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

Comparing ray/src/rt/aniso.c (file contents):
Revision 2.9 by greg, Thu Jan 30 11:37:04 1992 UTC vs.
Revision 2.46 by greg, Fri Oct 1 18:11:18 2010 UTC

#	Line 1 \| Line 1
1	–	/* Copyright (c) 1992 Regents of the University of California */
2	–
1		#ifndef lint
2	<	static char SCCSid[] = "$SunId$ LBL";
2	>	static const char RCSid[] = "$Id$";
3		#endif
6	–
4		/*
5		* Shading functions for anisotropic materials.
6		*/
7
8	<	#include "ray.h"
8	>	#include "copyright.h"
9
10	+	#include "ray.h"
11	+	#include "ambient.h"
12		#include "otypes.h"
13	<
13	>	#include "rtotypes.h"
14	>	#include "source.h"
15		#include "func.h"
16	–
16		#include "random.h"
17
18	<	extern double specthresh; /* specular sampling threshold */
19	<	extern double specjitter; /* specular sampling jitter */
18	>	#ifndef MAXITER
19	>	#define MAXITER 10 /* maximum # specular ray attempts */
20	>	#endif
21
22		/*
23	<	* This anisotropic reflection model uses a variant on the
24	<	* exponential Gaussian used in normal.c.
23	>	* This routine implements the anisotropic Gaussian
24	>	* model described by Ward in Siggraph `92 article.
25		* We orient the surface towards the incoming ray, so a single
26		* surface can be used to represent an infinitely thin object.
27		*
#	Line 34 \| Line 34 \| *extern double specjitter; / specular sampling jitte**
34		* 8 red grn blu rspec u-rough v-rough trans tspec
35		*/
36
37	–	#define BSPEC(m) (6.0) /* specularity parameter b */
38	–
37		/* specularity flags */
38		#define SP_REFL 01 /* has reflected specular component */
39		#define SP_TRAN 02 /* has transmitted specular */
40	<	#define SP_PURE 010 /* purely specular (zero roughness) */
41	<	#define SP_FLAT 020 /* reflecting surface is flat */
42	<	#define SP_RBLT 040 /* reflection below sample threshold */
43	<	#define SP_TBLT 0100 /* transmission below threshold */
46	<	#define SP_BADU 0200 /* bad u direction calculation */
40	>	#define SP_FLAT 04 /* reflecting surface is flat */
41	>	#define SP_RBLT 010 /* reflection below sample threshold */
42	>	#define SP_TBLT 020 /* transmission below threshold */
43	>	#define SP_BADU 040 /* bad u direction calculation */
44
45		typedef struct {
46		OBJREC mp; / material pointer */
#	Line 63 \| Line 60 \| typedef struct {
60		double pdot; /* perturbed dot product */
61		} ANISODAT; /* anisotropic material data */
62
63	+	static srcdirf_t diraniso;
64	+	static void getacoords(RAY r, ANISODAT np);
65	+	static void agaussamp(RAY r, ANISODAT np);
66
67	<	diraniso(cval, np, ldir, omega) /* compute source contribution */
68	<	COLOR cval; /* returned coefficient */
69	<	register ANISODAT np; / material data */
70	<	FVECT ldir; /* light source direction */
71	<	double omega; /* light source size */
67	>
68	>	static void
69	>	diraniso( /* compute source contribution */
70	>	COLOR cval, /* returned coefficient */
71	>	void nnp, / material data */
72	>	FVECT ldir, /* light source direction */
73	>	double omega /* light source size */
74	>	)
75		{
76	+	register ANISODAT *np = nnp;
77		double ldot;
78	<	double dtmp, dtmp2;
78	>	double dtmp, dtmp1, dtmp2;
79		FVECT h;
80		double au2, av2;
81		COLOR ctmp;
#	Line 90 \| Line 94 \| *double omega; / light source size /*
94		* modified by the color of the material.
