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

Comparing ray/src/common/interp2d.c (file contents):
Revision 2.2 by greg, Sat Feb 9 17:39:21 2013 UTC vs.
Revision 2.11 by greg, Fri Feb 15 01:26:47 2013 UTC

#	Line 9 \| Line 9 \| static const char RCSid[] = "$Id$";
9
10		#include "copyright.h"
11
12	<	/*************************************************************
12	>	/***************************************************************
13		* This is a general method for 2-D interpolation similar to
14		* radial basis functions but allowing for a good deal of local
15		* anisotropy in the point distribution. Each sample point
16		* is examined to determine the closest neighboring samples in
17		* each of NI2DIR surrounding directions. To speed this
18	<	* calculation, we sort the data into 3 half-planes and
19	<	* perform simple tests to see which neighbor is closest in
20	<	* a each direction. Once we have our approximate neighborhood
21	<	* for a sample, we can use it in a Gaussian weighting scheme
22	<	* with anisotropic surround. This gives us a fairly smooth
23	<	* interpolation however the sample points may be initially
24	<	* distributed. Evaluation is accelerated by use of a fast
25	<	* approximation to the atan2(y,x) function.
26	<	**************************************************************/
18	>	* calculation, we sort the data into half-planes and apply
19	>	* simple tests to see which neighbor is closest in each
20	>	* angular slice. Once we have our approximate neighborhood
21	>	* for a sample, we can use it in a modified Gaussian weighting
22	>	* with allowing local anisotropy. Harmonic weighting is added
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 and an array
27	>	* of flags indicating where weights are (nearly) zero.
28	>	****************************************************************/
29
30		#include <stdio.h>
31		#include <stdlib.h>
32		#include "rtmath.h"
33		#include "interp2d.h"
34
35	<	#define DECODE_RAD(ip,er) ((ip)->rmin(1. + .5(er)))
36	<	#define ENCODE_RAD(ip,r) ((int)(2.*(r)/(ip)->rmin) - 2)
35	>	#define DECODE_DIA(ip,ed) ((ip)->dmin(1. + .5(ed)))
36	>	#define ENCODE_DIA(ip,d) ((int)(2.*(d)/(ip)->dmin) - 2)
37
38		/* Sample order (private) */
39		typedef struct {
#	Line 53 \| Line 55 \| interp2_alloc(int nsamps)
55		return(NULL);
56
57		nip->ns = nsamps;
58	<	nip->rmin = .5; /* default radius minimum */
58	>	nip->dmin = 1; /* default minimum diameter */
59		nip->smf = NI2DSMF; /* default smoothing factor */
60	<	nip->ra = NULL;
60	>	nip->da = NULL;
61		/* caller must assign spt[] array */
62		return(nip);
63		}
#	Line 70 \| Line 72 \| *interp2_realloc(INTERP2 ip, int nsamps)**
72		interp2_free(ip);
73		return(NULL);
74		}
75	<	if (nsamps == ip->ns);
75	>	if (nsamps == ip->ns)
76		return(ip);
