[ViewVC] Diff of: radiance/ray/src/hd/rhd

Comparing ray/src/hd/rhd_qtree.c (file contents):
Revision 3.3 by gregl, Thu Nov 20 18:03:43 1997 UTC vs.
Revision 3.10 by gregl, Fri Dec 5 09:40:05 1997 UTC

#	Line 10 \| Line 10 \| static char SCCSid[] = "$SunId$ SGI";
10
11		#include "standard.h"
12		#include "rhd_qtree.h"
13	+	/* quantity of leaves to free at a time */
14	+	#ifndef LFREEPCT
15	+	#define LFREEPCT 25
16	+	#endif
17	+	/* maximum allowed angle difference (deg.) */
18	+	#ifndef MAXANG
19	+	#define MAXANG 20.
20	+	#endif
21
22	+	#define MAXDIFF2 (long)( MAXANGMAXANG /90./90.(1L<<15)*(1L<<15))
23	+
24	+	#define abs(i) ((i) < 0 ? -(i) : (i))
25	+
26		RTREE qtrunk; /* our quadtree trunk */
27	<	double qtDepthEps = .02; /* epsilon to compare depths (z fraction) */
27	>	double qtDepthEps = .05; /* epsilon to compare depths (z fraction) */
28		int qtMinNodesiz = 2; /* minimum node dimension (pixels) */
29	+	struct rleaves qtL; /* our pile of leaves */
30
18	–	static RLEAF leafpile; / our collection of leaf values */
19	–	static int nleaves; /* count of leaves in our pile */
20	–	static int bleaf, tleaf; /* bottom and top (next) leaf index (ring) */
21	–
31		#define TBUNDLESIZ 409 /* number of twigs in a bundle */
32
33		static RTREE *twigbundle; / free twig blocks (NULL term.) */
34		static int nexttwig; /* next free twig */
35
36	<	static RTREE emptytree; /* empty tree for test below */
36	>	#define ungetleaf(li) (qtL.tl=(li)) /* dangerous if used improperly */
37
29	–	#define is_stump(t) (!bcmp((char )(t), (char )&emptytree, sizeof(RTREE)))
38
31	–
39		static RTREE *
40		newtwig() /* allocate a twig */
41		{
#	Line 63 \| Line 70 \| int really;
70		{
71		register int i;
72
73	<	if (tmTop != NULL)
67	<	tmClearHisto();
68	<	bzero((char *)&qtrunk, sizeof(RTREE));
69	<	nexttwig = 0;
73	>	qtrunk.flgs = CH_ANY; /* chop down tree */
74		if (twigbundle == NULL)
75		return;
76	+	i = (TBUNDLESIZ-1+nexttwig)/TBUNDLESIZ;
77	+	nexttwig = 0;
78		if (!really) { /* just clear allocated blocks */
79	<	for (i = 0; twigbundle[i] != NULL; i++)
79	>	while (i--)
80		bzero((char )twigbundle[i], TBUNDLESIZsizeof(RTREE));
81		return;
82		}
#	Line 82 \| Line 88 \| int really;
88		}
89
90
91	<	static RLEAF *
91	>	static int
92		newleaf() /* allocate a leaf from our pile */
93		{
94	<	if (tleaf++ >= nleaves) /* get next leaf in ring */
95	<	tleaf = 0;
96	<	if (tleaf == bleaf) /* need to shake some free */
94	>	int li;
95	>
96	>	li = qtL.tl++;
97	>	if (qtL.tl >= qtL.nl) /* get next leaf in ring */
