[ViewVC] Diff of: radiance/ray/src/hd/rholo3.c

Comparing ray/src/hd/rholo3.c (file contents):
Revision 3.4 by gregl, Tue Nov 4 11:52:21 1997 UTC vs.
Revision 3.39 by greg, Mon Jul 7 17:21:51 2003 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		* Routines for tracking beam compuatations
6		*/
7
8	+	#include <string.h>
9	+
10		#include "rholo.h"
11	+	#include "view.h"
12
13	+	#ifndef NFRAG2CHUNK
14	+	#define NFRAG2CHUNK 4096 /* number of fragments to start chunking */
15	+	#endif
16
17	+	#ifndef abs
18		#define abs(x) ((x) > 0 ? (x) : -(x))
19	+	#endif
20	+	#ifndef sgn
21		#define sgn(x) ((x) > 0 ? 1 : (x) < 0 ? -1 : 0)
22	+	#endif
23
24	+	#define rchunk(n) (((n)+(RPACKSIZ/2))/RPACKSIZ)
25
26	+	extern time_t time();
27	+
28	+	int chunkycmp = 0; /* clump beams together on disk */
29	+
30		static PACKHEAD complist=NULL; / list of beams to compute */
31		static int complen=0; /* length of complist */
32		static int listpos=0; /* current list position for next_packet */
#	Line 22 \| Line 34 \| *static int lastin= -1; / last ordered position in lis**
34
35
36		int
37	<	beamcmp(b0, b1) /* comparison for descending compute order */
37	>	beamcmp(b0, b1) /* comparison for compute order */
38		register PACKHEAD b0, b1;
39		{
40	<	return( b1->nr*(bnrays(hdlist[b0->hd],b0->bi)+1) -
41	<	b0->nr*(bnrays(hdlist[b1->hd],b1->bi)+1) );
40	>	BEAMI bip0, bip1;
41	>	register long c;
42	>	/* first check desired quantities */
43	>	if (chunkycmp)
44	>	c = rchunk(b1->nr)*(rchunk(b0->nc)+1L) -
45	>	rchunk(b0->nr)*(rchunk(b1->nc)+1L);
46	>	else
47	>	c = b1->nr(b0->nc+1L) - b0->nr(b1->nc+1L);
48	>	if (c > 0) return(1);
49	>	if (c < 0) return(-1);
50	>	/* only one file, so skip the following: */
51	>	#if 0
52	>	/* next, check file descriptors */
53	>	c = hdlist[b0->hd]->fd - hdlist[b1->hd]->fd;
54	>	if (c) return(c);
55	>	#endif
56	>	/* finally, check file positions */
57	>	bip0 = &hdlist[b0->hd]->bi[b0->bi];
58	>	bip1 = &hdlist[b1->hd]->bi[b1->bi];
59	>	/* put diskless beams last */
60	>	if (!bip0->nrd)
61	>	return(bip1->nrd > 0);
62	>	if (!bip1->nrd)
63	>	return(-1);
64	>	c = bip0->fo - bip1->fo;
65	>	return(c < 0 ? -1 : c > 0);
66		}
67
68
69	+	int
70	+	beamidcmp(b0, b1) /* comparison for beam searching */
71	+	register PACKHEAD b0, b1;
72	+	{
73	+	register int c = b0->hd - b1->hd;
74	+
75	+	if (c) return(c);
76	+	return(b0->bi - b1->bi);
77	+	}
78	+
79	+
80	+	void
81	+	dispbeam(b, hb) /* display a holodeck beam */
82	+	register BEAM *b;
83	+	register HDBEAMI *hb;
84	+	{
85	+	static int n = 0;
86	+	static PACKHEAD *p = NULL;
87	+
88	+	if (b == NULL)
89	+	return;
90	+	if (b->nrm > n) { /* (re)allocate packet holder */
91	+	n = b->nrm;
92	+	if (p == NULL) p = (PACKHEAD *)malloc(packsiz(n));
93	+	else p = (PACKHEAD )realloc((void )p, packsiz(n));
94	+	CHECK(p==NULL, SYSTEM, "out of memory in dispbeam");
95	+	}
96	+	/* assign packet fields */
