ViewVC Help

View File | Revision Log | Show Annotations | Download File | Root Listing

root/Development/ray/src/cv/bsdfrep.c

Comparing ray/src/cv/bsdfrep.c (file contents):
Revision 2.4 by greg, Tue Oct 23 05:10:42 2012 UTC vs.
Revision 2.12 by greg, Wed Mar 20 01:00:22 2013 UTC

#	Line 14 | Line 14 | static const char RCSid[] = "$Id$";
14		#include "rtio.h"
15		#include "resolu.h"
16		#include "bsdfrep.h"
17	+	/* active grid resolution */
18	+	int                     grid_res = GRIDRES;
19	+
20		/* coverage/symmetry using INP_QUAD? flags */
21		int                     inp_coverage = 0;
22		/* all incident angles in-plane so far? */
#	Line 23 | Line 26 | int                    single_plane_incident = -1;
26		int                     input_orient = 0;
27		int                     output_orient = 0;
28
29	+	/* BSDF histogram */
30	+	int                     bsdf_hist[HISTLEN];
31	+
32	+	/* BSDF value for boundary regions */
33	+	double                  bsdf_min = 0;
34	+
35		/* processed incident DSF measurements */
36		RBFNODE                 *dsf_list = NULL;
37
#	Line 53 | Line 62 | new_input_direction(double new_theta, double new_phi)
62		new_theta = -new_theta;
63		new_phi += 180.;
64		}
65	+	if ((theta_in_deg = new_theta) < 1.0)
66	+	return(1);              /* don't rely on phi near normal */
67		while (new_phi < 0)
68		new_phi += 360.;
69		while (new_phi >= 360.)
#	Line 61 | Line 72 | new_input_direction(double new_theta, double new_phi)
72		single_plane_incident = (round(new_phi) == round(phi_in_deg));
73		else if (single_plane_incident < 0)
74		single_plane_incident = 1;
64	–	theta_in_deg = new_theta;       /* assume it's OK */
75		phi_in_deg = new_phi;
76		if ((1. < new_phi) & (new_phi < 89.))
77		inp_coverage |= INP_QUAD1;
#	Line 78 | Line 88 | new_input_direction(double new_theta, double new_phi)
88		int
89		use_symmetry(FVECT vec)
90		{
91	<	double  phi = get_phi360(vec);
91	>	const double    phi = get_phi360(vec);
92
93		switch (inp_coverage) {
94		case INP_QUAD1|INP_QUAD2|INP_QUAD3|INP_QUAD4:
#	Line 168 | Line 178 | rev_rbf_symmetry(RBFNODE *rbf, int sym)
178		rev_symmetry(rbf->invec, sym);
179		if (sym & MIRROR_X)
180		for (n = rbf->nrbf; n-- > 0; )
181	<	rbf->rbfa[n].gx = GRIDRES-1 - rbf->rbfa[n].gx;
181	>	rbf->rbfa[n].gx = grid_res-1 - rbf->rbfa[n].gx;
182		if (sym & MIRROR_Y)
183		for (n = rbf->nrbf; n-- > 0; )
184	<	rbf->rbfa[n].gy = GRIDRES-1 - rbf->rbfa[n].gy;
184	>	rbf->rbfa[n].gy = grid_res-1 - rbf->rbfa[n].gy;
185		}
186
187	+	/* Rotate RBF to correspond to given incident vector */
188	+	void
189	+	rotate_rbf(RBFNODE *rbf, const FVECT invec)
190	+	{
191	+	static const FVECT      vnorm = {.0, .0, 1.};
192	+	const double            phi = atan2(invec[1],invec[0]) -
193	+	atan2(rbf->invec[1],rbf->invec[0]);
194	+	FVECT                   outvec;
195	+	int                     pos[2];
196	+	int                     n;
197	+
198	+	for (n = ((-.01 > phi) | (phi > .01))*rbf->nrbf; n-- > 0; ) {
199	+	ovec_from_pos(outvec, rbf->rbfa[n].gx, rbf->rbfa[n].gy);
200	+	spinvector(outvec, outvec, vnorm, phi);
201	+	pos_from_vec(pos, outvec);
202	+	rbf->rbfa[n].gx = pos[0];
203	+	rbf->rbfa[n].gy = pos[1];
204	+	}
205	+	VCOPY(rbf->invec, invec);
206	+	}
207	+
208		/* Compute volume associated with Gaussian lobe */
209		double
210		rbf_volume(const RBFVAL *rbfp)
#	Line 190 | Line 221 | ovec_from_pos(FVECT vec, int xpos, int ypos)
221		double  uv[2];
