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

Comparing ray/src/rt/data.c (file contents):
Revision 2.11 by greg, Tue Aug 22 08:51:57 1995 UTC vs.
Revision 2.37 by greg, Tue Mar 12 16:54:51 2024 UTC

#	Line 1 \| Line 1
1	–	/* Copyright (c) 1995 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		* data.c - routines dealing with interpolated data.
9	–	*
10	–	* 6/4/86
6		*/
7
8	<	#include "standard.h"
8	>	#include "copyright.h"
9
10	<	#include "color.h"
10	>	#include <time.h>
11
12	+	#include "platform.h"
13	+	#include "paths.h"
14	+	#include "standard.h"
15	+	#include "color.h"
16		#include "resolu.h"
17	<
17	>	#include "view.h"
18		#include "data.h"
19
20		/* picture memory usage before warning */
21		#ifndef PSIZWARN
22	<	#ifdef BIGMEM
22	>	#ifdef SMLMEM
23		#define PSIZWARN 3000000
24		#else
25	<	#define PSIZWARN 1000000
25	>	#define PSIZWARN 50000000
26		#endif
27		#endif
28
29		#ifndef TABSIZ
30	<	#define TABSIZ 97 /* table size (prime) */
30	>	#define TABSIZ 997 /* table size (prime) */
31		#endif
32
33		#define hash(s) (shash(s)%TABSIZ)
34
35
37	–	extern char getlibpath(); / library search path */
38	–
36		static DATARRAY dtab[TABSIZ]; / data array list */
37
38	<	static DATARRAY ptab[TABSIZ]; / picture list */
38	>	static gethfunc headaspect;
39
40
41		DATARRAY *
42	<	getdata(dname) /* get data array dname */
43	<	char *dname;
42	>	getdata( /* get data array dname */
43	>	char *dname
44	>	)
45		{
46		char *dfname;
47		FILE *fp;
48	<	int asize;
49	<	register int i, j;
50	<	register DATARRAY *dp;
48	>	int asize=0;
49	>	int i, j;
50	>	DATARRAY *dp;
51		/* look for array in list */
52		for (dp = dtab[hash(dname)]; dp != NULL; dp = dp->next)
53		if (!strcmp(dname, dp->name))
54		return(dp); /* found! */
57	–
55		/*
56		* If we haven't loaded the data already, we will look
57		* for it in the directories specified by the library path.
#	Line 75 \| Line 72 \| *char dname;**
72		* 0 0 ni p0i p1i .. pni
73		*/
74
75	<	if ((dfname = getpath(dname, getlibpath(), R_OK)) == NULL) {
75	>	if ((dfname = getpath(dname, getrlibpath(), R_OK)) == NULL) {
76		sprintf(errmsg, "cannot find data file \"%s\"", dname);
77	<	error(USER, errmsg);
77	>	error(SYSTEM, errmsg);
78		}
82	–	if ((dp = (DATARRAY *)malloc(sizeof(DATARRAY))) == NULL)
83	–	goto memerr;
84	–
85	–	dp->name = savestr(dname);
86	–
79		if ((fp = fopen(dfname, "r")) == NULL) {
80		sprintf(errmsg, "cannot open data file \"%s\"", dfname);
81		error(SYSTEM, errmsg);
82		}
83		/* get dimensions */
84	<	if (fgetval(fp, 'i', &dp->nd) <= 0)
84	>	if (fgetval(fp, 'i', &asize) <= 0)
85		goto scanerr;
86	<	if (dp->nd <= 0 \|\| dp->nd > MAXDDIM) {
86	>	if ((asize <= 0) \| (asize > MAXDDIM)) {
87		sprintf(errmsg, "bad number of dimensions for \"%s\"", dname);
88		error(USER, errmsg);
89		}
90	+	if ((dp = (DATARRAY *)malloc(sizeof(DATARRAY))) == NULL)
91	+	goto memerr;
92	+	dp->name = savestr(dname);
