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

Comparing ray/src/rt/ambcomp.c (file contents):
Revision 2.27 by greg, Sat Apr 19 02:39:44 2014 UTC vs.
Revision 2.52 by greg, Wed May 7 21:45:13 2014 UTC

#	Line 8 \| Line 8 \| static const char RCSid[] = "$Id$";
8		* for Irradiance Caching" by Schwarzhaupt, Wann Jensen, & Jarosz
9		* from ACM SIGGRAPH Asia 2012 conference proceedings.
10		*
11	+	* Added book-keeping optimization to avoid calculations that would
12	+	* cancel due to traversal both directions on edges that are adjacent
13	+	* to same-valued triangles. This cuts about half of Hessian math.
14	+	*
15		* Declarations of external symbols in ambient.h
16		*/
17
#	Line 21 \| Line 25 \| static const char RCSid[] = "$Id$";
25
26		extern void SDsquare2disk(double ds[2], double seedx, double seedy);
27
28	+	/* vertex direction bit positions */
29	+	#define VDB_xy 0
30	+	#define VDB_y 01
31	+	#define VDB_x 02
32	+	#define VDB_Xy 03
33	+	#define VDB_xY 04
34	+	#define VDB_X 05
35	+	#define VDB_Y 06
36	+	#define VDB_XY 07
37	+	/* get opposite vertex direction bit */
38	+	#define VDB_OPP(f) (~(f) & 07)
39	+	/* adjacent triangle vertex flags */
40	+	static const int adjacent_trifl[8] = {
41	+	0, /* forbidden diagonal */
42	+	1<<VDB_x\|1<<VDB_y\|1<<VDB_Xy,
43	+	1<<VDB_y\|1<<VDB_x\|1<<VDB_xY,
44	+	1<<VDB_y\|1<<VDB_Xy\|1<<VDB_X,
45	+	1<<VDB_x\|1<<VDB_xY\|1<<VDB_Y,
46	+	1<<VDB_Xy\|1<<VDB_X\|1<<VDB_Y,
47	+	1<<VDB_xY\|1<<VDB_Y\|1<<VDB_X,
48	+	0, /* forbidden diagonal */
49	+	};
50	+
51		typedef struct {
52	+	COLOR v; /* hemisphere sample value */
53	+	float d; /* reciprocal distance (1/rt) */
54	+	FVECT p; /* intersection point */
55	+	} AMBSAMP; /* sample value */
56	+
57	+	typedef struct {
58		RAY rp; / originating ray sample */
59		FVECT ux, uy; /* tangent axis unit vectors */
60		int ns; /* number of samples per axis */
61		COLOR acoef; /* division contribution coefficient */
62	<	struct s_ambsamp {
30	<	COLOR v; /* hemisphere sample value */
31	<	float p[3]; /* intersection point */
32	<	} sa[1]; /* sample array (extends struct) */
62	>	AMBSAMP sa[1]; /* sample array (extends struct) */
63		} AMBHEMI; /* ambient sample hemisphere */
64
65	<	#define ambsamp(h,i,j) (h)->sa[(i)*(h)->ns + (j)]
65	>	#define ambndx(h,i,j) ((i)*(h)->ns + (j))
66	>	#define ambsam(h,i,j) (h)->sa[ambndx(h,i,j)]
67
68		typedef struct {
69	<	FVECT r_i, r_i1, e_i;
70	<	double nf, I1, I2, J2;
69	>	FVECT r_i, r_i1, e_i, rcp, rI2_eJ2;
70	>	double I1, I2;
71	>	int valid;
72		} FFTRI; /* vectors and coefficients for Hessian calculation */
73
74
75	+	/* Get index for adjacent vertex */
76	+	static int
77	+	adjacent_verti(AMBHEMI *hp, int i, int j, int dbit)
78	+	{
79	+	int i0 = i*hp->ns + j;
80	+
81	+	switch (dbit) {
82	+	case VDB_y: return(i0 - hp->ns);
83	+	case VDB_x: return(i0 - 1);
84	+	case VDB_Xy: return(i0 - hp->ns + 1);
85	+	case VDB_xY: return(i0 + hp->ns - 1);
86	+	case VDB_X: return(i0 + 1);
87	+	case VDB_Y: return(i0 + hp->ns);
88	+	/* the following should never occur */
89	+	case VDB_xy: return(i0 - hp->ns - 1);
90	+	case VDB_XY: return(i0 + hp->ns + 1);
91	+	}
92	+	return(-1);
93	+	}
94	+
95	+
96	+	/* Get vertex direction bit for the opposite edge to complete triangle */
97	+	static int
98	+	vdb_edge(int db1, int db2)
99	+	{
100	+	switch (db1) {
101	+	case VDB_x: return(db2==VDB_y ? VDB_Xy : VDB_Y);
102	+	case VDB_y: return(db2==VDB_x ? VDB_xY : VDB_X);
103	+	case VDB_X: return(db2==VDB_Xy ? VDB_y : VDB_xY);
104	+	case VDB_Y: return(db2==VDB_xY ? VDB_x : VDB_Xy);
105	+	case VDB_xY: return(db2==VDB_x ? VDB_y : VDB_X);
106	+	case VDB_Xy: return(db2==VDB_y ? VDB_x : VDB_Y);
107	+	}
108	+	error(INTERNAL, "forbidden diagonal in vdb_edge()");
109	+	return(-1);
110	+	}
111	+
112	+
113		static AMBHEMI *
114		inithemi( /* initialize sampling hemisphere */
115		COLOR ac,
#	Line 59 \| Line 129 \| *inithemi( / initialize sampling hemisphere /*
129		if (n < i)
130		n = i;
