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

Comparing ray/src/common/image.c (file contents):
Revision 2.5 by greg, Tue Sep 8 10:04:30 1992 UTC vs.
Revision 2.38 by greg, Fri Nov 16 00:14:19 2012 UTC

#	Line 1 \| Line 1
1	–	/* Copyright (c) 1992 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		* image.c - routines for image generation.
6		*
7	<	* 10/17/85
7	>	* External symbols declared in view.h
8		*/
9
10	<	#include "standard.h"
10	>	#include "copyright.h"
11
12	+	#include <ctype.h>
13	+	#include "rtio.h"
14	+	#include "rtmath.h"
15	+	#include "paths.h"
16		#include "view.h"
17
17	–	#include "resolu.h"
18
19	<	#include "paths.h"
19	>	#define FEQ(x,y) (fabs((x)-(y)) <= FTINY)
20	>	#define VEQ(v,w) (FEQ((v)[0],(w)[0]) && FEQ((v)[1],(w)[1]) \
21	>	&& FEQ((v)[2],(w)[2]))
22
23		VIEW stdview = STDVIEW; /* default view parameters */
24
25	+	static gethfunc gethview;
26
27	+
28		char *
29	<	setview(v) /* set hvec and vvec, return message on error */
30	<	register VIEW *v;
29	>	setview( /* set hvec and vvec, return message on error */
30	>	VIEW *v
31	>	)
32		{
33		static char ill_horiz[] = "illegal horizontal view size";
34		static char ill_vert[] = "illegal vertical view size";
35
36	<	if (normalize(v->vdir) == 0.0) /* normalize direction */
36	>	if (v->vaft < -FTINY \|\| (v->vaft > FTINY && v->vaft <= v->vfore))
37	>	return("illegal fore/aft clipping plane");
38	>
39	>	if (v->vdist <= FTINY)
40	>	return("illegal view distance");
41	>	v->vdist = normalize(v->vdir); / normalize direction */
42	>	if (v->vdist == 0.0)
43		return("zero view direction");
44
45		if (normalize(v->vup) == 0.0) /* normalize view up */
#	Line 59 \| Line 70 \| *register VIEW v;**
70		v->hn2 = 2.0 * tan(v->horiz*(PI/180.0/2.0));
71		v->vn2 = 2.0 * tan(v->vert*(PI/180.0/2.0));
72		break;
73	+	case VT_CYL: /* cylindrical panorama */
74	+	if (v->horiz > 360.0+FTINY)
75	+	return(ill_horiz);
76	+	if (v->vert >= 180.0-FTINY)
77	+	return(ill_vert);
78	+	v->hn2 = v->horiz * (PI/180.0);
79	+	v->vn2 = 2.0 * tan(v->vert*(PI/180.0/2.0));
80	+	break;
81		case VT_ANG: /* angular fisheye */
82		if (v->horiz > 360.0+FTINY)
83		return(ill_horiz);
84		if (v->vert > 360.0+FTINY)
85		return(ill_vert);
86	<	v->hn2 = v->horiz / 90.0;
87	<	v->vn2 = v->vert / 90.0;
86	>	v->hn2 = v->horiz * (PI/180.0);
87	>	v->vn2 = v->vert * (PI/180.0);
88		break;
89		case VT_HEM: /* hemispherical fisheye */
90		if (v->horiz > 180.0+FTINY)
#	Line 75 \| Line 94 \| *register VIEW v;**
94		v->hn2 = 2.0 * sin(v->horiz*(PI/180.0/2.0));
95		v->vn2 = 2.0 * sin(v->vert*(PI/180.0/2.0));
96		break;
97	+	case VT_PLS: /* planispheric fisheye */