93	+	dp->type = DATATY;
94	+	dp->nd = asize;
95		asize = 1;
96		for (i = 0; i < dp->nd; i++) {
97	<	if (fgetval(fp, 'd', &dp->dim[i].org) <= 0)
97	>	if (fgetval(fp, DATATY, &dp->dim[i].org) <= 0)
98		goto scanerr;
99	<	if (fgetval(fp, 'd', &dp->dim[i].siz) <= 0)
99	>	if (fgetval(fp, DATATY, &dp->dim[i].siz) <= 0)
100		goto scanerr;
101		if (fgetval(fp, 'i', &dp->dim[i].ne) <= 0)
102		goto scanerr;
#	Line 107 \| Line 104 \| *char dname;**
104		goto scanerr;
105		asize *= dp->dim[i].ne;
106		if ((dp->dim[i].siz -= dp->dim[i].org) == 0) {
107	<	dp->dim[i].p = (double )malloc(dp->dim[i].nesizeof(double));
107	>	dp->dim[i].p = (DATATYPE *)
108	>	malloc(dp->dim[i].ne*sizeof(DATATYPE));
109		if (dp->dim[i].p == NULL)
110		goto memerr;
111		for (j = 0; j < dp->dim[i].ne; j++)
112	<	if (fgetval(fp, 'd', &dp->dim[i].p[j]) <= 0)
112	>	if (fgetval(fp, DATATY, &dp->dim[i].p[j]) <= 0)
113		goto scanerr;
114		for (j = 1; j < dp->dim[i].ne-1; j++)
115		if ((dp->dim[i].p[j-1] < dp->dim[i].p[j]) !=
#	Line 123 \| Line 121 \| *char dname;**
121		} else
122		dp->dim[i].p = NULL;
123		}
124	<	if ((dp->arr = (DATATYPE )malloc(asizesizeof(DATATYPE))) == NULL)
124	>	if ((dp->arr.d = (DATATYPE )malloc(asizesizeof(DATATYPE))) == NULL)
125		goto memerr;
126
127		for (i = 0; i < asize; i++)
128	<	if (fgetval(fp, DATATY, &dp->arr[i]) <= 0)
128	>	if (fgetval(fp, DATATY, &dp->arr.d[i]) <= 0)
129		goto scanerr;
130		fclose(fp);
131		i = hash(dname);
132		dp->next = dtab[i];
133		return(dtab[i] = dp);
136	–
134		memerr:
135		error(SYSTEM, "out of memory in getdata");
136		scanerr:
137		sprintf(errmsg, "%s in data file \"%s\"",
138		feof(fp) ? "unexpected EOF" : "bad format", dfname);
139		error(USER, errmsg);
140	+	return NULL; /* pro forma return */
141		}
142
143
144	<	static
145	<	headaspect(s, iap) /* check string for aspect ratio */
146	<	char *s;
147	<	double *iap;
144	>	static int
145	>	headaspect( /* check string for aspect ratio */
146	>	char *s,
147	>	void *iap
148	>	)
149		{
150	+	char fmt[MAXFMTLEN];
151	+
152		if (isaspect(s))
153	<	iap = aspectval(s);
153	>	(double)iap *= aspectval(s);
154	>	else if (formatval(fmt, s) && strcmp(fmt, COLRFMT))
155	>	(double)iap = 0.0;
156	>	return(0);
157		}
158
155	–
159		DATARRAY *
160	<	getpict(pname) /* get picture pname */
161	<	char *pname;
160	>	getpict( /* get picture pname */
161	>	char *pname
162	>	)
163		{
164		double inpaspect;
165		char *pfname;
166		FILE *fp;
167	<	COLOR *scanin;
167	>	COLR *scanin;
168		int sl, ns;
169		RESOLU inpres;
170	<	FLOAT loc[2];
170	>	RREAL loc[2];
171		int y;
172	<	register int x, i;
173	<	register DATARRAY *pp;
172	>	int x, i;
173	>	DATARRAY *pp;
174		/* look for array in list */
175	<	for (pp = ptab[hash(pname)]; pp != NULL; pp = pp->next)
175	>	for (pp = dtab[hash(pname)]; pp != NULL; pp = pp->next)
176		if (!strcmp(pname, pp->name))
177		return(pp); /* found! */