77	<	if (ip->ra != NULL) { /* will need to recompute distribution */
78	<	free(ip->ra);
79	<	ip->ra = NULL;
77	>	if (ip->da != NULL) { /* will need to recompute distribution */
78	>	free(ip->da);
79	>	ip->da = NULL;
80		}
81		ip = (INTERP2 )realloc(ip, sizeof(INTERP2)+sizeof(float)2*(nsamps-1));
82		if (ip == NULL)
#	Line 83 \| Line 85 \| *interp2_realloc(INTERP2 ip, int nsamps)**
85		return(ip);
86		}
87
88	+	/* Set minimum distance under which samples will start to merge */
89	+	void
90	+	interp2_spacing(INTERP2 *ip, double mind)
91	+	{
92	+	if (mind <= 0)
93	+	return;
94	+	if ((.998ip->dmin <= mind) & (mind <= 1.002ip->dmin))
95	+	return;
96	+	if (ip->da != NULL) { /* will need to recompute distribution */
97	+	free(ip->da);
98	+	ip->da = NULL;
99	+	}
100	+	ip->dmin = mind;
101	+	}
102	+
103	+	/* Modify smoothing parameter by the given factor */
104	+	void
105	+	interp2_smooth(INTERP2 *ip, double sf)
106	+	{
107	+	if ((ip->smf *= sf) < NI2DSMF)
108	+	ip->smf = NI2DSMF;
109	+	}
110	+
111		/* private call-back to sort position index */
112		static int
113		cmp_spos(const void p1, const void p2)
#	Line 112 \| Line 137 \| *sort_samples(SAMPORD sord, const INTERP2 ip, double*
137		qsort(sord, ip->ns, sizeof(SAMPORD), &cmp_spos);
138		}
139
140	<	/* private routine to encode radius with range checks */
140	>	/* private routine to encode sample diameter with range checks */
141		static int
142	<	encode_radius(const INTERP2 *ip, double r)
142	>	encode_diameter(const INTERP2 *ip, double d)
143		{
144	<	const int er = ENCODE_RAD(ip, r);
144	>	const int ed = ENCODE_DIA(ip, d);
145
146	<	if (er <= 0)
146	>	if (ed <= 0)
147		return(0);
148	<	if (er >= 0xffff)
148	>	if (ed >= 0xffff)
149		return(0xffff);
150	<	return(er);
150	>	return(ed);
151		}
152
153		/* (Re)compute anisotropic basis function interpolant (normally automatic) */
#	Line 131 \| Line 156 \| *interp2_analyze(INTERP2 ip)**
156		{
157		SAMPORD *sortord;
158		int rightrndx, leftrndx, *endrndx;
159	<	int bd;
159	>	int i, bd;
160		/* sanity checks */
161	<	if (ip == NULL \|\| (ip->ns <= 1) \| (ip->rmin <= 0))
161	>	if (ip == NULL)
162		return(0);
163	<	/* need to allocate? */
164	<	if (ip->ra == NULL) {
165	<	ip->ra = (unsigned short (*)[NI2DIR])malloc(
141	<	sizeof(unsigned short)NI2DIRip->ns);
142	<	if (ip->ra == NULL)
143	<	return(0);
163	>	if (ip->da != NULL) { /* free previous data if any */
164	>	free(ip->da);
165	>	ip->da = NULL;
166		}
167	+	if ((ip->ns <= 1) \| (ip->dmin <= 0))
168	+	return(0);
169	+	/* compute sample domain */
170	+	ip->smin[0] = ip->smin[1] = FHUGE;
171	+	ip->smax[0] = ip->smax[1] = -FHUGE;
172	+	for (i = ip->ns; i--; ) {
173	+	if (ip->spt[i][0] < ip->smin[0])
174	+	ip->smin[0] = ip->spt[i][0];
175	+	if (ip->spt[i][0] > ip->smax[0])
176	+	ip->smax[0] = ip->spt[i][0];