95		*/
96		copycolor(ctmp, np->mcolor);
97	<	dtmp = ldot * omega * np->rdiff / PI;
97	>	dtmp = ldot * omega * np->rdiff * (1.0/PI);
98		scalecolor(ctmp, dtmp);
99		addcolor(cval, ctmp);
100		}
101	<	if (ldot > FTINY && (np->specfl&(SP_REFL\|SP_PURE\|SP_BADU)) == SP_REFL) {
101	>	if (ldot > FTINY && (np->specfl&(SP_REFL\|SP_BADU)) == SP_REFL) {
102		/*
103		* Compute specular reflection coefficient using
104	<	* anisotropic gaussian distribution model.
104	>	* anisotropic Gaussian distribution model.
105		*/
106		/* add source width if flat */
107		if (np->specfl & SP_FLAT)
108	<	au2 = av2 = omega/(4.0*PI);
108	>	au2 = av2 = omega * (0.25/PI);
109		else
110		au2 = av2 = 0.0;
111	<	au2 += np->u_alpha * np->u_alpha;
112	<	av2 += np->v_alpha * np->v_alpha;
111	>	au2 += np->u_alpha*np->u_alpha;
112	>	av2 += np->v_alpha*np->v_alpha;
113		/* half vector */
114		h[0] = ldir[0] - np->rp->rdir[0];
115		h[1] = ldir[1] - np->rp->rdir[1];
116		h[2] = ldir[2] - np->rp->rdir[2];
113	–	normalize(h);
117		/* ellipse */
118	<	dtmp = DOT(np->u, h);
119	<	dtmp *= dtmp / au2;
118	>	dtmp1 = DOT(np->u, h);
119	>	dtmp1 *= dtmp1 / au2;
120		dtmp2 = DOT(np->v, h);
121		dtmp2 *= dtmp2 / av2;
122	<	/* gaussian */
123	<	dtmp = (dtmp + dtmp2) / (1.0 + DOT(np->pnorm, h));
124	<	dtmp = exp(-2.0dtmp) / (4.0PI * sqrt(au2*av2));
122	>	/* new W-G-M-D model */
123	>	dtmp = DOT(np->pnorm, h);
124	>	dtmp *= dtmp;
125	>	dtmp1 = (dtmp1 + dtmp2) / dtmp;
126	>	dtmp = exp(-dtmp1) * DOT(h,h) /
127	>	(PI * dtmpdtmp sqrt(au2*av2));
128		/* worth using? */
129		if (dtmp > FTINY) {
130		copycolor(ctmp, np->scolor);
131	<	dtmp *= omega / np->pdot;
131	>	dtmp = ldot omega;
132		scalecolor(ctmp, dtmp);
133		addcolor(cval, ctmp);
134		}
#	Line 132 \| Line 138 \| *double omega; / light source size /*
138		* Compute diffuse transmission.
139		*/
140		copycolor(ctmp, np->mcolor);
141	<	dtmp = -ldot * omega * np->tdiff / PI;
141	>	dtmp = -ldot * omega * np->tdiff * (1.0/PI);
142		scalecolor(ctmp, dtmp);
143		addcolor(cval, ctmp);
144		}
145	<	if (ldot < -FTINY && (np->specfl&(SP_TRAN\|SP_PURE\|SP_BADU)) == SP_TRAN) {
145	>	if (ldot < -FTINY && (np->specfl&(SP_TRAN\|SP_BADU)) == SP_TRAN) {
146		/*
147		* Compute specular transmission. Specular transmission
148		* is always modified by material color.
