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

Comparing ray/src/rt/rtrace.c (file contents):
Revision 2.25 by gregl, Fri Oct 17 10:14:37 1997 UTC vs.
Revision 2.80 by greg, Thu Jul 4 01:06:35 2019 UTC

#	Line 1 \| Line 1
1	–	/* Copyright (c) 1997 Silicon Graphics, Inc. */
2	–
1		#ifndef lint
2	<	static char SCCSid[] = "$SunId$ SGI";
2	>	static const char RCSid[] = "$Id$";
3		#endif
6	–
4		/*
5		* rtrace.c - program and variables for individual ray tracing.
9	–	*
10	–	* 6/11/86
6		*/
7
8	+	#include "copyright.h"
9	+
10		/*
11		* Input is in the form:
12		*
#	Line 24 \| Line 21 \| static char SCCSid[] = "$SunId$ SGI";
21		* irradiance values are desired.
22		*/
23
24	<	#include "ray.h"
24	>	#include <time.h>
25
26	<	#include "octree.h"
27	<
26	>	#include "platform.h"
27	>	#include "ray.h"
28	>	#include "ambient.h"
29	>	#include "source.h"
30		#include "otypes.h"
31	<
31	>	#include "otspecial.h"
32		#include "resolu.h"
33	+	#include "random.h"
34
35	<	int dimlist[MAXDIM]; /* sampling dimensions */
36	<	int ndims = 0; /* number of sampling dimensions */
37	<	int samplendx = 0; /* index for this sample */
35	>	extern int inform; /* input format */
36	>	extern int outform; /* output format */
37	>	extern char outvals; / output values */
38
39	<	int imm_irrad = 0; /* compute immediate irradiance? */
40	<	int lim_dist = 0; /* limit distance? */
39	>	extern int imm_irrad; /* compute immediate irradiance? */
40	>	extern int lim_dist; /* limit distance? */
41
42	<	int inform = 'a'; /* input format */
43	<	int outform = 'a'; /* output format */
44	<	char outvals = "v"; / output specification */
42	>	extern char tralist[]; / list of modifers to trace (or no) */
43	>	extern int traincl; /* include == 1, exclude == 0 */
44
45	<	char tralist[128]; / list of modifers to trace (or no) */
46	<	int traincl = -1; /* include == 1, exclude == 0 */
48	<	#define MAXTSET 511 /* maximum number in trace set */
49	<	OBJECT traset[MAXTSET+1]={0}; /* trace include/exclude set */
45	>	extern int hresolu; /* horizontal resolution */
46	>	extern int vresolu; /* vertical resolution */
47
48	<	int hresolu = 0; /* horizontal (scan) size */
52	<	int vresolu = 0; /* vertical resolution */
48	>	static int castonly = 0;
49
50	<	double dstrsrc = 0.0; /* square source distribution */
51	<	double shadthresh = .05; /* shadow threshold */
52	<	double shadcert = .5; /* shadow certainty */
53	<	int directrelay = 2; /* number of source relays */
58	<	int vspretest = 512; /* virtual source pretest density */
59	<	int directvis = 1; /* sources visible? */
60	<	double srcsizerat = .2; /* maximum ratio source size/dist. */
50	>	#ifndef MAXTSET
51	>	#define MAXTSET 8191 /* maximum number in trace set */
52	>	#endif
53	>	OBJECT traset[MAXTSET+1]={0}; /* trace include/exclude set */
54
62	–	COLOR cextinction = BLKCOLOR; /* global extinction coefficient */
63	–	COLOR salbedo = BLKCOLOR; /* global scattering albedo */
64	–	double seccg = 0.; /* global scattering eccentricity */
65	–	double ssampdist = 0.; /* scatter sampling distance */
66	–
67	–	double specthresh = .15; /* specular sampling threshold */
68	–	double specjitter = 1.; /* specular sampling jitter */
69	–
70	–	int backvis = 1; /* back face visibility */
71	–
72	–	int maxdepth = 6; /* maximum recursion depth */
