[ViewVC] Diff of: radiance/ray/src/gen/gensurf.c

Comparing ray/src/gen/gensurf.c (file contents):
Revision 2.2 by greg, Thu Jan 30 14:11:39 1992 UTC vs.
Revision 2.28 by greg, Sat Nov 14 00:29:51 2020 UTC

#	Line 1 \| Line 1
1		#ifndef lint
2	<	static char SCCSid[] = "$SunId$ LBL";
2	>	static const char RCSid[] = "$Id$";
3		#endif
4	–
5	–	/* Copyright (c) 1989 Regents of the University of California */
6	–
4		/*
5		* gensurf.c - program to generate functional surfaces
6		*
#	Line 14 \| Line 11 \| static char SCCSid[] = "$SunId$ LBL";
11		* rule applied to (s,t).
12		*
13		* 4/3/87
14	+	*
15	+	* 4/16/02 Added conditional vertex output
16		*/
17
18		#include "standard.h"
19
20	<	char XNAME[] = "X`SYS`"; /* x function name */
21	<	char YNAME[] = "Y`SYS`"; /* y function name */
22	<	char ZNAME[] = "Z`SYS`"; /* z function name */
20	>	#include "paths.h"
21	>	#include "resolu.h"
22	>	#include "rterror.h"
23	>	#include "calcomp.h"
24
25	+	char XNAME[] = "X`SYS"; /* x function name */
26	+	char YNAME[] = "Y`SYS"; /* y function name */
27	+	char ZNAME[] = "Z`SYS"; /* z function name */
28	+
29	+	char VNAME[] = "valid"; /* valid vertex name */
30	+
31		#define ABS(x) ((x)>=0 ? (x) : -(x))
32
33	+	#define ZEROVECT(v) (DOT(v,v) <= FTINY*FTINY)
34	+
35		#define pvect(p) printf(vformat, (p)[0], (p)[1], (p)[2])
36
37	<	char vformat[] = "%15.9g %15.9g %15.9g\n";
38	<	char tsargs[] = "4 surf_dx surf_dy surf_dz surf.cal\n";
37	>	char vformat[] = "%18.12g %18.12g %18.12g\n";
38	>	char tsargs[] = "4 surf_dx surf_dy surf_dz surf.cal";
39		char texname[] = "Phong";
40
41		int smooth = 0; /* apply smoothing? */
42	+	int objout = 0; /* output .OBJ format? */
43
44		char modname, surfname;
45
#	Line 41 \| Line 50 \| *char modname, surfname;*
50		struct {
51		int flags; /* data type */
52		short m, n; /* number of s and t values */
53	<	FLOAT data; / the data itself, s major sort */
53	>	RREAL data; / the data itself, s major sort */
54		} datarec; /* our recorded data */
55
56	+	/* XXX this is redundant with rt/noise3.c, should go to a library */
57		double l_hermite(), l_bezier(), l_bspline(), l_dataval();
48	–	extern double funvalue(), argument();
58
59		typedef struct {
60	+	int valid; /* point is valid (vertex number) */
61	+	int nvalid; /* normal is valid */
62		FVECT p; /* vertex position */
63		FVECT n; /* average normal */
64	+	RREAL uv[2]; /* (u,v) position */
65		} POINT;
66
67	+	int nverts = 0; /* vertex output count */
68	+	int nnorms = 0; /* normal output count */
69
70	<	main(argc, argv)
71	<	int argc;
72	<	char *argv[];
70	>	void loaddata(char *file, int m, int n, int pointsize);
71	>	double l_dataval(char *nam);
72	>	void putobjrow(POINT *rp, int n);
73	>	void putobjvert(POINT *p);
74	>	void putsquare(POINT p0, POINT p1, POINT p2, POINT p3);
75	>	void comprow(double s, POINT *row, int siz);
76	>	void compnorms(POINT r0, POINT r1, POINT *r2, int siz);
77	>	int norminterp(FVECT resmat[4], POINT p0, POINT p1, POINT p2, POINT p3);
78	>
79	>
80	>	int
81	>	main(int argc, char *argv[])
82		{
60	–	extern long eclock;
83		POINT row0, row1, row2, rp;
84		int i, j, m, n;
85		char stmp[256];
86
87	+	esupport \|= E_VARIABLE\|E_FUNCTION\|E_RCONST;