149		*/
150		/* roughness + source */
151	<	/* gaussian */
152	<	dtmp = 0.0;
151	>	au2 = av2 = omega * (1.0/PI);
152	>	au2 += np->u_alpha*np->u_alpha;
153	>	av2 += np->v_alpha*np->v_alpha;
154	>	/* "half vector" */
155	>	h[0] = ldir[0] - np->prdir[0];
156	>	h[1] = ldir[1] - np->prdir[1];
157	>	h[2] = ldir[2] - np->prdir[2];
158	>	dtmp = DOT(h,h);
159	>	if (dtmp > FTINY*FTINY) {
160	>	dtmp1 = DOT(h,np->pnorm);
161	>	dtmp = 1.0 - dtmp1*dtmp1/dtmp;
162	>	if (dtmp > FTINY*FTINY) {
163	>	dtmp1 = DOT(h,np->u);
164	>	dtmp1 *= dtmp1 / au2;
165	>	dtmp2 = DOT(h,np->v);
166	>	dtmp2 *= dtmp2 / av2;
167	>	dtmp = (dtmp1 + dtmp2) / dtmp;
168	>	}
169	>	} else
170	>	dtmp = 0.0;
171	>	/* Gaussian */
172	>	dtmp = exp(-dtmp) * (1.0/PI) * sqrt(-ldot/(np->pdotau2av2));
173		/* worth using? */
174		if (dtmp > FTINY) {
175		copycolor(ctmp, np->mcolor);
176	<	dtmp = np->tspec omega / np->pdot;
176	>	dtmp = np->tspec omega;
177		scalecolor(ctmp, dtmp);
178		addcolor(cval, ctmp);
179		}
#	Line 155 \| Line 181 \| *double omega; / light source size /*
181		}
182
183
184	<	m_aniso(m, r) /* shade ray that hit something anisotropic */
185	<	register OBJREC *m;
186	<	register RAY *r;
184	>	extern int
185	>	m_aniso( /* shade ray that hit something anisotropic */
186	>	register OBJREC *m,
187	>	register RAY *r
188	>	)
189		{
190		ANISODAT nd;
163	–	double transtest, transdist;
164	–	double dtmp;
191		COLOR ctmp;
192		register int i;
193		/* easy shadow test */
194	<	if (r->crtype & SHADOW && m->otype != MAT_TRANS2)
195	<	return;
194	>	if (r->crtype & SHADOW)
195	>	return(1);
196
197		if (m->oargs.nfargs != (m->otype == MAT_TRANS2 ? 8 : 6))
198		objerror(m, USER, "bad number of real arguments");
199	+	/* check for back side */
200	+	if (r->rod < 0.0) {
201	+	if (!backvis && m->otype != MAT_TRANS2) {
202	+	raytrans(r);
203	+	return(1);
204	+	}
205	+	raytexture(r, m->omod);
206	+	flipsurface(r); /* reorient if backvis */
207	+	} else
208	+	raytexture(r, m->omod);
209	+	/* get material color */
210		nd.mp = m;
211		nd.rp = r;
175	–	/* get material color */
212		setcolor(nd.mcolor, m->oargs.farg[0],
213		m->oargs.farg[1],
214		m->oargs.farg[2]);
#	Line 181 \| Line 217 \| *register RAY r;**
217		nd.u_alpha = m->oargs.farg[4];
218		nd.v_alpha = m->oargs.farg[5];
219		if (nd.u_alpha <= FTINY \|\| nd.v_alpha <= FTINY)
220	<	nd.specfl \|= SP_PURE;
221	<	/* reorient if necessary */
186	<	if (r->rod < 0.0)
187	<	flipsurface(r);
188	<	/* get modifiers */
189	<	raytexture(r, m->omod);
220	>	objerror(m, USER, "roughness too small");
221	>
222		nd.pdot = raynormal(nd.pnorm, r); /* perturb normal */