178
179	<	if ((pfname = getpath(pname, getlibpath(), R_OK)) == NULL) {
179	>	if ((pfname = getpath(pname, getrlibpath(), R_OK)) == NULL) {
180		sprintf(errmsg, "cannot find picture file \"%s\"", pname);
181	<	error(USER, errmsg);
181	>	error(SYSTEM, errmsg);
182		}
183	<	if ((pp = (DATARRAY *)calloc(3, sizeof(DATARRAY))) == NULL)
183	>	if ((pp = (DATARRAY )malloc(3sizeof(DATARRAY))) == NULL)
184		goto memerr;
185
186	<	pp[0].name =
183	<	pp[1].name =
184	<	pp[2].name = savestr(pname);
186	>	pp[0].name = savestr(pname);
187
188	<	if ((fp = fopen(pfname, "r")) == NULL) {
188	>	if ((fp = fopen(pfname, "rb")) == NULL) {
189		sprintf(errmsg, "cannot open picture file \"%s\"", pfname);
190		error(SYSTEM, errmsg);
191		}
190	–	#ifdef MSDOS
191	–	setmode(fileno(fp), O_BINARY);
192	–	#endif
192		/* get dimensions */
193		inpaspect = 1.0;
194		getheader(fp, headaspect, &inpaspect);
195	<	if (!fgetsresolu(&inpres, fp))
195	>	if (inpaspect <= FTINY \|\| !fgetsresolu(&inpres, fp))
196		goto readerr;
197	+	pp[0].nd = 2;
198	+	pp[0].dim[0].ne = inpres.yr;
199	+	pp[0].dim[1].ne = inpres.xr;
200	+	pp[0].dim[0].org =
201	+	pp[0].dim[1].org = 0.0;
202	+	if (inpres.xr <= inpres.yr*inpaspect) {
203	+	pp[0].dim[0].siz = inpaspect *
204	+	(double)inpres.yr/inpres.xr;
205	+	pp[0].dim[1].siz = 1.0;
206	+	} else {
207	+	pp[0].dim[0].siz = 1.0;
208	+	pp[0].dim[1].siz = (double)inpres.xr/inpres.yr /
209	+	inpaspect;
210	+	}
211	+	pp[0].dim[0].p = pp[0].dim[1].p = NULL;
212	+	sl = scanlen(&inpres); /* allocate array */
213	+	ns = numscans(&inpres);
214	+	i = nsslsizeof(COLR);
215		#if PSIZWARN
216	<	/* check memory usage */
217	<	i = 3sizeof(DATATYPE)inpres.xr*inpres.yr;
218	<	if (i > PSIZWARN) {
202	<	sprintf(errmsg, "picture file \"%s\" using %d bytes of memory",
203	<	pname, i);
216	>	if (i > PSIZWARN) { /* memory warning */
217	>	sprintf(errmsg, "picture file \"%s\" using %.1f MB of memory",
218	>	pname, i(1.0/(10241024)));
219		error(WARNING, errmsg);
220		}
221		#endif
222	<	for (i = 0; i < 3; i++) {
223	<	pp[i].nd = 2;
209	<	pp[i].dim[0].ne = inpres.yr;
210	<	pp[i].dim[1].ne = inpres.xr;
211	<	pp[i].dim[0].org =
212	<	pp[i].dim[1].org = 0.0;
213	<	if (inpres.xr <= inpres.yr*inpaspect) {
214	<	pp[i].dim[0].siz = inpaspect *
215	<	(double)inpres.yr/inpres.xr;
216	<	pp[i].dim[1].siz = 1.0;
217	<	} else {
218	<	pp[i].dim[0].siz = 1.0;
219	<	pp[i].dim[1].siz = (double)inpres.xr/inpres.yr /
220	<	inpaspect;
221	<	}
222	<	pp[i].dim[0].p = pp[i].dim[1].p = NULL;
223	<	pp[i].arr = (DATATYPE *)
224	<	malloc(inpres.xrinpres.yrsizeof(DATATYPE));
225	<	if (pp[i].arr == NULL)
226	<	goto memerr;
227	<	}
222	>	if ((pp[0].arr.c = (COLR *)malloc(i)) == NULL)
223	>	goto memerr;
224		/* load picture */
225	<	sl = scanlen(&inpres);
230	<	ns = numscans(&inpres);
231	<	if ((scanin = (COLOR )malloc(slsizeof(COLOR))) == NULL)
225	>	if ((scanin = (COLR )malloc(slsizeof(COLR))) == NULL)
