINY)
286	>	return(0);
287	>	copycolor(cval, ndp->cthru_surr);
288	>	return(1); /* return non-zero surround BTDF */
289	>	}
290	>	}
291		ec = SDsizeBSDF(&tomega, ndp->vray, vsrc, SDqueryMin, ndp->sd);
292		if (ec)
293		goto baderror;
294	<	/* check indirect over-counting */
295	<	if (ndp->thick != 0 && ndp->pr->crtype & (SPECULAR\|AMBIENT)
296	<	&& (vsrc[2] > 0) ^ (ndp->vray[2] > 0)) {
297	<	double dx = vsrc[0] + ndp->vray[0];
145	<	double dy = vsrc[1] + ndp->vray[1];
146	<	if (dxdx + dydy <= omega+tomega)
147	<	return(0);
294	>	/* check if sampling BSDF */
295	>	if ((tsr = sqrt(tomega)) > 0) {
296	>	nsamp = 4.specjitterndp->pr->rweight + .5;
297	>	nsamp += !nsamp;
298		}
299	<	sf = specjitter * ndp->pr->rweight;
150	<	if (tomega <= .0)
151	<	nsamp = 1;
152	<	else if (25.*tomega <= omega)
153	<	nsamp = 100.*sf + .5;
154	<	else
155	<	nsamp = 4.sfomega/tomega + .5;
156	<	nsamp += !nsamp;
157	<	setcolor(cval, .0, .0, .0); /* sample our source area */
158	<	sf = sqrt(omega);
159	<	tsr = sqrt(tomega);
299	>	/* jitter to fuzz BSDF cells */
300		for (i = nsamp; i--; ) {
161	–	VCOPY(vsmp, vsrc); /* jitter query directions */
162	–	if (nsamp > 1) {
163	–	multisamp(sd, 2, (i + frandom())/(double)nsamp);
164	–	vsmp[0] += (sd[0] - .5)*sf;
165	–	vsmp[1] += (sd[1] - .5)*sf;
166	–	if (normalize(vsmp) == 0) {
167	–	--nsamp;
168	–	continue;
169	–	}
170	–	}
301		bsdf_jitter(vjit, ndp, tsr);
302		/* compute BSDF */
303	<	ec = SDevalBSDF(&sv, vjit, vsmp, ndp->sd);
303	>	ec = SDevalBSDF(&sv, vjit, vsrc, ndp->sd);
304		if (ec)
305		goto baderror;
306	<	if (sv.cieY - diffY <= FTINY) {
177	<	addcolor(cval, cdiff);
306	>	if (sv.cieY - diffY <= FTINY)
307		continue; /* no specular part */
308	<	}
308	>	/* check for variable resolution */
309	>	ec = SDsizeBSDF(&tomega2, vjit, vsrc, SDqueryMin, ndp->sd);
310	>	if (ec)
311	>	goto baderror;
312	>	if (tomega2 < .12*tomega)
313	>	continue; /* not safe to include */
314		cvt_sdcolor(csmp, &sv);
315	<	addcolor(cval, csmp); /* else average it in */
316	<	++ok;
315	>	addcolor(cval, csmp);
316	>	++scnt;
317		}
318	<	if (!ok) {
319	<	setcolor(cval, .0, .0, .0);
320	<	return(0); /* no valid specular samples */
321	<	}
188	<	sf = 1./(double)nsamp;
318	>	if (!scnt) /* no valid specular samples? */
319	>	return(0);
320	>
321	>	sf = 1./scnt; /* weighted average BSDF */
322		scalecolor(cval, sf);
323		/* subtract diffuse contribution */
324		for (i = 3*(diffY > FTINY); i--; )
325	<	if ((colval(cval,i) -= colval(cdiff,i)) < .0)
326	<	colval(cval,i) = .0;
325	>	if ((colval(cval,i) -= colval(cdiff,i)) < 0)
326	>	colval(cval,i) = 0;
327		return(1);
328		baderror:
329		objerror(ndp->mp, USER, transSDError(ec));
#	Line 211 \| Line 344 \| dir_bsdf(
344		double dtmp;
345		COLOR ctmp;
346
347	<	setcolor(cval, .0, .0, .0);
347	>	setcolor(cval, 0, 0, 0);
348
349		ldot = DOT(np->pnorm, ldir);
350		if ((-FTINY <= ldot) & (ldot <= FTINY))
#	Line 219 \| Line 352 \| dir_bsdf(
352
353		if (ldot > 0 && bright(np->rdiff) > FTINY) {
354		/*
355	<	* Compute added diffuse reflected component.