97	+	memcpy((void )packra(p), (void )hdbray(b), b->nrm*sizeof(RAYVAL));
98	+	p->nr = p->nc = b->nrm;
99	+	for (p->hd = 0; hdlist[p->hd] != hb->h; p->hd++)
100	+	if (hdlist[p->hd] == NULL)
101	+	error(CONSISTENCY, "unregistered holodeck in dispbeam");
102	+	p->bi = hb->b;
103	+	disp_packet(p); /* display it */
104	+	if (n >= 1024) { /* free ridiculous packets */
105	+	free((void *)p);
106	+	p = NULL; n = 0;
107	+	}
108	+	}
109	+
110	+
111		bundle_set(op, clist, nents) /* bundle set operation */
112		int op;
113		PACKHEAD *clist;
114		int nents;
115		{
116	<	BEAM *b;
117	<	PACKHEAD *p;
118	<	register int i, n;
119	<
116	>	int oldnr, n;
117	>	HDBEAMI *hbarr;
118	>	register PACKHEAD *csm;
119	>	register int i;
120	>	/* search for common members */
121	>	for (csm = clist+nents; csm-- > clist; )
122	>	csm->nc = -1;
123	>	qsort((void *)clist, nents, sizeof(PACKHEAD), beamidcmp);
124	>	for (i = 0; i < complen; i++) {
125	>	csm = (PACKHEAD )bsearch((void )(complist+i), (void *)clist,
126	>	nents, sizeof(PACKHEAD), beamidcmp);
127	>	if (csm == NULL)
128	>	continue;
129	>	oldnr = complist[i].nr;
130	>	csm->nc = complist[i].nc;
131	>	switch (op) {
132	>	case BS_ADD: /* add to count */
133	>	complist[i].nr += csm->nr;
134	>	csm->nr = 0;
135	>	break;
136	>	case BS_MAX: /* maximum of counts */
137	>	if (csm->nr > complist[i].nr)
138	>	complist[i].nr = csm->nr;
139	>	csm->nr = 0;
140	>	break;
141	>	case BS_ADJ: /* reset count */
142	>	complist[i].nr = csm->nr;
143	>	csm->nr = 0;
144	>	break;
145	>	case BS_DEL: /* delete count */
146	>	if (csm->nr == 0 \|\| csm->nr >= complist[i].nr)
147	>	complist[i].nr = 0;
148	>	else
149	>	complist[i].nr -= csm->nr;
150	>	break;
151	>	}
152	>	if (complist[i].nr != oldnr)
153	>	lastin = -1; /* flag sort */
154	>	}
155	>	/* record computed rays for uncommon beams */
156	>	for (csm = clist+nents; csm-- > clist; )
157	>	if (csm->nc < 0)
158	>	csm->nc = bnrays(hdlist[csm->hd], csm->bi);
159	>	/* complete list operations */
160		switch (op) {
161		case BS_NEW: /* new computation set */
162	<	if (complen)
163	<	free((char *)complist);
164	<	if (nents <= 0) {
165	<	complist = NULL;
166	<	listpos = complen = 0;
49	<	lastin = -1;
162	>	listpos = 0; lastin = -1;
163	>	if (complen) /* free old list */
164	>	free((void *)complist);
165	>	complist = NULL;
166	>	if (!(complen = nents))
167		return;
51	–	}
168		complist = (PACKHEAD )malloc(nentssizeof(PACKHEAD));
169		if (complist == NULL)
170		goto memerr;
171	<	bcopy((char )clist, (char )complist, nents*sizeof(PACKHEAD));
56	<	complen = nents;
57	<	listpos = 0;
58	<	lastin = -1; /* flag for initial sort */
171	>	memcpy((void )complist, (void )clist, nents*sizeof(PACKHEAD));
172		break;
173		case BS_ADD: /* add to computation set */
174	+	case BS_MAX: /* maximum of quantities */
175	+	case BS_ADJ: /* adjust set quantities */
176		if (nents <= 0)
177		return;
178	<	/* merge any common members */
