[ViewVC] Diff of: radiance/ray/src/cv/mgflib/parser.c

Comparing ray/src/cv/mgflib/parser.c (file contents):
Revision 1.2 by greg, Wed Jun 22 15:33:47 1994 UTC vs.
Revision 1.19 by greg, Fri Oct 27 15:47:18 1995 UTC

#	Line 1 \| Line 1
1	<	/* Copyright (c) 1994 Regents of the University of California */
1	>	/* Copyright (c) 1995 Regents of the University of California */
2
3		#ifndef lint
4		static char SCCSid[] = "$SunId$ LBL";
#	Line 27 \| Line 27 \| char mg_ename[MG_NENTITIES][MG_MAXELEN] = MG_NAMELIST;
27
28		int (*mg_ehand[MG_NENTITIES])();
29
30	+	/* Handler routine for unknown entities */
31	+
32	+	int (*mg_uhand)() = mg_defuhand;
33	+
34	+	unsigned mg_nunknown; /* count of unknown entities */
35	+
36		/* error messages */
37
38		char *mg_err[MG_NERRS] = MG_ERRLIST;
#	Line 59 \| Line 65 \| static int e_any_toss(), /* discard unneeded entity *
65		e_ies(), /* IES luminaire file */
66		e_include(), /* include file */
67		e_sph(), /* sphere */
68	+	e_cct(), /* color temperature */
69	+	e_cmix(), /* color mixtures */
70	+	e_cspec(), /* color spectra */
71		e_cyl(), /* cylinder */
72		e_cone(), /* cone */
73	+	e_prism(), /* prism */
74		e_ring(), /* ring */
75		e_torus(); /* torus */
76
#	Line 85 \| Line 95 \| *mg_init() / initialize alternate entity handlers /*
95		mg_ehand[MG_E_INCLUDE] = e_include;
96		if (mg_ehand[MG_E_SPH] == NULL) {
97		mg_ehand[MG_E_SPH] = e_sph;
98	<	ineed \|= 1<<MG_E_POINT\|1<<MG_E_VERTEX;
98	>	ineed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX;
99		} else
100	<	uneed \|= 1<<MG_E_POINT\|1<<MG_E_VERTEX\|1<<MG_E_XF;
100	>	uneed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX\|1L<<MG_E_XF;
101		if (mg_ehand[MG_E_CYL] == NULL) {
102		mg_ehand[MG_E_CYL] = e_cyl;
103	<	ineed \|= 1<<MG_E_POINT\|1<<MG_E_VERTEX;
103	>	ineed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX;
104		} else
105	<	uneed \|= 1<<MG_E_POINT\|1<<MG_E_VERTEX\|1<<MG_E_XF;
105	>	uneed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX\|1L<<MG_E_XF;
106		if (mg_ehand[MG_E_CONE] == NULL) {
107		mg_ehand[MG_E_CONE] = e_cone;
108	<	ineed \|= 1<<MG_E_POINT\|1<<MG_E_VERTEX;
108	>	ineed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX;
109		} else
110	<	uneed \|= 1<<MG_E_POINT\|1<<MG_E_VERTEX\|1<<MG_E_XF;
110	>	uneed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX\|1L<<MG_E_XF;
111		if (mg_ehand[MG_E_RING] == NULL) {
112		mg_ehand[MG_E_RING] = e_ring;
113	<	ineed \|= 1<<MG_E_POINT\|1<<MG_E_NORMAL\|1<<MG_E_VERTEX;
113	>	ineed \|= 1L<<MG_E_POINT\|1L<<MG_E_NORMAL\|1L<<MG_E_VERTEX;
114		} else
115	<	uneed \|= 1<<MG_E_POINT\|1<<MG_E_NORMAL\|1<<MG_E_VERTEX\|1<<MG_E_XF;
115	>	uneed \|= 1L<<MG_E_POINT\|1L<<MG_E_NORMAL\|1L<<MG_E_VERTEX\|1L<<MG_E_XF;
116	>	if (mg_ehand[MG_E_PRISM] == NULL) {
117	>	mg_ehand[MG_E_PRISM] = e_prism;
118	>	ineed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX;
119	>	} else
120	>	uneed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX\|1L<<MG_E_XF;
121		if (mg_ehand[MG_E_TORUS] == NULL) {
122		mg_ehand[MG_E_TORUS] = e_torus;
123	<	ineed \|= 1<<MG_E_POINT\|1<<MG_E_NORMAL\|1<<MG_E_VERTEX;
123	>	ineed \|= 1L<<MG_E_POINT\|1L<<MG_E_NORMAL\|1L<<MG_E_VERTEX;
124		} else
125	<	uneed \|= 1<<MG_E_POINT\|1<<MG_E_NORMAL\|1<<MG_E_VERTEX\|1<<MG_E_XF;
125	>	uneed \|= 1L<<MG_E_POINT\|1L<<MG_E_NORMAL\|1L<<MG_E_VERTEX\|1L<<MG_E_XF;
126	>	if (mg_ehand[MG_E_COLOR] != NULL) {
127	>	if (mg_ehand[MG_E_CMIX] == NULL) {
128	>	mg_ehand[MG_E_CMIX] = e_cmix;
129	>	ineed \|= 1L<<MG_E_COLOR\|1L<<MG_E_CXY\|1L<<MG_E_CSPEC\|1L<<MG_E_CMIX\|1L<<MG_E_CCT;
130	>	}
131	>	if (mg_ehand[MG_E_CSPEC] == NULL) {
132	>	mg_ehand[MG_E_CSPEC] = e_cspec;
133	>	ineed \|= 1L<<MG_E_COLOR\|1L<<MG_E_CXY\|1L<<MG_E_CSPEC\|1L<<MG_E_CMIX\|1L<<MG_E_CCT;
134	>	}
135	>	if (mg_ehand[MG_E_CCT] == NULL) {
136	>	mg_ehand[MG_E_CCT] = e_cct;
137	>	ineed \|= 1L<<MG_E_COLOR\|1L<<MG_E_CXY\|1L<<MG_E_CSPEC\|1L<<MG_E_CMIX\|1L<<MG_E_CCT;
138	>	}
139	>	}
140		/* check for consistency */
141		if (mg_ehand[MG_E_FACE] != NULL)
142	<	uneed \|= 1<<MG_E_POINT\|1<<MG_E_VERTEX\|1<<MG_E_XF;
143	<	if (mg_ehand[MG_E_CXY] != NULL)
144	<	uneed \|= 1<<MG_E_COLOR;
142	>	uneed \|= 1L<<MG_E_POINT\|1L<<MG_E_VERTEX\|1L<<MG_E_XF;
143	>	if (mg_ehand[MG_E_CXY] != NULL \|\| mg_ehand[MG_E_CSPEC] != NULL \|\|
144	>	mg_ehand[MG_E_CMIX] != NULL)
145	>	uneed \|= 1L<<MG_E_COLOR;
146		if (mg_ehand[MG_E_RD] != NULL \|\| mg_ehand[MG_E_TD] != NULL \|\|
147	+	mg_ehand[MG_E_IR] != NULL \|\|
148		mg_ehand[MG_E_ED] != NULL \|\|
149		mg_ehand[MG_E_RS] != NULL \|\|