98	>	qtL.tl = 0;
99	>	if (qtL.tl == qtL.bl) /* need to shake some free */
100		qtCompost(LFREEPCT);
101	<	return(leafpile + tleaf);
101	>	return(li);
102		}
103
104
105	+	#define LEAFSIZ (3sizeof(float)+2sizeof(short)+\
106	+	sizeof(TMbright)+6*sizeof(BYTE))
107	+
108		int
109		qtAllocLeaves(n) /* allocate space for n leaves */
110	<	int n;
110	>	register int n;
111		{
112		unsigned nbytes;
113		register unsigned i;
#	Line 103 \| Line 115 \| int n;
115		qtFreeTree(0); /* make sure tree is empty */
116		if (n <= 0)
117		return(0);
118	<	if (nleaves >= n)
119	<	return(nleaves);
120	<	else if (nleaves > 0)
121	<	free((char *)leafpile);
118	>	if (qtL.nl >= n)
119	>	return(qtL.nl);
120	>	else if (qtL.nl > 0)
121	>	free(qtL.base);
122		/* round space up to nearest power of 2 */
123	<	nbytes = n*sizeof(RLEAF) + 8;
123	>	nbytes = n*LEAFSIZ + 8;
124		for (i = 1024; nbytes > i; i <<= 1)
125		;
126	<	n = (i - 8) / sizeof(RLEAF);
127	<	leafpile = (RLEAF )malloc(nsizeof(RLEAF));
128	<	if (leafpile == NULL)
129	<	return(-1);
130	<	nleaves = n;
131	<	bleaf = tleaf = 0;
132	<	return(nleaves);
126	>	n = (i - 8) / LEAFSIZ; /* should we make sure n is even? */
127	>	qtL.base = (char )malloc(nLEAFSIZ);
128	>	if (qtL.base == NULL)
129	>	return(0);
130	>	/* assign larger alignment types earlier */
131	>	qtL.wp = (float (*)[3])qtL.base;
132	>	qtL.wd = (short (*)[2])(qtL.wp + n);
133	>	qtL.brt = (TMbright *)(qtL.wd + n);
134	>	qtL.chr = (BYTE (*)[3])(qtL.brt + n);
135	>	qtL.rgb = (BYTE (*)[3])(qtL.chr + n);
136	>	qtL.nl = n;
137	>	qtL.tml = qtL.bl = qtL.tl = 0;
138	>	return(n);
139		}
140
141	+	#undef LEAFSIZ
142
143	+
144		qtFreeLeaves() /* free our allocated leaves and twigs */
145		{
146		qtFreeTree(1); /* free tree also */
147	<	if (nleaves <= 0)
147	>	if (qtL.nl <= 0)
148		return;
149	<	free((char *)leafpile);
150	<	leafpile = NULL;
151	<	nleaves = 0;
149	>	free(qtL.base);
150	>	qtL.base = NULL;
151	>	qtL.nl = 0;
152		}
153
154
#	Line 139 \| Line 159 \| *register RTREE tp;**
159		register int i, li;
160
161		for (i = 0; i < 4; i++)
162	<	if (tp->flgs & BRF(i))
162	>	if (tp->flgs & BRF(i)) {
163		shaketree(tp->k[i].b);
164	<	else if (tp->k[i].l != NULL) {
165	<	li = tp->k[i].l - leafpile;
166	<	if (bleaf < tleaf ? (li < bleaf \|\| li >= tleaf) :
167	<	(li < bleaf && li >= tleaf)) {
168	<	tmAddHisto(&tp->k[i].l->brt, 1, -1);
169	<	tp->k[i].l = NULL;
170	<	}
164	>	if (is_stump(tp->k[i].b))
165	>	tp->flgs &= ~BRF(i);
166	>	} else if (tp->flgs & LFF(i)) {
167	>	li = tp->k[i].li;
168	>	if (qtL.bl < qtL.tl ?