179	<	for (i = 0; i < complen; i++)
65	<	for (n = 0; n < nents; n++)
66	<	if (clist[n].bi == complist[i].bi &&
67	<	clist[n].hd == complist[i].hd) {
68	<	complist[i].nr += clist[n].nr;
69	<	clist[n].nr = 0;
70	<	lastin = -1; /* flag full sort */
71	<	break;
72	<	}
73	<	/* sort updated list */
74	<	sortcomplist();
75	<	/* sort new entries */
76	<	qsort((char *)clist, nents, sizeof(PACKHEAD), beamcmp);
178	>	sortcomplist(); /* sort updated list & new entries */
179	>	qsort((void *)clist, nents, sizeof(PACKHEAD), beamcmp);
180		/* what can't we satisfy? */
181	<	for (n = 0; n < nents && clist[n].nr >
79	<	bnrays(hdlist[clist[n].hd],clist[n].bi); n++)
181	>	for (i = nents, csm = clist; i-- && csm->nr > csm->nc; csm++)
182		;
183	+	n = csm - clist;
184	+	if (op != BS_ADD) { /* don't regenerate adjusted beams */
185	+	for (++i; i-- && csm->nr > 0; csm++)
186	+	;
187	+	nents = csm - clist;
188	+	}
189		if (n) { /* allocate space for merged list */
190		PACKHEAD *newlist;
191		newlist = (PACKHEAD *)malloc(
#	Line 87 \| Line 195 \| int nents;
195		/* merge lists */
196		mergeclists(newlist, clist, n, complist, complen);
197		if (complen)
198	<	free((char *)complist);
198	>	free((void *)complist);
199		complist = newlist;
200		complen += n;
201		}
#	Line 95 \| Line 203 \| int nents;
203		lastin = complen-1; /* list is now sorted */
204		break;
205		case BS_DEL: /* delete from computation set */
206	<	if (nents <= 0)
99	<	return;
100	<	/* find each member */
101	<	for (i = 0; i < complen; i++)
102	<	for (n = 0; n < nents; n++)
103	<	if (clist[n].bi == complist[i].bi &&
104	<	clist[n].hd == complist[i].hd) {
105	<	if (clist[n].nr == 0 \|\|
106	<	clist[n].nr >= complist[i].nr)
107	<	complist[i].nr = 0;
108	<	else
109	<	complist[i].nr -= clist[n].nr;
110	<	lastin = -1; /* flag full sort */
111	<	break;
112	<	}
113	<	if (lastin < 0) /* sort updated list */
114	<	sortcomplist();
115	<	return; /* no display */
206	>	return; /* already done */
207		default:
208		error(CONSISTENCY, "bundle_set called with unknown operation");
209		}
210	<	n = 0; /* allocate packet holder */
211	<	for (i = 0; i < nents; i++)
212	<	if (clist[i].nr > n)
213	<	n = clist[i].nr;
214	<	p = (PACKHEAD )malloc(sizeof(PACKHEAD) + nsizeof(RAYVAL));
215	<	if (p == NULL)
216	<	goto memerr;
217	<	/* display what we have */
218	<	for (i = 0; i < nents; i++)
219	<	if ((b = hdgetbeam(hdlist[clist[i].hd], clist[i].bi)) != NULL) {
220	<	bcopy((char )hdbray(b), (char )(p+1),
221	<	(p->nr=b->nrm)*sizeof(RAYVAL));
222	<	disp_packet((PACKET *)p);
223	<	}
133	<	free((char )p); / clean up */
210	>	if (outdev == NULL \|\| !nents) /* nothing to display? */
211	>	return;
212	>	/* load and display beams we have */
213	>	hbarr = (HDBEAMI )malloc(nentssizeof(HDBEAMI));
214	>	for (i = nents; i--; ) {
215	>	hbarr[i].h = hdlist[clist[i].hd];
216	>	hbarr[i].b = clist[i].bi;
217	>	}
218	>	hdloadbeams(hbarr, nents, dispbeam);