73	–	double minweight = 4e-3; /* minimum ray weight */
74	–
75	–	COLOR ambval = BLKCOLOR; /* ambient value */
76	–	int ambvwt = 0; /* initial weight for ambient value */
77	–	double ambacc = 0.2; /* ambient accuracy */
78	–	int ambres = 128; /* ambient resolution */
79	–	int ambdiv = 512; /* ambient divisions */
80	–	int ambssamp = 0; /* ambient super-samples */
81	–	int ambounce = 0; /* ambient bounces */
82	–	char amblist[128]; / ambient include/exclude list */
83	–	int ambincl = -1; /* include == 1, exclude == 0 */
84	–
85	–	extern OBJREC Lamb; /* a Lambertian surface */
86	–	extern OBJREC Aftplane; /* aft clipping object */
87	–
88	–
55		static RAY thisray; /* for our convenience */
56
57	<	static int oputo(), oputd(), oputv(), oputl(), oputL(),
58	<	oputp(), oputn(), oputN(), oputs(), oputw(), oputm();
57	>	typedef void putf_t(RREAL *v, int n);
58	>	static putf_t puta, putd, putf, putrgbe;
59
60	<	static int ourtrace(), tabin();
61	<	static int (ray_out[16])(), (every_out[16])();
62	<	static int castonly = 0;
60	>	typedef void oputf_t(RAY *r);
61	>	static oputf_t oputo, oputd, oputv, oputV, oputl, oputL, oputc, oputp,
62	>	oputr, oputR, oputx, oputX, oputn, oputN, oputs,
63	>	oputw, oputW, oputm, oputM, oputtilde;
64
65	<	static int puta(), putf(), putd();
65	>	static void setoutput(char *vs);
66	>	extern void tranotify(OBJECT obj);
67	>	static void bogusray(void);
68	>	static void raycast(RAY *r);
69	>	static void rayirrad(RAY *r);
70	>	static void rtcompute(FVECT org, FVECT dir, double dmax);
71	>	static int printvals(RAY *r);
72	>	static int getvec(FVECT vec, int fmt, FILE *fp);
73	>	static void tabin(RAY *r);
74	>	static void ourtrace(RAY *r);
75
76	<	static int (*putreal)();
76	>	static oputf_t ray_out[32], every_out[32];
77	>	static putf_t *putreal;
78
79
80	<	quit(code) /* quit program */
81	<	int code;
80	>	void
81	>	quit( /* quit program */
82	>	int code
83	>	)
84		{
85	<	#ifndef NIX
86	<	headclean(); /* delete header file */
87	<	pfclean(); /* clean up persist files */
85	>	if (ray_pnprocs > 0) /* close children if any */
86	>	ray_pclose(0);
87	>	#ifndef NON_POSIX
88	>	else if (!ray_pnprocs) {
89	>	headclean(); /* delete header file */
90	>	pfclean(); /* clean up persist files */
91	>	}
92		#endif
93		exit(code);
94		}
95
96
97		char *
98	<	formstr(f) /* return format identifier */
99	<	int f;
98	>	formstr( /* return format identifier */
99	>	int f
100	>	)
101		{
102		switch (f) {
103		case 'a': return("ascii");
#	Line 125 \| Line 109 \| int f;
109		}
110
111
112	<	rtrace(fname) /* trace rays from file */
113	<	char *fname;
112	>	extern void
113	>	rtrace( /* trace rays from file */
114	>	char *fname,
115	>	int nproc
116	>	)
117		{
118	<	long vcount = hresolu>1 ? hresolu*vresolu : vresolu;
119	<	long nextflush = hresolu;
118	>	unsigned long vcount = (hresolu > 1) ? (unsigned long)hresolu*vresolu
119	>	: (unsigned long)vresolu;
120	>	long nextflush = (vresolu > 0) & (hresolu > 1) ? 0 : hresolu;
121	>	int something2flush = 0;
122		FILE *fp;
123		double d;
124		FVECT orig, direc;
#	Line 140 \| Line 129 \| *char fname;**
129		sprintf(errmsg, "cannot open input file \"%s\"", fname);
130		error(SYSTEM, errmsg);
131		}
143	–	#ifdef MSDOS
132		if (inform != 'a')
133	<	setmode(fileno(fp), O_BINARY);