177	+	if (ip->spt[i][1] < ip->smin[1])
178	+	ip->smin[1] = ip->spt[i][1];
179	+	if (ip->spt[i][1] > ip->smax[1])
180	+	ip->smax[1] = ip->spt[i][1];
181	+	}
182	+	ip->grid2 = ((ip->smax[0]-ip->smin[0])*(ip->smax[0]-ip->smin[0]) +
183	+	(ip->smax[1]-ip->smin[1])(ip->smax[1]-ip->smin[1]))
184	+	(1./NI2DIM/NI2DIM);
185	+	if (ip->grid2 <= FTINYip->dminip->dmin)
186	+	return(0);
187	+	/* allocate analysis data */
188	+	ip->da = (struct interp2_samp *)calloc( ip->ns,
189	+	sizeof(struct interp2_samp) );
190	+	if (ip->da == NULL)
191	+	return(0);
192		/* get temporary arrays */
193		sortord = (SAMPORD )malloc(sizeof(SAMPORD)ip->ns);
194		rightrndx = (int )malloc(sizeof(int)ip->ns);
#	Line 154 \| Line 201 \| *interp2_analyze(INTERP2 ip)**
201		for (bd = 0; bd < NI2DIR/2; bd++) {
202		const double ang = 2.PI/NI2DIRbd;
203		int *sptr;
157	–	int i;
204		/* create right reverse index */
205		if (bd) { /* re-use from previous iteration? */
206		sptr = rightrndx;
#	Line 182 \| Line 228 \| *interp2_analyze(INTERP2 ip)**
228		sort_samples(sortord, ip, ang);
229		/* find nearest neighbors each side */
230		for (i = ip->ns; i--; ) {
231	<	const int rpos = rightrndx[sortord[i].si];
186	<	const int lpos = leftrndx[sortord[i].si];
231	>	const int ii = sortord[i].si;
232		int j;
233	<	/* preload with large radius */
234	<	ip->ra[i][bd] = ip->ra[i][bd+NI2DIR/2] = encode_radius(ip,
235	<	.25*(sortord[ip->ns-1].dm - sortord[0].dm));
233	>	/* preload with large radii */
234	>	ip->da[ii].dia[bd] =
235	>	ip->da[ii].dia[bd+NI2DIR/2] = encode_diameter(ip,
236	>	.5*(sortord[ip->ns-1].dm - sortord[0].dm));
237		for (j = i; ++j < ip->ns; ) /* nearest above */
238	<	if (rightrndx[sortord[j].si] > rpos &&
239	<	leftrndx[sortord[j].si] < lpos) {
240	<	ip->ra[i][bd] = encode_radius(ip,
241	<	.5*(sortord[j].dm - sortord[i].dm));
238	>	if (rightrndx[sortord[j].si] > rightrndx[ii] &&
239	>	leftrndx[sortord[j].si] < leftrndx[ii]) {
240	>	ip->da[ii].dia[bd] = encode_diameter(ip,
241	>	sortord[j].dm - sortord[i].dm);
242		break;
243		}
244		for (j = i; j-- > 0; ) /* nearest below */
245	<	if (rightrndx[sortord[j].si] < rpos &&
246	<	leftrndx[sortord[j].si] > lpos) {
247	<	ip->ra[i][bd+NI2DIR/2] = encode_radius(ip,
248	<	.5*(sortord[i].dm - sortord[j].dm));
245	>	if (rightrndx[sortord[j].si] < rightrndx[ii] &&
246	>	leftrndx[sortord[j].si] > leftrndx[ii]) {
247	>	ip->da[ii].dia[bd+NI2DIR/2] = encode_diameter(ip,
248	>	sortord[i].dm - sortord[j].dm);
249		break;
250		}
251		}
#	Line 211 \| Line 257 \| *interp2_analyze(INTERP2 ip)**
257		return(1);
258		}
259
260	<	/* private call returns log of raw weight for a particular sample */
261	<	static double
262	<	get_ln_wt(const INTERP2 *ip, const int i, double x, double y)
260	>	/* Compute unnormalized weight for a position relative to a sample */
261	>	double