98	+	if (v->horiz >= 360.0-FTINY)
99	+	return(ill_horiz);
100	+	if (v->vert >= 360.0-FTINY)
101	+	return(ill_vert);
102	+	v->hn2 = 2.sin(v->horiz(PI/180.0/2.0)) /
103	+	(1.0 + cos(v->horiz*(PI/180.0/2.0)));
104	+	v->vn2 = 2.sin(v->vert(PI/180.0/2.0)) /
105	+	(1.0 + cos(v->vert*(PI/180.0/2.0)));
106	+	break;
107		default:
108		return("unknown view type");
109		}
110	<	if (v->type != VT_ANG) {
111	<	v->hvec[0] *= v->hn2;
112	<	v->hvec[1] *= v->hn2;
113	<	v->hvec[2] *= v->hn2;
110	>	if (v->type != VT_ANG && v->type != VT_PLS) {
111	>	if (v->type != VT_CYL) {
112	>	v->hvec[0] *= v->hn2;
113	>	v->hvec[1] *= v->hn2;
114	>	v->hvec[2] *= v->hn2;
115	>	}
116		v->vvec[0] *= v->vn2;
117		v->vvec[1] *= v->vn2;
118		v->vvec[2] *= v->vn2;
#	Line 93 \| Line 124 \| *register VIEW v;**
124		}
125
126
127	<	normaspect(va, ap, xp, yp) /* fix pixel aspect or resolution */
128	<	double va; /* view aspect ratio */
129	<	double ap; / pixel aspect in (or out if 0) */
130	<	int xp, yp; /* x and y resolution in (or out if ap!=0) /
127	>	void
128	>	normaspect( /* fix pixel aspect or resolution */
129	>	double va, /* view aspect ratio */
130	>	double ap, / pixel aspect in (or out if 0) */
131	>	int *xp,
132	>	int yp / x and y resolution in (or out if ap!=0) /
133	>	)
134		{
135		if (*ap <= FTINY)
136		ap = va xp / yp; /* compute pixel aspect */
#	Line 107 \| Line 141 \| int xp, yp; /* x and y resolution in (or out if *
141		}
142
143
144	<	viewray(orig, direc, v, x, y) /* compute ray origin and direction */
145	<	FVECT orig, direc;
146	<	register VIEW *v;
147	<	double x, y;
144	>	double
145	>	viewray( /* compute ray origin and direction */
146	>	FVECT orig,
147	>	FVECT direc,
148	>	VIEW *v,
149	>	double x,
150	>	double y
151	>	)
152		{
153		double d, z;
154
#	Line 119 \| Line 157 \| double x, y;
157
158		switch(v->type) {
159		case VT_PAR: /* parallel view */
160	<	orig[0] = v->vp[0] + xv->hvec[0] + yv->vvec[0];
161	<	orig[1] = v->vp[1] + xv->hvec[1] + yv->vvec[1];
162	<	orig[2] = v->vp[2] + xv->hvec[2] + yv->vvec[2];
160	>	orig[0] = v->vp[0] + v->vfore*v->vdir[0]
161	>	+ xv->hvec[0] + yv->vvec[0];
162	>	orig[1] = v->vp[1] + v->vfore*v->vdir[1]
163	>	+ xv->hvec[1] + yv->vvec[1];
164	>	orig[2] = v->vp[2] + v->vfore*v->vdir[2]
165	>	+ xv->hvec[2] + yv->vvec[2];
166		VCOPY(direc, v->vdir);
167	<	return(0);
167	>	return(v->vaft > FTINY ? v->vaft - v->vfore : 0.0);
168		case VT_PER: /* perspective view */
128	–	VCOPY(orig, v->vp);
169		direc[0] = v->vdir[0] + xv->hvec[0] + yv->vvec[0];
170		direc[1] = v->vdir[1] + xv->hvec[1] + yv->vvec[1];