226		goto memerr;
227		for (y = 0; y < ns; y++) {
228	<	if (freadscan(scanin, sl, fp) < 0)
228	>	if (freadcolrs(scanin, sl, fp) < 0)
229		goto readerr;
230		for (x = 0; x < sl; x++) {
231		pix2loc(loc, &inpres, x, y);
232		i = (int)(loc[1]inpres.yr)inpres.xr +
233		(int)(loc[0]*inpres.xr);
234	<	pp[0].arr[i] = colval(scanin[x],RED);
241	<	pp[1].arr[i] = colval(scanin[x],GRN);
242	<	pp[2].arr[i] = colval(scanin[x],BLU);
234	>	copycolr(pp[0].arr.c[i], scanin[x]);
235		}
236		}
237	<	free((char *)scanin);
237	>	free(scanin);
238		fclose(fp);
239		i = hash(pname);
240	<	pp[0].next =
241	<	pp[1].next =
242	<	pp[2].next = ptab[i];
243	<	return(ptab[i] = pp);
244	<
240	>	pp[0].next = dtab[i]; /* link into picture list */
241	>	pp[1] = pp[0];
242	>	pp[2] = pp[0];
243	>	pp[0].type = RED; /* differentiate RGB records */
244	>	pp[1].type = GRN;
245	>	pp[2].type = BLU;
246	>	return(dtab[i] = pp);
247		memerr:
248		error(SYSTEM, "out of memory in getpict");
249		readerr:
250		sprintf(errmsg, "bad picture file \"%s\"", pfname);
251		error(USER, errmsg);
252	+	return NULL; /* pro forma return */
253		}
254
255
256	<	freedata(dname) /* free memory associated with dname */
257	<	char *dname;
256	>	/* header info type for hyperspectral image */
257	>	typedef struct {
258	>	float wlpart[4]; /* wavelength partitions */
259	>	int nc; /* number of components */
260	>	double inpaspect; /* pixel aspect ratio */
261	>	} SPECINFO;
262	>
263	>	static int
264	>	specheadline( /* get info for spectral image */
265	>	char *s,
266	>	void *cdp
267	>	)
268		{
269	+	SPECINFO sip = (SPECINFO )cdp;
270	+	char fmt[MAXFMTLEN];
271	+
272	+	if (isaspect(s))
273	+	sip->inpaspect *= aspectval(s);
274	+	else if (isncomp(s))
275	+	sip->nc = ncompval(s);
276	+	else if (iswlsplit(s))
277	+	wlsplitval(sip->wlpart, s);
278	+	else if (formatval(fmt, s) && strcmp(fmt, SPECFMT))
279	+	return(-1);
280	+	return(0);
281	+	}
282	+
283	+	DATARRAY *
284	+	getspec( /* load hyperspectral image as data */
285	+	char *sname
286	+	)
287	+	{
288	+	SPECINFO si;
289	+	char *pfname;
290	+	FILE *fp;
291	+	int sl, ns;
292	+	int y, i;
293	+	DATARRAY *pp;
294	+	/* look for array in list */
295	+	for (pp = dtab[hash(sname)]; pp != NULL; pp = pp->next)
296	+	if (!strcmp(sname, pp->name))
297	+	return(pp); /* found! */
298	+
299	+	if ((pfname = getpath(sname, getrlibpath(), R_OK)) == NULL) {
300	+	sprintf(errmsg, "cannot find hyperspectral image \"%s\"", sname);
301	+	error(SYSTEM, errmsg);
302	+	}
303	+	if ((fp = fopen(pfname, "rb")) == NULL) {
304	+	sprintf(errmsg, "cannot open hyperspectral image \"%s\"", pfname);
305	+	error(SYSTEM, errmsg);
306	+	}
307	+	si.wlpart[3] = 0;
308	+	si.nc = 0;
309	+	si.inpaspect = 1.0;
310	+	if (getheader(fp, specheadline, &si) < 0 \|\|
311	+	(si.nc <= 3) \| (si.nc > MAXCSAMP) \| (si.wlpart[3] < 1) \|\|
312	+	!fscnresolu(&sl, &ns, fp))
313	+	goto readerr;
314	+