223		if (nd.pdot < .001)
224		nd.pdot = .001; /* non-zero for diraniso() */
225		multcolor(nd.mcolor, r->pcol); /* modify material color */
194	–	transtest = 0;
226		/* get specular component */
227		if ((nd.rspec = m->oargs.farg[3]) > FTINY) {
228		nd.specfl \|= SP_REFL;
#	Line 201 \| Line 232 \| *register RAY r;**
232		else
233		setcolor(nd.scolor, 1.0, 1.0, 1.0);
234		scalecolor(nd.scolor, nd.rspec);
204	–	/* improved model */
205	–	dtmp = exp(-BSPEC(m)*nd.pdot);
206	–	for (i = 0; i < 3; i++)
207	–	colval(nd.scolor,i) += (1.0-colval(nd.scolor,i))*dtmp;
208	–	nd.rspec += (1.0-nd.rspec)*dtmp;
235		/* check threshold */
236	<	if (specthresh > FTINY &&
211	<	((specthresh >= 1.-FTINY \|\|
212	<	specthresh + (.05 - .1*frandom()) > nd.rspec)))
236	>	if (specthresh >= nd.rspec-FTINY)
237		nd.specfl \|= SP_RBLT;
238		/* compute refl. direction */
239		for (i = 0; i < 3; i++)
#	Line 217 \| Line 241 \| *register RAY r;**
241		if (DOT(nd.vrefl, r->ron) <= FTINY) /* penetration? */
242		for (i = 0; i < 3; i++) /* safety measure */
243		nd.vrefl[i] = r->rdir[i] + 2.r->rodr->ron[i];
220	–
221	–	if (!(r->crtype & SHADOW) && nd.specfl & SP_PURE) {
222	–	RAY lr;
223	–	if (rayorigin(&lr, r, REFLECTED, nd.rspec) == 0) {
224	–	VCOPY(lr.rdir, nd.vrefl);
225	–	rayvalue(&lr);
226	–	multcolor(lr.rcol, nd.scolor);
227	–	addcolor(r->rcol, lr.rcol);
228	–	}
229	–	}
244		}
245		/* compute transmission */
246	<	if (m->otype == MAT_TRANS) {
246	>	if (m->otype == MAT_TRANS2) {
247		nd.trans = m->oargs.farg[6]*(1.0 - nd.rspec);
248		nd.tspec = nd.trans * m->oargs.farg[7];
249		nd.tdiff = nd.trans - nd.tspec;
250		if (nd.tspec > FTINY) {
251		nd.specfl \|= SP_TRAN;
252		/* check threshold */
253	<	if (specthresh > FTINY &&
240	<	((specthresh >= 1.-FTINY \|\|
241	<	specthresh +
242	<	(.05 - .1*frandom()) > nd.tspec)))
253	>	if (specthresh >= nd.tspec-FTINY)
254		nd.specfl \|= SP_TBLT;
255	<	if (r->crtype & SHADOW \|\|
245	<	DOT(r->pert,r->pert) <= FTINY*FTINY) {
255	>	if (DOT(r->pert,r->pert) <= FTINY*FTINY) {
256		VCOPY(nd.prdir, r->rdir);
247	–	transtest = 2;
257		} else {
258		for (i = 0; i < 3; i++) /* perturb */
259	<	nd.prdir[i] = r->rdir[i] -
251	<	0.5*r->pert[i];
259	>	nd.prdir[i] = r->rdir[i] - r->pert[i];
260		if (DOT(nd.prdir, r->ron) < -FTINY)
261		normalize(nd.prdir); /* OK */
262		else
#	Line 257 \| Line 265 \| *register RAY r;**
265		}
266		} else
267		nd.tdiff = nd.tspec = nd.trans = 0.0;
260	–	/* transmitted ray */
261	–	if ((nd.specfl&(SP_TRAN\|SP_PURE)) == (SP_TRAN\|SP_PURE)) {
262	–	RAY lr;
263	–	if (rayorigin(&lr, r, TRANS, nd.tspec) == 0) {
