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

Comparing ray/src/common/calfunc.c (file contents):
Revision 2.11 by schorsch, Sat Jun 7 12:50:20 2003 UTC vs.
Revision 2.29 by greg, Sun Feb 25 18:36:27 2024 UTC

#	Line 17 \| Line 17 \| static const char RCSid[] = "$Id$";
17		#include <errno.h>
18		#include <math.h>
19
20	+	#include "rterror.h"
21		#include "calcomp.h"
22
23		/* bits in argument flag (better be right!) */
24		#define AFLAGSIZ (8*sizeof(unsigned long))
25	<	#define ALISTSIZ 6 /* maximum saved argument list */
25	>	#define ALISTSIZ 10 /* maximum saved argument list */
26
27		typedef struct activation {
28		char name; / function name */
#	Line 33 \| Line 34 \| typedef struct activation {
34
35		static ACTIVATION *curact = NULL;
36
37	<	static double libfunc();
37	>	static double libfunc(char fname, VARDEF vp);
38
39		#ifndef MAXLIB
40		#define MAXLIB 64 /* maximum number of library functions */
41		#endif
42
43	<	static double l_if(), l_select(), l_rand();
44	<	static double l_floor(), l_ceil();
45	<	static double l_sqrt();
46	<	static double l_sin(), l_cos(), l_tan();
47	<	static double l_asin(), l_acos(), l_atan(), l_atan2();
48	<	static double l_exp(), l_log(), l_log10();
43	>	static double l_if(char ), l_select(char );
44	>	static double l_min(char ), l_max(char );
45	>	static double l_rand(char *);
46	>	static double l_floor(char ), l_ceil(char );
47	>	static double l_sqrt(char *);
48	>	static double l_sin(char ), l_cos(char ), l_tan(char *);
49	>	static double l_asin(char ), l_acos(char ), l_atan(char ), l_atan2(char );
50	>	static double l_exp(char ), l_log(char ), l_log10(char *);
51
52		/* functions must be listed alphabetically */
53		static LIBR library[MAXLIB] = {
#	Line 59 \| Line 62 \| static LIBR library[MAXLIB] = {
62		{ "if", 3, ':', l_if },
63		{ "log", 1, ':', l_log },
64		{ "log10", 1, ':', l_log10 },
65	+	{ "max", 1, ':', l_max },
66	+	{ "min", 1, ':', l_min },
67		{ "rand", 1, ':', l_rand },
68		{ "select", 1, ':', l_select },
69		{ "sin", 1, ':', l_sin },
#	Line 66 \| Line 71 \| static LIBR library[MAXLIB] = {
71		{ "tan", 1, ':', l_tan },
72		};
73
74	<	static int libsize = 16;
74	>	static int libsize = 18;
75
76		#define resolve(ep) ((ep)->type==VAR?(ep)->v.ln:argf((ep)->v.chan))
77
78
79		int
80	<	fundefined(fname) /* return # of arguments for function */
81	<	char *fname;
80	>	fundefined( /* return # of req'd arguments for function */
81	>	char *fname
82	>	)
83		{
84	<	register LIBR *lp;
85	<	register VARDEF *vp;
84	>	LIBR *lp;
85	>	VARDEF *vp;
86
87		if ((vp = varlookup(fname)) != NULL && vp->def != NULL
88		&& vp->def->v.kid->type == FUNC)
#	Line 89 \| Line 95 \| *char fname;**
95
96
97		double
98	<	funvalue(fname, n, a) /* return a function value to the user */
99	<	char *fname;
100	<	int n;
101	<	double *a;
98	>	funvalue( /* return a function value to the user */
99	>	char *fname,
100	>	int n,
101	>	double *a
102	>	)
103		{
104		ACTIVATION act;
105	<	register VARDEF *vp;
105	>	VARDEF *vp;
106		double rval;
107		/* push environment */
108		act.name = fname;