222		double  r2;
223
224	<	SDsquare2disk(uv, (1./GRIDRES)*(xpos+.5), (1./GRIDRES)*(ypos+.5));
224	>	SDsquare2disk(uv, (xpos+.5)/grid_res, (ypos+.5)/grid_res);
225		/* uniform hemispherical projection */
226		r2 = uv[0]*uv[0] + uv[1]*uv[1];
227		vec[0] = vec[1] = sqrt(2. - r2);
#	Line 208 | Line 239 | pos_from_vec(int pos[2], const FVECT vec)
239
240		SDdisk2square(sq, vec[0]*norm, vec[1]*norm);
241
242	<	pos[0] = (int)(sq[0]*GRIDRES);
243	<	pos[1] = (int)(sq[1]*GRIDRES);
242	>	pos[0] = (int)(sq[0]*grid_res);
243	>	pos[1] = (int)(sq[1]*grid_res);
244		}
245
246		/* Evaluate RBF for DSF at the given normalized outgoing direction */
247		double
248		eval_rbfrep(const RBFNODE *rp, const FVECT outvec)
249		{
250	<	double          res = .0;
250	>	double          res = 0;
251		const RBFVAL    *rbfp;
252		FVECT           odir;
253		double          sig2;
254		int             n;
255	<
256	<	if (rp == NULL)
257	<	return(.0);
255	>	/* use minimum if no information avail. */
256	>	if (rp == NULL) {
257	>	if (outvec[2] > 0 ^ output_orient > 0)
258	>	return(.0);
259	>	return(bsdf_min*output_orient*outvec[2]);
260	>	}
261		rbfp = rp->rbfa;
262		for (n = rp->nrbf; n--; rbfp++) {
263		ovec_from_pos(odir, rbfp->gx, rbfp->gy);
#	Line 351 | Line 385 | clear_bsdf_rep(void)
385		inp_coverage = 0;
386		single_plane_incident = -1;
387		input_orient = output_orient = 0;
388	+	grid_res = GRIDRES;
389		}
390
391		/* Write our BSDF mesh interpolant out to the given binary stream */
#	Line 363 | Line 398 | save_bsdf_rep(FILE *ofp)
398		/* finish header */
399		fprintf(ofp, "SYMMETRY=%d\n", !single_plane_incident * inp_coverage);
400		fprintf(ofp, "IO_SIDES= %d %d\n", input_orient, output_orient);
401	+	fprintf(ofp, "GRIDRES=%d\n", grid_res);
402	+	fprintf(ofp, "BSDFMIN=%g\n", bsdf_min);
403		fputformat(BSDFREP_FMT, ofp);
404		fputc('\n', ofp);
405		/* write each DSF */
#	Line 424 | Line 461 | headline(char *s, void *p)
461		sscanf(s+9, "%d %d", &input_orient, &output_orient);
462		return(0);
463		}
464	+	if (!strncmp(s, "GRIDRES=", 8)) {
465	+	sscanf(s+8, "%d", &grid_res);
466	+	return(0);
467	+	}
468	+	if (!strncmp(s, "BSDFMIN=", 8)) {
469	+	sscanf(s+8, "%lf", &bsdf_min);
470	+	return(0);
471	+	}
472		if (formatval(fmt, s) && strcmp(fmt, BSDFREP_FMT))
473		return(-1);
474		return(0);
#	Line 438 | Line 483 | load_bsdf_rep(FILE *ifp)
483		int             i;
484
485		clear_bsdf_rep();
486	+	if (ifp == NULL)
487	+	return(0);
488		if (getheader(ifp, headline, NULL) < 0 || single_plane_incident < 0 |
489		!input_orient | !output_orient) {
490		fprintf(stderr, "%s: missing/bad format for BSDF interpolant\n",
#	Line 452 | Line 499 | load_bsdf_rep(FILE *ifp)
499		rbfh.invec[0] = getflt(ifp);
500		rbfh.invec[1] = getflt(ifp);
501		rbfh.invec[2] = getflt(ifp);
502	+	if (normalize(rbfh.invec) == 0) {
503	+	fprintf(stderr, "%s: zero incident vector\n", progname);
504	+	return(0);
505	+	}
506		rbfh.vtotal = getflt(ifp);
507		rbfh.nrbf = getint(4, ifp);
508		newrbf = (RBFNODE *)malloc(sizeof(RBFNODE) +
509		sizeof(RBFVAL)*(rbfh.nrbf-1));
510		if (newrbf == NULL)
511		goto memerr;
512	<	memcpy(newrbf, &rbfh, sizeof(RBFNODE));
512	>	memcpy(newrbf, &rbfh, sizeof(RBFNODE)-sizeof(RBFVAL));
513		for (i = 0; i < rbfh.nrbf; i++) {
514		newrbf->rbfa[i].peak = getflt(ifp);
515		newrbf->rbfa[i].crad = getint(2, ifp) & 0xffff;

Diff Legend

–	Removed lines
+	Added lines
<	Changed lines (old)
>	Changed lines (new)