171		direc[2] = v->vdir[2] + xv->hvec[2] + yv->vvec[2];
172	<	normalize(direc);
173	<	return(0);
172	>	orig[0] = v->vp[0] + v->vfore*direc[0];
173	>	orig[1] = v->vp[1] + v->vfore*direc[1];
174	>	orig[2] = v->vp[2] + v->vfore*direc[2];
175	>	d = normalize(direc);
176	>	return(v->vaft > FTINY ? (v->vaft - v->vfore)*d : 0.0);
177		case VT_HEM: /* hemispherical fisheye */
178		z = 1.0 - xxv->hn2 - yyv->vn2;
179		if (z < 0.0)
180	<	return(-1);
180	>	return(-1.0);
181		z = sqrt(z);
139	–	VCOPY(orig, v->vp);
182		direc[0] = zv->vdir[0] + xv->hvec[0] + y*v->vvec[0];
183		direc[1] = zv->vdir[1] + xv->hvec[1] + y*v->vvec[1];
184		direc[2] = zv->vdir[2] + xv->hvec[2] + y*v->vvec[2];
185	<	return(0);
185	>	orig[0] = v->vp[0] + v->vfore*direc[0];
186	>	orig[1] = v->vp[1] + v->vfore*direc[1];
187	>	orig[2] = v->vp[2] + v->vfore*direc[2];
188	>	return(v->vaft > FTINY ? v->vaft - v->vfore : 0.0);
189	>	case VT_CYL: /* cylindrical panorama */
190	>	d = x * v->horiz * (PI/180.0);
191	>	z = cos(d);
192	>	x = sin(d);
193	>	direc[0] = zv->vdir[0] + xv->hvec[0] + y*v->vvec[0];
194	>	direc[1] = zv->vdir[1] + xv->hvec[1] + y*v->vvec[1];
195	>	direc[2] = zv->vdir[2] + xv->hvec[2] + y*v->vvec[2];
196	>	orig[0] = v->vp[0] + v->vfore*direc[0];
197	>	orig[1] = v->vp[1] + v->vfore*direc[1];
198	>	orig[2] = v->vp[2] + v->vfore*direc[2];
199	>	d = normalize(direc);
200	>	return(v->vaft > FTINY ? (v->vaft - v->vfore)*d : 0.0);
201		case VT_ANG: /* angular fisheye */
202	<	x *= v->horiz/180.0;
203	<	y *= v->vert/180.0;
202	>	x = (1.0/180.0)v->horiz;
203	>	y = (1.0/180.0)v->vert;
204		d = xx + yy;
205		if (d > 1.0)
206	<	return(-1);
150	<	VCOPY(orig, v->vp);
151	<	if (d <= FTINY) {
152	<	VCOPY(direc, v->vdir);
153	<	return(0);
154	<	}
206	>	return(-1.0);
207		d = sqrt(d);
208		z = cos(PI*d);
209	<	d = sqrt(1 - z*z)/d;
209	>	d = d <= FTINY ? PI : sqrt(1.0 - z*z)/d;
210		x *= d;
211		y *= d;
212		direc[0] = zv->vdir[0] + xv->hvec[0] + y*v->vvec[0];
213		direc[1] = zv->vdir[1] + xv->hvec[1] + y*v->vvec[1];
214		direc[2] = zv->vdir[2] + xv->hvec[2] + y*v->vvec[2];
215	<	return(0);
215	>	orig[0] = v->vp[0] + v->vfore*direc[0];
216	>	orig[1] = v->vp[1] + v->vfore*direc[1];
217	>	orig[2] = v->vp[2] + v->vfore*direc[2];
218	>	return(v->vaft > FTINY ? v->vaft - v->vfore : 0.0);
219	>	case VT_PLS: /* planispheric fisheye */
220	>	x *= sqrt(v->hn2);
221	>	y *= sqrt(v->vn2);
222	>	d = xx + yy;
223	>	z = (1. - d)/(1. + d);
224	>	x *= (1. + z);
225	>	y *= (1. + z);
226	>	direc[0] = zv->vdir[0] + xv->hvec[0] + y*v->vvec[0];
227	>	direc[1] = zv->vdir[1] + xv->hvec[1] + y*v->vvec[1];
228	>	direc[2] = zv->vdir[2] + xv->hvec[2] + y*v->vvec[2];