264	–	VCOPY(lr.rdir, nd.prdir);
265	–	rayvalue(&lr);
266	–	scalecolor(lr.rcol, nd.tspec);
267	–	multcolor(lr.rcol, nd.mcolor); /* modified by color */
268	–	addcolor(r->rcol, lr.rcol);
269	–	transtest *= bright(lr.rcol);
270	–	transdist = r->rot + lr.rt;
271	–	}
272	–	}
268
274	–	if (r->crtype & SHADOW) /* the rest is shadow */
275	–	return;
269		/* diffuse reflection */
270		nd.rdiff = 1.0 - nd.trans - nd.rspec;
271
272	<	if (nd.specfl & SP_PURE && nd.rdiff <= FTINY && nd.tdiff <= FTINY)
280	<	return; /* 100% pure specular */
281	<
282	<	if (r->ro->otype == OBJ_FACE \|\| r->ro->otype == OBJ_RING)
272	>	if (r->ro != NULL && isflat(r->ro->otype))
273		nd.specfl \|= SP_FLAT;
274
275		getacoords(r, &nd); /* set up coordinates */
276
277	<	if (nd.specfl & (SP_REFL\|SP_TRAN) && !(nd.specfl & (SP_PURE\|SP_BADU)))
277	>	if (nd.specfl & (SP_REFL\|SP_TRAN) && !(nd.specfl & SP_BADU))
278		agaussamp(r, &nd);
279
280		if (nd.rdiff > FTINY) { /* ambient from this side */
281	<	ambient(ctmp, r);
281	>	copycolor(ctmp, nd.mcolor); /* modified by material color */
282		if (nd.specfl & SP_RBLT)
283		scalecolor(ctmp, 1.0-nd.trans);
284		else
285		scalecolor(ctmp, nd.rdiff);
286	<	multcolor(ctmp, nd.mcolor); /* modified by material color */
286	>	multambient(ctmp, r, nd.pnorm);
287		addcolor(r->rcol, ctmp); /* add to returned color */
288		}
289		if (nd.tdiff > FTINY) { /* ambient from other side */
290	+	FVECT bnorm;
291	+
292		flipsurface(r);
293	<	ambient(ctmp, r);
293	>	bnorm[0] = -nd.pnorm[0];
294	>	bnorm[1] = -nd.pnorm[1];
295	>	bnorm[2] = -nd.pnorm[2];
296	>	copycolor(ctmp, nd.mcolor); /* modified by color */
297		if (nd.specfl & SP_TBLT)
298		scalecolor(ctmp, nd.trans);
299		else
300		scalecolor(ctmp, nd.tdiff);
301	<	multcolor(ctmp, nd.mcolor); /* modified by color */
301	>	multambient(ctmp, r, bnorm);
302		addcolor(r->rcol, ctmp);
303		flipsurface(r);
304		}
305		/* add direct component */
306		direct(r, diraniso, &nd);
307	<	/* check distance */
308	<	if (transtest > bright(r->rcol))
314	<	r->rt = transdist;
307	>
308	>	return(1);
309		}
310
311
312	<	static
313	<	getacoords(r, np) /* set up coordinate system */
314	<	RAY *r;
315	<	register ANISODAT *np;
312	>	static void
313	>	getacoords( /* set up coordinate system */
314	>	RAY *r,
315	>	register ANISODAT *np
316	>	)
317		{
318		register MFUNC *mf;
319		register int i;
#	Line 328 \| Line 323 \| *register ANISODAT np;**
323		errno = 0;
324		for (i = 0; i < 3; i++)
325		np->u[i] = evalue(mf->ep[i]);
326	<	if (errno) {
326	>	if (errno == EDOM \|\| errno == ERANGE) {
327		objerror(np->mp, WARNING, "compute error");