131		/* allocate sampling array */
132	<	hp = (AMBHEMI *)malloc(sizeof(AMBHEMI) +
63	<	sizeof(struct s_ambsamp)(nn - 1));
132	>	hp = (AMBHEMI )malloc(sizeof(AMBHEMI) + sizeof(AMBSAMP)(n*n - 1));
133		if (hp == NULL)
134		return(NULL);
135		hp->rp = r;
#	Line 69 \| Line 138 \| *inithemi( / initialize sampling hemisphere /*
138		copycolor(hp->acoef, ac);
139		d = 1.0/(n*n);
140		scalecolor(hp->acoef, d);
141	<	/* make tangent axes */
142	<	hp->uy[0] = hp->uy[1] = hp->uy[2] = 0.0;
143	<	for (i = 0; i < 3; i++)
144	<	if (r->ron[i] < 0.6 && r->ron[i] > -0.6)
141	>	/* make tangent plane axes */
142	>	hp->uy[0] = 0.5 - frandom();
143	>	hp->uy[1] = 0.5 - frandom();
144	>	hp->uy[2] = 0.5 - frandom();
145	>	for (i = 3; i--; )
146	>	if ((-0.6 < r->ron[i]) & (r->ron[i] < 0.6))
147		break;
148	<	if (i >= 3)
149	<	error(CONSISTENCY, "bad ray direction in inithemi()");
148	>	if (i < 0)
149	>	error(CONSISTENCY, "bad ray direction in inithemi");
150		hp->uy[i] = 1.0;
151		VCROSS(hp->ux, hp->uy, r->ron);
152		normalize(hp->ux);
#	Line 85 \| Line 156 \| *inithemi( / initialize sampling hemisphere /*
156		}
157
158
159	+	/* Sample ambient division and apply weighting coefficient */
160		static int
161	<	ambsample( /* sample an ambient direction */
90	<	AMBHEMI *hp,
91	<	int i,
92	<	int j
93	<	)
161	>	getambsamp(RAY arp, AMBHEMI hp, int i, int j, int n)
162		{
163	<	struct s_ambsamp *ap = &ambsamp(hp,i,j);
164	<	RAY ar;
97	<	int hlist[3];
98	<	double spt[2], zd;
99	<	int ii;
163	>	int hlist[3], ii;
164	>	double spt[2], zd;
165		/* ambient coefficient for weight */
166		if (ambacc > FTINY)
167	<	setcolor(ar.rcoef, AVGREFL, AVGREFL, AVGREFL);
167	>	setcolor(arp->rcoef, AVGREFL, AVGREFL, AVGREFL);
168		else
169	<	copycolor(ar.rcoef, hp->acoef);
170	<	if (rayorigin(&ar, AMBIENT, hp->rp, ar.rcoef) < 0) {
171	<	setcolor(ap->v, 0., 0., 0.);
107	<	VCOPY(ap->p, hp->rp->rop);
108	<	return(0); /* no sample taken */
109	<	}
169	>	copycolor(arp->rcoef, hp->acoef);
170	>	if (rayorigin(arp, AMBIENT, hp->rp, arp->rcoef) < 0)
171	>	return(0);
172		if (ambacc > FTINY) {
173	<	multcolor(ar.rcoef, hp->acoef);
174	<	scalecolor(ar.rcoef, 1./AVGREFL);
173	>	multcolor(arp->rcoef, hp->acoef);
174	>	scalecolor(arp->rcoef, 1./AVGREFL);
175		}
176	<	/* generate hemispherical sample */
177	<	SDsquare2disk(spt, (i+.1+.8*frandom())/hp->ns,
178	<	(j+.1+.8*frandom())/hp->ns);
176	>	hlist[0] = hp->rp->rno;
177	>	hlist[1] = j;
178	>	hlist[2] = i;
179	>	multisamp(spt, 2, urand(ilhash(hlist,3)+n));
180	>	if (!n) { /* avoid border samples for n==0 */
181	>	if ((spt[0] < 0.1) \| (spt[0] >= 0.9))
182	>	spt[0] = 0.1 + 0.8*frandom();
183	>	if ((spt[1] < 0.1) \| (spt[1] >= 0.9))
184	>	spt[1] = 0.1 + 0.8*frandom();
185	>	}
186	>	SDsquare2disk(spt, (j+spt[1])/hp->ns, (i+spt[0])/hp->ns);
187		zd = sqrt(1. - spt[0]spt[0] - spt[1]spt[1]);
188		for (ii = 3; ii--; )
189	<	ar.rdir[ii] = spt[0]*hp->ux[ii] +
189	>	arp->rdir[ii] = spt[0]*hp->ux[ii] +
190		spt[1]*hp->uy[ii] +
191		zd*hp->rp->ron[ii];
192	<	checknorm(ar.rdir);
193	<	dimlist[ndims++] = i*hp->ns + j + 90171;
194	<	rayvalue(&ar); /* evaluate ray */
195	<	ndims--;
196	<	multcolor(ar.rcol, ar.rcoef); /* apply coefficient */
127	<	copycolor(ap->v, ar.rcol);
128	<	if (ar.rt > 20.0maxarad) / limit vertex distance */
129	<	ar.rt = 20.0*maxarad;
130	<	VSUM(ap->p, ar.rorg, ar.rdir, ar.rt);
192	>	checknorm(arp->rdir);
193	>	dimlist[ndims++] = ambndx(hp,i,j) + 90171;
194	>	rayvalue(arp); /* evaluate ray */
195	>	ndims--; /* apply coefficient */
196	>	multcolor(arp->rcol, arp->rcoef);
197		return(1);
198		}
199
200
201	+	static AMBSAMP *
202	+	ambsample( /* initial ambient division sample */
203	+	AMBHEMI *hp,
204	+	int i,
205	+	int j
206	+	)
207	+	{
208	+	AMBSAMP *ap = &ambsam(hp,i,j);
209	+	RAY ar;
210	+	/* generate hemispherical sample */
211	+	if (!getambsamp(&ar, hp, i, j, 0) \|\| ar.rt <= FTINY) {
212	+	memset(ap, 0, sizeof(AMBSAMP));
213	+	return(NULL);
214	+	}
215	+	ap->d = 1.0/ar.rt; /* limit vertex distance */