229	>	orig[0] = v->vp[0] + v->vfore*direc[0];
230	>	orig[1] = v->vp[1] + v->vfore*direc[1];
231	>	orig[2] = v->vp[2] + v->vfore*direc[2];
232	>	return(v->vaft > FTINY ? v->vaft - v->vfore : 0.0);
233		}
234	<	return(-1);
234	>	return(-1.0);
235		}
236
237
238	<	viewloc(ip, v, p) /* find image location for point */
239	<	FVECT ip;
240	<	register VIEW *v;
241	<	FVECT p;
238	>	void
239	>	viewloc( /* find image location for point */
240	>	FVECT ip,
241	>	VIEW *v,
242	>	FVECT p
243	>	)
244		{
245	<	double d;
245	>	double d, d2;
246		FVECT disp;
247
248	<	disp[0] = p[0] - v->vp[0];
178	<	disp[1] = p[1] - v->vp[1];
179	<	disp[2] = p[2] - v->vp[2];
248	>	VSUB(disp, p, v->vp);
249
250		switch (v->type) {
251		case VT_PAR: /* parallel view */
252	<	ip[2] = DOT(disp,v->vdir);
252	>	ip[2] = DOT(disp,v->vdir) - v->vfore;
253		break;
254		case VT_PER: /* perspective view */
255		d = DOT(disp,v->vdir);
256	<	ip[2] = sqrt(DOT(disp,disp));
256	>	ip[2] = VLEN(disp);
257		if (d < 0.0) { /* fold pyramid */
258		ip[2] = -ip[2];
259		d = -d;
260	<	} else if (d > FTINY) {
260	>	}
261	>	if (d > FTINY) {
262		d = 1.0/d;
263		disp[0] *= d;
264		disp[1] *= d;
265		disp[2] *= d;
266		}
267	+	ip[2] = (1.0 - v->vfored);
268		break;
269		case VT_HEM: /* hemispherical fisheye */
270		d = normalize(disp);
#	Line 201 \| Line 272 \| FVECT p;
272		ip[2] = -d;
273		else
274		ip[2] = d;
275	+	ip[2] -= v->vfore;
276		break;
277	+	case VT_CYL: /* cylindrical panorama */
278	+	d = DOT(disp,v->hvec);
279	+	d2 = DOT(disp,v->vdir);
280	+	ip[0] = 180.0/PI * atan2(d,d2) / v->horiz + 0.5 - v->hoff;
281	+	d = 1.0/sqrt(dd + d2d2);
282	+	ip[1] = DOT(disp,v->vvec)*d/v->vn2 + 0.5 - v->voff;
283	+	ip[2] = VLEN(disp);
284	+	ip[2] = (1.0 - v->vfored);
285	+	return;
286		case VT_ANG: /* angular fisheye */
287		ip[0] = 0.5 - v->hoff;
288		ip[1] = 0.5 - v->voff;
289	<	ip[2] = normalize(disp);
289	>	ip[2] = normalize(disp) - v->vfore;
290		d = DOT(disp,v->vdir);
291		if (d >= 1.0-FTINY)
292		return;
293		if (d <= -(1.0-FTINY)) {
294	<	ip[1] += 180.0/v->horiz;
214	<	ip[2] += 180.0/v->vert;
294	>	ip[0] += 180.0/v->horiz;
295		return;
296		}
297	<	d = acos(d)/PI / sqrt(1.0 - d*d);
298	<	ip[0] += DOT(disp,v->hvec)d180.0/v->horiz;
299	<	ip[1] += DOT(disp,v->vvec)d180.0/v->vert;
297	>	d = (180.0/PI)acos(d) / sqrt(1.0 - dd);
298	>	ip[0] += DOT(disp,v->hvec)*d/v->horiz;
299	>	ip[1] += DOT(disp,v->vvec)*d/v->vert;
300		return;
301	+	case VT_PLS: /* planispheric fisheye */
302	+	ip[0] = 0.5 - v->hoff;
303	+	ip[1] = 0.5 - v->voff;
304	+	ip[2] = normalize(disp) - v->vfore;
305	+	d = DOT(disp,v->vdir);