146	<	#endif
133	>	SET_FILE_BINARY(fp);
134		/* set up output */
135		setoutput(outvals);
136	+	if (imm_irrad)
137	+	castonly = 0;
138	+	else if (castonly)
139	+	nproc = 1; /* don't bother multiprocessing */
140	+	if ((nextflush > 0) & (nproc > nextflush)) {
141	+	error(WARNING, "reducing number of processes to match flush interval");
142	+	nproc = nextflush;
143	+	}
144		switch (outform) {
145		case 'a': putreal = puta; break;
146		case 'f': putreal = putf; break;
147		case 'd': putreal = putd; break;
148		case 'c':
149	<	if (strcmp(outvals, "v"))
150	<	error(USER, "color format with value output only");
151	<	break;
149	>	if (outvals[0] && (outvals[1] \|\| !strchr("vVWrx", outvals[0])))
150	>	error(USER, "color format only with one of 'vVWrx'");
151	>	putreal = putrgbe; break;
152		default:
153		error(CONSISTENCY, "botched output format");
154		}
155	+	if (nproc > 1) { /* start multiprocessing */
156	+	ray_popen(nproc);
157	+	ray_fifo_out = printvals;
158	+	}
159		if (hresolu > 0) {
160		if (vresolu > 0)
161		fprtresolu(hresolu, vresolu, stdout);
162	<	fflush(stdout);
162	>	else
163	>	fflush(stdout);
164		}
165		/* process file */
166		while (getvec(orig, inform, fp) == 0 &&
#	Line 168 \| Line 168 \| *char fname;**
168
169		d = normalize(direc);
170		if (d == 0.0) { /* zero ==> flush */
171	<	bogusray();
172	<	if (--nextflush <= 0) {
171	>	if ((--nextflush <= 0) \| !vcount && something2flush) {
172	>	if (ray_pnprocs > 1 && ray_fifo_flush() < 0)
173	>	error(USER, "child(ren) died");
174	>	bogusray();
175		fflush(stdout);
176	<	nextflush = hresolu;
177	<	}
178	<	} else {
179	<	samplendx++;
180	<	/* compute and print */
181	<	if (imm_irrad)
182	<	irrad(orig, direc);
181	<	else
182	<	rad(orig, direc, lim_dist ? d : 0.0);
176	>	something2flush = 0;
177	>	nextflush = (vresolu > 0) & (hresolu > 1) ? 0 :
178	>	hresolu;
179	>	} else
180	>	bogusray();
181	>	} else { /* compute and print */
182	>	rtcompute(orig, direc, lim_dist ? d : 0.0);
183		/* flush if time */
184	<	if (--nextflush == 0) {
184	>	if (!--nextflush) {
185	>	if (ray_pnprocs > 1 && ray_fifo_flush() < 0)
186	>	error(USER, "child(ren) died");
187		fflush(stdout);
188		nextflush = hresolu;
189	<	}
189	>	} else
190	>	something2flush = 1;
191		}
192		if (ferror(stdout))
193		error(SYSTEM, "write error");
194	<	if (--vcount == 0) /* check for end */
194	>	if (vcount && !--vcount) /* check for end */
195		break;
196		}
197	<	fflush(stdout);
198	<	if (vcount > 0)
199	<	error(USER, "read error");
197	>	if (ray_pnprocs > 1) { /* clean up children */
198	>	if (ray_fifo_flush() < 0)
199	>	error(USER, "unable to complete processing");
200	>	ray_pclose(0);
201	>	}
202	>	if (fflush(stdout) < 0)
203	>	error(SYSTEM, "write error");
204	>	if (vcount)
205	>	error(USER, "unexpected EOF on input");
206		if (fname != NULL)
207		fclose(fp);
208		}
209
210
211	<	setoutput(vs) /* set up output tables */
212	<	register char *vs;
211	>	static void
212	>	trace_sources(void) /* trace rays to light sources, also */
213		{
214	<	extern int (*trace)();
215	<	register int (**table)() = ray_out;
214	>	int sn;
215	>
216	>	for (sn = 0; sn < nsources; sn++)
217	>	source[sn].sflags \|= SFOLLOW;
218	>	}
219
220	+
221	+	static void
222	+	setoutput( /* set up output tables */
223	+	char *vs
224	+	)
225	+	{
