[ViewVC] Diff of: radiance/ray/src/common/interp2d.c

Comparing ray/src/common/interp2d.c (file contents):
Revision 2.7 by greg, Tue Feb 12 17:47:58 2013 UTC vs.
Revision 2.15 by greg, Sat Feb 13 16:49:18 2021 UTC

#	Line 23 \| Line 23 \| static const char RCSid[] = "$Id$";
23		* to reduce the influence of distant neighbors. This yields a
24		* smooth interpolation regardless of how the sample points are
25		* initially distributed. Evaluation is accelerated by use of
26	<	* a fast approximation to the atan2(y,x) function.
26	>	* a fast approximation to the atan2(y,x) function and a low-res
27	>	* map indicating where sample weights are significant.
28		****************************************************************/
29
30		#include <stdio.h>
#	Line 40 \| Line 41 \| typedef struct {
41		float dm; /* distance measure in this direction */
42		} SAMPORD;
43
44	+	/* private routine to encode sample diameter with range checks */
45	+	static int
46	+	encode_diameter(const INTERP2 *ip, double d)
47	+	{
48	+	const int ed = ENCODE_DIA(ip, d);
49	+
50	+	if (ed <= 0)
51	+	return(0);
52	+	if (ed >= 0xffff)
53	+	return(0xffff);
54	+	return(ed);
55	+	}
56	+
57		/* Allocate a new set of interpolation samples (caller assigns spt[] array) */
58		INTERP2 *
59		interp2_alloc(int nsamps)
#	Line 56 \| Line 70 \| interp2_alloc(int nsamps)
70		nip->ns = nsamps;
71		nip->dmin = 1; /* default minimum diameter */
72		nip->smf = NI2DSMF; /* default smoothing factor */
73	+	nip->c_data = NULL;
74		nip->da = NULL;
75		/* caller must assign spt[] array */
76		return(nip);
#	Line 71 \| Line 86 \| *interp2_realloc(INTERP2 ip, int nsamps)**
86		interp2_free(ip);
87		return(NULL);
88		}
89	<	if (nsamps == ip->ns);
89	>	if (nsamps == ip->ns)
90		return(ip);
91		if (ip->da != NULL) { /* will need to recompute distribution */
92		free(ip->da);
#	Line 99 \| Line 114 \| *interp2_spacing(INTERP2 ip, double mind)**
114		ip->dmin = mind;
115		}
116
117	+	/* Compute unnormalized weight for a position relative to a sample */
118	+	double
119	+	interp2_wti(INTERP2 *ip, const int i, double x, double y)
120	+	{
121	+	double dir, rd, r2, d2;
122	+	int ri;
123	+	/* get relative direction */
124	+	x -= ip->spt[i][0];
125	+	y -= ip->spt[i][1];
126	+	dir = atan2a(y, x);
127	+	dir += 2.PI(dir < 0);
128	+	/* linear radius interpolation */
129	+	rd = dir * (NI2DIR/2./PI);
130	+	ri = (int)rd;
131	+	rd -= (double)ri;
132	+	rd = (1.-rd)ip->da[i].dia[ri] + rdip->da[i].dia[(ri+1)%NI2DIR];
133	+	rd = ip->smf * DECODE_DIA(ip, rd);
134	+	r2 = 2.rdrd;
135	+	d2 = xx + yy;
136	+	if (d2 > 21.r2) / result would be < 1e-9 */
137	+	return(.0);
138	+	/* Gaussian times harmonic weighting */
139	+	return( exp(-d2/r2) * ip->dmin/(ip->dmin + sqrt(d2)) );
140	+	}
141	+
142	+	/* private call to get grid flag index */
143	+	static int
144	+	interp2_flagpos(int fgi[2], INTERP2 *ip, double x, double y)
145	+	{
146	+	int inbounds = 0;
147	+
148	+	if (ip == NULL) /* paranoia */
149	+	return(-1);
150	+	/* need to compute interpolant? */
151	+	if (ip->da == NULL && !interp2_analyze(ip))
152	+	return(-1);
153	+	/* get x & y grid positions */
154	+	fgi[0] = (x - ip->smin[0]) * NI2DIM / (ip->smax[0] - ip->smin[0]);
155	+