109		act.prev = curact;
110		act.ap = a;
111	<	if (n >= AFLAGSIZ)
105	<	act.an = ~0;
106	<	else
111	>	if (n < AFLAGSIZ)
112		act.an = (1L<<n)-1;
113	+	else {
114	+	act.an = ~0;
115	+	if (n > AFLAGSIZ)
116	+	wputs("Excess arguments in funvalue()\n");
117	+	}
118		act.fun = NULL;
119		curact = &act;
120
#	Line 120 \| Line 130 \| *double a;**
130
131
132		void
133	<	funset(fname, nargs, assign, fptr) /* set a library function */
134	<	char *fname;
135	<	int nargs;
136	<	int assign;
137	<	double (*fptr)();
133	>	funset( /* set a library function */
134	>	char *fname,
135	>	int nargs,
136	>	int assign,
137	>	double (fptr)(char )
138	>	)
139		{
140		int oldlibsize = libsize;
141		char *cp;
142	<	register LIBR *lp;
142	>	LIBR *lp;
143		/* check for context */
144		for (cp = fname; *cp; cp++)
145		;
146		if (cp == fname)
147		return;
148	<	if (cp[-1] == CNTXMARK)
148	>	while (cp[-1] == CNTXMARK) {
149		*--cp = '\0';
150	+	if (cp == fname) return;
151	+	}
152		if ((lp = liblookup(fname)) == NULL) { /* insert */
153	+	if (fptr == NULL)
154	+	return; /* nothing! */
155		if (libsize >= MAXLIB) {
156		eputs("Too many library functons!\n");
157		quit(1);
158		}
159		for (lp = &library[libsize]; lp > library; lp--)
160	<	if (strcmp(lp[-1].fname, fname) > 0) {
161	<	lp[0].fname = lp[-1].fname;
162	<	lp[0].nargs = lp[-1].nargs;
148	<	lp[0].atyp = lp[-1].atyp;
149	<	lp[0].f = lp[-1].f;
150	<	} else
160	>	if (strcmp(lp[-1].fname, fname) > 0)
161	>	lp[0] = lp[-1];
162	>	else
163		break;
164		libsize++;
165		}
166		if (fptr == NULL) { /* delete */
167		while (lp < &library[libsize-1]) {
168	<	lp[0].fname = lp[1].fname;
157	<	lp[0].nargs = lp[1].nargs;
158	<	lp[0].atyp = lp[1].atyp;
159	<	lp[0].f = lp[1].f;
168	>	lp[0] = lp[1];
169		lp++;
170		}
171		libsize--;
#	Line 172 \| Line 181 \| *double (fptr)();**
181
182
183		int
184	<	nargum() /* return number of available arguments */
184	>	nargum(void) /* return number of available arguments */
185		{
186	<	register int n;
186	>	int n;
187
188		if (curact == NULL)
189		return(0);
#	Line 188 \| Line 197 \| *nargum() / return number of available arguments /*
197
198
199		double
200	<	argument(n) /* return nth argument for active function */
192	<	register int n;
200	>	argument(int n) /* return nth argument for active function */
201		{
202	<	register ACTIVATION *actp = curact;
203	<	register EPNODE *ep;
202	>	ACTIVATION *actp = curact;
203	>	EPNODE *ep = NULL;
204		double aval;
205
206	<	if (actp == NULL \|\| --n < 0) {
206	>	if (!actp \| (--n < 0)) {
207		eputs("Bad call to argument!\n");
208		quit(1);
209		}
210	<	/* already computed? */
203	<	if (n < AFLAGSIZ && 1L<<n & actp->an)
210	>	if ((n < AFLAGSIZ) & actp->an >> n) /* already computed? */
211		return(actp->ap[n]);
212
213	<	if (actp->fun == NULL \|\| (ep = ekid(actp->fun, n+1)) == NULL) {
213	>	if (!actp->fun \|\| !(ep = ekid(actp->fun, n+1))) {
214		eputs(actp->name);
215		eputs(": too few arguments\n");
216		quit(1);
217		}
218	<	curact = actp->prev; /* pop environment */
218	>	curact = actp->prev; /* previous context */