226	+	oputf_t **table = ray_out;
227	+
228		castonly = 1;
229		while (*vs)
230		switch (*vs++) {
231	+	case 'T': /* trace sources */
232	+	if (!*vs) break;
233	+	trace_sources();
234	+	/* fall through */
235		case 't': /* trace */
236	+	if (!*vs) break;
237		*table = NULL;
238		table = every_out;
239		trace = ourtrace;
#	Line 220 \| Line 245 \| *register char vs;**
245		case 'd': /* direction */
246		*table++ = oputd;
247		break;
248	+	case 'r': /* reflected contrib. */
249	+	*table++ = oputr;
250	+	castonly = 0;
251	+	break;
252	+	case 'R': /* reflected distance */
253	+	*table++ = oputR;
254	+	castonly = 0;
255	+	break;
256	+	case 'x': /* xmit contrib. */
257	+	*table++ = oputx;
258	+	castonly = 0;
259	+	break;
260	+	case 'X': /* xmit distance */
261	+	*table++ = oputX;
262	+	castonly = 0;
263	+	break;
264		case 'v': /* value */
265		*table++ = oputv;
266		castonly = 0;
267		break;
268	+	case 'V': /* contribution */
269	+	*table++ = oputV;
270	+	castonly = 0;
271	+	if (ambounce > 0 && (ambacc > FTINY \|\| ambssamp > 0))
272	+	error(WARNING,
273	+	"-otV accuracy depends on -aa 0 -as 0");
274	+	break;
275		case 'l': /* effective distance */
276		*table++ = oputl;
277		castonly = 0;
278		break;
279	+	case 'c': /* local coordinates */
280	+	*table++ = oputc;
281	+	break;
282		case 'L': /* single ray length */
283		*table++ = oputL;
284		break;
#	Line 247 \| Line 298 \| *register char vs;**
298		case 'w': /* weight */
299		*table++ = oputw;
300		break;
301	+	case 'W': /* coefficient */
302	+	*table++ = oputW;
303	+	castonly = 0;
304	+	if (ambounce > 0 && (ambacc > FTINY) \| (ambssamp > 0))
305	+	error(WARNING,
306	+	"-otW accuracy depends on -aa 0 -as 0");
307	+	break;
308		case 'm': /* modifier */
309		*table++ = oputm;
310		break;
311	+	case 'M': /* material */
312	+	*table++ = oputM;
313	+	break;
314	+	case '~': /* tilde */
315	+	*table++ = oputtilde;
316	+	break;
317		}
318		*table = NULL;
319	+	if (do_irrad \| imm_irrad) /* compatibile? */
320	+	for (table = ray_out; *table != NULL; table++)
321	+	if ((table == oputr) \| (table == oputR) \|
322	+	(table == oputx) \| (table == oputX)) {
323	+	error(WARNING, "-orRxX options incompatible with -I+ and -i+");
324	+	break;
325	+	}
326		}
327
328
329	<	bogusray() /* print out empty record */
329	>	static void
330	>	bogusray(void) /* print out empty record */
331		{
332	<	thisray.rorg[0] = thisray.rorg[1] = thisray.rorg[2] =
261	<	thisray.rdir[0] = thisray.rdir[1] = thisray.rdir[2] = 0.0;
262	<	rayorigin(&thisray, NULL, PRIMARY, 1.0);
332	>	rayorigin(&thisray, PRIMARY, NULL, NULL);
333		printvals(&thisray);
334		}
335
336
337	<	rad(org, dir, dmax) /* compute and print ray value(s) */
338	<	FVECT org, dir;
339	<	double dmax;
337	>	static void
338	>	raycast( /* compute first ray intersection only */
339	>	RAY *r
340	>	)
341		{
342	<	VCOPY(thisray.rorg, org);
343	<	VCOPY(thisray.rdir, dir);
344	<	thisray.rmax = dmax;
345	<	rayorigin(&thisray, NULL, PRIMARY, 1.0);
346	<	if (castonly) {
347	<	if (!localhit(&thisray, &thescene))
348	<	if (thisray.ro == &Aftplane) { /* clipped */
278	<	thisray.ro = NULL;
279	<	thisray.rot = FHUGE;
280	<	} else
281	<	sourcehit(&thisray);
282	<	} else
283	<	rayvalue(&thisray);
284	<	printvals(&thisray);
342	>	if (!localhit(r, &thescene)) {