219	>	free((void *)hbarr);
220	>	if (hdfragflags&FF_READ) {
221	>	listpos = 0;
222	>	lastin = -1; /* need to re-sort list */
223	>	}
224		return;
225		memerr:
226		error(SYSTEM, "out of memory in bundle_set");
227		}
228
229
230	<	int
231	<	weightf(hp, x0, x1, x2) /* voxel weighting function */
142	<	register HOLO *hp;
143	<	register int x0, x1, x2;
144	<	{
145	<	switch (vlet(OCCUPANCY)) {
146	<	case 'U': /* uniform weighting */
147	<	return(1);
148	<	case 'C': /* center weighting (crude) */
149	<	x0 += x0 - hp->grid[0] + 1;
150	<	x0 = abs(x0)hp->grid[1]hp->grid[2];
151	<	x1 += x1 - hp->grid[1] + 1;
152	<	x1 = abs(x1)hp->grid[0]hp->grid[2];
153	<	x2 += x2 - hp->grid[2] + 1;
154	<	x2 = abs(x2)hp->grid[0]hp->grid[1];
155	<	return(hp->grid[0]hp->grid[1]hp->grid[2] -
156	<	(x0+x1+x2)/3);
157	<	default:
158	<	badvalue(OCCUPANCY);
159	<	}
160	<	}
161	<
162	<
163	<	/* The following is by Daniel Cohen, taken from Graphics Gems IV, p. 368 */
164	<	long
165	<	lineweight(hp, x, y, z, dx, dy, dz) /* compute weights along a line */
230	>	double
231	>	beamvolume(hp, bi) /* compute approximate volume of a beam */
232		HOLO *hp;
233	<	int x, y, z, dx, dy, dz;
233	>	int bi;
234		{
235	<	long wres = 0;
236	<	int n, sx, sy, sz, exy, exz, ezy, ax, ay, az, bx, by, bz;
237	<
238	<	sx = sgn(dx); sy = sgn(dy); sz = sgn(dz);
239	<	ax = abs(dx); ay = abs(dy); az = abs(dz);
240	<	bx = 2ax; by = 2ay; bz = 2*az;
241	<	exy = ay-ax; exz = az-ax; ezy = ay-az;
242	<	n = ax+ay+az + 1; /* added increment to visit last */
243	<	while (n--) {
244	<	wres += weightf(hp, x, y, z);
245	<	if (exy < 0) {
246	<	if (exz < 0) {
247	<	x += sx;
248	<	exy += by; exz += bz;
249	<	} else {
250	<	z += sz;
251	<	exz -= bx; ezy += by;
186	<	}
187	<	} else {
188	<	if (ezy < 0) {
189	<	z += sz;
190	<	exz -= bx; ezy += by;
191	<	} else {
192	<	y += sy;
193	<	exy -= bx; ezy -= bz;
194	<	}
195	<	}
235	>	GCOORD gc[2];
236	>	FVECT cp[4], edgeA, edgeB, cent[2];
237	>	FVECT v, crossp[2], diffv;
238	>	double vol[2];
239	>	register int i;
240	>	/* get grid coordinates */
241	>	if (!hdbcoord(gc, hp, bi))
242	>	error(CONSISTENCY, "bad beam index in beamvolume");
243	>	for (i = 0; i < 2; i++) { /* compute cell area vectors */
244	>	hdcell(cp, hp, gc+i);
245	>	VSUM(edgeA, cp[1], cp[0], -1.0);
246	>	VSUM(edgeB, cp[3], cp[1], -1.0);
247	>	fcross(crossp[i], edgeA, edgeB);
248	>	/* compute center */
249	>	cent[i][0] = 0.5*(cp[0][0] + cp[2][0]);
250	>	cent[i][1] = 0.5*(cp[0][1] + cp[2][1]);
251	>	cent[i][2] = 0.5*(cp[0][2] + cp[2][2]);
252		}
253	<	return(wres);
253	>	/* compute difference vector */
254	>	VSUM(diffv, cent[1], cent[0], -1.0);
255	>	for (i = 0; i < 2; i++) { /* compute volume contributions */
256	>	vol[i] = 0.5*DOT(crossp[i], diffv);
257	>	if (vol[i] < 0.) vol[i] = -vol[i];
258	>	}
259	>	return(vol[0] + vol[1]); /* return total volume */
260		}
261
262
263	<	init_global() /* initialize global ray computation */