156	+	if (fgi[0] >= NI2DIM)
157	+	fgi[0] = NI2DIM-1;
158	+	else if (fgi[0] < 0)
159	+	fgi[0] = 0;
160	+	else
161	+	++inbounds;
162	+
163	+	fgi[1] = (y - ip->smin[1]) * NI2DIM / (ip->smax[1] - ip->smin[1]);
164	+
165	+	if (fgi[1] >= NI2DIM)
166	+	fgi[1] = NI2DIM-1;
167	+	else if (fgi[1] < 0)
168	+	fgi[1] = 0;
169	+	else
170	+	++inbounds;
171	+
172	+	return(inbounds == 2);
173	+	}
174	+
175	+	#define setflg(fl,xi,yi) ((fl)[yi] \|= 1<<(xi))
176	+
177	+	#define chkflg(fl,xi,yi) ((fl)[yi]>>(xi) & 1)
178	+
179	+	/* private flood function to determine sample influence */
180	+	static void
181	+	influence_flood(INTERP2 *ip, const int i, unsigned short visited[NI2DIM],
182	+	int xfi, int yfi)
183	+	{
184	+	double gx = (xfi+.5)(1./NI2DIM)(ip->smax[0] - ip->smin[0]) +
185	+	ip->smin[0];
186	+	double gy = (yfi+.5)(1./NI2DIM)(ip->smax[1] - ip->smin[1]) +
187	+	ip->smin[1];
188	+	double dx = gx - ip->spt[i][0];
189	+	double dy = gy - ip->spt[i][1];
190	+
191	+	setflg(visited, xfi, yfi);
192	+
193	+	if (dxdx + dydy > 2.*ip->grid2 && interp2_wti(ip, i, gx, gy) <= 1e-7)
194	+	return;
195	+
196	+	setflg(ip->da[i].infl, xfi, yfi);
197	+
198	+	if (xfi > 0 && !chkflg(visited, xfi-1, yfi))
199	+	influence_flood(ip, i, visited, xfi-1, yfi);
200	+
201	+	if (yfi > 0 && !chkflg(visited, xfi, yfi-1))
202	+	influence_flood(ip, i, visited, xfi, yfi-1);
203	+
204	+	if (xfi < NI2DIM-1 && !chkflg(visited, xfi+1, yfi))
205	+	influence_flood(ip, i, visited, xfi+1, yfi);
206	+
207	+	if (yfi < NI2DIM-1 && !chkflg(visited, xfi, yfi+1))
208	+	influence_flood(ip, i, visited, xfi, yfi+1);
209	+	}
210	+
211	+	/* private call to compute sample influence maps */
212	+	static void
213	+	map_influence(INTERP2 *ip)
214	+	{
215	+	unsigned short visited[NI2DIM];
216	+	int fgi[2];
217	+	int i, j;
218	+
219	+	for (i = ip->ns; i--; ) {
220	+	for (j = NI2DIM; j--; ) {
221	+	ip->da[i].infl[j] = 0;
222	+	visited[j] = 0;
223	+	}
224	+	interp2_flagpos(fgi, ip, ip->spt[i][0], ip->spt[i][1]);
225	+
226	+	influence_flood(ip, i, visited, fgi[0], fgi[1]);
227	+	}
228	+	}
229	+
230		/* Modify smoothing parameter by the given factor */
231		void
232		interp2_smooth(INTERP2 *ip, double sf)
233		{
234	+	float old_smf = ip->smf;
235	+
236		if ((ip->smf *= sf) < NI2DSMF)
237		ip->smf = NI2DSMF;
238	+	/* need to recompute influence maps? */
239	+	if (ip->da != NULL && (old_smf*.85 > ip->smf) \|
240	+	(ip->smf > old_smf*1.15))
241	+	map_influence(ip);
242		}
243
244		/* private call-back to sort position index */
#	Line 133 \| Line 267 \| *sort_samples(SAMPORD sord, const INTERP2 ip, double*
267		sord[i].si = i;
268		sord[i].dm = cosdip->spt[i][0] + sindip->spt[i][1];
269		}
270	<	qsort(sord, ip->ns, sizeof(SAMPORD), &cmp_spos);
270	>	qsort(sord, ip->ns, sizeof(SAMPORD), cmp_spos);
271		}
272
139	–	/* private routine to encode sample diameter with range checks */
140	–	static int
141	–	encode_diameter(const INTERP2 *ip, double d)
142	–	{
143	–	const int ed = ENCODE_DIA(ip, d);
144	–
145	–	if (ed <= 0)
146	–	return(0);
147	–	if (ed >= 0xffff)
148	–	return(0xffff);
149	–	return(ed);
150	–	}
151	–
273		/* (Re)compute anisotropic basis function interpolant (normally automatic) */
274		int