216	+	if (ar.rt > 10.0*thescene.cusize)
217	+	ar.rt = 10.0*thescene.cusize;
218	+	VSUM(ap->p, ar.rorg, ar.rdir, ar.rt);
219	+	copycolor(ap->v, ar.rcol);
220	+	return(ap);
221	+	}
222	+
223	+
224	+	/* Estimate errors based on ambient division differences */
225	+	static float *
226	+	getambdiffs(AMBHEMI *hp)
227	+	{
228	+	float earr = (float )calloc(hp->ns*hp->ns, sizeof(float));
229	+	float *ep;
230	+	AMBSAMP *ap;
231	+	double b, d2;
232	+	int i, j;
233	+
234	+	if (earr == NULL) /* out of memory? */
235	+	return(NULL);
236	+	/* compute squared neighbor diffs */
237	+	for (ap = hp->sa, ep = earr, i = 0; i < hp->ns; i++)
238	+	for (j = 0; j < hp->ns; j++, ap++, ep++) {
239	+	b = bright(ap[0].v);
240	+	if (i) { /* from above */
241	+	d2 = b - bright(ap[-hp->ns].v);
242	+	d2 *= d2;
243	+	ep[0] += d2;
244	+	ep[-hp->ns] += d2;
245	+	}
246	+	if (j) { /* from behind */
247	+	d2 = b - bright(ap[-1].v);
248	+	d2 *= d2;
249	+	ep[0] += d2;
250	+	ep[-1] += d2;
251	+	}
252	+	}
253	+	/* correct for number of neighbors */
254	+	earr[0] *= 2.f;
255	+	earr[hp->ns-1] *= 2.f;
256	+	earr[(hp->ns-1)hp->ns] = 2.f;
257	+	earr[(hp->ns-1)hp->ns + hp->ns-1] = 2.f;
258	+	for (i = 1; i < hp->ns-1; i++) {
259	+	earr[ihp->ns] = 4./3.;
260	+	earr[ihp->ns + hp->ns-1] = 4./3.;
261	+	}
262	+	for (j = 1; j < hp->ns-1; j++) {
263	+	earr[j] *= 4./3.;
264	+	earr[(hp->ns-1)hp->ns + j] = 4./3.;
265	+	}
266	+	return(earr);
267	+	}
268	+
269	+
270	+	/* Perform super-sampling on hemisphere (introduces bias) */
271	+	static void
272	+	ambsupersamp(double acol[3], AMBHEMI *hp, int cnt)
273	+	{
274	+	float *earr = getambdiffs(hp);
275	+	double e2sum = 0.0;
276	+	AMBSAMP *ap;
277	+	RAY ar;
278	+	double asum[3];
279	+	float *ep;
280	+	int i, j, n;
281	+
282	+	if (earr == NULL) /* just skip calc. if no memory */
283	+	return;
284	+	/* add up estimated variances */
285	+	for (ep = earr + hp->ns*hp->ns; ep-- > earr; )
286	+	e2sum += *ep;
287	+	ep = earr; /* perform super-sampling */
288	+	for (ap = hp->sa, i = 0; i < hp->ns; i++)
289	+	for (j = 0; j < hp->ns; j++, ap++) {
290	+	int nss = ep/e2sumcnt + frandom();
291	+	asum[0] = asum[1] = asum[2] = 0.0;
292	+	for (n = 1; n <= nss; n++) {
293	+	if (!getambsamp(&ar, hp, i, j, n)) {
294	+	nss = n-1;
295	+	break;
296	+	}
297	+	addcolor(asum, ar.rcol);
298	+	}
299	+	if (nss) { /* update returned ambient value */
300	+	const double ssf = 1./(nss + 1);
301	+	for (n = 3; n--; )
302	+	acol[n] += ssf*asum[n] +
303	+	(ssf - 1.)*colval(ap->v,n);
304	+	}
305	+	e2sum -= ep++; / update remainders */
306	+	cnt -= nss;
307	+	}
308	+	free(earr);
309	+	}
310	+
311	+
312	+	/* Compute vertex flags, indicating farthest in each direction */
313	+	static uby8 *
314	+	vertex_flags(AMBHEMI *hp)
315	+	{
316	+	uby8 vflags = (uby8 )calloc(hp->ns*hp->ns, sizeof(uby8));
317	+	uby8 *vf;
318	+	AMBSAMP *ap;
319	+	int i, j;
320	+
321	+	if (vflags == NULL)
322	+	error(SYSTEM, "out of memory in vertex_flags()");
323	+	vf = vflags;
324	+	ap = hp->sa; /* compute farthest along first row */
325	+	for (j = 0; j < hp->ns-1; j++, vf++, ap++)
326	+	if (ap[0].d <= ap[1].d)
327	+	vf[0] \|= 1<<VDB_X;
328	+	else
329	+	vf[1] \|= 1<<VDB_x;
330	+	++vf; ++ap;
331	+	/* flag subsequent rows */
332	+	for (i = 1; i < hp->ns; i++) {
333	+	for (j = 0; j < hp->ns-1; j++, vf++, ap++) {
334	+	if (ap[0].d <= ap[-hp->ns].d) /* row before */
335	+	vf[0] \|= 1<<VDB_y;
336	+	else
337	+	vf[-hp->ns] \|= 1<<VDB_Y;
338	+	if (ap[0].d <= ap[1-hp->ns].d) /* diagonal we care about */
339	+	vf[0] \|= 1<<VDB_Xy;
340	+	else
341	+	vf[1-hp->ns] \|= 1<<VDB_xY;
342	+	if (ap[0].d <= ap[1].d) /* column after */
343	+	vf[0] \|= 1<<VDB_X;
344	+	else
345	+	vf[1] \|= 1<<VDB_x;
346	+	}
347	+	if (ap[0].d <= ap[-hp->ns].d) /* final column edge */
348	+	vf[0] \|= 1<<VDB_y;
349	+	else
350	+	vf[-hp->ns] \|= 1<<VDB_Y;
351	+	++vf; ++ap;
352	+	}
353	+	return(vflags);
354	+	}
355	+
356	+
357	+	/* Return brightness of farthest ambient sample */