88	+	esupport &= ~(E_OUTCHAN\|E_INCHAN);
89		varset("PI", ':', PI);
90		funset("hermite", 5, ':', l_hermite);
91		funset("bezier", 5, ':', l_bezier);
#	Line 73 \| Line 97 \| *char argv[];**
97		for (i = 8; i < argc; i++)
98		if (!strcmp(argv[i], "-e"))
99		scompile(argv[++i], NULL, 0);
100	<	else if (!strcmp(argv[i], "-f"))
101	<	fcompile(argv[++i]);
102	<	else if (!strcmp(argv[i], "-s"))
100	>	else if (!strcmp(argv[i], "-f")) {
101	>	char *fpath = getpath(argv[++i], getrlibpath(), 0);
102	>	if (fpath == NULL) {
103	>	fprintf(stderr, "%s: cannot find file '%s'\n",
104	>	argv[0], argv[i]);
105	>	quit(1);
106	>	}
107	>	fcompile(fpath);
108	>	} else if (!strcmp(argv[i], "-s"))
109		smooth++;
110	+	else if (!strcmp(argv[i], "-o"))
111	+	objout++;
112		else
113		goto userror;
114
115		modname = argv[1];
116		surfname = argv[2];
117	<	m = atoi(argv[6]);
118	<	n = atoi(argv[7]);
117	>	m = eval(argv[6]) + .5;
118	>	n = eval(argv[7]) + .5;
119		if (m <= 0 \|\| n <= 0)
120		goto userror;
121		if (!strcmp(argv[5], "-") \|\| access(argv[5], 4) == 0) { /* file? */
#	Line 116 \| Line 148 \| *char argv[];**
148		}
149		row0++; row1++; row2++;
150		/* print header */
151	<	printhead(argc, argv);
151	>	fputs("# ", stdout);
152	>	printargs(argc, argv, stdout);
153		eclock = 0;
154		/* initialize */
155		comprow(-1.0/m, row0, n);
156		comprow(0.0, row1, n);
157		comprow(1.0/m, row2, n);
158		compnorms(row0, row1, row2, n);
159	+	if (objout) {
160	+	printf("\nusemtl %s\n\n", modname);
161	+	printf("o %s\n\n", surfname);
162	+	putobjrow(row1, n);
163	+	}
164		/* for each row */
165		for (i = 0; i < m; i++) {
166		/* compute next row */
#	Line 132 \| Line 170 \| *char argv[];**
170		row2 = rp;
171		comprow((double)(i+2)/m, row2, n);
172		compnorms(row0, row1, row2, n);
173	+	if (objout)
174	+	putobjrow(row1, n);
175
176		for (j = 0; j < n; j++) {
177	+	int orient = (j & 1);
178		/* put polygons */
179	<	if ((i+j) & 1)
179	>	if (!(row0[j].valid && row1[j+1].valid))
180	>	orient = 1;
181	>	else if (!(row1[j].valid && row0[j+1].valid))
182	>	orient = 0;
183	>	if (orient)
184		putsquare(&row0[j], &row1[j],
185		&row0[j+1], &row1[j+1]);
186		else
#	Line 144 \| Line 189 \| *char argv[];**
189		}
190		}
191
192	<	quit(0);
192	>	return 0;
193
194		userror:
195		fprintf(stderr, "Usage: %s material name ", argv[0]);
196	<	fprintf(stderr, "x(s,t) y(s,t) z(s,t) m n [-s][-e expr][-f file]\n");
197	<	quit(1);
196	>	fprintf(stderr, "x(s,t) y(s,t) z(s,t) m n [-s][-o][-e expr][-f file]\n");
197	>	return 1;
198		}
199
200
201	<	loaddata(file, m, n, pointsize) /* load point data from file */
202	<	char *file;
203	<	int m, n;
204	<	int pointsize;
201	>	void
202	>	loaddata( /* load point data from file */
203	>	char *file,
204	>	int m,
205	>	int n,
206	>	int pointsize
207	>	)
208		{
161	–	extern char *fgetword();
209		FILE *fp;
210		char word[64];
211	<	register int size;
212	<	register FLOAT *dp;
211	>	int size;
212	>	RREAL *dp;
213
214		datarec.flags = HASBORDER; /* assume border values */
215	<	size = (m+1)(n+1)pointsize;
215	>	datarec.m = m+1;
216	>	datarec.n = n+1;
217	>	size = datarec.mdatarec.npointsize;
218		if (pointsize == 3)