262	>	interp2_wti(INTERP2 *ip, const int i, double x, double y)
263		{
264	<	double dir, rd;
265	<	int ri;
264	>	double dir, rd, r2, d2;
265	>	int ri;
266		/* get relative direction */
267		x -= ip->spt[i][0];
268		y -= ip->spt[i][1];
#	Line 226 \| Line 272 \| *get_ln_wt(const INTERP2 ip, const int i, double x, do**
272		rd = dir * (NI2DIR/2./PI);
273		ri = (int)rd;
274		rd -= (double)ri;
275	<	rd = (1.-rd)ip->ra[i][ri] + rdip->ra[i][(ri+1)%NI2DIR];
276	<	rd = ip->smf * DECODE_RAD(ip, rd);
277	<	/* return log of Gaussian weight */
278	<	return( (xx + yy) / (-2.rdrd) );
275	>	rd = (1.-rd)ip->da[i].dia[ri] + rdip->da[i].dia[(ri+1)%NI2DIR];
276	>	rd = ip->smf * DECODE_DIA(ip, rd);
277	>	r2 = 2.rdrd;
278	>	d2 = xx + yy;
279	>	if (d2 > 21.r2) / result would be < 1e-9 */
280	>	return(.0);
281	>	/* Gaussian times harmonic weighting */
282	>	return( exp(-d2/r2) * ip->dmin/(ip->dmin + sqrt(d2)) );
283		}
284
285	+	/* private call to get grid flag index */
286	+	static int
287	+	interp2_flagpos(int fgi[2], INTERP2 *ip, double x, double y)
288	+	{
289	+	int ingrid = 1;
290	+
291	+	if (ip == NULL) /* paranoia */
292	+	return(-1);
293	+	/* need to compute interpolant? */
294	+	if (ip->da == NULL && !interp2_analyze(ip))
295	+	return(-1);
296	+	/* get grid position */
297	+	fgi[0] = (x - ip->smin[0]) * NI2DIM / (ip->smax[0] - ip->smin[0]);
298	+	if (fgi[0] >= NI2DIM) {
299	+	fgi[0] = NI2DIM-1;
300	+	ingrid = 0;
301	+	} else if (fgi[0] < 0) {
302	+	fgi[0] = 0;
303	+	ingrid = 0;
304	+	}
305	+	fgi[1] = (y - ip->smin[1]) * NI2DIM / (ip->smax[1] - ip->smin[1]);
306	+	if (fgi[1] >= NI2DIM) {
307	+	fgi[1] = NI2DIM-1;
308	+	ingrid = 0;
309	+	} else if (fgi[1] < 0) {
310	+	fgi[1] = 0;
311	+	ingrid = 0;
312	+	}
313	+	return(ingrid);
314	+	}
315	+
316	+	/* private call to set black flag if not too close to the given sample */
317	+	static void
318	+	setblk(INTERP2 *ip, const int i, const int gi[2])
319	+	{
320	+	double dx = (gi[0]+.5)(1./NI2DIM)(ip->smax[0] - ip->smin[0]) +
321	+	ip->smin[0] - ip->spt[i][0];
322	+	double dy = (gi[1]+.5)(1./NI2DIM)(ip->smax[1] - ip->smin[1]) +
323	+	ip->smin[1] - ip->spt[i][1];
324	+
325	+	if (dxdx + dydy > 2.*ip->grid2)
326	+	ip->da[i].blkflg[gi[1]] \|= 1<<gi[0];
327	+	}
328	+
329	+	#define chkblk(ip,i,gi) ((ip)->da[i].blkflg[(gi)[1]]>>(gi)[0] & 1)
330	+
331		/* Assign full set of normalized weights to interpolate the given position */
332		int
333		interp2_weights(float wtv[], INTERP2 *ip, double x, double y)
334		{
335		double wnorm;
336	+	int fgi[2];
337	+	int ingrid;
338		int i;
339
340	<	if ((wtv == NULL) \| (ip == NULL))
340	>	if (wtv == NULL)
341		return(0);
342	<	/* need to compute interpolant? */
343	<	if (ip->ra == NULL && !interp2_analyze(ip))
342	>	/* get flag position */
343	>	if ((ingrid = interp2_flagpos(fgi, ip, x, y)) < 0)