150	<	mg_ehand[MG_E_TS] != NULL)
151	<	uneed \|= 1<<MG_E_MATERIAL;
150	>	mg_ehand[MG_E_TS] != NULL \|\|
151	>	mg_ehand[MG_E_SIDES] != NULL)
152	>	uneed \|= 1L<<MG_E_MATERIAL;
153		for (i = 0; i < MG_NENTITIES; i++)
154	<	if (uneed & 1<<i && mg_ehand[i] == NULL) {
154	>	if (uneed & 1L<<i && mg_ehand[i] == NULL) {
155		fprintf(stderr, "Missing support for \"%s\" entity\n",
156		mg_ename[i]);
157		exit(1);
158		}
159		/* add support as needed */
160	<	if (ineed & 1<<MG_E_VERTEX && mg_ehand[MG_E_VERTEX] != c_hvertex)
160	>	if (ineed & 1L<<MG_E_VERTEX && mg_ehand[MG_E_VERTEX] != c_hvertex)
161		e_supp[MG_E_VERTEX] = c_hvertex;
162	<	if (ineed & 1<<MG_E_POINT && mg_ehand[MG_E_POINT] != c_hvertex)
162	>	if (ineed & 1L<<MG_E_POINT && mg_ehand[MG_E_POINT] != c_hvertex)
163		e_supp[MG_E_POINT] = c_hvertex;
164	<	if (ineed & 1<<MG_E_NORMAL && mg_ehand[MG_E_NORMAL] != c_hvertex)
164	>	if (ineed & 1L<<MG_E_NORMAL && mg_ehand[MG_E_NORMAL] != c_hvertex)
165		e_supp[MG_E_NORMAL] = c_hvertex;
166	+	if (ineed & 1L<<MG_E_COLOR && mg_ehand[MG_E_COLOR] != c_hcolor)
167	+	e_supp[MG_E_COLOR] = c_hcolor;
168	+	if (ineed & 1L<<MG_E_CXY && mg_ehand[MG_E_CXY] != c_hcolor)
169	+	e_supp[MG_E_CXY] = c_hcolor;
170	+	if (ineed & 1L<<MG_E_CSPEC && mg_ehand[MG_E_CSPEC] != c_hcolor)
171	+	e_supp[MG_E_CSPEC] = c_hcolor;
172	+	if (ineed & 1L<<MG_E_CMIX && mg_ehand[MG_E_CMIX] != c_hcolor)
173	+	e_supp[MG_E_CMIX] = c_hcolor;
174	+	if (ineed & 1L<<MG_E_CCT && mg_ehand[MG_E_CCT] != c_hcolor)
175	+	e_supp[MG_E_CCT] = c_hcolor;
176		/* discard remaining entities */
177		for (i = 0; i < MG_NENTITIES; i++)
178		if (mg_ehand[i] == NULL)
#	Line 138 \| Line 180 \| *mg_init() / initialize alternate entity handlers /*
180		}
181
182
141	–
183		int
184		mg_entity(name) /* get entity number from its name */
185		char *name;
186		{
187	<	static LUTAB ent_tab; /* entity lookup table */
187	>	static LUTAB ent_tab = LU_SINIT(NULL,NULL); /* lookup table */
188		register char *cp;
189
190		if (!ent_tab.tsiz) { /* initialize hash table */
#	Line 160 \| Line 201 \| *char name;**
201		}
202
203
204	<	static int
205	<	handle_it(en, ac, av) /* pass entity to appropriate handler */
204	>	int
205	>	mg_handle(en, ac, av) /* pass entity to appropriate handler */
206		register int en;
207		int ac;
208		char **av;
209		{
210		int rv;
211
212	<	if (en < 0 && (en = mg_entity(av[0])) < 0)
212	>	if (en < 0 && (en = mg_entity(av[0])) < 0) { /* unknown entity */
213	>	if (mg_uhand != NULL)
214	>	return((*mg_uhand)(ac, av));
215		return(MG_EUNK);
216	<	if (e_supp[en] != NULL) {
216	>	}
217	>	if (e_supp[en] != NULL) { /* support handler */
218		if ((rv = (*e_supp[en])(ac, av)) != MG_OK)
219		return(rv);
220		}
221	<	return((*mg_ehand[en])(ac, av));
221	>	return((mg_ehand[en])(ac, av)); / assigned handler */
222		}
223
224
#	Line 183 \| Line 227 \| *mg_open(ctx, fn) / open new input file /*
227		register MG_FCTXT *ctx;
228		char *fn;
229		{
230	<	int olen;
230	>	static int nfids;
231		register char *cp;
232
233	+	ctx->fid = ++nfids;
234		ctx->lineno = 0;
235		if (fn == NULL) {
236	<	ctx->fname = "<stdin>";
236	>	strcpy(ctx->fname, "<stdin>");
237		ctx->fp = stdin;
238		ctx->prev = mg_file;
239		mg_file = ctx;
240		return(MG_OK);
241		}
242		/* get name relative to this context */
243	<	if (mg_file != NULL &&
199	<	(cp = strrchr(mg_file->fname, '/')) != NULL)
200	<	olen = cp - mg_file->fname + 1;
201	<	else
202	<	olen = 0;
203	<	ctx->fname = (char *)malloc(olen+strlen(fn)+1);
204	<	if (ctx->fname == NULL)
205	<	return(MG_EMEM);
206	<	if (olen)
243	>	if (mg_file != NULL && (cp = strrchr(mg_file->fname, '/')) != NULL) {
244		strcpy(ctx->fname, mg_file->fname);
245	<	strcpy(ctx->fname+olen, fn);
245	>	strcpy(ctx->fname+(cp-mg_file->fname+1), fn);
246	>	} else
247	>	strcpy(ctx->fname, fn);
248		ctx->fp = fopen(ctx->fname, "r");
249	<	if (ctx->fp == NULL) {
211	<	free((MEM_PTR)ctx->fname);
249	>	if (ctx->fp == NULL)
250		return(MG_ENOFILE);
213	–	}
251		ctx->prev = mg_file; /* establish new context */
252		mg_file = ctx;
253		return(MG_OK);
#	Line 226 \| Line 263 \| *mg_close() / close input file /*
263		if (ctx->fp == stdin)
264		return; /* don't close standard input */
265		fclose(ctx->fp);
229	–	free((MEM_PTR)ctx->fname);
266		}
267
268
269	+	void
270	+	mg_fgetpos(pos) /* get current position in input file */
271	+	register MG_FPOS *pos;
272	+	{
273	+	extern long ftell();
274	+
275	+	pos->fid = mg_file->fid;
276	+	pos->lineno = mg_file->lineno;
277	+	pos->offset = ftell(mg_file->fp);