306	+	if (d >= 1.0-FTINY)
307	+	return;
308	+	if (d <= -(1.0-FTINY))
309	+	return; /* really an error */
310	+	ip[0] += DOT(disp,v->hvec)/((1. + d)*sqrt(v->hn2));
311	+	ip[1] += DOT(disp,v->vvec)/((1. + d)*sqrt(v->vn2));
312	+	return;
313		}
314		ip[0] = DOT(disp,v->hvec)/v->hn2 + 0.5 - v->hoff;
315		ip[1] = DOT(disp,v->vvec)/v->vn2 + 0.5 - v->voff;
316		}
317
318
319	<	pix2loc(loc, rp, px, py) /* compute image location from pixel pos. */
320	<	FLOAT loc[2];
321	<	register RESOLU *rp;
322	<	int px, py;
319	>	void
320	>	pix2loc( /* compute image location from pixel pos. */
321	>	RREAL loc[2],
322	>	RESOLU *rp,
323	>	int px,
324	>	int py
325	>	)
326		{
327	<	register int x, y;
327	>	int x, y;
328
329	<	if (rp->or & YMAJOR) {
329	>	if (rp->rt & YMAJOR) {
330		x = px;
331		y = py;
332		} else {
333		x = py;
334		y = px;
335		}
336	<	if (rp->or & XDECR)
336	>	if (rp->rt & XDECR)
337		x = rp->xr-1 - x;
338	<	if (rp->or & YDECR)
338	>	if (rp->rt & YDECR)
339		y = rp->yr-1 - y;
340		loc[0] = (x+.5)/rp->xr;
341		loc[1] = (y+.5)/rp->yr;
342		}
343
344
345	<	loc2pix(pp, rp, lx, ly) /* compute pixel pos. from image location */
346	<	int pp[2];
347	<	register RESOLU *rp;
348	<	double lx, ly;
345	>	void
346	>	loc2pix( /* compute pixel pos. from image location */
347	>	int pp[2],
348	>	RESOLU *rp,
349	>	double lx,
350	>	double ly
351	>	)
352		{
353	<	register int x, y;
353	>	int x, y;
354
355	<	x = lx * rp->xr;
356	<	y = ly * rp->yr;
357	<	if (rp->or & XDECR)
355	>	x = (int)(lx*rp->xr + .5 - (lx < 0.0));
356	>	y = (int)(ly*rp->yr + .5 - (ly < 0.0));
357	>
358	>	if (rp->rt & XDECR)
359		x = rp->xr-1 - x;
360	<	if (rp->or & YDECR)
360	>	if (rp->rt & YDECR)
361		y = rp->yr-1 - y;
362	<	if (rp->or & YMAJOR) {
362	>	if (rp->rt & YMAJOR) {
363		pp[0] = x;
364		pp[1] = y;
365		} else {
#	Line 271 \| Line 370 \| double lx, ly;
370
371
372		int
373	<	getviewopt(v, ac, av) /* process view argument */
374	<	register VIEW *v;
375	<	int ac;
376	<	register char *av[];
373	>	getviewopt( /* process view argument */
374	>	VIEW *v,
375	>	int ac,
376	>	char *av[]
377	>	)
378		{
379		#define check(c,l) if ((av[0][c]&&av[0][c]!=' ') \|\| \
380		badarg(ac-1,av+1,l)) return(-1)
#	Line 299 \| Line 399 \| *register char av[];**
399		v->vdir[0] = atof(av[1]);
400		v->vdir[1] = atof(av[2]);
401		v->vdir[2] = atof(av[3]);
402	+	v->vdist = 1.;
403		return(3);
404		case 'u': /* up */
405		check(3,"fff");
#	Line 314 \| Line 415 \| *register char av[];**
415		check(3,"f");
416		v->vert = atof(av[1]);
417		return(1);
418	+	case 'o': /* fore clipping plane */
419	+	check(3,"f");
420	+	v->vfore = atof(av[1]);