169	>	(li < qtL.bl \|\| li >= qtL.tl) :
170	>	(li < qtL.bl && li >= qtL.tl))
171	>	tp->flgs &= ~LFF(i);
172		}
173		}
174
#	Line 156 \| Line 177 \| int
177		qtCompost(pct) /* free up some leaves */
178		int pct;
179		{
180	<	int nused, nclear;
180	>	int nused, nclear, nmapped;
181	>
182		/* figure out how many leaves to clear */
183	<	nclear = nleaves * pct / 100;
183	>	nclear = qtL.nl * pct / 100;
184	>	nused = qtL.tl - qtL.bl;
185	>	if (nused <= 0) nused += qtL.nl;
186	>	nclear -= qtL.nl - nused;
187		if (nclear <= 0)
188		return(0);
164	–	nused = tleaf > bleaf ? tleaf-bleaf : tleaf+nleaves-bleaf;
189		if (nclear >= nused) { /* clear them all */
190		qtFreeTree(0);
191	<	bleaf = tleaf = 0;
191	>	qtL.tml = qtL.bl = qtL.tl = 0;
192		return(nused);
193		}
194		/* else clear leaves from bottom */
195	<	bleaf = (bleaf + nclear) % nleaves;
195	>	nmapped = qtL.tml - qtL.bl;
196	>	if (nmapped < 0) nmapped += qtL.nl;
197	>	qtL.bl += nclear;
198	>	if (qtL.bl >= qtL.nl) qtL.bl -= qtL.nl;
199	>	if (nmapped <= nclear) qtL.tml = qtL.bl;
200		shaketree(&qtrunk);
201		return(nclear);
202		}
203
204
205	<	RLEAF *
205	>	static
206	>	encodedir(pa, dv) /* encode a normalized direction vector */
207	>	short pa[2];
208	>	FVECT dv;
209	>	{
210	>	pa[1] = 0;
211	>	if (dv[2] >= 1.)
212	>	pa[0] = (1L<<15)-1;
213	>	else if (dv[2] <= -1.)
214	>	pa[0] = -((1L<<15)-1);
215	>	else {
216	>	pa[0] = ((1L<<15)-1)/(PI/2.) * asin(dv[2]);
217	>	pa[1] = ((1L<<15)-1)/PI * atan2(dv[1], dv[0]);
218	>	}
219	>	}
220	>
221	>
222	>	#define ALTSHFT 5
223	>	#define NALT (1<<ALTSHFT)
224	>	#define azisft(alt) azisftab[abs(alt)>>(15-ALTSHFT)]
225	>
226	>	static unsigned short azisftab[NALT];
227	>
228	>	static
229	>	azisftinit(alt) /* initialize azimuth scale factor table */
230	>	int alt;
231	>	{
232	>	register int i;
233	>
234	>	for (i = NALT; i--; )
235	>	azisftab[i] = 2.(1L<<15) cos(PI/2.*(i+.5)/NALT);
236	>	return(azisft(alt));
237	>	}
238	>
239	>	#define azisf(alt) (azisftab[0] ? azisft(alt) : azisftinit(alt)) >> 15
240	>
241	>	static long
242	>	dir2diff(pa1, pa2) /* relative distance^2 between directions */
243	>	short pa1[2], pa2[2];
244	>	{
245	>	long altd2, azid2;
246	>	int alt;
247	>
248	>	altd2 = pa1[0] - pa2[0]; /* get altitude difference^2 */
249	>	altd2 *= altd2;
250	>	if (altd2 > MAXDIFF2)
251	>	return(altd2); /* too large already */
252	>	azid2 = pa1[1] - pa2[1]; /* get adjusted azimuth difference^2 */
253	>	if (azid2 < 0) azid2 = -azid2;
254	>	if (azid2 >= 1L<<15) { /* wrap sphere */
255	>	azid2 -= 1L<<16;
256	>	if (azid2 < 0) azid2 = -azid2;
257	>	}
258	>	alt = (pa1[0]+pa2[0])/2;
259	>	azid2 = azid2azisf(alt); / evaluation order is important */
260	>	azid2 *= azid2;