278	+	}
279	+
280	+
281		int
282	<	mg_rewind() /* rewind input file */
282	>	mg_fgoto(pos) /* reposition input file pointer */
283	>	register MG_FPOS *pos;
284		{
285	<	if (mg_file->lineno == 0)
285	>	if (pos->fid != mg_file->fid)
286	>	return(MG_ESEEK);
287	>	if (pos->lineno == mg_file->lineno)
288		return(MG_OK);
289		if (mg_file->fp == stdin)
290		return(MG_ESEEK); /* cannot seek on standard input */
291	<	if (fseek(mg_file->fp, 0L, 0) == EOF)
291	>	if (fseek(mg_file->fp, pos->offset, 0) == EOF)
292		return(MG_ESEEK);
293	<	mg_file->lineno = 0;
293	>	mg_file->lineno = pos->lineno;
294		return(MG_OK);
295		}
296
#	Line 288 \| Line 339 \| *mg_parse() / parse current input line /*
339		return(MG_OK); /* no words in line */
340		*ap = NULL;
341		/* else handle it */
342	<	return(handle_it(-1, ap-argv, argv));
342	>	return(mg_handle(-1, ap-argv, argv));
343		}
344
345
#	Line 315 \| Line 366 \| *char fn;**
366		}
367
368
369	+	int
370	+	mg_defuhand(ac, av) /* default handler for unknown entities */
371	+	int ac;
372	+	char **av;
373	+	{
374	+	if (mg_nunknown++ == 0) /* report first incident */
375	+	fprintf(stderr, "%s: %d: %s: %s\n", mg_file->fname,
376	+	mg_file->lineno, mg_err[MG_EUNK], av[0]);
377	+	return(MG_OK);
378	+	}
379	+
380	+
381		void
382		mg_clear() /* clear parser history */
383		{
#	Line 323 \| Line 386 \| *mg_clear() / clear parser history /*
386		}
387
388
326	–	int
327	–	mg_iterate(ac, av, f) /* iterate on statement */
328	–	int ac;
329	–	register char **av;
330	–	int (*f)();
331	–	{
332	–	int niter, rval;
333	–	register int i, j;
334	–	char *argv[MG_MAXARGC];
335	–	char cntbuf[10];
336	–	/* build partial transformation */
337	–	for (i = 0; i < ac; i++) {
338	–	if (av[i][0] == '-' && av[i][1] == 'a' && av[i][2] == '\0')
339	–	break;
340	–	argv[i+1] = av[i];
341	–	}
342	–	argv[i+1] = NULL;
343	–	if (i) { /* handle transformation */
344	–	argv[0] = mg_ename[MG_E_XF];
345	–	if ((rval = handle_it(MG_E_XF, i+1, argv)) != MG_OK)
346	–	return(rval);
347	–	}
348	–	if (i < ac) { /* run array */
349	–	if (i+1 >= ac \|\| !isint(av[i+1]))
350	–	return(MG_ETYPE);
351	–	niter = atoi(av[i+1]);
352	–	argv[0] = mg_ename[MG_E_OBJECT];
353	–	argv[1] = cntbuf;
354	–	for (j = 2; j+i < ac; j++)
355	–	argv[j] = av[j+i];
356	–	argv[j] = NULL;
357	–	for (j = 0; j < niter; j++) {
358	–	sprintf(cntbuf, "%d", j);
359	–	if ((rval = handle_it(MG_E_OBJECT, 2, argv)) != MG_OK)
360	–	return(rval);
361	–	argv[0] = "-i";
362	–	if ((rval = mg_iterate(ac-i, argv, f)) != MG_OK)
363	–	return(rval);
364	–	argv[0] = mg_ename[MG_E_OBJECT];
365	–	if ((rval = handle_it(MG_E_OBJECT, 1, argv)) != MG_OK)
366	–	return(rval);
367	–	}
368	–	} else if ((rval = (f)()) != MG_OK) / else do this instance */
369	–	return(rval);
370	–	if (i) { /* reset the transform */
371	–	argv[0] = mg_ename[MG_E_XF];
372	–	argv[1] = NULL;
373	–	(void)handle_it(MG_E_XF, 1, argv);
374	–	}
375	–	return(MG_OK);
376	–	}
377	–
378	–
389		/****************************************************************************
390		* The following routines handle unsupported entities
391		*/
#	Line 391 \| Line 401 \| char av;**
401
402
403		static int
394	–	reload_file() /* reload current MGF file */
395	–	{
396	–	register int rval;
397	–
398	–	if ((rval = mg_rewind()) != MG_OK)
399	–	return(rval);
400	–	while (mg_read())
401	–	if ((rval = mg_parse()) != MG_OK)
402	–	return(rval);
403	–	return(MG_OK);
404	–	}
405	–
406	–
407	–	static int
404		e_include(ac, av) /* include file */
405		int ac;
406		char **av;
407		{
408	+	char *xfarg[MG_MAXARGC];
409		MG_FCTXT ictx;
410	+	XF_SPEC *xf_orig = xf_context;
411		int rv;
412
413		if (ac < 2)
414		return(MG_EARGC);
415		if ((rv = mg_open(&ictx, av[1])) != MG_OK)
416		return(rv);
417	<	if ((rv = mg_iterate(ac-2, av+2, reload_file)) != MG_OK) {
418	<	fprintf(stderr, "%s: %d: %s:\n%s", ictx.fname,
419	<	ictx.lineno, mg_err[rv], ictx.inpline);
420	<	mg_close();
421	<	return(MG_EINCL);
417	>	if (ac > 2) {
418	>	register int i;
419	>
420	>	xfarg[0] = mg_ename[MG_E_XF];
421	>	for (i = 1; i < ac-1; i++)
422	>	xfarg[i] = av[i+1];
423	>	xfarg[ac-1] = NULL;
424	>	if ((rv = mg_handle(MG_E_XF, ac-1, xfarg)) != MG_OK)
425	>	return(rv);
426		}
427	+	do {
428	+	while (mg_read())
429	+	if ((rv = mg_parse()) != MG_OK) {
430	+	fprintf(stderr, "%s: %d: %s:\n%s", ictx.fname,
431	+	ictx.lineno, mg_err[rv],
432	+	ictx.inpline);
433	+	mg_close();
434	+	return(MG_EINCL);
435	+	}
436	+	if (ac > 2)
437	+	if ((rv = mg_handle(MG_E_XF, 1, xfarg)) != MG_OK)