315	+	if ((pp = (DATARRAY *)malloc(sizeof(DATARRAY))) == NULL)
316	+	goto memerr;
317	+
318	+	pp->name = savestr(sname);
319	+	pp->type = SPECTY;
320	+	pp->nd = 3;
321	+	pp->dim[0].ne = ns;
322	+	pp->dim[1].ne = sl;
323	+	pp->dim[0].org =
324	+	pp->dim[1].org = 0.0;
325	+	if (sl <= ns*si.inpaspect) {
326	+	pp->dim[0].siz = si.inpaspect * (double)ns/sl;
327	+	pp->dim[1].siz = 1.0;
328	+	} else {
329	+	pp->dim[0].siz = 1.0;
330	+	pp->dim[1].siz = (double)sl/ns / si.inpaspect;
331	+	}
332	+	pp->dim[2].ne = si.nc;
333	+	pp->dim[2].siz = si.wlpart[3] - si.wlpart[0];
334	+	pp->dim[2].org = si.wlpart[0] + 0.5*pp->dim[2].siz/si.nc;
335	+	pp->dim[2].siz *= (si.nc - 1.0)/si.nc;
336	+	pp->dim[0].p = pp->dim[1].p = pp->dim[2].p = NULL;
337	+	i = nssl(si.nc+1);
338	+	#if PSIZWARN
339	+	if (i > PSIZWARN) { /* memory warning */
340	+	sprintf(errmsg, "hyperspectral image \"%s\" using %.1f MB of memory",
341	+	sname, i(1.0/(10241024)));
342	+	error(WARNING, errmsg);
343	+	}
344	+	#endif
345	+	if ((pp->arr.s = (uby8 *)malloc(i)) == NULL)
346	+	goto memerr;
347	+	for (y = 0; y < ns; y++) /* read each scanline */
348	+	if (freadscolrs(pp->arr.s + ysl(si.nc+1), si.nc, sl, fp) < 0)
349	+	goto readerr;
350	+	fclose(fp);
351	+	i = hash(sname); /* insert in hash table */
352	+	pp->next = dtab[i];
353	+	return(dtab[i] = pp);
354	+	memerr:
355	+	error(SYSTEM, "out of memory in getspec");
356	+	readerr:
357	+	sprintf(errmsg, "bad hyperspectral image \"%s\"", pfname);
358	+	error(USER, errmsg);
359	+	return NULL; /* pro forma return */
360	+	}
361	+
362	+
363	+	void
364	+	freedata( /* release data array reference */
365	+	DATARRAY *dta
366	+	)
367	+	{
368		DATARRAY head;
369		int hval, nents;
370	<	register DATARRAY dp, dpl;
371	<	register int i;
370	>	DATARRAY dpl, dp;
371	>	int i;
372
373	<	if (dname == NULL) { /* free all if NULL */
373	>	if (dta == NULL) { /* free all if NULL */
374		hval = 0; nents = TABSIZ;
375		} else {
376	<	hval = hash(dname); nents = 1;
376	>	hval = hash(dta->name); nents = 1;
377	>	if (!dta->name) { / not a data file? */
378	>	dta->next = dtab[hval];
379	>	dtab[hval] = dta; /* ...fake position */
380	>	}
381		}
382		while (nents--) {
383		head.next = dtab[hval];
384		dpl = &head;
385		while ((dp = dpl->next) != NULL)
386	<	if (dname == NULL \|\| !strcmp(dname, dp->name)) {
386	>	if ((dta == NULL) \| (dta == dp)) {
387		dpl->next = dp->next;
388	<	free((char *)dp->arr);
388	>	free(dp->arr.p);
389		for (i = 0; i < dp->nd; i++)
390		if (dp->dim[i].p != NULL)
391	<	free((char *)dp->dim[i].p);
391	>	free(dp->dim[i].p);
392		freestr(dp->name);
393	<	free((char *)dp);
393	>	free(dp);
394		} else
395		dpl = dp;
396		dtab[hval++] = head.next;
#	Line 290 \| Line 398 \| *char dname;**
398		}
399
400
401	<	freepict(pname) /* free memory associated with pname */
402	<	char *pname;
401	>	/* internal call to interpolate data value or vector */
402	>	static double