263	>	ambient_list() /* compute ambient beam list */
264		{
265	<	long wtotal = 0;
204	<	int i, j;
205	<	int lseg[2][3];
265	>	int32 wtotal, minrt;
266		double frac;
267	<	register int k;
268	<	/* free old list */
269	<	if (complen > 0)
210	<	free((char *)complist);
211	<	/* allocate beam list */
267	>	int i;
268	>	register int j, k;
269	>
270		complen = 0;
271		for (j = 0; hdlist[j] != NULL; j++)
272		complen += nbeams(hdlist[j]);
273		complist = (PACKHEAD )malloc(complensizeof(PACKHEAD));
274	<	if (complist == NULL)
217	<	error(SYSTEM, "out of memory in init_global");
274	>	CHECK(complist==NULL, SYSTEM, "out of memory in ambient_list");
275		/* compute beam weights */
276	<	k = 0;
277	<	for (j = 0; hdlist[j] != NULL; j++)
276	>	k = 0; wtotal = 0;
277	>	for (j = 0; hdlist[j] != NULL; j++) {
278	>	frac = 512. * VLEN(hdlist[j]->wg[0]) *
279	>	VLEN(hdlist[j]->wg[1]) *
280	>	VLEN(hdlist[j]->wg[2]);
281		for (i = nbeams(hdlist[j]); i > 0; i--) {
222	–	hdlseg(lseg, hdlist[j], i);
282		complist[k].hd = j;
283		complist[k].bi = i;
284	<	complist[k].nr = lineweight( hdlist[j],
285	<	lseg[0][0], lseg[0][1], lseg[0][2],
227	<	lseg[1][0] - lseg[0][0],
228	<	lseg[1][1] - lseg[0][1],
229	<	lseg[1][2] - lseg[0][2] );
284	>	complist[k].nr = frac*beamvolume(hdlist[j], i) + 0.5;
285	>	complist[k].nc = bnrays(hdlist[j], i);
286		wtotal += complist[k++].nr;
287		}
232	–	/* adjust weights */
233	–	if (vdef(DISKSPACE)) {
234	–	frac = 1024.1024.vflt(DISKSPACE) / (wtotal*sizeof(RAYVAL));
235	–	if (frac < 0.95 \| frac > 1.05)
236	–	while (k--)
237	–	complist[k].nr = frac * complist[k].nr;
288		}
289	+	/* adjust sample weights */
290	+	if (vdef(DISKSPACE))
291	+	frac = 1024.1024.vflt(DISKSPACE) / (wtotal*sizeof(RAYVAL));
292	+	else
293	+	frac = 1024.1024.2048. / (wtotal*sizeof(RAYVAL));
294	+	minrt = .02fracwtotal/complen + .5; /* heuristic mimimum */
295	+	if (minrt > RPACKSIZ)
296	+	minrt = RPACKSIZ;
297	+	for (k = complen; k--; )
298	+	if ((complist[k].nr = frac*complist[k].nr + 0.5) < minrt)
299	+	complist[k].nr = minrt;
300		listpos = 0; lastin = -1; /* flag initial sort */
301		}
302
303
304	+	view_list(fp) /* assign beam priority from view list */
305	+	FILE *fp;
306	+	{
307	+	double pa = 1.;
308	+	VIEW curview;
309	+	int xr, yr;
310	+	char *err;
311	+	BEAMLIST blist;
312	+
313	+	copystruct(&curview, &stdview);
314	+	while (nextview(&curview, fp) != EOF) {
315	+	if ((err = setview(&curview)) != NULL) {
316	+	error(WARNING, err);
317	+	continue;
318	+	}
319	+	xr = yr = 1024;
320	+	normaspect(viewaspect(&curview), &pa, &xr, &yr);
321	+	viewbeams(&curview, xr, yr, &blist);
322	+	bundle_set(BS_MAX, blist.bl, blist.nb);
323	+	free((void *)blist.bl);
324	+	}
325	+	}
326	+
327	+
328	+	init_global() /* initialize global ray computation */
329	+	{
330	+	register int k;
331	+	/* free old list and empty queue */
332	+	if (complen > 0) {
333	+	free((void *)complist);