358	+	static double
359	+	back_ambval(AMBHEMI hp, int i, int j, int dbit1, int dbit2, const uby8 vflags)
360	+	{
361	+	const int v0 = ambndx(hp,i,j);
362	+	const int tflags = (1<<dbit1 \| 1<<dbit2);
363	+	int v1, v2;
364	+
365	+	if ((vflags[v0] & tflags) == tflags) /* is v0 the farthest? */
366	+	return(colval(hp->sa[v0].v,CIEY));
367	+	v1 = adjacent_verti(hp, i, j, dbit1);
368	+	if (vflags[v0] & 1<<dbit2) /* v1 farthest if v0>v2 */
369	+	return(colval(hp->sa[v1].v,CIEY));
370	+	v2 = adjacent_verti(hp, i, j, dbit2);
371	+	if (vflags[v0] & 1<<dbit1) /* v2 farthest if v0>v1 */
372	+	return(colval(hp->sa[v2].v,CIEY));
373	+	/* else check if v1>v2 */
374	+	if (vflags[v1] & 1<<vdb_edge(dbit1,dbit2))
375	+	return(colval(hp->sa[v1].v,CIEY));
376	+	return(colval(hp->sa[v2].v,CIEY));
377	+	}
378	+
379	+
380		/* Compute vectors and coefficients for Hessian/gradient calcs */
381		static void
382	<	comp_fftri(FFTRI *ftp, float ap0[3], float ap1[3], FVECT rop)
382	>	comp_fftri(FFTRI ftp, AMBHEMI hp, int i, int j, int dbit, const uby8 *vflags)
383		{
384	<	FVECT v1;
385	<	double dot_e, dot_er, dot_r, dot_r1;
384	>	const int i0 = ambndx(hp,i,j);
385	>	double rdot_cp, dot_e, dot_er, rdot_r, rdot_r1, J2;
386	>	int i1, ii;
387
388	<	VSUB(ftp->r_i, ap0, rop);
389	<	VSUB(ftp->r_i1, ap1, rop);
390	<	VSUB(ftp->e_i, ap1, ap0);
391	<	VCROSS(v1, ftp->e_i, ftp->r_i);
392	<	ftp->nf = 1.0/DOT(v1,v1);
393	<	VCROSS(v1, ftp->r_i, ftp->r_i1);
394	<	ftp->I1 = sqrt(DOT(v1,v1)*ftp->nf);
388	>	ftp->valid = 0; /* check if we can skip this edge */
389	>	ii = adjacent_trifl[dbit];
390	>	if ((vflags[i0] & ii) == ii) /* cancels if vertex used as value */
391	>	return;
392	>	i1 = adjacent_verti(hp, i, j, dbit);
393	>	ii = adjacent_trifl[VDB_OPP(dbit)];
394	>	if ((vflags[i1] & ii) == ii) /* on either end (for both triangles) */
395	>	return;
396	>	/* else go ahead with calculation */
397	>	VSUB(ftp->r_i, hp->sa[i0].p, hp->rp->rop);
398	>	VSUB(ftp->r_i1, hp->sa[i1].p, hp->rp->rop);
399	>	VSUB(ftp->e_i, hp->sa[i1].p, hp->sa[i0].p);
400	>	VCROSS(ftp->rcp, ftp->r_i, ftp->r_i1);
401	>	rdot_cp = 1.0/DOT(ftp->rcp,ftp->rcp);
402		dot_e = DOT(ftp->e_i,ftp->e_i);
403		dot_er = DOT(ftp->e_i, ftp->r_i);
404	<	dot_r = DOT(ftp->r_i,ftp->r_i);
405	<	dot_r1 = DOT(ftp->r_i1,ftp->r_i1);
406	<	ftp->I2 = ( DOT(ftp->e_i, ftp->r_i1)/dot_r1 - dot_er/dot_r +
407	<	dot_eftp->I1 )0.5*ftp->nf;
408	<	ftp->J2 = 0.25ftp->nf( 1.0/dot_r - 1.0/dot_r1 ) -
409	<	dot_er/dot_e*ftp->I2;
404	>	rdot_r = 1.0/DOT(ftp->r_i,ftp->r_i);
405	>	rdot_r1 = 1.0/DOT(ftp->r_i1,ftp->r_i1);
406	>	ftp->I1 = acos( DOT(ftp->r_i, ftp->r_i1) * sqrt(rdot_rrdot_r1) )
407	>	sqrt( rdot_cp );
408	>	ftp->I2 = ( DOT(ftp->e_i, ftp->r_i1)rdot_r1 - dot_errdot_r +
409	>	dot_eftp->I1 )0.5*rdot_cp;
410	>	J2 = ( 0.5(rdot_r - rdot_r1) - dot_erftp->I2 ) / dot_e;
411	>	for (ii = 3; ii--; )
412	>	ftp->rI2_eJ2[ii] = ftp->I2ftp->r_i[ii] + J2ftp->e_i[ii];
413	>	ftp->valid++;
414		}
415
416
417	<	/* Compose matrix from two vectors */
417	>	/* Compose 3x3 matrix from two vectors */
418		static void
419		compose_matrix(FVECT mat[3], FVECT va, FVECT vb)
420		{
#	Line 174 \| Line 431 \| compose_matrix(FVECT mat[3], FVECT va, FVECT vb)
431		static void
432		comp_hessian(FVECT hess[3], FFTRI *ftp, FVECT nrm)
433		{
434	<	FVECT v1, v2;
434	>	FVECT ncp;
435		FVECT m1[3], m2[3], m3[3], m4[3];
436		double d1, d2, d3, d4;
437		double I3, J3, K3;
438		int i, j;
439	+
440	+	if (!ftp->valid) { /* preemptive test */
441	+	memset(hess, 0, sizeof(FVECT)*3);
442	+	return;
443	+	}
444		/* compute intermediate coefficients */
445		d1 = 1.0/DOT(ftp->r_i,ftp->r_i);
446		d2 = 1.0/DOT(ftp->r_i1,ftp->r_i1);
447		d3 = 1.0/DOT(ftp->e_i,ftp->e_i);
448		d4 = DOT(ftp->e_i, ftp->r_i);
449	<	I3 = 0.25ftp->nf( DOT(ftp->e_i, ftp->r_i1)d2d2 - d4d1d1 +
450	<	3.0ftp->I2d3 );
449	>	I3 = ( DOT(ftp->e_i, ftp->r_i1)d2d2 - d4d1d1 + 3.0/d3*ftp->I2 )
450	>	/ ( 4.0*DOT(ftp->rcp,ftp->rcp) );
451		J3 = 0.25d3(d1d1 - d2d2) - d4d3I3;