355	>	* Compute diffuse reflected component
356		*/
357		copycolor(ctmp, np->rdiff);
358		dtmp = ldot * omega * (1./PI);
#	Line 228 \| Line 361 \| dir_bsdf(
361		}
362		if (ldot < 0 && bright(np->tdiff) > FTINY) {
363		/*
364	<	* Compute added diffuse transmission.
364	>	* Compute diffuse transmission
365		*/
366		copycolor(ctmp, np->tdiff);
367	<	dtmp = -ldot * omega * (1.0/PI);
367	>	dtmp = -ldot * omega * (1./PI);
368		scalecolor(ctmp, dtmp);
369		addcolor(cval, ctmp);
370		}
371		if (ambRayInPmap(np->pr))
372		return; /* specular already in photon map */
373		/*
374	<	* Compute scattering coefficient using BSDF.
374	>	* Compute specular scattering coefficient using BSDF
375		*/
376	<	if (!direct_bsdf_OK(ctmp, ldir, omega, np))
376	>	if (!direct_specular_OK(ctmp, ldir, omega, np))
377		return;
378		if (ldot < 0) { /* pattern for specular transmission */
379		multcolor(ctmp, np->pr->pcol);
#	Line 265 \| Line 398 \| dir_brdf(
398		double dtmp;
399		COLOR ctmp, ctmp1, ctmp2;
400
401	<	setcolor(cval, .0, .0, .0);
401	>	setcolor(cval, 0, 0, 0);
402
403		ldot = DOT(np->pnorm, ldir);
404
#	Line 274 \| Line 407 \| dir_brdf(
407
408		if (bright(np->rdiff) > FTINY) {
409		/*
410	<	* Compute added diffuse reflected component.
410	>	* Compute diffuse reflected component
411		*/
412		copycolor(ctmp, np->rdiff);
413		dtmp = ldot * omega * (1./PI);
#	Line 284 \| Line 417 \| dir_brdf(
417		if (ambRayInPmap(np->pr))
418		return; /* specular already in photon map */
419		/*
420	<	* Compute reflection coefficient using BSDF.
420	>	* Compute specular reflection coefficient using BSDF
421		*/
422	<	if (!direct_bsdf_OK(ctmp, ldir, omega, np))
422	>	if (!direct_specular_OK(ctmp, ldir, omega, np))
423		return;
424		dtmp = ldot * omega;
425		scalecolor(ctmp, dtmp);
#	Line 307 \| Line 440 \| dir_btdf(
440		double dtmp;
441		COLOR ctmp;
442
443	<	setcolor(cval, .0, .0, .0);
443	>	setcolor(cval, 0, 0, 0);
444
445		ldot = DOT(np->pnorm, ldir);
446
#	Line 316 \| Line 449 \| dir_btdf(
449
450		if (bright(np->tdiff) > FTINY) {
451		/*
452	<	* Compute added diffuse transmission.
452	>	* Compute diffuse transmission
453		*/
454		copycolor(ctmp, np->tdiff);
455	<	dtmp = -ldot * omega * (1.0/PI);
455	>	dtmp = -ldot * omega * (1./PI);
456		scalecolor(ctmp, dtmp);
457		addcolor(cval, ctmp);
458		}
459		if (ambRayInPmap(np->pr))
460		return; /* specular already in photon map */
461		/*
462	<	* Compute scattering coefficient using BSDF.