403	>	data_interp(DATARRAY dp, double pt, double coef, DATATYPE *rvec)
404		{
405	<	DATARRAY head;
406	<	int hval, nents;
407	<	register DATARRAY pp, ppl;
405	>	DATARRAY sd;
406	>	int stride, i;
407	>	double x, c0, c1, y0, y1;
408	>	/* set up dimensions for recursion */
409	>	if (dp->nd > 1) {
410	>	sd.name = dp->name;
411	>	sd.type = dp->type;
412	>	sd.nd = dp->nd - 1;
413	>	memcpy(sd.dim, dp->dim+1, sd.nd*sizeof(struct dadim));
414	>	stride = sd.dim[i = sd.nd-1].ne + (sd.type==SPECTY);
415	>	while (i-- > 0)
416	>	stride *= sd.dim[i].ne;
417	>	}
418	>	/* get independent variable */
419	>	if (dp->dim[0].p == NULL) { /* evenly spaced points */
420	>	x = (pt[0] - dp->dim[0].org)/dp->dim[0].siz;
421	>	x *= (double)(dp->dim[0].ne - 1);
422	>	i = x;
423	>	if (i < 0)
424	>	i = 0;
425	>	else if (i > dp->dim[0].ne - 2)
426	>	i = dp->dim[0].ne - 2;
427	>	} else { /* unevenly spaced points */
428	>	int lower, upper;
429	>	if (dp->dim[0].siz > 0.0) {
430	>	lower = 0;
431	>	upper = dp->dim[0].ne;
432	>	} else {
433	>	lower = dp->dim[0].ne;
434	>	upper = 0;
435	>	}
436	>	do {
437	>	i = (lower + upper) >> 1;
438	>	if (pt[0] >= dp->dim[0].p[i])
439	>	lower = i;
440	>	else
441	>	upper = i;
442	>	} while (i != (lower + upper) >> 1);
443
444	<	if (pname == NULL) { /* free all if NULL */
445	<	hval = 0; nents = TABSIZ;
444	>	if (i > dp->dim[0].ne - 2)
445	>	i = dp->dim[0].ne - 2;
446	>
447	>	x = i + (pt[0] - dp->dim[0].p[i]) /
448	>	(dp->dim[0].p[i+1] - dp->dim[0].p[i]);
449	>	}
450	>	/*
451	>	* Compute interpolation coefficients:
452	>	* extrapolate as far as one division, then
453	>	* taper off harmonically to zero.
454	>	*/
455	>	if (x > i+2) {
456	>	c0 = 1./(i-1 - x);
457	>	c1 = -2.*c0;
458	>	} else if (x < i-1) {
459	>	c1 = 1./(i - x);
460	>	c0 = -2.*c1;
461		} else {
462	<	hval = hash(pname); nents = 1;
462	>	c0 = i+1 - x;
463	>	c1 = x - i;
464		}
465	<	while (nents--) {
466	<	head.next = ptab[hval];
467	<	ppl = &head;
468	<	while ((pp = ppl->next) != NULL)
469	<	if (pname == NULL \|\| !strcmp(pname, pp->name)) {
470	<	ppl->next = pp->next;
471	<	free((char *)pp[0].arr);
472	<	free((char *)pp[1].arr);
473	<	free((char *)pp[2].arr);
474	<	freestr(pp[0].name);
475	<	free((char *)pp);
465	>	c0 *= coef;
466	>	c1 *= coef;
467	>	/* check if vector interp */
468	>	if ((dp->nd == 2) & (rvec != NULL)) {
469	>	if (dp->type == DATATY) {
470	>	sd.arr.d = dp->arr.d + i*stride;
471	>	for (i = sd.dim[0].ne; i--; )
472	>	rvec[i] += c0*sd.arr.d[i]
473	>	+ c1*sd.arr.d[i+stride];
474	>	return(0.);
475	>	}
476	>	if (dp->type == SPECTY) {
477	>	double f;
478	>	sd.arr.s = dp->arr.s + i*stride;
479	>	f = ldexp(1.0, (int)sd.arr.s[sd.dim[0].ne]
480	>	- (COLXS+8));
481	>	for (i = sd.dim[0].ne; i--; )
482	>	rvec[i] += c0f(sd.arr.s[i] + 0.5);
483	>	sd.arr.s += stride;
484	>	f = ldexp(1.0, (int)sd.arr.s[sd.dim[0].ne]
485	>	- (COLXS+8));
486	>	for (i = sd.dim[0].ne; i--; )