343	>	if (r->ro == &Aftplane) { /* clipped */
344	>	r->ro = NULL;
345	>	r->rot = FHUGE;
346	>	} else
347	>	sourcehit(r);
348	>	}
349		}
350
351
352	<	irrad(org, dir) /* compute immediate irradiance value */
353	<	FVECT org, dir;
352	>	static void
353	>	rayirrad( /* compute irradiance rather than radiance */
354	>	RAY *r
355	>	)
356		{
357	<	register int i;
357	>	void (old_revf)(RAY ) = r->revf;
358	>	/* pretend we hit surface */
359	>	r->rxt = r->rot = 1e-5;
360	>	VSUM(r->rop, r->rorg, r->rdir, r->rot);
361	>	r->ron[0] = -r->rdir[0];
362	>	r->ron[1] = -r->rdir[1];
363	>	r->ron[2] = -r->rdir[2];
364	>	r->rod = 1.0;
365	>	/* compute result */
366	>	r->revf = raytrace;
367	>	(*ofun[Lamb.otype].funp)(&Lamb, r);
368	>	r->revf = old_revf;
369	>	}
370
371	<	for (i = 0; i < 3; i++) {
372	<	thisray.rorg[i] = org[i] + dir[i];
373	<	thisray.rdir[i] = -dir[i];
371	>
372	>	static void
373	>	rtcompute( /* compute and print ray value(s) */
374	>	FVECT org,
375	>	FVECT dir,
376	>	double dmax
377	>	)
378	>	{
379	>	/* set up ray */
380	>	rayorigin(&thisray, PRIMARY, NULL, NULL);
381	>	if (imm_irrad) {
382	>	VSUM(thisray.rorg, org, dir, 1.1e-4);
383	>	thisray.rdir[0] = -dir[0];
384	>	thisray.rdir[1] = -dir[1];
385	>	thisray.rdir[2] = -dir[2];
386	>	thisray.rmax = 0.0;
387	>	thisray.revf = rayirrad;
388	>	} else {
389	>	VCOPY(thisray.rorg, org);
390	>	VCOPY(thisray.rdir, dir);
391	>	thisray.rmax = dmax;
392	>	if (castonly)
393	>	thisray.revf = raycast;
394		}
395	<	rayorigin(&thisray, NULL, PRIMARY, 1.0);
396	<	/* pretend we hit surface */
397	<	thisray.rot = 1.0-1e-4;
398	<	thisray.rod = 1.0;
399	<	VCOPY(thisray.ron, dir);
400	<	for (i = 0; i < 3; i++) /* fudge factor */
401	<	thisray.rop[i] = org[i] + 1e-4*dir[i];
304	<	/* compute and print */
305	<	(*ofun[Lamb.otype].funp)(&Lamb, &thisray);
395	>	if (ray_pnprocs > 1) { /* multiprocessing FIFO? */
396	>	if (ray_fifo_in(&thisray) < 0)
397	>	error(USER, "lost children");
398	>	return;
399	>	}
400	>	samplendx++; /* else do it ourselves */
401	>	rayvalue(&thisray);
402		printvals(&thisray);
403		}
404
405
406	<	printvals(r) /* print requested ray values */
407	<	RAY *r;
406	>	static int
407	>	printvals( /* print requested ray values */
408	>	RAY *r
409	>	)
410		{
411	<	register int (**tp)();
411	>	oputf_t **tp;
412
413		if (ray_out[0] == NULL)
414	<	return;
414	>	return(0);
415		for (tp = ray_out; *tp != NULL; tp++)
416		(**tp)(r);
417		if (outform == 'a')
418		putchar('\n');
419	+	return(1);
420		}
421
422
423	<	getvec(vec, fmt, fp) /* get a vector from fp */
424	<	register FVECT vec;
425	<	int fmt;
426	<	FILE *fp;
423	>	static int
424	>	getvec( /* get a vector from fp */
425	>	FVECT vec,
426	>	int fmt,
427	>	FILE *fp
428	>	)
429		{
329	–	extern char *fgetword();
430		static float vf[3];
431		static double vd[3];
432		char buf[32];
433	<	register int i;
433	>	int i;
434
435		switch (fmt) {
436		case 'a': /* ascii */
#	Line 342 \| Line 442 \| *FILE fp;**
442		}
443		break;
444		case 'f': /* binary float */
445	<	if (fread((char *)vf, sizeof(float), 3, fp) != 3)
445	>	if (getbinary(vf, sizeof(float), 3, fp) != 3)
446		return(-1);
447	<	vec[0] = vf[0]; vec[1] = vf[1]; vec[2] = vf[2];
447	>	VCOPY(vec, vf);
448		break;
449		case 'd': /* binary double */
450	<	if (fread((char *)vd, sizeof(double), 3, fp) != 3)