219		datarec.flags \|= TRIPLETS;
220	<	dp = (FLOAT )malloc(sizesizeof(FLOAT));
220	>	dp = (RREAL )malloc(sizesizeof(RREAL));
221		if ((datarec.data = dp) == NULL) {
222		fputs("Out of memory\n", stderr);
223		exit(1);
#	Line 191 \| Line 240 \| int pointsize;
240		size--;
241		}
242		if (size == (m+n+1)pointsize) { / no border after all */
243	<	dp = (FLOAT )realloc((char )datarec.data,
244	<	mnpointsize*sizeof(FLOAT));
243	>	dp = (RREAL *)realloc(datarec.data,
244	>	mnpointsize*sizeof(RREAL));
245		if (dp != NULL)
246		datarec.data = dp;
247		datarec.flags &= ~HASBORDER;
248	+	datarec.m = m;
249	+	datarec.n = n;
250		size = 0;
251		}
252	<	if (size \|\| fgetword(word, sizeof(word), fp) != NULL) {
252	>	if (datarec.m < 2 \|\| datarec.n < 2 \|\| size != 0 \|\|
253	>	fgetword(word, sizeof(word), fp) != NULL) {
254		fputs(file, stderr);
255		fputs(": bad number of data points\n", stderr);
256		exit(1);
#	Line 208 \| Line 260 \| int pointsize;
260
261
262		double
263	<	l_dataval(nam) /* return recorded data value */
264	<	char *nam;
263	>	l_dataval( /* return recorded data value */
264	>	char *nam
265	>	)
266		{
267		double u, v;
268	<	register int i, j;
269	<	register FLOAT *dp;
268	>	int i, j;
269	>	RREAL *dp;
270		double d00, d01, d10, d11;
271		/* compute coordinates */
272		u = argument(1); v = argument(2);
273		if (datarec.flags & HASBORDER) {
274	<	i = u *= datarec.m;
275	<	j = v *= datarec.n;
274	>	i = u *= datarec.m-1;
275	>	j = v *= datarec.n-1;
276		} else {
277	<	i = u = u*(datarec.m+1) - .5;
278	<	j = v = v*(datarec.n+1) - .5;
277	>	i = u = u*datarec.m - .5;
278	>	j = v = v*datarec.n - .5;
279		}
280		if (i < 0) i = 0;
281		else if (i > datarec.m-2) i = datarec.m-2;
#	Line 230 \| Line 283 \| *char nam;**
283		else if (j > datarec.n-2) j = datarec.n-2;
284		/* compute value */
285		if (datarec.flags & TRIPLETS) {
286	<	dp = datarec.data + 3(jdatarec.n + i);
287	<	if (nam == YNAME)
235	<	dp++;
236	<	else if (nam == ZNAME)
286	>	dp = datarec.data + 3(jdatarec.m + i);
287	>	if (nam == ZNAME)
288		dp += 2;
289	+	else if (nam == YNAME)
290	+	dp++;
291		d00 = dp[0]; d01 = dp[3];
292	<	dp += 3*datarec.n;
292	>	dp += 3*datarec.m;
293		d10 = dp[0]; d11 = dp[3];
294		} else {
295	<	dp = datarec.data + j*datarec.n + i;
295	>	dp = datarec.data + j*datarec.m + i;
296		d00 = dp[0]; d01 = dp[1];
297	<	dp += datarec.n;
297	>	dp += datarec.m;
298		d10 = dp[0]; d11 = dp[1];
299		}
300		/* bilinear interpolation */
#	Line 249 \| Line 302 \| *char nam;**
302		}
303
304
305	<	putsquare(p0, p1, p2, p3) /* put out a square */
306	<	POINT p0, p1, p2, p3;
305	>	void
306	>	putobjrow( /* output vertex row to .OBJ */
307	>	POINT *rp,
308	>	int n
309	>	)
310		{
311	+	for ( ; n-- >= 0; rp++) {
312	+	if (!rp->valid)
313	+	continue;
314	+	fputs("v ", stdout);
315	+	pvect(rp->p);
316	+	if (smooth && !ZEROVECT(rp->n)) {
317	+	printf("\tvn %.9g %.9g %.9g\n",
318	+	rp->n[0], rp->n[1], rp->n[2]);
319	+	rp->nvalid = ++nnorms;
320	+	} else
321	+	rp->nvalid = 0;
322	+	printf("\tvt %.9g %.9g\n", rp->uv[0], rp->uv[1]);
323	+	rp->valid = ++nverts;
324	+	}
325	+	}
326	+
327	+
328	+	void
329	+	putobjvert( /* put out OBJ vertex index triplet */
330	+	POINT *p