438	+	return(rv);
439	+	} while (xf_context != xf_orig);
440		mg_close();
441		return(MG_OK);
442		}
#	Line 469 \| Line 484 \| char av;**
484		rad = atof(av[2]);
485		/* initialize */
486		warpconends = 1;
487	<	if ((rval = handle_it(MG_E_VERTEX, 3, v2ent)) != MG_OK)
487	>	if ((rval = mg_handle(MG_E_VERTEX, 3, v2ent)) != MG_OK)
488		return(rval);
489		sprintf(p2x, FLTFMT, cv->p[0]);
490		sprintf(p2y, FLTFMT, cv->p[1]);
491		sprintf(p2z, FLTFMT, cv->p[2]+rad);
492	<	if ((rval = handle_it(MG_E_POINT, 4, p2ent)) != MG_OK)
492	>	if ((rval = mg_handle(MG_E_POINT, 4, p2ent)) != MG_OK)
493		return(rval);
494		r2[0] = '0'; r2[1] = '\0';
495		for (i = 1; i <= 2*mg_nqcdivs; i++) {
496		theta = i*(PI/2)/mg_nqcdivs;
497	<	if ((rval = handle_it(MG_E_VERTEX, 4, v1ent)) != MG_OK)
497	>	if ((rval = mg_handle(MG_E_VERTEX, 4, v1ent)) != MG_OK)
498		return(rval);
499		sprintf(p2z, FLTFMT, cv->p[2]+rad*cos(theta));
500	<	if ((rval = handle_it(MG_E_VERTEX, 2, v2ent)) != MG_OK)
500	>	if ((rval = mg_handle(MG_E_VERTEX, 2, v2ent)) != MG_OK)
501		return(rval);
502	<	if ((rval = handle_it(MG_E_POINT, 4, p2ent)) != MG_OK)
502	>	if ((rval = mg_handle(MG_E_POINT, 4, p2ent)) != MG_OK)
503		return(rval);
504		strcpy(r1, r2);
505		sprintf(r2, FLTFMT, rad*sin(theta));
506	<	if ((rval = handle_it(MG_E_CONE, 5, conent)) != MG_OK)
506	>	if ((rval = mg_handle(MG_E_CONE, 5, conent)) != MG_OK)
507		return(rval);
508		}
509		warpconends = 0;
#	Line 517 \| Line 532 \| char av;**
532		return(MG_EARGC);
533		if ((cv = c_getvert(av[1])) == NULL)
534		return(MG_EUNDEF);
535	<	if (cv->n[0]==0. && cv->n[1]==0. && cv->n[2]==0.)
535	>	if (is0vect(cv->n))
536		return(MG_EILL);
537		if (!isflt(av[2]) \|\| !isflt(av[3]))
538		return(MG_ETYPE);
539		minrad = atof(av[2]);
540	+	round0(minrad);
541		maxrad = atof(av[3]);
542		/* check orientation */
543		if (minrad > 0.)
#	Line 542 \| Line 558 \| char av;**
558		for (j = 0; j < 3; j++)
559		sprintf(p2[j], FLTFMT, cv->p[j] +
560		.5sgn(maxrad-minrad)*cv->n[j]);
561	<	if ((rval = handle_it(MG_E_VERTEX, 4, v2ent)) != MG_OK)
561	>	if ((rval = mg_handle(MG_E_VERTEX, 4, v2ent)) != MG_OK)
562		return(rval);
563	<	if ((rval = handle_it(MG_E_POINT, 4, p2ent)) != MG_OK)
563	>	if ((rval = mg_handle(MG_E_POINT, 4, p2ent)) != MG_OK)
564		return(rval);
565		sprintf(r2, FLTFMT, avgrad=.5*(minrad+maxrad));
566		/* run outer section */
567		for (i = 1; i <= 2*mg_nqcdivs; i++) {
568		theta = i*(PI/2)/mg_nqcdivs;
569	<	if ((rval = handle_it(MG_E_VERTEX, 4, v1ent)) != MG_OK)
569	>	if ((rval = mg_handle(MG_E_VERTEX, 4, v1ent)) != MG_OK)
570		return(rval);
571		for (j = 0; j < 3; j++)
572		sprintf(p2[j], FLTFMT, cv->p[j] +
573		.5sgn(maxrad-minrad)cos(theta)cv->n[j]);
574	<	if ((rval = handle_it(MG_E_VERTEX, 2, v2ent)) != MG_OK)
574	>	if ((rval = mg_handle(MG_E_VERTEX, 2, v2ent)) != MG_OK)
575		return(rval);
576	<	if ((rval = handle_it(MG_E_POINT, 4, p2ent)) != MG_OK)
576	>	if ((rval = mg_handle(MG_E_POINT, 4, p2ent)) != MG_OK)
577		return(rval);
578		strcpy(r1, r2);
579		sprintf(r2, FLTFMT, avgrad + .5(maxrad-minrad)sin(theta));
580	<	if ((rval = handle_it(MG_E_CONE, 5, conent)) != MG_OK)
580	>	if ((rval = mg_handle(MG_E_CONE, 5, conent)) != MG_OK)
581		return(rval);
582		}
583		/* run inner section */
#	Line 571 \| Line 587 \| char av;**
587		for (j = 0; j < 3; j++)
588		sprintf(p2[j], FLTFMT, cv->p[j] +
589		.5sgn(maxrad-minrad)cos(theta)cv->n[j]);
590	<	if ((rval = handle_it(MG_E_VERTEX, 4, v1ent)) != MG_OK)
590	>	if ((rval = mg_handle(MG_E_VERTEX, 4, v1ent)) != MG_OK)
591		return(rval);
592	<	if ((rval = handle_it(MG_E_VERTEX, 2, v2ent)) != MG_OK)
592	>	if ((rval = mg_handle(MG_E_VERTEX, 2, v2ent)) != MG_OK)
593		return(rval);
594	<	if ((rval = handle_it(MG_E_POINT, 4, p2ent)) != MG_OK)
594	>	if ((rval = mg_handle(MG_E_POINT, 4, p2ent)) != MG_OK)
595		return(rval);
596		strcpy(r1, r2);
597		sprintf(r2, FLTFMT, -avgrad - .5(maxrad-minrad)sin(theta));
598	<	if ((rval = handle_it(MG_E_CONE, 5, conent)) != MG_OK)
598	>	if ((rval = mg_handle(MG_E_CONE, 5, conent)) != MG_OK)
599		return(rval);
600		}
601		warpconends = 0;
#	Line 600 \| Line 616 \| char av;**
616		avnew[2] = av[2];
617		avnew[3] = av[3];
618		avnew[4] = av[2];
619	<	return(handle_it(MG_E_CONE, 5, avnew));
619	>	return(mg_handle(MG_E_CONE, 5, avnew));
620		}
621
622
#	Line 629 \| Line 645 \| char av;**
645		return(MG_EARGC);
646		if ((cv = c_getvert(av[1])) == NULL)
647		return(MG_EUNDEF);
648	<	if (cv->n[0]==0. && cv->n[1]==0. && cv->n[2]==0.)