328		np->specfl \|= SP_BADU;
329		return;
330		}
331	<	multv3(np->u, np->u, mf->f->xfm);
331	>	if (mf->f != &unitxf)
332	>	multv3(np->u, np->u, mf->f->xfm);
333		fcross(np->v, np->pnorm, np->u);
334		if (normalize(np->v) == 0.0) {
335		objerror(np->mp, WARNING, "illegal orientation vector");
#	Line 344 \| Line 340 \| *register ANISODAT np;**
340		}
341
342
343	<	static
344	<	agaussamp(r, np) /* sample anisotropic gaussian specular */
345	<	RAY *r;
346	<	register ANISODAT *np;
343	>	static void
344	>	agaussamp( /* sample anisotropic Gaussian specular */
345	>	RAY *r,
346	>	register ANISODAT *np
347	>	)
348		{
349		RAY sr;
350		FVECT h;
351		double rv[2];
352		double d, sinp, cosp;
353	+	int niter;
354		register int i;
355		/* compute reflection */
356		if ((np->specfl & (SP_REFL\|SP_RBLT)) == SP_REFL &&
357	<	rayorigin(&sr, r, SPECULAR, np->rspec) == 0) {
357	>	rayorigin(&sr, SPECULAR, r, np->scolor) == 0) {
358		dimlist[ndims++] = (int)np->mp;
359	<	d = urand(ilhash(dimlist,ndims)+samplendx);
360	<	multisamp(rv, 2, d);
361	<	d = 2.0PI rv[0];
362	<	cosp = np->u_alpha * cos(d);
363	<	sinp = np->v_alpha * sin(d);
364	<	d = sqrt(cospcosp + sinpsinp);
365	<	cosp /= d;
366	<	sinp /= d;
367	<	rv[1] = 1.0 - specjitter*rv[1];
368	<	if (rv[1] <= FTINY)
369	<	d = 1.0;
370	<	else
371	<	d = sqrt(-log(rv[1]) /
372	<	(cospcosp/(np->u_alphanp->u_alpha) +
373	<	sinpsinp/(np->v_alphanp->v_alpha)));
374	<	for (i = 0; i < 3; i++)
375	<	h[i] = np->pnorm[i] +
376	<	d(cospnp->u[i] + sinp*np->v[i]);
377	<	d = -2.0 * DOT(h, r->rdir) / (1.0 + d*d);
378	<	for (i = 0; i < 3; i++)
379	<	sr.rdir[i] = r->rdir[i] + d*h[i];
380	<	if (DOT(sr.rdir, r->ron) <= FTINY) /* penetration? */
381	<	VCOPY(sr.rdir, np->vrefl); /* jitter no good */
382	<	rayvalue(&sr);
383	<	multcolor(sr.rcol, np->scolor);
384	<	addcolor(r->rcol, sr.rcol);
359	>	for (niter = 0; niter < MAXITER; niter++) {
360	>	if (niter)
361	>	d = frandom();
362	>	else
363	>	d = urand(ilhash(dimlist,ndims)+samplendx);
364	>	multisamp(rv, 2, d);
365	>	d = 2.0PI rv[0];
366	>	cosp = tcos(d) * np->u_alpha;
367	>	sinp = tsin(d) * np->v_alpha;
368	>	d = sqrt(cospcosp + sinpsinp);
369	>	cosp /= d;
370	>	sinp /= d;
371	>	rv[1] = 1.0 - specjitter*rv[1];
372	>	if (rv[1] <= FTINY)
373	>	d = 1.0;
374	>	else
375	>	d = sqrt(-log(rv[1]) /
376	>	(cospcosp/(np->u_alphanp->u_alpha) +
377	>	sinpsinp/(np->v_alphanp->v_alpha)));
378	>	for (i = 0; i < 3; i++)
379	>	h[i] = np->pnorm[i] +
380	>	d(cospnp->u[i] + sinp*np->v[i]);
381	>	d = -2.0 * DOT(h, r->rdir) / (1.0 + d*d);
382	>	for (i = 0; i < 3; i++)