261	>	return(altd2 + azid2);
262	>	}
263	>
264	>
265	>	int
266		qtFindLeaf(x, y) /* find closest leaf to (x,y) */
267		int x, y;
268		{
269		register RTREE *tp = &qtrunk;
270	<	RLEAF *lp = NULL;
270	>	int li = -1;
271		int x0=0, y0=0, x1=odev.hres, y1=odev.vres;
272		int mx, my;
273		register int q;
274		/* check limits */
275		if (x < 0 \|\| x >= odev.hres \|\| y < 0 \|\| y >= odev.vres)
276	<	return(NULL);
276	>	return(-1);
277		/* find nearby leaf in our tree */
278		for ( ; ; ) {
279		for (q = 0; q < 4; q++) /* find any leaf this level */
280	<	if (!(tp->flgs & BRF(q)) && tp->k[q].l != NULL) {
281	<	lp = tp->k[q].l;
280	>	if (tp->flgs & LFF(q)) {
281	>	li = tp->k[q].li;
282		break;
283		}
284		q = 0; /* which quadrant are we? */
#	Line 204 \| Line 292 \| int x, y;
292		tp = tp->k[q].b;
293		continue;
294		}
295	<	if (tp->k[q].l != NULL) /* good shot! */
296	<	return(tp->k[q].l);
297	<	return(lp); /* else return what we have */
295	>	if (tp->flgs & LFF(q)) /* good shot! */
296	>	return(tp->k[q].li);
297	>	return(li); /* else return what we have */
298		}
299		}
300
301
302		static
303	<	addleaf(lp) /* add a leaf to our tree */
304	<	RLEAF *lp;
303	>	addleaf(li) /* add a leaf to our tree */
304	>	int li;
305		{
306		register RTREE *tp = &qtrunk;
307		int x0=0, y0=0, x1=odev.hres, y1=odev.vres;
308	<	RLEAF *lo = NULL;
308	>	int lo = -1;
309	>	long d2;
310	>	short dc[2];
311		int x, y, mx, my;
312		double z;
313		FVECT ip, wp;
314		register int q;
315	<	/* compute leaf location */
316	<	VCOPY(wp, lp->wp);
315	>	/* compute leaf location in view */
316	>	VCOPY(wp, qtL.wp[li]);
317		viewloc(ip, &odev.v, wp);
318		if (ip[2] <= 0. \|\| ip[0] < 0. \|\| ip[0] >= 1.
319		\|\| ip[1] < 0. \|\| ip[1] >= 1.)
320	<	return;
320	>	return(0); /* behind or outside view */
321	>	#ifdef DEBUG
322	>	if (odev.v.type == VT_PAR \| odev.v.vfore > FTINY)
323	>	error(INTERNAL, "bad view assumption in addleaf");
324	>	#endif
325	>	for (q = 0; q < 3; q++)
326	>	wp[q] = (wp[q] - odev.v.vp[q])/ip[2];
327	>	encodedir(dc, wp); /* compute pixel direction */
328	>	d2 = dir2diff(dc, qtL.wd[li]);
329	>	if (d2 > MAXDIFF2)
330	>	return(0); /* leaf dir. too far off */
331		x = ip[0] * odev.hres;
332		y = ip[1] * odev.vres;
333		z = ip[2];
#	Line 245 \| Line 345 \| *RLEAF lp;**
345		tp = tp->k[q].b;
346		continue;
347		}
348	<	if (tp->k[q].l == NULL) { /* found stem for leaf */
349	<	tp->k[q].l = lp;
350	<	tp->flgs \|= CHF(q);
348	>	if (!(tp->flgs & LFF(q))) { /* found stem for leaf */
349	>	tp->k[q].li = li;
350	>	tp->flgs \|= CHLFF(q);
351		break;
352		}
353	<	/* check existing leaf */
354	<	if (lo != tp->k[q].l) {
355	<	lo = tp->k[q].l;
256	<	VCOPY(wp, lo->wp);