648	>	if (is0vect(cv->n))
649		return(MG_EILL);
650		if (!isflt(av[2]) \|\| !isflt(av[3]))
651		return(MG_ETYPE);
652		minrad = atof(av[2]);
653	+	round0(minrad);
654		maxrad = atof(av[3]);
655		if (minrad < 0. \|\| maxrad <= minrad)
656		return(MG_EILL);
#	Line 641 \| Line 658 \| char av;**
658		make_axes(u, v, cv->n);
659		for (j = 0; j < 3; j++)
660		sprintf(p3[j], FLTFMT, cv->p[j] + maxrad*u[j]);
661	<	if ((rv = handle_it(MG_E_VERTEX, 3, v3ent)) != MG_OK)
661	>	if ((rv = mg_handle(MG_E_VERTEX, 3, v3ent)) != MG_OK)
662		return(rv);
663	<	if ((rv = handle_it(MG_E_POINT, 4, p3ent)) != MG_OK)
663	>	if ((rv = mg_handle(MG_E_POINT, 4, p3ent)) != MG_OK)
664		return(rv);
665		if (minrad == 0.) { /* closed */
666		v1ent[3] = av[1];
667	<	if ((rv = handle_it(MG_E_VERTEX, 4, v1ent)) != MG_OK)
667	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v1ent)) != MG_OK)
668		return(rv);
669	<	if ((rv = handle_it(MG_E_NORMAL, 4, nzent)) != MG_OK)
669	>	if ((rv = mg_handle(MG_E_NORMAL, 4, nzent)) != MG_OK)
670		return(rv);
671		for (i = 1; i <= 4*mg_nqcdivs; i++) {
672		theta = i*(PI/2)/mg_nqcdivs;
673	<	if ((rv = handle_it(MG_E_VERTEX, 4, v2ent)) != MG_OK)
673	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v2ent)) != MG_OK)
674		return(rv);
675		for (j = 0; j < 3; j++)
676		sprintf(p3[j], FLTFMT, cv->p[j] +
677		maxradu[j]cos(theta) +
678		maxradv[j]sin(theta));
679	<	if ((rv = handle_it(MG_E_VERTEX, 3, v3ent)) != MG_OK)
679	>	if ((rv = mg_handle(MG_E_VERTEX, 2, v3ent)) != MG_OK)
680		return(rv);
681	<	if ((rv = handle_it(MG_E_POINT, 4, p3ent)) != MG_OK)
681	>	if ((rv = mg_handle(MG_E_POINT, 4, p3ent)) != MG_OK)
682		return(rv);
683	<	if ((rv = handle_it(MG_E_FACE, 4, fent)) != MG_OK)
683	>	if ((rv = mg_handle(MG_E_FACE, 4, fent)) != MG_OK)
684		return(rv);
685		}
686		} else { /* open */
687	<	if ((rv = handle_it(MG_E_VERTEX, 3, v4ent)) != MG_OK)
687	>	if ((rv = mg_handle(MG_E_VERTEX, 3, v4ent)) != MG_OK)
688		return(rv);
689		for (j = 0; j < 3; j++)
690		sprintf(p4[j], FLTFMT, cv->p[j] + minrad*u[j]);
691	<	if ((rv = handle_it(MG_E_POINT, 4, p4ent)) != MG_OK)
691	>	if ((rv = mg_handle(MG_E_POINT, 4, p4ent)) != MG_OK)
692		return(rv);
693		v1ent[3] = "_rv4";
694		for (i = 1; i <= 4*mg_nqcdivs; i++) {
695		theta = i*(PI/2)/mg_nqcdivs;
696	<	if ((rv = handle_it(MG_E_VERTEX, 4, v1ent)) != MG_OK)
696	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v1ent)) != MG_OK)
697		return(rv);
698	<	if ((rv = handle_it(MG_E_VERTEX, 4, v2ent)) != MG_OK)
698	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v2ent)) != MG_OK)
699		return(rv);
700		for (j = 0; j < 3; j++) {
701		d = u[j]cos(theta) + v[j]sin(theta);
702		sprintf(p3[j], FLTFMT, cv->p[j] + maxrad*d);
703		sprintf(p4[j], FLTFMT, cv->p[j] + minrad*d);
704		}
705	<	if ((rv = handle_it(MG_E_VERTEX, 3, v3ent)) != MG_OK)
705	>	if ((rv = mg_handle(MG_E_VERTEX, 2, v3ent)) != MG_OK)
706		return(rv);
707	<	if ((rv = handle_it(MG_E_POINT, 4, p3ent)) != MG_OK)
707	>	if ((rv = mg_handle(MG_E_POINT, 4, p3ent)) != MG_OK)
708		return(rv);
709	<	if ((rv = handle_it(MG_E_VERTEX, 3, v4ent)) != MG_OK)
709	>	if ((rv = mg_handle(MG_E_VERTEX, 2, v4ent)) != MG_OK)
710		return(rv);
711	<	if ((rv = handle_it(MG_E_POINT, 4, p4ent)) != MG_OK)
711	>	if ((rv = mg_handle(MG_E_POINT, 4, p4ent)) != MG_OK)
712		return(rv);
713	<	if ((rv = handle_it(MG_E_FACE, 5, fent)) != MG_OK)
713	>	if ((rv = mg_handle(MG_E_FACE, 5, fent)) != MG_OK)
714		return(rv);
715		}
716		}
#	Line 716 \| Line 733 \| char av;**
733		static char *p4ent[5] = {mg_ename[MG_E_POINT],p4[0],p4[1],p4[2]};
734		static char *n4ent[5] = {mg_ename[MG_E_NORMAL],n4[0],n4[1],n4[2]};
735		static char *fent[6] = {mg_ename[MG_E_FACE],"_cv1","_cv2","_cv3","_cv4"};
736	+	char *v1n;
737		register C_VERTEX cv1, cv2;
738		register int i, j;
739		FVECT u, v, w;
#	Line 731 \| Line 749 \| char av;**
749		if ((cv1 = c_getvert(av[1])) == NULL \|\|
750		(cv2 = c_getvert(av[3])) == NULL)
751		return(MG_EUNDEF);
752	+	v1n = av[1];
753		if (!isflt(av[2]) \|\| !isflt(av[4]))
754		return(MG_ETYPE);
755		rad1 = atof(av[2]);
756	+	round0(rad1);
757		rad2 = atof(av[4]);
758	+	round0(rad2);
759		if (rad1 == 0.) {
760		if (rad2 == 0.)