487	>	rvec[i] += c1f(sd.arr.s[i] + 0.5);
488	>	return(0.);
489	>	}
490	>	sd.arr.c = dp->arr.c + i*stride;
491	>	for (i = sd.dim[0].ne; i--; )
492	>	rvec[i] += c0*colrval(sd.arr.c[i],sd.type)
493	>	+ c1*colrval(sd.arr.c[i+stride],sd.type);
494	>	return(0.);
495	>	}
496	>	/* get dependent variable */
497	>	if (dp->nd > 1) {
498	>	if (dp->type == DATATY) {
499	>	sd.arr.d = dp->arr.d + i*stride;
500	>	y0 = data_interp(&sd, pt+1, c0, rvec);
501	>	sd.arr.d += stride;
502	>	} else if (dp->type == SPECTY) {
503	>	sd.arr.s = dp->arr.s + i*stride;
504	>	y0 = data_interp(&sd, pt+1, c0, rvec);
505	>	sd.arr.s += stride;
506	>	} else {
507	>	sd.arr.c = dp->arr.c + i*stride;
508	>	y0 = data_interp(&sd, pt+1, c0, rvec);
509	>	sd.arr.c += stride;
510	>	}
511	>	y1 = data_interp(&sd, pt+1, c1, rvec);
512	>	} else { /* end of recursion */
513	>	if (dp->type == DATATY) {
514	>	y0 = dp->arr.d[i];
515	>	y1 = dp->arr.d[i+1];
516	>	} else if (dp->type == SPECTY) {
517	>	if (dp->arr.s[dp->dim[0].ne]) {
518	>	double f = ldexp(1.0, -(COLXS+8) +
519	>	(int)dp->arr.s[dp->dim[0].ne]);
520	>	y0 = (dp->arr.s[i] + 0.5)*f;
521	>	y1 = (dp->arr.s[i+1] + 0.5)*f;
522		} else
523	<	ppl = pp;
524	<	ptab[hval++] = head.next;
523	>	y0 = y1 = 0.0;
524	>	} else {
525	>	y0 = colrval(dp->arr.c[i],dp->type);
526	>	y1 = colrval(dp->arr.c[i+1],dp->type);
527	>	}
528	>	y0 *= c0;
529	>	y1 *= c1;
530		}
531	+	return(y0 + y1); /* coefficients already applied */
532		}
533
534
535		double
536	<	datavalue(dp, pt) /* interpolate data value at a point */
537	<	register DATARRAY *dp;
538	<	double *pt;
536	>	datavalue( /* interpolate data value at a point */
537	>	DATARRAY *dp,
538	>	double *pt
539	>	)
540		{
541	+	return(data_interp(dp, pt, 1., NULL));
542	+	}
543	+
544	+
545	+	/* Interpolate final vector corresponding to last dimension in data array */
546	+	DATARRAY *
547	+	datavector(DATARRAY dp, double pt)
548	+	{
549	+	DATARRAY *newdp;
550	+
551	+	if (dp->nd < 2)
552	+	error(INTERNAL, "datavector() called with 1-D array");
553	+	/* create vector array */
554	+	newdp = (DATARRAY *)malloc(sizeof(DATARRAY) -
555	+	(MAXDDIM-1)*sizeof(struct dadim) +
556	+	sizeof(DATATYPE)*dp->dim[dp->nd-1].ne);
557	+	if (newdp == NULL)
558	+	error(SYSTEM, "out of memory in datavector");
559	+	newdp->next = NULL;
560	+	newdp->name = dp->name;
561	+	newdp->type = DATATY;
562	+	newdp->nd = 1; /* vector data goes here */
563	+	newdp->dim[0] = dp->dim[dp->nd-1];
564	+	newdp->arr.d = (DATATYPE *)(newdp->dim + 1);
565	+	memset(newdp->arr.d, 0, sizeof(DATATYPE)*newdp->dim[0].ne);
566	+
567	+	(void)data_interp(dp, pt, 1., newdp->arr.d);
568	+
569	+	return(newdp); /* will be free'd using free() */
570	+	}
571	+
572	+
573	+	#if 0
574	+	double
575	+	datavalue( /* interpolate data value at a point */
576	+	DATARRAY *dp,
577	+	double *pt
578	+	)
579	+	{
580		DATARRAY sd;
581		int asize;
582		int lower, upper;