452		K3 = d3(ftp->I2 - I3/d1 - 2.0d4*J3);
453		/* intermediate matrices */
454	<	VCROSS(v1, nrm, ftp->e_i);
455	<	for (j = 3; j--; )
194	<	v2[i] = ftp->I2ftp->r_i[j] + ftp->J2ftp->e_i[j];
195	<	compose_matrix(m1, v1, v2);
454	>	VCROSS(ncp, nrm, ftp->e_i);
455	>	compose_matrix(m1, ncp, ftp->rI2_eJ2);
456		compose_matrix(m2, ftp->r_i, ftp->r_i);
457		compose_matrix(m3, ftp->e_i, ftp->e_i);
458		compose_matrix(m4, ftp->r_i, ftp->e_i);
459	<	VCROSS(v1, ftp->r_i, ftp->e_i);
200	<	d1 = DOT(nrm, v1);
459	>	d1 = DOT(nrm, ftp->rcp);
460		d2 = -d1*ftp->I2;
461		d1 *= 2.0;
462		for (i = 3; i--; ) /* final matrix sum */
#	Line 227 \| Line 486 \| rev_hessian(FVECT hess[3])
486		/* Add to radiometric Hessian from the given triangle */
487		static void
488		add2hessian(FVECT hess[3], FVECT ehess1[3],
489	<	FVECT ehess2[3], FVECT ehess3[3], COLORV v)
489	>	FVECT ehess2[3], FVECT ehess3[3], double v)
490		{
491		int i, j;
492
#	Line 241 \| Line 500 \| add2hessian(FVECT hess[3], FVECT ehess1[3],
500		static void
501		comp_gradient(FVECT grad, FFTRI *ftp, FVECT nrm)
502		{
503	<	FVECT vcp;
503	>	FVECT ncp;
504		double f1;
505		int i;
506
507	<	VCROSS(vcp, ftp->r_i, ftp->r_i1);
508	<	f1 = 2.0*DOT(nrm, vcp);
509	<	VCROSS(vcp, nrm, ftp->e_i);
507	>	if (!ftp->valid) { /* preemptive test */
508	>	memset(grad, 0, sizeof(FVECT));
509	>	return;
510	>	}
511	>	f1 = 2.0*DOT(nrm, ftp->rcp);
512	>	VCROSS(ncp, nrm, ftp->e_i);
513		for (i = 3; i--; )
514	<	grad[i] = (0.5/PI)( ftp->I1vcp[i] +
253	<	f1(ftp->I2ftp->r_i[i] + ftp->J2*ftp->e_i[i]) );
514	>	grad[i] = (0.5/PI)( ftp->I1ncp[i] + f1*ftp->rI2_eJ2[i] );
515		}
516
517
#	Line 266 \| Line 527 \| rev_gradient(FVECT grad)
527
528		/* Add to displacement gradient from the given triangle */
529		static void
530	<	add2gradient(FVECT grad, FVECT egrad1, FVECT egrad2, FVECT egrad3, COLORV v)
530	>	add2gradient(FVECT grad, FVECT egrad1, FVECT egrad2, FVECT egrad3, double v)
531		{
532		int i;
533
#	Line 275 \| Line 536 \| add2gradient(FVECT grad, FVECT egrad1, FVECT egrad2, F
536		}
537
538
278	–	/* Return brightness of furthest ambient sample */
279	–	static COLORV
280	–	back_ambval(struct s_ambsamp ap1, struct s_ambsamp ap2,
281	–	struct s_ambsamp *ap3, FVECT orig)
282	–	{
283	–	COLORV vback;
284	–	FVECT vec;
285	–	double d2, d2best;
286	–
287	–	VSUB(vec, ap1->p, orig);
288	–	d2best = DOT(vec,vec);
289	–	vback = ap1->v[CIEY];
290	–	VSUB(vec, ap2->p, orig);
291	–	d2 = DOT(vec,vec);
292	–	if (d2 > d2best) {
293	–	d2best = d2;
294	–	vback = ap2->v[CIEY];
295	–	}
296	–	VSUB(vec, ap3->p, orig);
297	–	d2 = DOT(vec,vec);
298	–	if (d2 > d2best)
299	–	return(ap3->v[CIEY]);
300	–	return(vback);
301	–	}
302	–
303	–
539		/* Compute anisotropic radii and eigenvector directions */
540		static int
541		eigenvectors(FVECT uv[2], float ra[2], FVECT hessian[3])
#	Line 318 \| Line 553 \| eigenvectors(FVECT uv[2], float ra[2], FVECT hessian[3
553		hess2[0][1] = DOT(uv[0], b);
554		hess2[1][0] = DOT(uv[1], a);
555		hess2[1][1] = DOT(uv[1], b);
556	<	/* compute eigenvalues */
557	<	if (quadratic(evalue, 1.0, -hess2[0][0]-hess2[1][1],
558	<	hess2[0][0]hess2[1][1]-hess2[0][1]hess2[1][0]) != 2 \|\|
559	<	(evalue[0] = fabs(evalue[0])) <= FTINYFTINYFTINY \|\|
560	<	(evalue[1] = fabs(evalue[1])) <= FTINYFTINYFTINY)
556	>	/* compute eigenvalue(s) */
557	>	i = quadratic(evalue, 1.0, -hess2[0][0]-hess2[1][1],
558	>	hess2[0][0]hess2[1][1]-hess2[0][1]hess2[1][0]);
559	>	if (i == 1) /* double-root (circle) */
560	>	evalue[1] = evalue[0];
561	>	if (!i \|\| ((evalue[0] = fabs(evalue[0])) <= FTINY*FTINY) \|
562	>	((evalue[1] = fabs(evalue[1])) <= FTINY*FTINY) )
563		error(INTERNAL, "bad eigenvalue calculation");
564
565		if (evalue[0] > evalue[1]) {
566	<	ra[0] = 1.0/sqrt(sqrt(evalue[0]));
567	<	ra[1] = 1.0/sqrt(sqrt(evalue[1]));
566	>	ra[0] = sqrt(sqrt(4.0/evalue[0]));
567	>	ra[1] = sqrt(sqrt(4.0/evalue[1]));
568		slope1 = evalue[1];
569		} else {