275		interp2_analyze(INTERP2 *ip)
276		{
277		SAMPORD *sortord;
278		int rightrndx, leftrndx, *endrndx;
279	<	int bd;
279	>	int i, bd;
280		/* sanity checks */
281	<	if (ip == NULL \|\| (ip->ns <= 1) \| (ip->dmin <= 0))
281	>	if (ip == NULL)
282		return(0);
283	<	/* need to allocate? */
284	<	if (ip->da == NULL) {
285	<	ip->da = (unsigned short (*)[NI2DIR])malloc(
165	<	sizeof(unsigned short)NI2DIRip->ns);
166	<	if (ip->da == NULL)
167	<	return(0);
283	>	if (ip->da != NULL) { /* free previous data if any */
284	>	free(ip->da);
285	>	ip->da = NULL;
286		}
287	<	/* get temporary arrays */
287	>	if ((ip->ns <= 1) \| (ip->dmin <= 0))
288	>	return(0);
289	>	/* compute sample domain */
290	>	ip->smin[0] = ip->smin[1] = FHUGE;
291	>	ip->smax[0] = ip->smax[1] = -FHUGE;
292	>	for (i = ip->ns; i--; ) {
293	>	if (ip->spt[i][0] < ip->smin[0]) ip->smin[0] = ip->spt[i][0];
294	>	if (ip->spt[i][0] > ip->smax[0]) ip->smax[0] = ip->spt[i][0];
295	>	if (ip->spt[i][1] < ip->smin[1]) ip->smin[1] = ip->spt[i][1];
296	>	if (ip->spt[i][1] > ip->smax[1]) ip->smax[1] = ip->spt[i][1];
297	>	}
298	>	ip->grid2 = ((ip->smax[0]-ip->smin[0])*(ip->smax[0]-ip->smin[0]) +
299	>	(ip->smax[1]-ip->smin[1])(ip->smax[1]-ip->smin[1]))
300	>	(1./NI2DIM/NI2DIM);
301	>	if (ip->grid2 <= FTINYip->dminip->dmin)
302	>	return(0);
303	>	/* allocate analysis data */
304	>	ip->da = (struct interp2_samp *)malloc(
305	>	sizeof(struct interp2_samp)*ip->ns );
306	>	if (ip->da == NULL)
307	>	return(0);
308	>	/* allocate temporary arrays */
309		sortord = (SAMPORD )malloc(sizeof(SAMPORD)ip->ns);
310		rightrndx = (int )malloc(sizeof(int)ip->ns);
311		leftrndx = (int )malloc(sizeof(int)ip->ns);
#	Line 178 \| Line 317 \| *interp2_analyze(INTERP2 ip)**
317		for (bd = 0; bd < NI2DIR/2; bd++) {
318		const double ang = 2.PI/NI2DIRbd;
319		int *sptr;
181	–	int i;
320		/* create right reverse index */
321		if (bd) { /* re-use from previous iteration? */
322		sptr = rightrndx;
#	Line 209 \| Line 347 \| *interp2_analyze(INTERP2 ip)**
347		const int ii = sortord[i].si;
348		int j;
349		/* preload with large radii */
350	<	ip->da[ii][bd] = ip->da[ii][bd+NI2DIR/2] = encode_diameter(ip,
351	<	.5*(sortord[ip->ns-1].dm - sortord[0].dm));
350	>	ip->da[ii].dia[bd] =
351	>	ip->da[ii].dia[bd+NI2DIR/2] = encode_diameter(ip,
352	>	.5*(sortord[ip->ns-1].dm - sortord[0].dm));
353		for (j = i; ++j < ip->ns; ) /* nearest above */
354		if (rightrndx[sortord[j].si] > rightrndx[ii] &&
355		leftrndx[sortord[j].si] < leftrndx[ii]) {
356	<	ip->da[ii][bd] = encode_diameter(ip,
356	>	ip->da[ii].dia[bd] = encode_diameter(ip,
357		sortord[j].dm - sortord[i].dm);
358		break;
359		}
360		for (j = i; j-- > 0; ) /* nearest below */
361		if (rightrndx[sortord[j].si] < rightrndx[ii] &&
362		leftrndx[sortord[j].si] > leftrndx[ii]) {
363	<	ip->da[ii][bd+NI2DIR/2] = encode_diameter(ip,
363	>	ip->da[ii].dia[bd+NI2DIR/2] = encode_diameter(ip,
364		sortord[i].dm - sortord[j].dm);
365		break;
366		}
367		}
368		}
369	<	free(sortord); /* clean up */
369	>	free(sortord); /* release temp arrays */
370		free(rightrndx);
371		free(leftrndx);
372		free(endrndx);
373	<	return(1);
373	>	/* map sample influence areas */
374	>	map_influence(ip);
375	>	return(1); /* all done */