450	>	if (getbinary(vd, sizeof(double), 3, fp) != 3)
451		return(-1);
452	<	vec[0] = vd[0]; vec[1] = vd[1]; vec[2] = vd[2];
452	>	VCOPY(vec, vd);
453		break;
454		default:
455		error(CONSISTENCY, "botched input format");
#	Line 358 \| Line 458 \| *FILE fp;**
458		}
459
460
461	<	tranotify(obj) /* record new modifier */
462	<	OBJECT obj;
461	>	void
462	>	tranotify( /* record new modifier */
463	>	OBJECT obj
464	>	)
465		{
466		static int hitlimit = 0;
467	<	register OBJREC *o = objptr(obj);
468	<	register char **tralp;
467	>	OBJREC *o = objptr(obj);
468	>	char **tralp;
469
470	+	if (obj == OVOID) { /* starting over */
471	+	traset[0] = 0;
472	+	hitlimit = 0;
473	+	return;
474	+	}
475		if (hitlimit \|\| !ismodifier(o->otype))
476		return;
477		for (tralp = tralist; *tralp != NULL; tralp++)
#	Line 380 \| Line 487 \| OBJECT obj;
487		}
488
489
490	<	static
491	<	ourtrace(r) /* print ray values */
492	<	RAY *r;
490	>	static void
491	>	ourtrace( /* print ray values */
492	>	RAY *r
493	>	)
494		{
495	<	register int (**tp)();
495	>	oputf_t **tp;
496
497		if (every_out[0] == NULL)
498		return;
#	Line 396 \| Line 504 \| *RAY r;**
504		tabin(r);
505		for (tp = every_out; *tp != NULL; tp++)
506		(**tp)(r);
507	<	putchar('\n');
507	>	if (outform == 'a')
508	>	putchar('\n');
509		}
510
511
512	<	static
513	<	tabin(r) /* tab in appropriate amount */
514	<	RAY *r;
512	>	static void
513	>	tabin( /* tab in appropriate amount */
514	>	RAY *r
515	>	)
516		{
517	<	register RAY *rp;
517	>	const RAY *rp;
518
519		for (rp = r->parent; rp != NULL; rp = rp->parent)
520		putchar('\t');
521		}
522
523
524	<	static
525	<	oputo(r) /* print origin */
526	<	register RAY *r;
524	>	static void
525	>	oputo( /* print origin */
526	>	RAY *r
527	>	)
528		{
529	<	(*putreal)(r->rorg[0]);
419	<	(*putreal)(r->rorg[1]);
420	<	(*putreal)(r->rorg[2]);
529	>	(*putreal)(r->rorg, 3);
530		}
531
532
533	<	static
534	<	oputd(r) /* print direction */
535	<	register RAY *r;
533	>	static void
534	>	oputd( /* print direction */
535	>	RAY *r
536	>	)
537		{
538	<	(*putreal)(r->rdir[0]);
429	<	(*putreal)(r->rdir[1]);
430	<	(*putreal)(r->rdir[2]);
538	>	(*putreal)(r->rdir, 3);
539		}
540
541
542	<	static
543	<	oputv(r) /* print value */
544	<	register RAY *r;
542	>	static void
543	>	oputr( /* print mirrored contribution */
544	>	RAY *r
545	>	)
546		{
547	<	COLR cout;
548	<
549	<	if (outform == 'c') {
550	<	setcolr(cout, colval(r->rcol,RED),
551	<	colval(r->rcol,GRN),
552	<	colval(r->rcol,BLU));
444	<	fwrite((char *)cout, sizeof(cout), 1, stdout);
445	<	return;
446	<	}
447	<	(*putreal)(colval(r->rcol,RED));
448	<	(*putreal)(colval(r->rcol,GRN));
449	<	(*putreal)(colval(r->rcol,BLU));
547	>	RREAL cval[3];
548	>
549	>	cval[0] = colval(r->mcol,RED);
550	>	cval[1] = colval(r->mcol,GRN);
551	>	cval[2] = colval(r->mcol,BLU);
552	>	(*putreal)(cval, 3);
553		}
554
555
556	<	static
557	<	oputl(r) /* print effective distance */
558	<	register RAY *r;
556	>
557	>	static void
558	>	oputR( /* print mirrored distance */
559	>	RAY *r
560	>	)
561		{
562	<	(*putreal)(r->rt);
562	>	(*putreal)(&r->rmt, 1);
563		}
564
565
566	<	static
567	<	oputL(r) /* print single ray length */
568	<	register RAY *r;
566	>	static void
567	>	oputx( /* print unmirrored contribution */
568	>	RAY *r
569	>	)