334	+	done_packets(flush_queue());
335	+	}
336	+	/* reseed random number generator */
337	+	srandom(time(NULL));
338	+	/* allocate beam list */
339	+	if (readinp)
340	+	view_list(stdin);
341	+	else
342	+	ambient_list();
343	+	/* no view vicinity */
344	+	myeye.rng = 0;
345	+	}
346	+
347	+
348		mergeclists(cdest, cl1, n1, cl2, n2) /* merge two sorted lists */
349	<	PACKHEAD *cdest;
350	<	PACKHEAD cl1, cl2;
349	>	register PACKHEAD *cdest;
350	>	register PACKHEAD cl1, cl2;
351		int n1, n2;
352		{
353	<	int cmp;
353	>	register int cmp;
354
355		while (n1 \| n2) {
356		if (!n1) cmp = 1;
#	Line 266 \| Line 371 \| int n1, n2;
371		sortcomplist() /* fix our list order */
372		{
373		PACKHEAD *list2;
374	+	int listlen;
375		register int i;
376
271	–	/* empty queue */
272	–	done_packets(flush_queue());
377		if (complen <= 0) /* check to see if there is even a list */
378		return;
379	<	if (lastin < 0) /* flag to sort entire list */
380	<	qsort((char *)complist, complen, sizeof(PACKHEAD), beamcmp);
379	>	if (!chunkycmp) /* check to see if fragment list is full */
380	>	if (!hdfragOK(hdlist[0]->fd, &listlen, NULL)
381	>	#if NFRAG2CHUNK
382	>	\|\| listlen >= NFRAG2CHUNK
383	>	#endif
384	>	) {
385	>	chunkycmp++; /* use "chunky" comparison */
386	>	lastin = -1; /* need to re-sort list */
387	>	#ifdef DEBUG
388	>	error(WARNING, "using chunky comparison mode");
389	>	#endif
390	>	}
391	>	if (lastin < 0 \|\| listpos4 >= complen3)
392	>	qsort((void *)complist, complen, sizeof(PACKHEAD), beamcmp);
393		else if (listpos) { /* else sort and merge sublist */
394		list2 = (PACKHEAD )malloc(listpossizeof(PACKHEAD));
395	<	if (list2 == NULL)
396	<	error(SYSTEM, "out of memory in sortcomplist");
397	<	bcopy((char )complist,(char )list2,listpos*sizeof(PACKHEAD));
282	<	qsort((char *)list2, listpos, sizeof(PACKHEAD), beamcmp);
395	>	CHECK(list2==NULL, SYSTEM, "out of memory in sortcomplist");
396	>	memcpy((void )list2,(void )complist,listpos*sizeof(PACKHEAD));
397	>	qsort((void *)list2, listpos, sizeof(PACKHEAD), beamcmp);
398		mergeclists(complist, list2, listpos,
399		complist+listpos, complen-listpos);
400	<	free((char *)list2);
400	>	free((void *)list2);
401		}
287	–	/* check for all finished */
288	–	if (complist[0].nr <= bnrays(hdlist[complist[0].hd],complist[0].bi)) {
289	–	free((char *)complist);
290	–	complist = NULL;
291	–	complen = 0;
292	–	}
402		/* drop satisfied requests */
403	<	for (i = complen; i-- && complist[i].nr <=
295	<	bnrays(hdlist[complist[i].hd],complist[i].bi); )
403	>	for (i = complen; i-- && complist[i].nr <= complist[i].nc; )
404		;
405		if (i < 0) {
406	<	free((char *)complist);
406	>	free((void *)complist);
407		complist = NULL;
408		complen = 0;
409		} else if (i < complen-1) {
410	<	list2 = (PACKHEAD )realloc((char )complist,
410	>	list2 = (PACKHEAD )realloc((void )complist,
411		(i+1)*sizeof(PACKHEAD));
412	<	if (list2 != NULL) {