761		return(MG_EILL);
#	Line 747 \| Line 768 \| char av;**
768		cv = cv1;
769		cv1 = cv2;
770		cv2 = cv;
771	+	v1n = av[3];
772		d = rad1;
773		rad1 = rad2;
774		rad2 = d;
#	Line 758 \| Line 780 \| char av;**
780		if ((d = normalize(w)) == 0.)
781		return(MG_EILL);
782		n1off = n2off = (rad2 - rad1)/d;
783	<	if (warpconends) /* hack for e_sph and e_torus */
784	<	n2off = tan(atan(n2off)-(PI/4)/mg_nqcdivs);
785	<	n2off = sgn*n2off;
783	>	if (warpconends) { /* hack for e_sph and e_torus */
784	>	d = atan(n2off) - (PI/4)/mg_nqcdivs;
785	>	if (d <= -PI/2+FTINY)
786	>	n2off = -FHUGE;
787	>	else
788	>	n2off = tan(d);
789	>	}
790		make_axes(u, v, w);
791		for (j = 0; j < 3; j++) {
792		sprintf(p3[j], FLTFMT, cv2->p[j] + rad2*u[j]);
793	<	sprintf(n3[j], FLTFMT, u[j] + w[j]*n2off);
793	>	if (n2off <= -FHUGE)
794	>	sprintf(n3[j], FLTFMT, -w[j]);
795	>	else
796	>	sprintf(n3[j], FLTFMT, u[j] + w[j]*n2off);
797		}
798	<	if ((rv = handle_it(MG_E_VERTEX, 3, v3ent)) != MG_OK)
798	>	if ((rv = mg_handle(MG_E_VERTEX, 3, v3ent)) != MG_OK)
799		return(rv);
800	<	if ((rv = handle_it(MG_E_POINT, 4, p3ent)) != MG_OK)
800	>	if ((rv = mg_handle(MG_E_POINT, 4, p3ent)) != MG_OK)
801		return(rv);
802	<	if ((rv = handle_it(MG_E_NORMAL, 4, n3ent)) != MG_OK)
802	>	if ((rv = mg_handle(MG_E_NORMAL, 4, n3ent)) != MG_OK)
803		return(rv);
804		if (rad1 == 0.) { /* triangles */
805	<	v1ent[3] = av[1];
806	<	if ((rv = handle_it(MG_E_VERTEX, 4, v1ent)) != MG_OK)
805	>	v1ent[3] = v1n;
806	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v1ent)) != MG_OK)
807		return(rv);
808		for (j = 0; j < 3; j++)
809		sprintf(n4[j], FLTFMT, w[j]);
810	<	if ((rv = handle_it(MG_E_NORMAL, 4, n4ent)) != MG_OK)
810	>	if ((rv = mg_handle(MG_E_NORMAL, 4, n4ent)) != MG_OK)
811		return(rv);
812		for (i = 1; i <= 4*mg_nqcdivs; i++) {
813		theta = sgni(PI/2)/mg_nqcdivs;
814	<	if ((rv = handle_it(MG_E_VERTEX, 4, v2ent)) != MG_OK)
814	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v2ent)) != MG_OK)
815		return(rv);
816		for (j = 0; j < 3; j++) {
817		d = u[j]cos(theta) + v[j]sin(theta);
818		sprintf(p3[j], FLTFMT, cv2->p[j] + rad2*d);
819	<	sprintf(n3[j], FLTFMT, d + w[j]*n2off);
819	>	if (n2off > -FHUGE)
820	>	sprintf(n3[j], FLTFMT, d + w[j]*n2off);
821		}
822	<	if ((rv = handle_it(MG_E_VERTEX, 3, v3ent)) != MG_OK)
822	>	if ((rv = mg_handle(MG_E_VERTEX, 2, v3ent)) != MG_OK)
823		return(rv);
824	<	if ((rv = handle_it(MG_E_POINT, 4, p3ent)) != MG_OK)
824	>	if ((rv = mg_handle(MG_E_POINT, 4, p3ent)) != MG_OK)
825		return(rv);
826	<	if ((rv = handle_it(MG_E_NORMAL, 4, n3ent)) != MG_OK)
826	>	if (n2off > -FHUGE &&
827	>	(rv = mg_handle(MG_E_NORMAL, 4, n3ent)) != MG_OK)
828		return(rv);
829	<	if ((rv = handle_it(MG_E_FACE, 4, fent)) != MG_OK)
829	>	if ((rv = mg_handle(MG_E_FACE, 4, fent)) != MG_OK)
830		return(rv);
831		}
832		} else { /* quads */
833		v1ent[3] = "_cv4";
834	<	if (warpconends) /* hack for e_sph and e_torus */
835	<	n1off = tan(atan(n1off)+(PI/4)/mg_nqcdivs);
836	<	n1off = sgn*n1off;
834	>	if (warpconends) { /* hack for e_sph and e_torus */
835	>	d = atan(n1off) + (PI/4)/mg_nqcdivs;
836	>	if (d >= PI/2-FTINY)
837	>	n1off = FHUGE;
838	>	else
839	>	n1off = tan(atan(n1off)+(PI/4)/mg_nqcdivs);
840	>	}
841		for (j = 0; j < 3; j++) {
842		sprintf(p4[j], FLTFMT, cv1->p[j] + rad1*u[j]);
843	<	sprintf(n4[j], FLTFMT, u[j] + w[j]*n1off);
843	>	if (n1off >= FHUGE)
844	>	sprintf(n4[j], FLTFMT, w[j]);
845	>	else
846	>	sprintf(n4[j], FLTFMT, u[j] + w[j]*n1off);
847		}
848	<	if ((rv = handle_it(MG_E_VERTEX, 3, v4ent)) != MG_OK)