353	>	if (lo != tp->k[q].li) { /* check old leaf */
354	>	lo = tp->k[q].li;
355	>	VCOPY(wp, qtL.wp[lo]);
356		viewloc(ip, &odev.v, wp);
357		}
358		/* is node minimum size? */
359	<	if (x1-x0 <= qtMinNodesiz \|\| y1-y0 <= qtMinNodesiz) {
360	<	if (z > (1.-qtDepthEps)ip[2]) / who is closer? */
361	<	return; /* old one is */
362	<	tp->k[q].l = lp; /* new one is */
359	>	if (y1-y0 <= qtMinNodesiz \|\| x1-x0 <= qtMinNodesiz) {
360	>	if (z > (1.+qtDepthEps)*ip[2])
361	>	return(0); /* old one closer */
362	>	if (z >= (1.-qtDepthEps)*ip[2] &&
363	>	dir2diff(dc, qtL.wd[lo]) < d2)
364	>	return(0); /* old one better */
365	>	tp->k[q].li = li; /* else new one is */
366		tp->flgs \|= CHF(q);
265	–	tmAddHisto(&lo->brt, 1, -1); /* drop old one */
367		break;
368		}
369	<	tp->flgs \|= CHBRF(q); /* else grow tree */
369	>	tp->flgs &= ~LFF(q); /* else grow tree */
370	>	tp->flgs \|= CHBRF(q);
371		tp = tp->k[q].b = newtwig();
270	–	tp->flgs \|= CH_ANY; /* all new */
372		q = 0; /* old leaf -> new branch */
373		mx = ip[0] * odev.hres;
374		my = ip[1] * odev.vres;
375		if (mx >= (x0 + x1) >> 1) q \|= 01;
376		if (my >= (y0 + y1) >> 1) q \|= 02;
377	<	tp->k[q].l = lo;
377	>	tp->k[q].li = lo;
378	>	tp->flgs \|= LFF(q)\|CH_ANY; /* all new */
379		}
380	<	tmAddHisto(&lp->brt, 1, 1); /* add leaf to histogram */
380	>	return(1); /* done */
381		}
382
383
384	<	dev_value(c, p) /* add a pixel value to our output queue */
384	>	dev_value(c, p, v) /* add a pixel value to our quadtree */
385		COLR c;
386	<	FVECT p;
386	>	FVECT p, v;
387		{
388	<	register RLEAF *lp;
388	>	register int li;
389
390	<	lp = newleaf();
391	<	VCOPY(lp->wp, p);
392	<	tmCvColrs(&lp->brt, lp->chr, c, 1);
393	<	addleaf(lp);
390	>	li = newleaf();
391	>	VCOPY(qtL.wp[li], p);
392	>	encodedir(qtL.wd[li], v);
393	>	tmCvColrs(&qtL.brt[li], qtL.chr[li], c, 1);
394	>	if (!addleaf(li))
395	>	ungetleaf(li);
396		}
397
398
399		qtReplant() /* replant our tree using new view */
400		{
401		register int i;
402	<
403	<	if (bleaf == tleaf) /* anything to replant? */
402	>	/* anything to replant? */
403	>	if (qtL.bl == qtL.tl)
404		return;
405	<	qtFreeTree(0); /* blow the tree away */
406	<	/* now rebuild it */
407	<	for (i = bleaf; i != tleaf; ) {
408	<	addleaf(leafpile+i);
409	<	if (++i >= nleaves) i = 0;
405	>	qtFreeTree(0); /* blow the old tree away */
406	>	/* regrow it in new place */
407	>	for (i = qtL.bl; i != qtL.tl; ) {
408	>	addleaf(i);
409	>	if (++i >= qtL.nl) i = 0;
410		}
307	–	tmComputeMapping(0., 0., 0.); /* update the display */
308	–	qtUpdate();
411		}
412
413
414	<	static
415	<	redraw(ca, tp, x0, y0, x1, y1, l) /* redraw portion of a tree */
314	<	BYTE ca[3]; /* returned average color */