331	+	)
332	+	{
333	+	int pti = p->valid ? p->valid-nverts-1 : 0;
334	+	int ni = p->nvalid ? p->nvalid-nnorms-1 : 0;
335	+
336	+	printf(" %d/%d/%d", pti, pti, ni);
337	+	}
338	+
339	+
340	+	void
341	+	putsquare( /* put out a square */
342	+	POINT *p0,
343	+	POINT *p1,
344	+	POINT *p2,
345	+	POINT *p3
346	+	)
347	+	{
348		static int nout = 0;
349		FVECT norm[4];
350		int axis;
351		FVECT v1, v2, vc1, vc2;
352		int ok1, ok2;
353		/* compute exact normals */
354	<	fvsum(v1, p1->p, p0->p, -1.0);
355	<	fvsum(v2, p2->p, p0->p, -1.0);
356	<	fcross(vc1, v1, v2);
357	<	ok1 = normalize(vc1) != 0.0;
358	<	fvsum(v1, p2->p, p3->p, -1.0);
359	<	fvsum(v2, p1->p, p3->p, -1.0);
360	<	fcross(vc2, v1, v2);
361	<	ok2 = normalize(vc2) != 0.0;
354	>	ok1 = (p0->valid && p1->valid && p2->valid);
355	>	if (ok1) {
356	>	VSUB(v1, p1->p, p0->p);
357	>	VSUB(v2, p2->p, p0->p);
358	>	fcross(vc1, v1, v2);
359	>	ok1 = (normalize(vc1) != 0.0);
360	>	}
361	>	ok2 = (p1->valid && p2->valid && p3->valid);
362	>	if (ok2) {
363	>	VSUB(v1, p2->p, p3->p);
364	>	VSUB(v2, p1->p, p3->p);
365	>	fcross(vc2, v1, v2);
366	>	ok2 = (normalize(vc2) != 0.0);
367	>	}
368		if (!(ok1 \| ok2))
369		return;
370	+	if (objout) { /* output .OBJ faces */
371	+	if (ok1 & ok2 && fdot(vc1,vc2) >= 1.0-FTINY*FTINY) {
372	+	putc('f', stdout);
373	+	putobjvert(p0); putobjvert(p1);
374	+	putobjvert(p3); putobjvert(p2);
375	+	putc('\n', stdout);
376	+	return;
377	+	}
378	+	if (ok1) {
379	+	putc('f', stdout);
380	+	putobjvert(p0); putobjvert(p1); putobjvert(p2);
381	+	putc('\n', stdout);
382	+	}
383	+	if (ok2) {
384	+	putc('f', stdout);
385	+	putobjvert(p2); putobjvert(p1); putobjvert(p3);
386	+	putc('\n', stdout);
387	+	}
388	+	return;
389	+	}
390		/* compute normal interpolation */
391		axis = norminterp(norm, p0, p1, p2, p3);
392
#	Line 275 \| Line 394 \| *POINT p0, p1, p2, p3;*
394		if (ok1 & ok2 && fdot(vc1,vc2) >= 1.0-FTINY*FTINY) {
395		printf("\n%s ", modname);
396		if (axis != -1) {
397	<	printf("texfunc %s\n", texname);
279	<	printf(tsargs);
397	>	printf("texfunc %s\n%s\n", texname, tsargs);
398		printf("0\n13\t%d\n", axis);
399		pvect(norm[0]);
400		pvect(norm[1]);
#	Line 298 \| Line 416 \| *POINT p0, p1, p2, p3;*
416		if (ok1) {
417		printf("\n%s ", modname);
418		if (axis != -1) {
419	<	printf("texfunc %s\n", texname);
302	<	printf(tsargs);
419	>	printf("texfunc %s\n%s\n", texname, tsargs);
420		printf("0\n13\t%d\n", axis);
421		pvect(norm[0]);
422		pvect(norm[1]);
#	Line 317 \| Line 434 \| *POINT p0, p1, p2, p3;*
434		if (ok2) {
435		printf("\n%s ", modname);
436		if (axis != -1) {
437	<	printf("texfunc %s\n", texname);
321	<	printf(tsargs);
437	>	printf("texfunc %s\n%s\n", texname, tsargs);
438		printf("0\n13\t%d\n", axis);
439		pvect(norm[0]);
440		pvect(norm[1]);
#	Line 336 \| Line 452 \| *POINT p0, p1, p2, p3;*
452		}
453
454
455	<	comprow(s, row, siz) /* compute row of values */
456	<	double s;
457	<	register POINT *row;
458	<	int siz;
455	>	void
456	>	comprow( /* compute row of values */
457	>	double s,
458	>	POINT *row,
459	>	int siz
460	>	)
461		{
462		double st[2];
463		int end;
464	<	register int i;
464	>	int checkvalid;
465	>	int i;
466
467		if (smooth) {