570	<	ra[0] = 1.0/sqrt(sqrt(evalue[1]));
571	<	ra[1] = 1.0/sqrt(sqrt(evalue[0]));
570	>	ra[0] = sqrt(sqrt(4.0/evalue[1]));
571	>	ra[1] = sqrt(sqrt(4.0/evalue[0]));
572		slope1 = evalue[0];
573		}
574		/* compute unit eigenvectors */
#	Line 352 \| Line 589 \| static void
589		ambHessian( /* anisotropic radii & pos. gradient */
590		AMBHEMI *hp,
591		FVECT uv[2], /* returned */
592	<	float ra[2], /* returned */
593	<	float pg[2] /* returned */
592	>	float ra[2], /* returned (optional) */
593	>	float pg[2] /* returned (optional) */
594		)
595		{
596		static char memerrmsg[] = "out of memory in ambHessian()";
597		FVECT (*hessrow)[3] = NULL;
598		FVECT *gradrow = NULL;
599	+	uby8 *vflags;
600		FVECT hessian[3];
601		FVECT gradient;
602		FFTRI fftr;
#	Line 368 \| Line 606 \| *ambHessian( / anisotropic radii & pos. gradient /*
606		VCOPY(uv[1], hp->uy);
607		/* clock-wise vertex traversal from sample POV */
608		if (ra != NULL) { /* initialize Hessian row buffer */
609	<	hessrow = (FVECT ()[3])malloc(sizeof(FVECT)3*hp->ns);
609	>	hessrow = (FVECT ()[3])malloc(sizeof(FVECT)3*(hp->ns-1));
610		if (hessrow == NULL)
611		error(SYSTEM, memerrmsg);
612		memset(hessian, 0, sizeof(hessian));
613		} else if (pg == NULL) /* bogus call? */
614		return;
615		if (pg != NULL) { /* initialize form factor row buffer */
616	<	gradrow = (FVECT )malloc(sizeof(FVECT)hp->ns);
616	>	gradrow = (FVECT )malloc(sizeof(FVECT)(hp->ns-1));
617		if (gradrow == NULL)
618		error(SYSTEM, memerrmsg);
619		memset(gradient, 0, sizeof(gradient));
620		}
621	+	/* get vertex position flags */
622	+	vflags = vertex_flags(hp);
623		/* compute first row of edges */
624		for (j = 0; j < hp->ns-1; j++) {
625	<	comp_fftri(&fftr, ambsamp(hp,0,j).p,
386	<	ambsamp(hp,0,j+1).p, hp->rp->rop);
625	>	comp_fftri(&fftr, hp, 0, j, VDB_X, vflags);
626		if (hessrow != NULL)
627		comp_hessian(hessrow[j], &fftr, hp->rp->ron);
628		if (gradrow != NULL)
#	Line 393 \| Line 632 \| *ambHessian( / anisotropic radii & pos. gradient /*
632		for (i = 0; i < hp->ns-1; i++) {
633		FVECT hesscol[3]; /* compute first vertical edge */
634		FVECT gradcol;
635	<	comp_fftri(&fftr, ambsamp(hp,i,0).p,
397	<	ambsamp(hp,i+1,0).p, hp->rp->rop);
635	>	comp_fftri(&fftr, hp, i, 0, VDB_Y, vflags);
636		if (hessrow != NULL)
637		comp_hessian(hesscol, &fftr, hp->rp->ron);
638		if (gradrow != NULL)
#	Line 402 \| Line 640 \| *ambHessian( / anisotropic radii & pos. gradient /*
640		for (j = 0; j < hp->ns-1; j++) {
641		FVECT hessdia[3]; /* compute triangle contributions */
642		FVECT graddia;
643	<	COLORV backg;
644	<	backg = back_ambval(&ambsamp(hp,i,j), &ambsamp(hp,i,j+1),
407	<	&ambsamp(hp,i+1,j), hp->rp->rop);
643	>	double backg;
644	>	backg = back_ambval(hp, i, j, VDB_X, VDB_Y, vflags);
645		/* diagonal (inner) edge */
646	<	comp_fftri(&fftr, ambsamp(hp,i,j+1).p,
410	<	ambsamp(hp,i+1,j).p, hp->rp->rop);
646	>	comp_fftri(&fftr, hp, i, j+1, VDB_xY, vflags);
647		if (hessrow != NULL) {
648		comp_hessian(hessdia, &fftr, hp->rp->ron);
649		rev_hessian(hesscol);
650		add2hessian(hessian, hessrow[j], hessdia, hesscol, backg);
651		}
652	<	if (gradient != NULL) {
652	>	if (gradrow != NULL) {
653		comp_gradient(graddia, &fftr, hp->rp->ron);
654		rev_gradient(gradcol);
655		add2gradient(gradient, gradrow[j], graddia, gradcol, backg);
656		}
657		/* initialize edge in next row */
658	<	comp_fftri(&fftr, ambsamp(hp,i+1,j+1).p,
423	<	ambsamp(hp,i+1,j).p, hp->rp->rop);
658	>	comp_fftri(&fftr, hp, i+1, j+1, VDB_x, vflags);
659		if (hessrow != NULL)
660		comp_hessian(hessrow[j], &fftr, hp->rp->ron);
661		if (gradrow != NULL)
662		comp_gradient(gradrow[j], &fftr, hp->rp->ron);
663		/* new column edge & paired triangle */
664	<	backg = back_ambval(&ambsamp(hp,i,j+1), &ambsamp(hp,i+1,j+1),
665	<	&ambsamp(hp,i+1,j), hp->rp->rop);
431	<	comp_fftri(&fftr, ambsamp(hp,i,j+1).p, ambsamp(hp,i+1,j+1).p,
432	<	hp->rp->rop);
664	>	backg = back_ambval(hp, i+1, j+1, VDB_x, VDB_y, vflags);