462	>	* Compute specular scattering coefficient using BSDF
463		*/
464	<	if (!direct_bsdf_OK(ctmp, ldir, omega, np))
464	>	if (!direct_specular_OK(ctmp, ldir, omega, np))
465		return;
466		/* full pattern on transmission */
467		multcolor(ctmp, np->pr->pcol);
#	Line 339 \| Line 472 \| dir_btdf(
472
473		/* Sample separate BSDF component */
474		static int
475	<	sample_sdcomp(BSDFDAT ndp, SDComponent dcp, int usepat)
475	>	sample_sdcomp(BSDFDAT ndp, SDComponent dcp, int xmit)
476		{
477	<	int nstarget = 1;
478	<	int nsent;
479	<	SDError ec;
480	<	SDValue bsv;
481	<	double xrand;
482	<	FVECT vsmp;
483	<	RAY sr;
477	>	const int hasthru = (xmit &&
478	>	!(ndp->pr->crtype & (SPECULAR\|AMBIENT))
479	>	&& bright(ndp->cthru) > FTINY);
480	>	int nstarget = 1;
481	>	int nsent = 0;
482	>	int n;
483	>	SDError ec;
484	>	SDValue bsv;
485	>	double xrand;
486	>	FVECT vsmp, vinc;
487	>	RAY sr;
488		/* multiple samples? */
489		if (specjitter > 1.5) {
490		nstarget = specjitter*ndp->pr->rweight + .5;
491		nstarget += !nstarget;
492		}
493		/* run through our samples */
494	<	for (nsent = 0; nsent < nstarget; nsent++) {
494	>	for (n = 0; n < nstarget; n++) {
495		if (nstarget == 1) { /* stratify random variable */
496		xrand = urand(ilhash(dimlist,ndims)+samplendx);
497		if (specjitter < 1.)
498		xrand = .5 + specjitter*(xrand-.5);
499		} else {
500	<	xrand = (nsent + frandom())/(double)nstarget;
500	>	xrand = (n + frandom())/(double)nstarget;
501		}
502		SDerrorDetail[0] = '\0'; /* sample direction & coef. */
503		bsdf_jitter(vsmp, ndp, ndp->sr_vpsa[0]);
504	+	VCOPY(vinc, vsmp); /* to compare after */
505		ec = SDsampComponent(&bsv, vsmp, xrand, dcp);
506		if (ec)
507		objerror(ndp->mp, USER, transSDError(ec));
508		if (bsv.cieY <= FTINY) /* zero component? */
509		break;
510	<	/* map vector to world */
510	>	if (hasthru) { /* check for view ray */
511	>	double dx = vinc[0] + vsmp[0];
512	>	double dy = vinc[1] + vsmp[1];
513	>	if (dxdx + dydy <= ndp->sr_vpsa[0]*ndp->sr_vpsa[0])
514	>	continue; /* exclude view sample */
515	>	}
516	>	/* map non-view sample->world */
517		if (SDmapDir(sr.rdir, ndp->fromloc, vsmp) != SDEnone)
518		break;
519		/* spawn a specular ray */
520		if (nstarget > 1)
521		bsv.cieY /= (double)nstarget;
522		cvt_sdcolor(sr.rcoef, &bsv); /* use sample color */
523	<	if (usepat) /* apply pattern? */
523	>	if (xmit) /* apply pattern on transmit */
524		multcolor(sr.rcoef, ndp->pr->pcol);
525		if (rayorigin(&sr, SPECULAR, ndp->pr, sr.rcoef) < 0) {
526	<	if (maxdepth > 0)
527	<	break;
528	<	continue; /* Russian roulette victim */
526	>	if (!n & (nstarget > 1)) {
527	>	n = nstarget; /* avoid infinitue loop */
528	>	nstarget = nstarget*sr.rweight/minweight;
529	>	if (n == nstarget) break;
530	>	n = -1; /* moved target */
531	>	}
532	>	continue; /* try again */
533		}
534	<	/* need to offset origin? */
387	<	if (ndp->thick != 0 && (ndp->pr->rod > 0) ^ (vsmp[2] > 0))
534	>	if (xmit && ndp->thick != 0) /* need to offset origin? */