468		i = -1; /* compute one past each end */
#	Line 355 \| Line 474 \| int siz;
474		end = siz;
475		}
476		st[0] = s;
477	+	checkvalid = (fundefined(VNAME) == 2);
478		while (i <= end) {
479		st[1] = (double)i/siz;
480	<	row[i].p[0] = funvalue(XNAME, 2, st);
481	<	row[i].p[1] = funvalue(YNAME, 2, st);
482	<	row[i].p[2] = funvalue(ZNAME, 2, st);
480	>	if (checkvalid && funvalue(VNAME, 2, st) <= 0.0) {
481	>	row[i].valid = 0;
482	>	row[i].p[0] = row[i].p[1] = row[i].p[2] = 0.0;
483	>	row[i].uv[0] = row[i].uv[1] = 0.0;
484	>	} else {
485	>	row[i].valid = 1;
486	>	row[i].p[0] = funvalue(XNAME, 2, st);
487	>	row[i].p[1] = funvalue(YNAME, 2, st);
488	>	row[i].p[2] = funvalue(ZNAME, 2, st);
489	>	row[i].uv[0] = st[0];
490	>	row[i].uv[1] = st[1];
491	>	}
492		i++;
493		}
494		}
495
496
497	<	compnorms(r0, r1, r2, siz) /* compute row of averaged normals */
498	<	register POINT r0, r1, *r2;
499	<	int siz;
497	>	void
498	>	compnorms( /* compute row of averaged normals */
499	>	POINT *r0,
500	>	POINT *r1,
501	>	POINT *r2,
502	>	int siz
503	>	)
504		{
505		FVECT v1, v2;
373	–	register int i;
506
507		if (!smooth) /* not needed if no smoothing */
508		return;
509	<	/* compute middle points */
509	>	/* compute row 1 normals */
510		while (siz-- >= 0) {
511	<	fvsum(v1, r2[0].p, r0[0].p, -1.0);
512	<	fvsum(v2, r1[1].p, r1[-1].p, -1.0);
511	>	if (!r1[0].valid)
512	>	goto skip;
513	>	if (!r0[0].valid) {
514	>	if (!r2[0].valid) {
515	>	r1[0].n[0] = r1[0].n[1] = r1[0].n[2] = 0.0;
516	>	goto skip;
517	>	}
518	>	fvsum(v1, r2[0].p, r1[0].p, -1.0);
519	>	} else if (!r2[0].valid)
520	>	fvsum(v1, r1[0].p, r0[0].p, -1.0);
521	>	else
522	>	fvsum(v1, r2[0].p, r0[0].p, -1.0);
523	>	if (!r1[-1].valid) {
524	>	if (!r1[1].valid) {
525	>	r1[0].n[0] = r1[0].n[1] = r1[0].n[2] = 0.0;
526	>	goto skip;
527	>	}
528	>	fvsum(v2, r1[1].p, r1[0].p, -1.0);
529	>	} else if (!r1[1].valid)
530	>	fvsum(v2, r1[0].p, r1[-1].p, -1.0);
531	>	else
532	>	fvsum(v2, r1[1].p, r1[-1].p, -1.0);
533		fcross(r1[0].n, v1, v2);
534		normalize(r1[0].n);
535	+	skip:
536		r0++; r1++; r2++;
537		}
538		}
539
540
541		int
542	<	norminterp(resmat, p0, p1, p2, p3) /* compute normal interpolation */
543	<	register FVECT resmat[4];
544	<	POINT p0, p1, p2, p3;
542	>	norminterp( /* compute normal interpolation */
543	>	FVECT resmat[4],
544	>	POINT *p0,
545	>	POINT *p1,
546	>	POINT *p2,
547	>	POINT *p3
548	>	)
549		{
550		#define u ((ax+1)%3)
551		#define v ((ax+2)%3)
552
553	<	register int ax;
553	>	int ax;
554		MAT4 eqnmat;
555		FVECT v1;
556	<	register int i, j;
556	>	int i, j;
557
558		if (!smooth) /* no interpolation if no smoothing */
559		return(-1);
#	Line 425 \| Line 582 \| *POINT p0, p1, p2, p3;*
582		eqnmat[3][2] = p3->p[v];
583		eqnmat[3][3] = 1.0;
584		/* invert matrix (solve system) */
585	<	if (!invmat(eqnmat, eqnmat))
585	>	if (!invmat4(eqnmat, eqnmat))
586		return(-1); /* no solution */
587		/* compute result matrix */
588		for (j = 0; j < 4; j++)
#	Line 441 \| Line 598 \| *POINT p0, p1, p2, p3;*
598		}
599
600
444	–	/*
445	–	* invmat - computes the inverse of mat into inverse. Returns 1
446	–	* if there exists an inverse, 0 otherwise. It uses Gaussian Elimination
447	–	* method.