665	>	comp_fftri(&fftr, hp, i, j+1, VDB_Y, vflags);
666		if (hessrow != NULL) {
667		comp_hessian(hesscol, &fftr, hp->rp->ron);
668		rev_hessian(hessdia);
#	Line 449 \| Line 682 \| *ambHessian( / anisotropic radii & pos. gradient /*
682		/* release row buffers */
683		if (hessrow != NULL) free(hessrow);
684		if (gradrow != NULL) free(gradrow);
685	+	free(vflags);
686
687		if (ra != NULL) /* extract eigenvectors & radii */
688		eigenvectors(uv, ra, hessian);
689	<	if (pg != NULL) { /* project position gradient */
689	>	if (pg != NULL) { /* tangential position gradient */
690		pg[0] = DOT(gradient, uv[0]);
691		pg[1] = DOT(gradient, uv[1]);
692		}
#	Line 463 \| Line 697 \| *ambHessian( / anisotropic radii & pos. gradient /*
697		static void
698		ambdirgrad(AMBHEMI *hp, FVECT uv[2], float dg[2])
699		{
700	<	struct s_ambsamp *ap;
701	<	int n;
700	>	AMBSAMP *ap;
701	>	double dgsum[2];
702	>	int n;
703	>	FVECT vd;
704	>	double gfact;
705
706	<	dg[0] = dg[1] = 0;
706	>	dgsum[0] = dgsum[1] = 0.0; /* sum values times -tan(theta) */
707		for (ap = hp->sa, n = hp->ns*hp->ns; n--; ap++) {
471	–	FVECT vd;
472	–	double gfact;
708		/* use vector for azimuth + 90deg */
709		VSUB(vd, ap->p, hp->rp->rop);
710	<	/* brightness with tangent factor */
711	<	gfact = ap->v[CIEY] / DOT(hp->rp->ron, vd);
710	>	/* brightness over cosine factor */
711	>	gfact = colval(ap->v,CIEY) / DOT(hp->rp->ron, vd);
712		/* sine = proj_radius/vd_length */
713	<	dg[0] -= DOT(uv[1], vd) * gfact ;
714	<	dg[1] += DOT(uv[0], vd) * gfact;
713	>	dgsum[0] -= DOT(uv[1], vd) * gfact;
714	>	dgsum[1] += DOT(uv[0], vd) * gfact;
715		}
716	+	dg[0] = dgsum[0] / (hp->ns*hp->ns);
717	+	dg[1] = dgsum[1] / (hp->ns*hp->ns);
718		}
719
720
721	+	/* Compute potential light leak direction flags for cache value */
722	+	static uint32
723	+	ambcorral(AMBHEMI *hp, FVECT uv[2], const double r0, const double r1)
724	+	{
725	+	const double max_d = 1.0/(minarad*ambacc + 0.001);
726	+	const double ang_res = 0.5*PI/(hp->ns-1);
727	+	const double ang_step = ang_res/((int)(16/PI*ang_res) + (1+FTINY));
728	+	double avg_d = 0;
729	+	uint32 flgs = 0;
730	+	int i, j;
731	+	/* don't bother for a few samples */
732	+	if (hp->ns < 12)
733	+	return(0);
734	+	/* check distances overhead */
735	+	for (i = hp->ns*3/4; i-- > hp->ns>>2; )
736	+	for (j = hp->ns*3/4; j-- > hp->ns>>2; )
737	+	avg_d += ambsam(hp,i,j).d;
738	+	avg_d = 4.0/(hp->nshp->ns);
739	+	if (avg_dr0 >= 1.0) / ceiling too low for corral? */
740	+	return(0);
741	+	if (avg_d >= max_d) /* insurance */
742	+	return(0);
743	+	/* else circle around perimeter */
744	+	for (i = 0; i < hp->ns; i++)
745	+	for (j = 0; j < hp->ns; j += !i\|(i==hp->ns-1) ? 1 : hp->ns-1) {
746	+	AMBSAMP *ap = &ambsam(hp,i,j);
747	+	FVECT vec;
748	+	double u, v;
749	+	double ang, a1;
750	+	int abp;
751	+	if ((ap->d <= FTINY) \| (ap->d >= max_d))
752	+	continue; /* too far or too near */
753	+	VSUB(vec, ap->p, hp->rp->rop);
754	+	u = DOT(vec, uv[0]) * ap->d;
755	+	v = DOT(vec, uv[1]) * ap->d;
756	+	if ((r0r0uu + r1r1vv) * ap->d*ap->d <= 1.0)
757	+	continue; /* occluder outside ellipse */
758	+	ang = atan2a(v, u); /* else set direction flags */
759	+	for (a1 = ang-.5ang_res; a1 <= ang+.5ang_res; a1 += ang_step)
760	+	flgs \|= 1L<<(int)(16/PI(a1 + 2.PI*(a1 < 0)));
761	+	}
762	+	return(flgs);
763	+	}
764	+
765	+
766		int
767		doambient( /* compute ambient component */
768		COLOR rcol, /* input/output color */
#	Line 489 \| Line 771 \| *doambient( / compute ambient component /*
771		FVECT uv[2], /* returned (optional) */
772		float ra[2], /* returned (optional) */
773		float pg[2], /* returned (optional) */
774	<	float dg[2] /* returned (optional) */
774	>	float dg[2], /* returned (optional) */
775	>	uint32 crlp / returned (optional) */
776		)
777		{
778	<	int cnt = 0;
779	<	FVECT my_uv[2];
780	<	AMBHEMI *hp;
781	<	double d, acol[3];
782	<	struct s_ambsamp *ap;
783	<	int i, j;
784	<	/* initialize */