344		return(0);
345
346		wnorm = 0; /* compute raw weights */
347	<	for (i = ip->ns; i--; ) {
348	<	double wt = get_ln_wt(ip, i, x, y);
349	<	if (wt < -21.) {
350	<	wtv[i] = 0; /* ignore weights < 1e-9 */
351	<	continue;
254	<	}
255	<	wt = exp(wt); /* Gaussian weight */
347	>	for (i = ip->ns; i--; )
348	>	if (chkblk(ip, i, fgi)) {
349	>	wtv[i] = 0;
350	>	} else {
351	>	double wt = interp2_wti(ip, i, x, y);
352		wtv[i] = wt;
353		wnorm += wt;
354	<	}
354	>	if (wt <= 1e-9 && ingrid)
355	>	setblk(ip, i, fgi);
356	>	}
357		if (wnorm <= 0) /* too far from all our samples! */
358		return(0);
359		wnorm = 1./wnorm; /* normalize weights */
#	Line 270 \| Line 368 \| int
368		interp2_topsamp(float wt[], int si[], const int n, INTERP2 *ip, double x, double y)
369		{
370		int nn = 0;
371	+	int fgi[2];
372	+	int ingrid;
373		double wnorm;
374		int i, j;
375
376	<	if ((n <= 0) \| (wt == NULL) \| (si == NULL) \| (ip == NULL))
376	>	if ((n <= 0) \| (wt == NULL) \| (si == NULL))
377		return(0);
378	<	/* need to compute interpolant? */
379	<	if (ip->ra == NULL && !interp2_analyze(ip))
378	>	/* get flag position */
379	>	if ((ingrid = interp2_flagpos(fgi, ip, x, y)) < 0)
380		return(0);
381		/* identify top n weights */
382	<	for (i = ip->ns; i--; ) {
383	<	const double lnwt = get_ln_wt(ip, i, x, y);
382	>	for (i = ip->ns; i--; )
383	>	if (!chkblk(ip, i, fgi)) {
384	>	const double wti = interp2_wti(ip, i, x, y);
385	>	if (wti <= 1e-9) {
386	>	if (ingrid)
387	>	setblk(ip, i, fgi);
388	>	continue;
389	>	}
390		for (j = nn; j > 0; j--) {
391	<	if (wt[j-1] >= lnwt)
391	>	if (wt[j-1] >= wti)
392		break;
393		if (j < n) {
394		wt[j] = wt[j-1];
#	Line 290 \| Line 396 \| interp2_topsamp(float wt[], int si[], const int n, INT
396		}
397		}
398		if (j < n) { /* add/insert sample */
399	<	wt[j] = lnwt;
399	>	wt[j] = wti;
400		si[j] = i;
401		nn += (nn < n);
402		}
403	<	}
404	<	wnorm = 0; /* exponentiate and normalize */
405	<	for (j = nn; j--; ) {
406	<	double dwt = exp(wt[j]);
301	<	wt[j] = dwt;
302	<	wnorm += dwt;
303	<	}
403	>	}
404	>	wnorm = 0; /* normalize sample weights */
405	>	for (j = nn; j--; )
406	>	wnorm += wt[j];
407		if (wnorm <= 0)
408		return(0);
409		wnorm = 1./wnorm;
#	Line 315 \| Line 418 \| *interp2_free(INTERP2 ip)**
418		{
419		if (ip == NULL)
420		return;
421	<	if (ip->ra != NULL)
422	<	free(ip->ra);
421	>	if (ip->da != NULL)
422	>	free(ip->da);
423		free(ip);
424		}

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Comparing ray/src/common/interp2d.c (file contents): Revision 2.2 by greg, Sat Feb 9 17:39:21 2013 UTC vs. Revision 2.11 by greg, Fri Feb 15 01:26:47 2013 UTC

Diff Legend

Comparing ray/src/common/interp2d.c (file contents):
Revision 2.2 by greg, Sat Feb 9 17:39:21 2013 UTC vs.
Revision 2.11 by greg, Fri Feb 15 01:26:47 2013 UTC