448	–	*/
449	–
450	–	invmat(inverse,mat)
451	–	MAT4 inverse, mat;
452	–	{
453	–	#define SWAP(a,b,t) (t=a,a=b,b=t)
454	–
455	–	MAT4 m4tmp;
456	–	register int i,j,k;
457	–	register double temp;
458	–
459	–	copymat4(m4tmp, mat);
460	–	/* set inverse to identity */
461	–	for (i = 0; i < 4; i++)
462	–	for (j = 0; j < 4; j++)
463	–	inverse[i][j] = i==j ? 1.0 : 0.0;
464	–
465	–	for(i = 0; i < 4; i++) {
466	–	/* Look for row with largest pivot and swap rows */
467	–	temp = FTINY; j = -1;
468	–	for(k = i; k < 4; k++)
469	–	if(ABS(m4tmp[k][i]) > temp) {
470	–	temp = ABS(m4tmp[k][i]);
471	–	j = k;
472	–	}
473	–	if(j == -1) /* No replacing row -> no inverse */
474	–	return(0);
475	–	if (j != i)
476	–	for(k = 0; k < 4; k++) {
477	–	SWAP(m4tmp[i][k],m4tmp[j][k],temp);
478	–	SWAP(inverse[i][k],inverse[j][k],temp);
479	–	}
480	–
481	–	temp = m4tmp[i][i];
482	–	for(k = 0; k < 4; k++) {
483	–	m4tmp[i][k] /= temp;
484	–	inverse[i][k] /= temp;
485	–	}
486	–	for(j = 0; j < 4; j++) {
487	–	if(j != i) {
488	–	temp = m4tmp[j][i];
489	–	for(k = 0; k < 4; k++) {
490	–	m4tmp[j][k] -= m4tmp[i][k]*temp;
491	–	inverse[j][k] -= inverse[i][k]*temp;
492	–	}
493	–	}
494	–	}
495	–	}
496	–	return(1);
497	–
498	–	#undef SWAP
499	–	}
500	–
501	–
502	–	eputs(msg)
503	–	char *msg;
504	–	{
505	–	fputs(msg, stderr);
506	–	}
507	–
508	–
509	–	wputs(msg)
510	–	char *msg;
511	–	{
512	–	eputs(msg);
513	–	}
514	–
515	–
516	–	quit(code)
517	–	{
518	–	exit(code);
519	–	}
520	–
521	–
522	–	printhead(ac, av) /* print command header */
523	–	register int ac;
524	–	register char **av;
525	–	{
526	–	putchar('#');
527	–	while (ac--) {
528	–	putchar(' ');
529	–	fputs(*av++, stdout);
530	–	}
531	–	putchar('\n');
532	–	}
533	–
534	–
601		double
602	<	l_hermite()
602	>	l_hermite(char *nm)
603		{
604		double t;
605
#	Line 546 \| Line 612 \| l_hermite()
612
613
614		double
615	<	l_bezier()
615	>	l_bezier(char *nm)
616		{
617		double t;
618
#	Line 559 \| Line 625 \| l_bezier()
625
626
627		double
628	<	l_bspline()
628	>	l_bspline(char *nm)
629		{
630		double t;
631

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Comparing ray/src/gen/gensurf.c (file contents): Revision 2.2 by greg, Thu Jan 30 14:11:39 1992 UTC vs. Revision 2.28 by greg, Sat Nov 14 00:29:51 2020 UTC

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Comparing ray/src/gen/gensurf.c (file contents):
Revision 2.2 by greg, Thu Jan 30 14:11:39 1992 UTC vs.
Revision 2.28 by greg, Sat Nov 14 00:29:51 2020 UTC