383	>	sr.rdir[i] = r->rdir[i] + d*h[i];
384	>	if (DOT(sr.rdir, r->ron) > FTINY) {
385	>	checknorm(sr.rdir);
386	>	rayvalue(&sr);
387	>	multcolor(sr.rcol, sr.rcoef);
388	>	addcolor(r->rcol, sr.rcol);
389	>	break;
390	>	}
391	>	}
392		ndims--;
393		}
394		/* compute transmission */
395	+	copycolor(sr.rcoef, np->mcolor); /* modify by material color */
396	+	scalecolor(sr.rcoef, np->tspec);
397		if ((np->specfl & (SP_TRAN\|SP_TBLT)) == SP_TRAN &&
398	<	rayorigin(&sr, r, SPECULAR, np->tspec) == 0) {
398	>	rayorigin(&sr, SPECULAR, r, sr.rcoef) == 0) {
399		dimlist[ndims++] = (int)np->mp;
400	<	d = urand(ilhash(dimlist,ndims)+1823+samplendx);
401	<	multisamp(rv, 2, d);
402	<	d = 2.0PI rv[0];
403	<	cosp = cos(d);
404	<	sinp = sin(d);
405	<	rv[1] = 1.0 - specjitter*rv[1];
406	<	if (rv[1] <= FTINY)
407	<	d = 1.0;
408	<	else
409	<	d = sqrt(-log(rv[1]) /
410	<	(cospcosp4./(np->u_alpha*np->u_alpha) +
411	<	sinpsinp4./(np->v_alpha*np->v_alpha)));
412	<	for (i = 0; i < 3; i++)
413	<	sr.rdir[i] = np->prdir[i] +
414	<	d(cospnp->u[i] + sinp*np->v[i]);
415	<	if (DOT(sr.rdir, r->ron) < -FTINY)
416	<	normalize(sr.rdir); /* OK, normalize */
417	<	else
418	<	VCOPY(sr.rdir, np->prdir); /* else no jitter */
419	<	rayvalue(&sr);
420	<	multcolor(sr.rcol, np->scolor);
421	<	addcolor(r->rcol, sr.rcol);
400	>	for (niter = 0; niter < MAXITER; niter++) {
401	>	if (niter)
402	>	d = frandom();
403	>	else
404	>	d = urand(ilhash(dimlist,ndims)+1823+samplendx);
405	>	multisamp(rv, 2, d);
406	>	d = 2.0PI rv[0];
407	>	cosp = tcos(d) * np->u_alpha;
408	>	sinp = tsin(d) * np->v_alpha;
409	>	d = sqrt(cospcosp + sinpsinp);
410	>	cosp /= d;
411	>	sinp /= d;
412	>	rv[1] = 1.0 - specjitter*rv[1];
413	>	if (rv[1] <= FTINY)
414	>	d = 1.0;
415	>	else
416	>	d = sqrt(-log(rv[1]) /
417	>	(cospcosp/(np->u_alphanp->u_alpha) +
418	>	sinpsinp/(np->v_alphanp->v_alpha)));
419	>	for (i = 0; i < 3; i++)
420	>	sr.rdir[i] = np->prdir[i] +
421	>	d(cospnp->u[i] + sinp*np->v[i]);
422	>	if (DOT(sr.rdir, r->ron) < -FTINY) {
423	>	normalize(sr.rdir); /* OK, normalize */
424	>	rayvalue(&sr);
425	>	multcolor(sr.rcol, sr.rcoef);
426	>	addcolor(r->rcol, sr.rcol);
427	>	break;
428	>	}
429	>	}
430		ndims--;
431		}
432		}

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Comparing ray/src/rt/aniso.c (file contents): Revision 2.9 by greg, Thu Jan 30 11:37:04 1992 UTC vs. Revision 2.46 by greg, Fri Oct 1 18:11:18 2010 UTC

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Comparing ray/src/rt/aniso.c (file contents):
Revision 2.9 by greg, Thu Jan 30 11:37:04 1992 UTC vs.
Revision 2.46 by greg, Fri Oct 1 18:11:18 2010 UTC