315	<	register RTREE *tp;
316	<	int x0, y0, x1, y1;
317	<	int l[2][2];
414	>	qtMapLeaves(redo) /* map our leaves to RGB */
415	>	int redo;
416		{
417	<	int csm[3], nc;
418	<	BYTE rgb[3];
419	<	int quads = CH_ANY;
420	<	int mx, my;
421	<	register int i;
422	<	/* compute midpoint */
423	<	mx = (x0 + x1) >> 1;
424	<	my = (y0 + y1) >> 1;
425	<	/* see what to do */
426	<	if (l[0][0] >= mx)
427	<	quads &= ~(CHF(2)\|CHF(0));
428	<	else if (l[0][1] <= mx)
331	<	quads &= ~(CHF(3)\|CHF(1));
332	<	if (l[1][0] >= my)
333	<	quads &= ~(CHF(1)\|CHF(0));
334	<	else if (l[1][1] <= my)
335	<	quads &= ~(CHF(3)\|CHF(2));
336	<	tp->flgs &= ~quads; /* mark them done */
337	<	csm[0] = csm[1] = csm[2] = nc = 0;
338	<	/* do leaves first */
339	<	for (i = 0; i < 4; i++)
340	<	if (quads & CHF(i) && !(tp->flgs & BRF(i)) &&
341	<	tp->k[i].l != NULL) {
342	<	tmMapPixels(rgb, &tp->k[i].l->brt, tp->k[i].l->chr, 1);
343	<	dev_paintr(rgb, i&01 ? mx : x0, i&02 ? my : y0,
344	<	i&01 ? x1 : mx, i&02 ? y1 : my);
345	<	csm[0] += rgb[0]; csm[1] += rgb[1]; csm[2] += rgb[2];
346	<	nc++;
347	<	quads &= ~CHF(i);
348	<	}
349	<	/* now do branches */
350	<	for (i = 0; i < 4; i++)
351	<	if (quads & CHF(i) && tp->flgs & BRF(i)) {
352	<	redraw(rgb, tp->k[i].b, i&01 ? mx : x0, i&02 ? my : y0,
353	<	i&01 ? x1 : mx, i&02 ? y1 : my, l);
354	<	csm[0] += rgb[0]; csm[1] += rgb[1]; csm[2] += rgb[2];
355	<	nc++;
356	<	quads &= ~CHF(i);
357	<	}
358	<	if (nc > 1) {
359	<	ca[0] = csm[0]/nc; ca[1] = csm[1]/nc; ca[2] = csm[2]/nc;
417	>	int aorg, alen, borg, blen;
418	>	/* recompute mapping? */
419	>	if (redo)
420	>	qtL.tml = qtL.bl;
421	>	/* already done? */
422	>	if (qtL.tml == qtL.tl)
423	>	return(1);
424	>	/* compute segments */
425	>	aorg = qtL.tml;
426	>	if (qtL.tl >= aorg) {
427	>	alen = qtL.tl - aorg;
428	>	blen = 0;
429		} else {
430	<	ca[0] = csm[0]; ca[1] = csm[1]; ca[2] = csm[2];
430	>	alen = qtL.nl - aorg;
431	>	borg = 0;
432	>	blen = qtL.tl;
433		}
434	<	if (!quads) return;
435	<	/* fill in gaps with average */
436	<	for (i = 0; i < 4; i++)
437	<	if (quads & CHF(i))
438	<	dev_paintr(ca, i&01 ? mx : x0, i&02 ? my : y0,
439	<	i&01 ? x1 : mx, i&02 ? y1 : my);
440	<	}
441	<
371	<
372	<	static
373	<	update(ca, tp, x0, y0, x1, y1) /* update tree display as needed */
374	<	BYTE ca[3]; /* returned average color */
375	<	register RTREE *tp;
376	<	int x0, y0, x1, y1;
377	<	{
378	<	int csm[3], nc;
379	<	BYTE rgb[3];
380	<	int gaps = 0;
381	<	int mx, my;
382	<	register int i;
383	<	/* compute midpoint */
384	<	mx = (x0 + x1) >> 1;
385	<	my = (y0 + y1) >> 1;
386	<	csm[0] = csm[1] = csm[2] = nc = 0;
387	<	/* do leaves first */
388	<	for (i = 0; i < 4; i++)
389	<	if ((tp->flgs & CHBRF(i)) == CHF(i)) {