848	>	if ((rv = mg_handle(MG_E_VERTEX, 3, v4ent)) != MG_OK)
849		return(rv);
850	<	if ((rv = handle_it(MG_E_POINT, 4, p4ent)) != MG_OK)
850	>	if ((rv = mg_handle(MG_E_POINT, 4, p4ent)) != MG_OK)
851		return(rv);
852	<	if ((rv = handle_it(MG_E_NORMAL, 4, n4ent)) != MG_OK)
852	>	if ((rv = mg_handle(MG_E_NORMAL, 4, n4ent)) != MG_OK)
853		return(rv);
854		for (i = 1; i <= 4*mg_nqcdivs; i++) {
855		theta = sgni(PI/2)/mg_nqcdivs;
856	<	if ((rv = handle_it(MG_E_VERTEX, 4, v1ent)) != MG_OK)
856	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v1ent)) != MG_OK)
857		return(rv);
858	<	if ((rv = handle_it(MG_E_VERTEX, 4, v2ent)) != MG_OK)
858	>	if ((rv = mg_handle(MG_E_VERTEX, 4, v2ent)) != MG_OK)
859		return(rv);
860		for (j = 0; j < 3; j++) {
861		d = u[j]cos(theta) + v[j]sin(theta);
862		sprintf(p3[j], FLTFMT, cv2->p[j] + rad2*d);
863	<	sprintf(n3[j], FLTFMT, d + w[j]*n2off);
863	>	if (n2off > -FHUGE)
864	>	sprintf(n3[j], FLTFMT, d + w[j]*n2off);
865		sprintf(p4[j], FLTFMT, cv1->p[j] + rad1*d);
866	<	sprintf(n4[j], FLTFMT, d + w[j]*n1off);
866	>	if (n1off < FHUGE)
867	>	sprintf(n4[j], FLTFMT, d + w[j]*n1off);
868		}
869	<	if ((rv = handle_it(MG_E_VERTEX, 3, v3ent)) != MG_OK)
869	>	if ((rv = mg_handle(MG_E_VERTEX, 2, v3ent)) != MG_OK)
870		return(rv);
871	<	if ((rv = handle_it(MG_E_POINT, 4, p3ent)) != MG_OK)
871	>	if ((rv = mg_handle(MG_E_POINT, 4, p3ent)) != MG_OK)
872		return(rv);
873	<	if ((rv = handle_it(MG_E_NORMAL, 4, n3ent)) != MG_OK)
873	>	if (n2off > -FHUGE &&
874	>	(rv = mg_handle(MG_E_NORMAL, 4, n3ent)) != MG_OK)
875		return(rv);
876	<	if ((rv = handle_it(MG_E_VERTEX, 3, v4ent)) != MG_OK)
876	>	if ((rv = mg_handle(MG_E_VERTEX, 2, v4ent)) != MG_OK)
877		return(rv);
878	<	if ((rv = handle_it(MG_E_POINT, 4, p4ent)) != MG_OK)
878	>	if ((rv = mg_handle(MG_E_POINT, 4, p4ent)) != MG_OK)
879		return(rv);
880	<	if ((rv = handle_it(MG_E_NORMAL, 4, n4ent)) != MG_OK)
880	>	if (n1off < FHUGE &&
881	>	(rv = mg_handle(MG_E_NORMAL, 4, n4ent)) != MG_OK)
882		return(rv);
883	<	if ((rv = handle_it(MG_E_FACE, 5, fent)) != MG_OK)
883	>	if ((rv = mg_handle(MG_E_FACE, 5, fent)) != MG_OK)
884		return(rv);
885		}
886		}
887	+	return(MG_OK);
888	+	}
889	+
890	+
891	+	static int
892	+	e_prism(ac, av) /* turn a prism into polygons */
893	+	int ac;
894	+	char **av;
895	+	{
896	+	static char p[3][24];
897	+	static char *vent[5] = {mg_ename[MG_E_VERTEX],NULL,"="};
898	+	static char *pent[5] = {mg_ename[MG_E_POINT],p[0],p[1],p[2]};
899	+	static char *znorm[5] = {mg_ename[MG_E_NORMAL],"0","0","0"};
900	+	char *newav[MG_MAXARGC], nvn[MG_MAXARGC-1][8];
901	+	double length;
902	+	int hasnorm;
903	+	FVECT v1, v2, v3, norm;
904	+	register C_VERTEX *cv;
905	+	C_VERTEX *cv0;
906	+	int rv;
907	+	register int i, j;
908	+	/* check arguments */
909	+	if (ac < 5)
910	+	return(MG_EARGC);
911	+	if (!isflt(av[ac-1]))
912	+	return(MG_ETYPE);
913	+	length = atof(av[ac-1]);
914	+	if (length <= FTINY && length >= -FTINY)
915	+	return(MG_EILL);
916	+	/* compute face normal */
917	+	if ((cv0 = c_getvert(av[1])) == NULL)
918	+	return(MG_EUNDEF);
919	+	hasnorm = 0;
920	+	norm[0] = norm[1] = norm[2] = 0.;
921	+	v1[0] = v1[1] = v1[2] = 0.;
922	+	for (i = 2; i < ac-1; i++) {
923	+	if ((cv = c_getvert(av[i])) == NULL)
924	+	return(MG_EUNDEF);
925	+	hasnorm += !is0vect(cv->n);
926	+	v2[0] = cv->p[0] - cv0->p[0];
927	+	v2[1] = cv->p[1] - cv0->p[1];
928	+	v2[2] = cv->p[2] - cv0->p[2];
929	+	fcross(v3, v1, v2);
930	+	norm[0] += v3[0];
931	+	norm[1] += v3[1];
932	+	norm[2] += v3[2];
933	+	VCOPY(v1, v2);
934	+	}
935	+	if (normalize(norm) == 0.)