421	+	return(1);
422	+	case 'a': /* aft clipping plane */
423	+	check(3,"f");
424	+	v->vaft = atof(av[1]);
425	+	return(1);
426		case 's': /* shift */
427		check(3,"f");
428		v->hoff = atof(av[1]);
#	Line 330 \| Line 439 \| *register char av[];**
439
440
441		int
442	<	sscanview(vp, s) /* get view parameters from string */
443	<	VIEW *vp;
444	<	register char *s;
442	>	sscanview( /* get view parameters from string */
443	>	VIEW *vp,
444	>	char *s
445	>	)
446		{
447		int ac;
448		char *av[4];
449		int na;
450		int nvopts = 0;
451
452	<	if (*s != '-')
453	<	s = sskip(s);
452	>	while (isspace(*s))
453	>	if (!*s++)
454	>	return(0);
455		while (*s) {
456		ac = 0;
457		do {
458	<	av[ac++] = s;
459	<	while (s && s != ' ')
458	>	if (ac \|\| *s == '-')
459	>	av[ac++] = s;
460	>	while (s && !isspace(s))
461		s++;
462	<	while (*s == ' ')
462	>	while (isspace(*s))
463		s++;
464		} while (*s && ac < 4);
465		if ((na = getviewopt(vp, ac, av)) >= 0) {
#	Line 361 \| Line 473 \| *register char s;**
473		}
474
475
476	<	fprintview(vp, fp) /* write out view parameters */
477	<	register VIEW *vp;
478	<	FILE *fp;
476	>	void
477	>	fprintview( /* write out view parameters */
478	>	VIEW *vp,
479	>	FILE *fp
480	>	)
481		{
482		fprintf(fp, " -vt%c", vp->type);
483		fprintf(fp, " -vp %.6g %.6g %.6g", vp->vp[0], vp->vp[1], vp->vp[2]);
484	<	fprintf(fp, " -vd %.6g %.6g %.6g", vp->vdir[0], vp->vdir[1], vp->vdir[2]);
484	>	fprintf(fp, " -vd %.6g %.6g %.6g", vp->vdir[0]*vp->vdist,
485	>	vp->vdir[1]*vp->vdist,
486	>	vp->vdir[2]*vp->vdist);
487		fprintf(fp, " -vu %.6g %.6g %.6g", vp->vup[0], vp->vup[1], vp->vup[2]);
488		fprintf(fp, " -vh %.6g -vv %.6g", vp->horiz, vp->vert);
489	+	fprintf(fp, " -vo %.6g -va %.6g", vp->vfore, vp->vaft);
490		fprintf(fp, " -vs %.6g -vl %.6g", vp->hoff, vp->voff);
491		}
492
493
494	+	char *
495	+	viewopt( /* translate to minimal view string */
496	+	VIEW *vp
497	+	)
498	+	{
499	+	static char vwstr[128];
500	+	char *cp = vwstr;
501	+
502	+	*cp = '\0';
503	+	if (vp->type != stdview.type) {
504	+	sprintf(cp, " -vt%c", vp->type);
505	+	cp += strlen(cp);
506	+	}
507	+	if (!VEQ(vp->vp,stdview.vp)) {
508	+	sprintf(cp, " -vp %.6g %.6g %.6g",
509	+	vp->vp[0], vp->vp[1], vp->vp[2]);
510	+	cp += strlen(cp);
511	+	}
512	+	if (!FEQ(vp->vdist,stdview.vdist) \|\| !VEQ(vp->vdir,stdview.vdir)) {
513	+	sprintf(cp, " -vd %.6g %.6g %.6g",
514	+	vp->vdir[0]*vp->vdist,
515	+	vp->vdir[1]*vp->vdist,
516	+	vp->vdir[2]*vp->vdist);
517	+	cp += strlen(cp);
518	+	}
519	+	if (!VEQ(vp->vup,stdview.vup)) {
520	+	sprintf(cp, " -vu %.6g %.6g %.6g",
521	+	vp->vup[0], vp->vup[1], vp->vup[2]);