535		VSUM(sr.rorg, sr.rorg, ndp->pr->ron, -ndp->thick);
536		rayvalue(&sr); /* send & evaluate sample */
537		multcolor(sr.rcol, sr.rcoef);
538		addcolor(ndp->pr->rcol, sr.rcol);
539	+	++nsent;
540		}
541		return(nsent);
542		}
#	Line 397 \| Line 545 \| *sample_sdcomp(BSDFDAT ndp, SDComponent dcp, int usep*
545		static int
546		sample_sdf(BSDFDAT *ndp, int sflags)
547		{
548	+	int hasthru = (sflags == SDsampSpT &&
549	+	!(ndp->pr->crtype & (SPECULAR\|AMBIENT))
550	+	&& bright(ndp->cthru) > FTINY);
551		int n, ntotal = 0;
552	+	double b = 0;
553		SDSpectralDF *dfp;
554		COLORV *unsc;
555
556		if (sflags == SDsampSpT) {
557	<	unsc = ndp->tdiff;
557	>	unsc = ndp->tunsamp;
558		if (ndp->pr->rod > 0)
559		dfp = (ndp->sd->tf != NULL) ? ndp->sd->tf : ndp->sd->tb;
560		else
561		dfp = (ndp->sd->tb != NULL) ? ndp->sd->tb : ndp->sd->tf;
562		} else /* sflags == SDsampSpR */ {
563	<	unsc = ndp->rdiff;
563	>	unsc = ndp->runsamp;
564		if (ndp->pr->rod > 0)
565		dfp = ndp->sd->rf;
566		else
567		dfp = ndp->sd->rb;
568		}
569	+	setcolor(unsc, 0, 0, 0);
570		if (dfp == NULL) /* no specular component? */
571		return(0);
572	<	/* below sampling threshold? */
573	<	if (dfp->maxHemi <= specthresh+FTINY) {
574	<	if (dfp->maxHemi > FTINY) { /* XXX no color from BSDF */
575	<	FVECT vjit;
576	<	double d;
577	<	COLOR ctmp;
578	<	bsdf_jitter(vjit, ndp, ndp->sr_vpsa[1]);
579	<	d = SDdirectHemi(vjit, sflags, ndp->sd);
572	>
573	>	if (hasthru) { /* separate view sample? */
574	>	RAY tr;
575	>	if (rayorigin(&tr, TRANS, ndp->pr, ndp->cthru) == 0) {
576	>	VCOPY(tr.rdir, ndp->pr->rdir);
577	>	rayvalue(&tr);
578	>	multcolor(tr.rcol, tr.rcoef);
579	>	addcolor(ndp->pr->rcol, tr.rcol);
580	>	ndp->pr->rxt = ndp->pr->rot + raydistance(&tr);
581	>	++ntotal;
582	>	b = bright(ndp->cthru);
583	>	} else
584	>	hasthru = 0;
585	>	}
586	>	if (dfp->maxHemi - b <= FTINY) { /* have specular to sample? */
587	>	b = 0;
588	>	} else {
589	>	FVECT vjit;
590	>	bsdf_jitter(vjit, ndp, ndp->sr_vpsa[1]);
591	>	b = SDdirectHemi(vjit, sflags, ndp->sd) - b;
592	>	if (b < 0) b = 0;
593	>	}
594	>	if (b <= specthresh+FTINY) { /* below sampling threshold? */
595	>	if (b > FTINY) { /* XXX no color from BSDF */
596		if (sflags == SDsampSpT) {
597	<	copycolor(ctmp, ndp->pr->pcol);
598	<	scalecolor(ctmp, d);
597	>	copycolor(unsc, ndp->pr->pcol);
598	>	scalecolor(unsc, b);
599		} else /* no pattern on reflection */
600	<	setcolor(ctmp, d, d, d);
432	<	addcolor(unsc, ctmp);
600	>	setcolor(unsc, b, b, b);
601		}
602	<	return(0);
602	>	return(ntotal);
603		}
604	<	/* else need to sample */
605	<	dimlist[ndims++] = (int)(size_t)ndp->mp;
438	<	ndims++;
604	>	dimlist[ndims] = (int)(size_t)ndp->mp; /* else sample specular */
605	>	ndims += 2;
606		for (n = dfp->ncomp; n--; ) { /* loop over components */
607		dimlist[ndims-1] = n + 9438;
608		ntotal += sample_sdcomp(ndp, &dfp->comp[n], sflags==SDsampSpT);
#	Line 448 \| Line 615 \| *sample_sdf(BSDFDAT ndp, int sflags)**
615		int
616		m_bsdf(OBJREC m, RAY r)