570		{
571	<	(*putreal)(r->rot);
571	>	RREAL cval[3];
572	>
573	>	cval[0] = colval(r->rcol,RED) - colval(r->mcol,RED);
574	>	cval[1] = colval(r->rcol,GRN) - colval(r->mcol,GRN);
575	>	cval[2] = colval(r->rcol,BLU) - colval(r->mcol,BLU);
576	>	(*putreal)(cval, 3);
577		}
578
579
580	<	static
581	<	oputp(r) /* print point */
582	<	register RAY *r;
580	>	static void
581	>	oputX( /* print unmirrored distance */
582	>	RAY *r
583	>	)
584		{
585	<	if (r->rot < FHUGE) {
474	<	(*putreal)(r->rop[0]);
475	<	(*putreal)(r->rop[1]);
476	<	(*putreal)(r->rop[2]);
477	<	} else {
478	<	(*putreal)(0.0);
479	<	(*putreal)(0.0);
480	<	(*putreal)(0.0);
481	<	}
585	>	(*putreal)(&r->rxt, 1);
586		}
587
588
589	<	static
590	<	oputN(r) /* print unperturbed normal */
591	<	register RAY *r;
589	>	static void
590	>	oputv( /* print value */
591	>	RAY *r
592	>	)
593		{
594	<	if (r->rot < FHUGE) {
595	<	(*putreal)(r->ron[0]);
596	<	(*putreal)(r->ron[1]);
597	<	(*putreal)(r->ron[2]);
598	<	} else {
599	<	(*putreal)(0.0);
495	<	(*putreal)(0.0);
496	<	(*putreal)(0.0);
497	<	}
594	>	RREAL cval[3];
595	>
596	>	cval[0] = colval(r->rcol,RED);
597	>	cval[1] = colval(r->rcol,GRN);
598	>	cval[2] = colval(r->rcol,BLU);
599	>	(*putreal)(cval, 3);
600		}
601
602
603	<	static
604	<	oputn(r) /* print perturbed normal */
605	<	RAY *r;
603	>	static void
604	>	oputV( /* print value contribution */
605	>	RAY *r
606	>	)
607		{
608	+	RREAL contr[3];
609	+
610	+	raycontrib(contr, r, PRIMARY);
611	+	multcolor(contr, r->rcol);
612	+	(*putreal)(contr, 3);
613	+	}
614	+
615	+
616	+	static void
617	+	oputl( /* print effective distance */
618	+	RAY *r
619	+	)
620	+	{
621	+	RREAL d = raydistance(r);
622	+
623	+	(*putreal)(&d, 1);
624	+	}
625	+
626	+
627	+	static void
628	+	oputL( /* print single ray length */
629	+	RAY *r
630	+	)
631	+	{
632	+	(*putreal)(&r->rot, 1);
633	+	}
634	+
635	+
636	+	static void
637	+	oputc( /* print local coordinates */
638	+	RAY *r
639	+	)
640	+	{
641	+	(*putreal)(r->uv, 2);
642	+	}
643	+
644	+
645	+	static RREAL vdummy[3] = {0.0, 0.0, 0.0};
646	+
647	+
648	+	static void
649	+	oputp( /* print point */
650	+	RAY *r
651	+	)
652	+	{
653	+	if (r->rot < FHUGE)
654	+	(*putreal)(r->rop, 3);
655	+	else
656	+	(*putreal)(vdummy, 3);
657	+	}
658	+
659	+
660	+	static void
661	+	oputN( /* print unperturbed normal */
662	+	RAY *r
663	+	)
664	+	{
665	+	if (r->rot < FHUGE)
666	+	(*putreal)(r->ron, 3);
667	+	else
668	+	(*putreal)(vdummy, 3);
669	+	}
670	+
671	+
672	+	static void
673	+	oputn( /* print perturbed normal */
674	+	RAY *r
675	+	)
676	+	{
677		FVECT pnorm;
678
679		if (r->rot >= FHUGE) {
680	<	(*putreal)(0.0);
509	<	(*putreal)(0.0);
510	<	(*putreal)(0.0);
680	>	(*putreal)(vdummy, 3);
681		return;
682		}
683		raynormal(pnorm, r);
684	<	(*putreal)(pnorm[0]);
515	<	(*putreal)(pnorm[1]);
516	<	(*putreal)(pnorm[2]);
684	>	(*putreal)(pnorm, 3);
685		}
686
687
688	<	static
689	<	oputs(r) /* print name */
690	<	register RAY *r;
688	>	static void
689	>	oputs( /* print name */
690	>	RAY *r
691	>	)
692		{
693		if (r->ro != NULL)
694		fputs(r->ro->oname, stdout);
#	Line 529 \| Line 698 \| *register RAY r;**
698		}
699
700
701	<	static
702	<	oputw(r) /* print weight */
703	<	register RAY *r;
701	>	static void
702	>	oputw( /* print weight */
703	>	RAY *r
704	>	)
705		{