390	<	if (tp->k[i].l == NULL) {
391	<	gaps \|= 1<<i; /* empty stem */
392	<	continue;
393	<	}
394	<	tmMapPixels(rgb, &tp->k[i].l->brt, tp->k[i].l->chr, 1);
395	<	dev_paintr(rgb, i&01 ? mx : x0, i&02 ? my : y0,
396	<	i&01 ? x1 : mx, i&02 ? y1 : my);
397	<	csm[0] += rgb[0]; csm[1] += rgb[1]; csm[2] += rgb[2];
398	<	nc++;
399	<	}
400	<	/* now do branches */
401	<	for (i = 0; i < 4; i++)
402	<	if ((tp->flgs & CHBRF(i)) == CHBRF(i)) {
403	<	update(rgb, tp->k[i].b, i&01 ? mx : x0, i&02 ? my : y0,
404	<	i&01 ? x1 : mx, i&02 ? y1 : my);
405	<	csm[0] += rgb[0]; csm[1] += rgb[1]; csm[2] += rgb[2];
406	<	nc++;
407	<	}
408	<	if (nc > 1) {
409	<	ca[0] = csm[0]/nc; ca[1] = csm[1]/nc; ca[2] = csm[2]/nc;
410	<	} else {
411	<	ca[0] = csm[0]; ca[1] = csm[1]; ca[2] = csm[2];
434	>	/* (re)compute tone mapping? */
435	>	if (qtL.tml == qtL.bl) {
436	>	tmClearHisto();
437	>	tmAddHisto(qtL.brt+aorg, alen, 1);
438	>	if (blen > 0)
439	>	tmAddHisto(qtL.brt+borg, blen, 1);
440	>	if (tmComputeMapping(0., 0., 0.) != TM_E_OK)
441	>	return(0);
442		}
443	<	/* fill in gaps with average */
444	<	for (i = 0; gaps && i < 4; gaps >>= 1, i++)
445	<	if (gaps & 01)
446	<	dev_paintr(ca, i&01 ? mx : x0, i&02 ? my : y0,
447	<	i&01 ? x1 : mx, i&02 ? y1 : my);
448	<	tp->flgs &= ~CH_ANY; /* all done */
449	<	}
450	<
421	<
422	<	qtRedraw(x0, y0, x1, y1) /* redraw part of our screen */
423	<	int x0, y0, x1, y1;
424	<	{
425	<	int lim[2][2];
426	<	BYTE ca[3];
427	<
428	<	if (is_stump(&qtrunk))
429	<	return;
430	<	if ((lim[0][0]=x0) == 0 & (lim[1][0]=y0) == 0 &
431	<	(lim[0][1]=x1) == odev.hres & (lim[1][1]=y1) == odev.vres \|\|
432	<	tmTop->lumap == NULL)
433	<	tmComputeMapping(0., 0., 0.);
434	<	redraw(ca, &qtrunk, 0, 0, odev.hres, odev.vres, lim);
435	<	}
436	<
437	<
438	<	qtUpdate() /* update our tree display */
439	<	{
440	<	BYTE ca[3];
441	<
442	<	if (is_stump(&qtrunk))
443	<	return;
444	<	if (tmTop->lumap == NULL)
445	<	tmComputeMapping(0., 0., 0.);
446	<	update(ca, &qtrunk, 0, 0, odev.hres, odev.vres);
443	>	if (tmMapPixels(qtL.rgb+aorg, qtL.brt+aorg,
444	>	qtL.chr+aorg, alen) != TM_E_OK)
445	>	return(0);
446	>	if (blen > 0)
447	>	tmMapPixels(qtL.rgb+borg, qtL.brt+borg,
448	>	qtL.chr+borg, blen);
449	>	qtL.tml = qtL.tl;
450	>	return(1);
451		}

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Comparing ray/src/hd/rhd_qtree.c (file contents): Revision 3.3 by gregl, Thu Nov 20 18:03:43 1997 UTC vs. Revision 3.10 by gregl, Fri Dec 5 09:40:05 1997 UTC

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Comparing ray/src/hd/rhd_qtree.c (file contents):
Revision 3.3 by gregl, Thu Nov 20 18:03:43 1997 UTC vs.
Revision 3.10 by gregl, Fri Dec 5 09:40:05 1997 UTC