785	<	if ((hp = inithemi(rcol, r, wt)) == NULL)
778	>	AMBHEMI *hp = inithemi(rcol, r, wt);
779	>	int cnt;
780	>	FVECT my_uv[2];
781	>	double d, K, acol[3];
782	>	AMBSAMP *ap;
783	>	int i, j;
784	>	/* check/initialize */
785	>	if (hp == NULL)
786		return(0);
787		if (uv != NULL)
788		memset(uv, 0, sizeof(FVECT)*2);
#	Line 509 \| Line 792 \| *doambient( / compute ambient component /*
792		pg[0] = pg[1] = 0.0;
793		if (dg != NULL)
794		dg[0] = dg[1] = 0.0;
795	+	if (crlp != NULL)
796	+	*crlp = 0;
797		/* sample the hemisphere */
798		acol[0] = acol[1] = acol[2] = 0.0;
799	+	cnt = 0;
800		for (i = hp->ns; i--; )
801		for (j = hp->ns; j--; )
802	<	if (ambsample(hp, i, j)) {
517	<	ap = &ambsamp(hp,i,j);
802	>	if ((ap = ambsample(hp, i, j)) != NULL) {
803		addcolor(acol, ap->v);
804		++cnt;
805		}
#	Line 523 \| Line 808 \| *doambient( / compute ambient component /*
808		free(hp);
809		return(0); /* no valid samples */
810		}
811	<	d = 1.0 / cnt; /* final indirect irradiance/PI */
812	<	acol[0] = d; acol[1] = d; acol[2] *= d;
528	<	copycolor(rcol, acol);
529	<	if (cnt < hp->nshp->ns \|\| / incomplete sampling? */
530	<	(ra == NULL) & (pg == NULL) & (dg == NULL)) {
811	>	if (cnt < hp->nshp->ns) { / incomplete sampling? */
812	>	copycolor(rcol, acol);
813		free(hp);
814	+	return(-1); /* return value w/o Hessian */
815	+	}
816	+	cnt = ambssampwt + 0.5; / perform super-sampling? */
817	+	if (cnt > 8)
818	+	ambsupersamp(acol, hp, cnt);
819	+	copycolor(rcol, acol); /* final indirect irradiance/PI */
820	+	if ((ra == NULL) & (pg == NULL) & (dg == NULL)) {
821	+	free(hp);
822		return(-1); /* no radius or gradient calc. */
823		}
824	<	d = 0.01 * bright(rcol); /* add in 1% before Hessian comp. */
825	<	if (d < FTINY) d = FTINY;
826	<	ap = hp->sa; /* using Y channel from here on... */
824	>	if ((d = bright(acol)) > FTINY) { /* normalize Y values */
825	>	d = 0.99(hp->nshp->ns)/d;
826	>	K = 0.01;
827	>	} else { /* or fall back on geometric Hessian */
828	>	K = 1.0;
829	>	pg = NULL;
830	>	dg = NULL;
831	>	}
832	>	ap = hp->sa; /* relative Y channel from here on... */
833		for (i = hp->ns*hp->ns; i--; ap++)
834	<	colval(ap->v,CIEY) = bright(ap->v) + d;
834	>	colval(ap->v,CIEY) = bright(ap->v)*d + K;
835
836		if (uv == NULL) /* make sure we have axis pointers */
837		uv = my_uv;
838		/* compute radii & pos. gradient */
839		ambHessian(hp, uv, ra, pg);
840	+
841		if (dg != NULL) /* compute direction gradient */
842		ambdirgrad(hp, uv, dg);
843	<	if (ra != NULL) { /* adjust/clamp radii */
844	<	d = sqrt(sqrt((4.0/PI)*bright(rcol)/wt));
845	<	if ((ra[0] *= d) > maxarad)
846	<	ra[0] = maxarad;
843	>
844	>	if (ra != NULL) { /* scale/clamp radii */
845	>	if (pg != NULL) {
846	>	if (ra[0]*(d = fabs(pg[0])) > 1.0)
847	>	ra[0] = 1.0/d;
848	>	if (ra[1]*(d = fabs(pg[1])) > 1.0)
849	>	ra[1] = 1.0/d;
850	>	if (ra[0] > ra[1])
851	>	ra[0] = ra[1];
852	>	}
853	>	if (ra[0] < minarad) {
854	>	ra[0] = minarad;
855	>	if (ra[1] < minarad)
856	>	ra[1] = minarad;
857	>	}
858	>	ra[0] *= d = 1.0/sqrt(sqrt(wt));
859		if ((ra[1] = d) > 2.0ra[0])
860		ra[1] = 2.0*ra[0];
861	+	if (ra[1] > maxarad) {
862	+	ra[1] = maxarad;
863	+	if (ra[0] > maxarad)
864	+	ra[0] = maxarad;
865	+	}
866	+	if (crlp != NULL) /* flag encroached directions */
867	+	crlp = ambcorral(hp, uv, ra[0]ambacc, ra[1]*ambacc);
868	+	if (pg != NULL) { /* cap gradient if necessary */
869	+	d = pg[0]pg[0]ra[0]ra[0] + pg[1]pg[1]ra[1]ra[1];
870	+	if (d > 1.0) {
871	+	d = 1.0/sqrt(d);
872	+	pg[0] *= d;
873	+	pg[1] *= d;
874	+	}
875	+	}
876		}
877		free(hp); /* clean up and return */
878		return(1);

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Comparing ray/src/rt/ambcomp.c (file contents): Revision 2.27 by greg, Sat Apr 19 02:39:44 2014 UTC vs. Revision 2.52 by greg, Wed May 7 21:45:13 2014 UTC

Diff Legend

Comparing ray/src/rt/ambcomp.c (file contents):
Revision 2.27 by greg, Sat Apr 19 02:39:44 2014 UTC vs.
Revision 2.52 by greg, Wed May 7 21:45:13 2014 UTC