706	<	(*putreal)(r->rweight);
706	>	RREAL rwt = r->rweight;
707	>
708	>	(*putreal)(&rwt, 1);
709		}
710
711
712	<	static
713	<	oputm(r) /* print modifier */
714	<	register RAY *r;
712	>	static void
713	>	oputW( /* print coefficient */
714	>	RAY *r
715	>	)
716		{
717	+	RREAL contr[3];
718	+	/* shadow ray not on source? */
719	+	if (r->rsrc >= 0 && source[r->rsrc].so != r->ro)
720	+	setcolor(contr, 0.0, 0.0, 0.0);
721	+	else
722	+	raycontrib(contr, r, PRIMARY);
723	+
724	+	(*putreal)(contr, 3);
725	+	}
726	+
727	+
728	+	static void
729	+	oputm( /* print modifier */
730	+	RAY *r
731	+	)
732	+	{
733		if (r->ro != NULL)
734		if (r->ro->omod != OVOID)
735		fputs(objptr(r->ro->omod)->oname, stdout);
#	Line 552 \| Line 741 \| *register RAY r;**
741		}
742
743
744	<	static
745	<	puta(v) /* print ascii value */
746	<	double v;
744	>	static void
745	>	oputM( /* print material */
746	>	RAY *r
747	>	)
748		{
749	<	printf("%e\t", v);
749	>	OBJREC *mat;
750	>
751	>	if (r->ro != NULL) {
752	>	if ((mat = findmaterial(r->ro)) != NULL)
753	>	fputs(mat->oname, stdout);
754	>	else
755	>	fputs(VOIDID, stdout);
756	>	} else
757	>	putchar('*');
758	>	putchar('\t');
759		}
760
761
762	<	static
763	<	putd(v) /* print binary double */
764	<	double v;
762	>	static void
763	>	oputtilde( /* output tilde (spacer) */
764	>	RAY *r
765	>	)
766		{
767	<	fwrite((char *)&v, sizeof(v), 1, stdout);
767	>	fputs("~\t", stdout);
768		}
769
770
771	<	static
772	<	putf(v) /* print binary float */
773	<	double v;
771	>	static void
772	>	puta( /* print ascii value(s) */
773	>	RREAL *v, int n
774	>	)
775		{
776	<	float f = v;
776	>	if (n == 3) {
777	>	printf("%e\t%e\t%e\t", v[0], v[1], v[2]);
778	>	return;
779	>	}
780	>	while (n--)
781	>	printf("%e\t", *v++);
782	>	}
783
784	<	fwrite((char *)&f, sizeof(f), 1, stdout);
784	>
785	>	static void
786	>	putd(RREAL v, int n) / output binary double(s) */
787	>	{
788	>	#ifdef SMLFLT
789	>	double da[3];
790	>	int i;
791	>
792	>	if (n > 3)
793	>	error(INTERNAL, "code error in putd()");
794	>	for (i = n; i--; )
795	>	da[i] = v[i];
796	>	putbinary(da, sizeof(double), n, stdout);
797	>	#else
798	>	putbinary(v, sizeof(RREAL), n, stdout);
799	>	#endif
800	>	}
801	>
802	>
803	>	static void
804	>	putf(RREAL v, int n) / output binary float(s) */
805	>	{
806	>	#ifndef SMLFLT
807	>	float fa[3];
808	>	int i;
809	>
810	>	if (n > 3)
811	>	error(INTERNAL, "code error in putf()");
812	>	for (i = n; i--; )
813	>	fa[i] = v[i];
814	>	putbinary(fa, sizeof(float), n, stdout);
815	>	#else
816	>	putbinary(v, sizeof(RREAL), n, stdout);
817	>	#endif
818	>	}
819	>
820	>
821	>	static void
822	>	putrgbe(RREAL v, int n) / output RGBE color */
823	>	{
824	>	COLR cout;
825	>
826	>	if (n != 3)
827	>	error(INTERNAL, "putrgbe() not called with 3 components");
828	>	setcolr(cout, v[0], v[1], v[2]);
829	>	putbinary(cout, sizeof(cout), 1, stdout);
830		}

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Comparing ray/src/rt/rtrace.c (file contents): Revision 2.25 by gregl, Fri Oct 17 10:14:37 1997 UTC vs. Revision 2.80 by greg, Thu Jul 4 01:06:35 2019 UTC

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Comparing ray/src/rt/rtrace.c (file contents):
Revision 2.25 by gregl, Fri Oct 17 10:14:37 1997 UTC vs.
Revision 2.80 by greg, Thu Jul 4 01:06:35 2019 UTC