376		}
377
237	–	/* private call returns raw weight for a particular sample */
238	–	static double
239	–	get_wt(const INTERP2 *ip, const int i, double x, double y)
240	–	{
241	–	double dir, rd, r2, d2;
242	–	int ri;
243	–	/* get relative direction */
244	–	x -= ip->spt[i][0];
245	–	y -= ip->spt[i][1];
246	–	dir = atan2a(y, x);
247	–	dir += 2.PI(dir < 0);
248	–	/* linear radius interpolation */
249	–	rd = dir * (NI2DIR/2./PI);
250	–	ri = (int)rd;
251	–	rd -= (double)ri;
252	–	rd = (1.-rd)ip->da[i][ri] + rdip->da[i][(ri+1)%NI2DIR];
253	–	rd = ip->smf * DECODE_DIA(ip, rd);
254	–	r2 = 2.rdrd;
255	–	d2 = xx + yy;
256	–	if (d2 > 21.r2) / result would be < 1e-9 */
257	–	return(.0);
258	–	/* Gaussian times harmonic weighting */
259	–	return( exp(-d2/r2) * ip->dmin/(ip->dmin + sqrt(d2)) );
260	–	}
261	–
378		/* Assign full set of normalized weights to interpolate the given position */
379		int
380		interp2_weights(float wtv[], INTERP2 *ip, double x, double y)
381		{
382		double wnorm;
383	+	int fgi[2];
384		int i;
385
386	<	if ((wtv == NULL) \| (ip == NULL))
386	>	if (wtv == NULL)
387		return(0);
388	<	/* need to compute interpolant? */
389	<	if (ip->da == NULL && !interp2_analyze(ip))
388	>	/* get flag position */
389	>	if (interp2_flagpos(fgi, ip, x, y) < 0)
390		return(0);
391
392		wnorm = 0; /* compute raw weights */
393	<	for (i = ip->ns; i--; ) {
394	<	double wt = get_wt(ip, i, x, y);
393	>	for (i = ip->ns; i--; )
394	>	if (chkflg(ip->da[i].infl, fgi[0], fgi[1])) {
395	>	double wt = interp2_wti(ip, i, x, y);
396		wtv[i] = wt;
397		wnorm += wt;
398	<	}
398	>	} else
399	>	wtv[i] = 0;
400		if (wnorm <= 0) /* too far from all our samples! */
401		return(0);
402		wnorm = 1./wnorm; /* normalize weights */
#	Line 292 \| Line 411 \| int
411		interp2_topsamp(float wt[], int si[], const int n, INTERP2 *ip, double x, double y)
412		{
413		int nn = 0;
414	+	int fgi[2];
415		double wnorm;
416		int i, j;
417
418	<	if ((n <= 0) \| (wt == NULL) \| (si == NULL) \| (ip == NULL))
418	>	if ((n <= 0) \| (wt == NULL) \| (si == NULL))
419		return(0);
420	<	/* need to compute interpolant? */
421	<	if (ip->da == NULL && !interp2_analyze(ip))
420	>	/* get flag position */
421	>	if (interp2_flagpos(fgi, ip, x, y) < 0)
422		return(0);
423		/* identify top n weights */
424	<	for (i = ip->ns; i--; ) {
425	<	const double wti = get_wt(ip, i, x, y);
424	>	for (i = ip->ns; i--; )
425	>	if (chkflg(ip->da[i].infl, fgi[0], fgi[1])) {
426	>	const double wti = interp2_wti(ip, i, x, y);
427		for (j = nn; j > 0; j--) {
428		if (wt[j-1] >= wti)
429		break;
#	Line 316 \| Line 437 \| interp2_topsamp(float wt[], int si[], const int n, INT
437		si[j] = i;
438		nn += (nn < n);
439		}
440	<	}
440	>	}
441		wnorm = 0; /* normalize sample weights */
442		for (j = nn; j--; )
443		wnorm += wt[j];

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Comparing ray/src/common/interp2d.c (file contents): Revision 2.7 by greg, Tue Feb 12 17:47:58 2013 UTC vs. Revision 2.15 by greg, Sat Feb 13 16:49:18 2021 UTC

Diff Legend

Comparing ray/src/common/interp2d.c (file contents):
Revision 2.7 by greg, Tue Feb 12 17:47:58 2013 UTC vs.
Revision 2.15 by greg, Sat Feb 13 16:49:18 2021 UTC