219		aval = evalue(ep); /* compute argument */
220	<	curact = actp; /* push back environment */
221	<	if (n < ALISTSIZ) { /* save value */
220	>	curact = actp; /* put back calling context */
221	>	if (n < ALISTSIZ) { /* save value if room */
222		actp->ap[n] = aval;
223		actp->an \|= 1L<<n;
224		}
#	Line 220 \| Line 227 \| register int n;
227
228
229		VARDEF *
230	<	argf(n) /* return function def for nth argument */
224	<	int n;
230	>	argf(int n) /* return function def for nth argument */
231		{
232	<	register ACTIVATION *actp;
233	<	register EPNODE *ep;
232	>	ACTIVATION *actp;
233	>	EPNODE *ep;
234
235		for (actp = curact; actp != NULL; actp = actp->prev) {
236
#	Line 259 \| Line 265 \| badarg:
265
266
267		char *
268	<	argfun(n) /* return function name for nth argument */
263	<	int n;
268	>	argfun(int n) /* return function name for nth argument */
269		{
270		return(argf(n)->name);
271		}
272
273
274		double
275	<	efunc(ep) /* evaluate a function */
271	<	register EPNODE *ep;
275	>	efunc(EPNODE ep) / evaluate a function */
276		{
277		ACTIVATION act;
278		double alist[ALISTSIZ];
279		double rval;
280	<	register VARDEF *dp;
280	>	VARDEF *dp;
281		/* push environment */
282		dp = resolve(ep->v.kid);
283		act.name = dp->name;
#	Line 294 \| Line 298 \| *register EPNODE ep;**
298
299
300		LIBR *
301	<	liblookup(fname) /* look up a library function */
298	<	char *fname;
301	>	liblookup(char fname) / look up a library function */
302		{
303		int upper, lower;
304	<	register int cm, i;
304	>	int cm, i;
305
306		lower = 0;
307		upper = cm = libsize;
#	Line 323 \| Line 326 \| *char fname;**
326
327
328		static double
329	<	libfunc(fname, vp) /* execute library function */
330	<	char *fname;
331	<	VARDEF *vp;
329	>	libfunc( /* execute library function */
330	>	char *fname,
331	>	VARDEF *vp
332	>	)
333		{
334	<	register LIBR *lp;
334	>	LIBR *lp;
335		double d;
336		int lasterrno;
337
#	Line 343 \| Line 347 \| *VARDEF vp;**
347		lasterrno = errno;
348		errno = 0;
349		d = (*lp->f)(lp->fname);
350	<	#ifdef IEEE
351	<	if (errno == 0)
350	>	#ifdef isnan
351	>	if (errno == 0) {
352		if (isnan(d))
353		errno = EDOM;
354		else if (isinf(d))
355		errno = ERANGE;
356	+	}
357		#endif
358	<	if (errno == EDOM \|\| errno == ERANGE) {
358	>	if ((errno == EDOM) \| (errno == ERANGE)) {
359		wputs(fname);
360		if (errno == EDOM)
361		wputs(": domain error\n");
#	Line 371 \| Line 376 \| *VARDEF vp;**
376
377
378		static double
379	<	l_if() /* if(cond, then, else) conditional expression */
379	>	l_if(char nm) / if(cond, then, else) conditional expression */
380		/* cond evaluates true if greater than zero */
381		{
382		if (argument(1) > 0.0)
#	Line 382 \| Line 387 \| *l_if() / if(cond, then, else) conditional expressio**
387
388
389		static double
390	<	l_select() /* return argument #(A1+1) */
390	>	l_select(char nm) / return argument #(A1+1) */
391		{
392	<	register int n;
392	>	int narg = nargum();
393	>	double a1 = argument(1);
394	>	int n = (int)(a1 + .5);
395
396	<	n = (int)(argument(1) + .5);
390	<	if (n == 0)
391	<	return(nargum()-1);