617		{
618	+	int hasthick = (m->otype == MAT_BSDF);
619		int hitfront;
620		COLOR ctmp;
621		SDError ec;
#	Line 455 \| Line 623 \| *m_bsdf(OBJREC m, RAY r)*
623		MFUNC *mf;
624		BSDFDAT nd;
625		/* check arguments */
626	<	if ((m->oargs.nsargs < 6) \| (m->oargs.nfargs > 9) \|
626	>	if ((m->oargs.nsargs < hasthick+5) \| (m->oargs.nfargs > 9) \|
627		(m->oargs.nfargs % 3))
628		objerror(m, USER, "bad # arguments");
629		/* record surface struck */
630		hitfront = (r->rod > 0);
631		/* load cal file */
632	<	mf = getfunc(m, 5, 0x1d, 1);
632	>	mf = hasthick ? getfunc(m, 5, 0x1d, 1)
633	>	: getfunc(m, 4, 0xe, 1) ;
634		setfunc(m, r);
635	<	/* get thickness */
636	<	nd.thick = evalue(mf->ep[0]);
637	<	if ((-FTINY <= nd.thick) & (nd.thick <= FTINY))
638	<	nd.thick = .0;
639	<	/* check shadow */
471	<	if (r->crtype & SHADOW) {
472	<	if (nd.thick != 0)
473	<	raytrans(r); /* pass-through */
474	<	return(1); /* or shadow */
635	>	nd.thick = 0; /* set thickness */
636	>	if (hasthick) {
637	>	nd.thick = evalue(mf->ep[0]);
638	>	if ((-FTINY <= nd.thick) & (nd.thick <= FTINY))
639	>	nd.thick = 0;
640		}
641		/* check backface visibility */
642		if (!hitfront & !backvis) {
#	Line 479 \| Line 644 \| *m_bsdf(OBJREC m, RAY r)*
644		return(1);
645		}
646		/* check other rays to pass */
647	<	if (nd.thick != 0 && (!(r->crtype & (SPECULAR\|AMBIENT)) \|\|
647	>	if (nd.thick != 0 && (r->crtype & SHADOW \|\|
648	>	!(r->crtype & (SPECULAR\|AMBIENT)) \|\|
649		(nd.thick > 0) ^ hitfront)) {
650		raytrans(r); /* hide our proxy */
651		return(1);
652		}
653	+	if (hasthick && r->crtype & SHADOW) /* early shadow check #1 */
654	+	return(1);
655		nd.mp = m;
656		nd.pr = r;
657		/* get BSDF data */
658	<	nd.sd = loadBSDF(m->oargs.sarg[1]);
659	<	/* diffuse reflectance */
658	>	nd.sd = loadBSDF(m->oargs.sarg[hasthick]);
659	>	/* early shadow check #2 */
660	>	if (r->crtype & SHADOW && (nd.sd->tf == NULL) & (nd.sd->tb == NULL)) {
661	>	SDfreeCache(nd.sd);
662	>	return(1);
663	>	}
664	>	/* diffuse components */
665		if (hitfront) {
666		cvt_sdcolor(nd.rdiff, &nd.sd->rLambFront);
667		if (m->oargs.nfargs >= 3) {
#	Line 497 \| Line 670 \| *m_bsdf(OBJREC m, RAY r)*
670		m->oargs.farg[2]);
671		addcolor(nd.rdiff, ctmp);
672		}
673	+	cvt_sdcolor(nd.tdiff, &nd.sd->tLambFront);
674		} else {
675		cvt_sdcolor(nd.rdiff, &nd.sd->rLambBack);
676		if (m->oargs.nfargs >= 6) {
#	Line 505 \| Line 679 \| *m_bsdf(OBJREC m, RAY r)*
679		m->oargs.farg[5]);
680		addcolor(nd.rdiff, ctmp);
681		}
682	+	cvt_sdcolor(nd.tdiff, &nd.sd->tLambBack);
683		}
684	<	/* diffuse transmittance */
510	<	cvt_sdcolor(nd.tdiff, &nd.sd->tLamb);
511	<	if (m->oargs.nfargs >= 9) {
684	>	if (m->oargs.nfargs >= 9) { /* add diffuse transmittance? */
685		setcolor(ctmp, m->oargs.farg[6],
686		m->oargs.farg[7],
687		m->oargs.farg[8]);
#	Line 520 \| Line 693 \| *m_bsdf(OBJREC m, RAY r)*
693		multcolor(nd.rdiff, r->pcol);
694		multcolor(nd.tdiff, r->pcol);
695		/* get up vector */
696	<	upvec[0] = evalue(mf->ep[1]);