583	<	register int i;
583	>	int i;
584		double x, y0, y1;
585		/* set up dimensions for recursion */
586	<	sd.nd = dp->nd - 1;
587	<	asize = 1;
588	<	for (i = 0; i < sd.nd; i++) {
589	<	sd.dim[i].org = dp->dim[i+1].org;
590	<	sd.dim[i].siz = dp->dim[i+1].siz;
591	<	sd.dim[i].p = dp->dim[i+1].p;
592	<	asize *= sd.dim[i].ne = dp->dim[i+1].ne;
586	>	if (dp->nd > 1) {
587	>	sd.name = dp->name;
588	>	sd.type = dp->type;
589	>	sd.nd = dp->nd - 1;
590	>	asize = 1;
591	>	for (i = 0; i < sd.nd; i++) {
592	>	sd.dim[i].org = dp->dim[i+1].org;
593	>	sd.dim[i].siz = dp->dim[i+1].siz;
594	>	sd.dim[i].p = dp->dim[i+1].p;
595	>	asize *= (sd.dim[i].ne = dp->dim[i+1].ne) +
596	>	((sd.type==SPECTY) & (i==sd.nd-1));
597	>	}
598		}
599		/* get independent variable */
600		if (dp->dim[0].p == NULL) { /* evenly spaced points */
#	Line 363 \| Line 620 \| *double pt;**
620		else
621		upper = i;
622		} while (i != (lower + upper) >> 1);
623	+
624		if (i > dp->dim[0].ne - 2)
625		i = dp->dim[0].ne - 2;
626	+
627		x = i + (pt[0] - dp->dim[0].p[i]) /
628		(dp->dim[0].p[i+1] - dp->dim[0].p[i]);
629		}
630		/* get dependent variable */
631	<	if (dp->nd == 1) {
632	<	y0 = dp->arr[i];
633	<	y1 = dp->arr[i+1];
631	>	if (dp->nd > 1) {
632	>	if (dp->type == DATATY) {
633	>	sd.arr.d = dp->arr.d + i*asize;
634	>	y0 = datavalue(&sd, pt+1);
635	>	sd.arr.d += asize;
636	>	y1 = datavalue(&sd, pt+1);
637	>	} else if (dp->type == SPECTY) {
638	>	sd.arr.s = dp->arr.s + i*asize;
639	>	y0 = datavalue(&sd, pt+1);
640	>	sd.arr.s += asize;
641	>	y1 = datavalue(&sd, pt+1);
642	>	} else {
643	>	sd.arr.c = dp->arr.c + i*asize;
644	>	y0 = datavalue(&sd, pt+1);
645	>	sd.arr.c += asize;
646	>	y1 = datavalue(&sd, pt+1);
647	>	}
648		} else {
649	<	sd.arr = &dp->arr[i*asize];
650	<	y0 = datavalue(&sd, pt+1);
651	<	sd.arr = &dp->arr[(i+1)*asize];
652	<	y1 = datavalue(&sd, pt+1);
649	>	if (dp->type == DATATY) {
650	>	y0 = dp->arr.d[i];
651	>	y1 = dp->arr.d[i+1];
652	>	} else if (dp->type == SPECTY) {
653	>	if (dp->arr.s[dp->dim[0].ne]) {
654	>	double f = ldexp(1.0, -(COLXS+8) +
655	>	(int)dp->arr.s[dp->dim[0].ne]);
656	>	y0 = (dp->arr.s[i] + 0.5)*f;
657	>	y1 = (dp->arr.s[i+1] + 0.5)*f;
658	>	} else
659	>	y0 = y1 = 0.0;
660	>	} else {
661	>	y0 = colrval(dp->arr.c[i],dp->type);
662	>	y1 = colrval(dp->arr.c[i+1],dp->type);
663	>	}
664		}
665		/*
666		* Extrapolate as far as one division, then
#	Line 390 \| Line 674 \| *double pt;**
674
675		return( y0((i+1)-x) + y1(x-i) );
676		}
677	+	#endif

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Comparing ray/src/rt/data.c (file contents): Revision 2.11 by greg, Tue Aug 22 08:51:57 1995 UTC vs. Revision 2.37 by greg, Tue Mar 12 16:54:51 2024 UTC

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Comparing ray/src/rt/data.c (file contents):
Revision 2.11 by greg, Tue Aug 22 08:51:57 1995 UTC vs.
Revision 2.37 by greg, Tue Mar 12 16:54:51 2024 UTC