522	+	cp += strlen(cp);
523	+	}
524	+	if (!FEQ(vp->horiz,stdview.horiz)) {
525	+	sprintf(cp, " -vh %.6g", vp->horiz);
526	+	cp += strlen(cp);
527	+	}
528	+	if (!FEQ(vp->vert,stdview.vert)) {
529	+	sprintf(cp, " -vv %.6g", vp->vert);
530	+	cp += strlen(cp);
531	+	}
532	+	if (!FEQ(vp->vfore,stdview.vfore)) {
533	+	sprintf(cp, " -vo %.6g", vp->vfore);
534	+	cp += strlen(cp);
535	+	}
536	+	if (!FEQ(vp->vaft,stdview.vaft)) {
537	+	sprintf(cp, " -va %.6g", vp->vaft);
538	+	cp += strlen(cp);
539	+	}
540	+	if (!FEQ(vp->hoff,stdview.hoff)) {
541	+	sprintf(cp, " -vs %.6g", vp->hoff);
542	+	cp += strlen(cp);
543	+	}
544	+	if (!FEQ(vp->voff,stdview.voff)) {
545	+	sprintf(cp, " -vl %.6g", vp->voff);
546	+	cp += strlen(cp);
547	+	}
548	+	return(vwstr);
549	+	}
550	+
551	+
552		int
553	<	isview(s) /* is this a view string? */
554	<	char *s;
553	>	isview( /* is this a view string? */
554	>	char *s
555	>	)
556		{
557	<	static char *altname[]={NULL,VIEWSTR,"rpict","rview","pinterp",NULL};
557	>	static char *altname[]={NULL,VIEWSTR,"rpict","rview","rvu","rpiece","pinterp",NULL};
558		extern char *progname;
559	<	register char *cp;
560	<	register char **an;
559	>	char *cp;
560	>	char **an;
561		/* add program name to list */
562		if (altname[0] == NULL) {
563		for (cp = progname; *cp; cp++)
#	Line 409 \| Line 585 \| struct myview {
585		};
586
587
588	<	static
589	<	gethview(s, v) /* get view from header */
590	<	char *s;
591	<	register struct myview *v;
588	>	static int
589	>	gethview( /* get view from header */
590	>	char *s,
591	>	void *v
592	>	)
593		{
594	<	if (isview(s) && sscanview(v->hv, s) > 0)
595	<	v->ok++;
594	>	if (isview(s) && sscanview(((struct myview*)v)->hv, s) > 0)
595	>	((struct myview*)v)->ok++;
596	>	return(0);
597		}
598
599
600		int
601	<	viewfile(fname, vp, rp) /* get view from file */
602	<	char *fname;
603	<	VIEW *vp;
604	<	RESOLU *rp;
601	>	viewfile( /* get view from file */
602	>	char *fname,
603	>	VIEW *vp,
604	>	RESOLU *rp
605	>	)
606		{
607		struct myview mvs;
608		FILE *fp;
609
610	<	if ((fp = fopen(fname, "r")) == NULL)
610	>	if (fname == NULL \|\| !strcmp(fname, "-"))
611	>	fp = stdin;
612	>	else if ((fp = fopen(fname, "r")) == NULL)
613		return(-1);
614
615		mvs.hv = vp;

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Comparing ray/src/common/image.c (file contents): Revision 2.5 by greg, Tue Sep 8 10:04:30 1992 UTC vs. Revision 2.38 by greg, Fri Nov 16 00:14:19 2012 UTC

Diff Legend

Comparing ray/src/common/image.c (file contents):
Revision 2.5 by greg, Tue Sep 8 10:04:30 1992 UTC vs.
Revision 2.38 by greg, Fri Nov 16 00:14:19 2012 UTC