697	<	upvec[1] = evalue(mf->ep[2]);
698	<	upvec[2] = evalue(mf->ep[3]);
696	>	upvec[0] = evalue(mf->ep[hasthick+0]);
697	>	upvec[1] = evalue(mf->ep[hasthick+1]);
698	>	upvec[2] = evalue(mf->ep[hasthick+2]);
699		/* return to world coords */
700		if (mf->fxp != &unitxf) {
701		multv3(upvec, upvec, mf->fxp->xfm);
#	Line 541 \| Line 714 \| *m_bsdf(OBJREC m, RAY r)*
714		nd.vray[2] = -r->rdir[2];
715		ec = SDmapDir(nd.vray, nd.toloc, nd.vray);
716		}
544	–	if (!ec)
545	–	ec = SDinvXform(nd.fromloc, nd.toloc);
717		if (ec) {
718		objerror(m, WARNING, "Illegal orientation vector");
719	+	SDfreeCache(nd.sd);
720		return(1);
721		}
722	<	/* determine BSDF resolution */
723	<	ec = SDsizeBSDF(nd.sr_vpsa, nd.vray, NULL, SDqueryMin+SDqueryMax, nd.sd);
722	>	setcolor(nd.cthru, 0, 0, 0); /* consider through component */
723	>	setcolor(nd.cthru_surr, 0, 0, 0);
724	>	if (m->otype == MAT_ABSDF) {
725	>	compute_through(&nd);
726	>	if (r->crtype & SHADOW) {
727	>	RAY tr; /* attempt to pass shadow ray */
728	>	SDfreeCache(nd.sd);
729	>	if (rayorigin(&tr, TRANS, r, nd.cthru) < 0)
730	>	return(1); /* no through component */
731	>	VCOPY(tr.rdir, r->rdir);
732	>	rayvalue(&tr); /* transmit with scaling */
733	>	multcolor(tr.rcol, tr.rcoef);
734	>	copycolor(r->rcol, tr.rcol);
735	>	return(1); /* we're done */
736	>	}
737	>	}
738	>	ec = SDinvXform(nd.fromloc, nd.toloc);
739	>	if (!ec) /* determine BSDF resolution */
740	>	ec = SDsizeBSDF(nd.sr_vpsa, nd.vray, NULL,
741	>	SDqueryMin+SDqueryMax, nd.sd);
742		if (ec)
743		objerror(m, USER, transSDError(ec));
744
#	Line 564 \| Line 754 \| *m_bsdf(OBJREC m, RAY r)*
754		/* sample transmission */
755		sample_sdf(&nd, SDsampSpT);
756		/* compute indirect diffuse */
757	<	if (bright(nd.rdiff) > FTINY) { /* ambient from reflection */
757	>	copycolor(ctmp, nd.rdiff);
758	>	addcolor(ctmp, nd.runsamp);
759	>	if (bright(ctmp) > FTINY) { /* ambient from reflection */
760		if (!hitfront)
761		flipsurface(r);
570	–	copycolor(ctmp, nd.rdiff);
762		multambient(ctmp, r, nd.pnorm);
763		addcolor(r->rcol, ctmp);
764		if (!hitfront)
765		flipsurface(r);
766		}
767	<	if (bright(nd.tdiff) > FTINY) { /* ambient from other side */
767	>	copycolor(ctmp, nd.tdiff);
768	>	addcolor(ctmp, nd.tunsamp);
769	>	if (bright(ctmp) > FTINY) { /* ambient from other side */
770		FVECT bnorm;
771		if (hitfront)
772		flipsurface(r);
773		bnorm[0] = -nd.pnorm[0];
774		bnorm[1] = -nd.pnorm[1];
775		bnorm[2] = -nd.pnorm[2];
583	–	copycolor(ctmp, nd.tdiff);
776		if (nd.thick != 0) { /* proxy with offset? */
777		VCOPY(vtmp, r->rop);
778		VSUM(r->rop, vtmp, r->ron, nd.thick);

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Comparing ray/src/rt/m_bsdf.c (file contents): Revision 2.32 by greg, Sat Feb 18 19:12:49 2017 UTC vs. Revision 2.67 by greg, Tue Dec 7 23:49:50 2021 UTC

Diff Legend

Comparing ray/src/rt/m_bsdf.c (file contents):
Revision 2.32 by greg, Sat Feb 18 19:12:49 2017 UTC vs.
Revision 2.67 by greg, Tue Dec 7 23:49:50 2021 UTC