392	<	if (n < 1 \|\| n > nargum()-1) {
396	>	if ((a1 < -.5) \| (n >= narg)) {
397		errno = EDOM;
398		return(0.0);
399		}
400	+	if (!n) /* asking max index? */
401	+	return(narg-1);
402		return(argument(n+1));
403		}
404
405
406		static double
407	<	l_rand() /* random function between 0 and 1 */
407	>	l_max(char nm) / general maximum function */
408		{
409	+	int n = nargum();
410	+	double vmax = argument(1);
411	+
412	+	while (n > 1) {
413	+	double v = argument(n--);
414	+	if (vmax < v)
415	+	vmax = v;
416	+	}
417	+	return(vmax);
418	+	}
419	+
420	+
421	+	static double
422	+	l_min(char nm) / general minimum function */
423	+	{
424	+	int n = nargum();
425	+	double vmin = argument(1);
426	+
427	+	while (n > 1) {
428	+	double v = argument(n--);
429	+	if (vmin > v)
430	+	vmin = v;
431	+	}
432	+	return(vmin);
433	+	}
434	+
435	+
436	+	static double
437	+	l_rand(char nm) / random function between 0 and 1 */
438	+	{
439		double x;
440
441		x = argument(1);
#	Line 411 \| Line 447 \| *l_rand() / random function between 0 and 1 /*
447
448
449		static double
450	<	l_floor() /* return largest integer not greater than arg1 */
450	>	l_floor(char nm) / return largest integer not greater than arg1 */
451		{
452		return(floor(argument(1)));
453		}
454
455
456		static double
457	<	l_ceil() /* return smallest integer not less than arg1 */
457	>	l_ceil(char nm) / return smallest integer not less than arg1 */
458		{
459		return(ceil(argument(1)));
460		}
461
462
463		static double
464	<	l_sqrt()
464	>	l_sqrt(char *nm)
465		{
466		return(sqrt(argument(1)));
467		}
468
469
470		static double
471	<	l_sin()
471	>	l_sin(char *nm)
472		{
473		return(sin(argument(1)));
474		}
475
476
477		static double
478	<	l_cos()
478	>	l_cos(char *nm)
479		{
480		return(cos(argument(1)));
481		}
482
483
484		static double
485	<	l_tan()
485	>	l_tan(char *nm)
486		{
487		return(tan(argument(1)));
488		}
489
490
491		static double
492	<	l_asin()
492	>	l_asin(char *nm)
493		{
494		return(asin(argument(1)));
495		}
496
497
498		static double
499	<	l_acos()
499	>	l_acos(char *nm)
500		{
501		return(acos(argument(1)));
502		}
503
504
505		static double
506	<	l_atan()
506	>	l_atan(char *nm)
507		{
508		return(atan(argument(1)));
509		}
510
511
512		static double
513	<	l_atan2()
513	>	l_atan2(char *nm)
514		{
515		return(atan2(argument(1), argument(2)));
516		}
517
518
519		static double
520	<	l_exp()
520	>	l_exp(char *nm)
521		{
522		return(exp(argument(1)));
523		}
524
525
526		static double
527	<	l_log()
527	>	l_log(char *nm)
528		{
529		return(log(argument(1)));
530		}
531
532
533		static double
534	<	l_log10()
534	>	l_log10(char *nm)
535		{
536		return(log10(argument(1)));
537		}

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Comparing ray/src/common/calfunc.c (file contents): Revision 2.11 by schorsch, Sat Jun 7 12:50:20 2003 UTC vs. Revision 2.29 by greg, Sun Feb 25 18:36:27 2024 UTC

Diff Legend

Comparing ray/src/common/calfunc.c (file contents):
Revision 2.11 by schorsch, Sat Jun 7 12:50:20 2003 UTC vs.
Revision 2.29 by greg, Sun Feb 25 18:36:27 2024 UTC