412	>	if (list2 != NULL)
413		complist = list2;
414	<	complen = i+1;
307	<	}
414	>	complen = i+1;
415		}
416		listpos = 0; lastin = i;
417		}
#	Line 315 \| Line 422 \| *sortcomplist() / fix our list order /*
422		* more or less evenly distributed, such that computing a packet causes
423		* a given bundle to move way down in the computation order. We keep
424		* track of where the computed bundle with the highest priority would end
425	<	* up, and if we get further in our compute list than this, we resort the
426	<	* list and start again from the beginning. We have to flush the queue
427	<	* each time we sort, to ensure that we are not disturbing the order.
321	<	* If our major assumption is violated, and we have a very steep
322	<	* descent in our weights, then we will end up resorting much more often
323	<	* than necessary, resulting in frequent flushing of the queue. Since
324	<	* a merge sort is used, the sorting costs will be minimal.
425	>	* up, and if we get further in our compute list than this, we re-sort the
426	>	* list and start again from the beginning. Since
427	>	* a merge sort is used, the sorting costs are minimal.
428		*/
429	<	next_packet(p) /* prepare packet for computation */
429	>	next_packet(p, n) /* prepare packet for computation */
430		register PACKET *p;
431	+	int n;
432		{
329	–	int ncomp;
433		register int i;
434
332	–	if (complen <= 0)
333	–	return(0);
435		if (listpos > lastin) /* time to sort the list */
436		sortcomplist();
437	+	if (complen <= 0)
438	+	return(0);
439		p->hd = complist[listpos].hd;
440		p->bi = complist[listpos].bi;
441	<	ncomp = bnrays(hdlist[p->hd],p->bi);
442	<	p->nr = complist[listpos].nr - ncomp;
441	>	p->nc = complist[listpos].nc;
442	>	p->nr = complist[listpos].nr - p->nc;
443		if (p->nr <= 0)
444		return(0);
445	<	if (p->nr > RPACKSIZ)
446	<	p->nr = RPACKSIZ;
447	<	ncomp += p->nr; /* find where this one would go */
448	<	while (lastin > listpos && complist[listpos].nr *
449	<	(bnrays(hdlist[complist[lastin].hd],complist[lastin].bi)+1)
450	<	> complist[lastin].nr * (ncomp+1))
445	>	DCHECK(n < 1 \| n > RPACKSIZ,
446	>	CONSISTENCY, "next_packet called with bad n value");
447	>	if (p->nr > n)
448	>	p->nr = n;
449	>	complist[listpos].nc += p->nr; /* find where this one would go */
450	>	if (hdgetbeam(hdlist[p->hd], p->bi) != NULL)
451	>	hdfreefrag(hdlist[p->hd], p->bi);
452	>	while (lastin > listpos &&
453	>	beamcmp(complist+lastin, complist+listpos) > 0)
454		lastin--;
455		listpos++;
456		return(1);

Diff Legend

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Comparing ray/src/hd/rholo3.c (file contents): Revision 3.4 by gregl, Tue Nov 4 11:52:21 1997 UTC vs. Revision 3.39 by greg, Mon Jul 7 17:21:51 2003 UTC

Diff Legend

Comparing ray/src/hd/rholo3.c (file contents):
Revision 3.4 by gregl, Tue Nov 4 11:52:21 1997 UTC vs.
Revision 3.39 by greg, Mon Jul 7 17:21:51 2003 UTC