936	+	return(MG_EILL);
937	+	/* create moved vertices */
938	+	for (i = 1; i < ac-1; i++) {
939	+	sprintf(nvn[i-1], "_pv%d", i);
940	+	vent[1] = nvn[i-1];
941	+	vent[3] = av[i];
942	+	if ((rv = mg_handle(MG_E_VERTEX, 4, vent)) != MG_OK)
943	+	return(rv);
944	+	cv = c_getvert(av[i]); /* checked above */
945	+	for (j = 0; j < 3; j++)
946	+	sprintf(p[j], FLTFMT, cv->p[j] - length*norm[j]);
947	+	if ((rv = mg_handle(MG_E_POINT, 4, pent)) != MG_OK)
948	+	return(rv);
949	+	}
950	+	/* make faces */
951	+	newav[0] = mg_ename[MG_E_FACE];
952	+	/* do the side faces */
953	+	newav[5] = NULL;
954	+	newav[3] = av[ac-2];
955	+	newav[4] = nvn[ac-3];
956	+	for (i = 1; i < ac-1; i++) {
957	+	newav[1] = nvn[i-1];
958	+	newav[2] = av[i];
959	+	if ((rv = mg_handle(MG_E_FACE, 5, newav)) != MG_OK)
960	+	return(rv);
961	+	newav[3] = newav[2];
962	+	newav[4] = newav[1];
963	+	}
964	+	/* do top face */
965	+	for (i = 1; i < ac-1; i++) {
966	+	if (hasnorm) { /* zero normals */
967	+	vent[1] = nvn[i-1];
968	+	if ((rv = mg_handle(MG_E_VERTEX, 2, vent)) != MG_OK)
969	+	return(rv);
970	+	if ((rv = mg_handle(MG_E_NORMAL, 4, znorm)) != MG_OK)
971	+	return(rv);
972	+	}
973	+	newav[ac-1-i] = nvn[i-1]; /* reverse */
974	+	}
975	+	if ((rv = mg_handle(MG_E_FACE, ac-1, newav)) != MG_OK)
976	+	return(rv);
977	+	/* do bottom face */
978	+	if (hasnorm)
979	+	for (i = 1; i < ac-1; i++) {
980	+	vent[1] = nvn[i-1];
981	+	vent[3] = av[i];
982	+	if ((rv = mg_handle(MG_E_VERTEX, 4, vent)) != MG_OK)
983	+	return(rv);
984	+	if ((rv = mg_handle(MG_E_NORMAL, 4, znorm)) != MG_OK)
985	+	return(rv);
986	+	newav[i] = nvn[i-1];
987	+	}
988	+	else
989	+	for (i = 1; i < ac-1; i++)
990	+	newav[i] = av[i];
991	+	newav[i] = NULL;
992	+	if ((rv = mg_handle(MG_E_FACE, i, newav)) != MG_OK)
993	+	return(rv);
994	+	return(MG_OK);
995	+	}
996	+
997	+
998	+	static int
999	+	put_cxy() /* put out current xy chromaticities */
1000	+	{
1001	+	static char xbuf[24], ybuf[24];
1002	+	static char *ccom[4] = {mg_ename[MG_E_CXY], xbuf, ybuf};
1003	+	int rv;
1004	+
1005	+	sprintf(xbuf, "%.4f", c_ccolor->cx);
1006	+	sprintf(ybuf, "%.4f", c_ccolor->cy);
1007	+	if ((rv = mg_handle(MG_E_CXY, 3, ccom)) != MG_OK)
1008	+	return(rv);
1009	+	return(MG_OK);
1010	+	}
1011	+
1012	+
1013	+	static int
1014	+	put_cspec() /* put out current color spectrum */
1015	+	{
1016	+	char wl[2][6], vbuf[C_CNSS][24];
1017	+	char *newav[C_CNSS+4];
1018	+	double sf;
1019	+	register int i;
1020	+
1021	+	if (mg_ehand[MG_E_CSPEC] != c_hcolor) {
1022	+	sprintf(wl[0], "%d", C_CMINWL);
1023	+	sprintf(wl[1], "%d", C_CMAXWL);
1024	+	newav[0] = mg_ename[MG_E_CSPEC];
1025	+	newav[1] = wl[0];
1026	+	newav[2] = wl[1];
1027	+	sf = (double)C_CNSS / c_ccolor->ssum;
1028	+	for (i = 0; i < C_CNSS; i++) {
1029	+	sprintf(vbuf[i], "%.4f", sf*c_ccolor->ssamp[i]);
1030	+	newav[i+3] = vbuf[i];
1031	+	}
1032	+	newav[C_CNSS+3] = NULL;
1033	+	if ((i = mg_handle(MG_E_CSPEC, C_CNSS+3, newav)) != MG_OK)
1034	+	return(i);
1035	+	}
1036	+	return(MG_OK);
1037	+	}
1038	+
1039	+
1040	+	static int
1041	+	e_cspec(ac, av) /* handle spectral color */
1042	+	int ac;
1043	+	char **av;
1044	+	{
1045	+	/* convert to xy chromaticity */
1046	+	c_ccvt(c_ccolor, C_CSXY);
1047	+	/* if it's really their handler, use it */
1048	+	if (mg_ehand[MG_E_CXY] != c_hcolor)
1049	+	return(put_cxy());
1050	+	return(MG_OK);
1051	+	}
1052	+
1053	+
1054	+	static int
1055	+	e_cmix(ac, av) /* handle mixing of colors */
1056	+	int ac;
1057	+	char **av;
1058	+	{
1059	+	/*
1060	+	* Contorted logic works as follows:
1061	+	* 1. the colors are already mixed in c_hcolor() support function
1062	+	* 2. if we would handle a spectral result, make sure it's not
1063	+	* 3. if c_hcolor() would handle a spectral result, don't bother
1064	+	* 4. otherwise, make cspec entity and pass it to their handler
1065	+	* 5. if we have only xy results, handle it as c_spec() would
1066	+	*/
1067	+	if (mg_ehand[MG_E_CSPEC] == e_cspec)
1068	+	c_ccvt(c_ccolor, C_CSXY);
1069	+	else if (c_ccolor->flags & C_CDSPEC)
1070	+	return(put_cspec());
1071	+	if (mg_ehand[MG_E_CXY] != c_hcolor)
1072	+	return(put_cxy());
1073	+	return(MG_OK);
1074	+	}
1075	+
1076	+
1077	+	static int
1078	+	e_cct(ac, av) /* handle color temperature */
1079	+	int ac;
1080	+	char **av;
1081	+	{
1082	+	/*
1083	+	* Logic is similar to e_cmix here. Support handler has already
1084	+	* converted temperature to spectral color. Put it out as such
1085	+	* if they support it, otherwise convert to xy chromaticity and
1086	+	* put it out if they handle it.
1087	+	*/
1088	+	if (mg_ehand[MG_E_CSPEC] != e_cspec)
1089	+	return(put_cspec());
1090	+	c_ccvt(c_ccolor, C_CSXY);
1091	+	if (mg_ehand[MG_E_CXY] != c_hcolor)
1092	+	return(put_cxy());
1093		return(MG_OK);
1094		}

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Comparing ray/src/cv/mgflib/parser.c (file contents): Revision 1.2 by greg, Wed Jun 22 15:33:47 1994 UTC vs. Revision 1.19 by greg, Fri Oct 27 15:47:18 1995 UTC

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Comparing ray/src/cv/mgflib/parser.c (file contents):
Revision 1.2 by greg, Wed Jun 22 15:33:47 1994 UTC vs.
Revision 1.19 by greg, Fri Oct 27 15:47:18 1995 UTC