[ViewVC] Diff of: radiance/ray/src/hd/rhdisp3.c

Comparing ray/src/hd/rhdisp3.c (file contents):
Revision 3.4 by gregl, Fri Nov 21 18:17:37 1997 UTC vs.
Revision 3.11 by gwlarson, Thu Nov 5 13:58:37 1998 UTC

#	Line 1 \| Line 1
1	<	/* Copyright (c) 1997 Silicon Graphics, Inc. */
1	>	/* Copyright (c) 1998 Silicon Graphics, Inc. */
2
3		#ifndef lint
4		static char SCCSid[] = "$SunId$ SGI";
#	Line 19 \| Line 19 \| struct cellist {
19
20
21		int
22	<	npixels(vp, hr, vr, hp, bi) /* compute appropriate number to evaluate */
23	<	VIEW *vp;
22	>	npixels(vp, hr, vr, hp, bi) /* compute appropriate nrays to evaluate */
23	>	register VIEW *vp;
24		int hr, vr;
25		HOLO *hp;
26		int bi;
27		{
28	<	static VIEW vdo, vlast;
29	<	static HOLO *hplast;
28	>	VIEW vrev;
29		GCOORD gc[2];
30	<	FVECT cp[4];
31	<	FVECT ip[4];
33	<	double d;
30	>	FVECT cp[4], ip[4], pf, pb;
31	>	double af, ab, sf2, sb2, dfb2, df2, db2, penalty;
32		register int i;
33	+	/* special case */
34	+	if (hr <= 0 \| vr <= 0)
35	+	return(0);
36		/* compute cell corners in image */
37		if (!hdbcoord(gc, hp, bi))
38		error(CONSISTENCY, "bad beam index in npixels");
39	<	/* has holodeck or view changed? */
40	<	if (hp != hplast \|\| bcmp((char )vp, (char )&vlast, sizeof(VIEW))) {
41	<	copystruct(&vdo, vp);
42	<	if (sect_behind(hp, &vdo)) { /* reverse view sense */
43	<	vdo.vdir[0] = -vdo.vdir[0];
44	<	vdo.vdir[1] = -vdo.vdir[1];
45	<	vdo.vdir[2] = -vdo.vdir[2];
46	<	setview(&vdo);
39	>	hdcell(cp, hp, gc+1); /* find cell on front image */
40	>	for (i = 3; i--; ) /* compute front center */
41	>	pf[i] = 0.5*(cp[0][i] + cp[2][i]);
42	>	sf2 = 0.25dist2(cp[0], cp[2]); / compute half diagonal length */
43	>	for (i = 0; i < 4; i++) { /* compute visible quad */
44	>	viewloc(ip[i], vp, cp[i]);
45	>	if (ip[i][2] < 0.) {
46	>	af = 0;
47	>	goto getback;
48		}
49	<	hplast = hp;
50	<	copystruct(&vlast, vp);
49	>	ip[i][0] = (double)hr; / scale by resolution */
50	>	ip[i][1] *= (double)vr;
51		}
52	<	hdcell(cp, hp, gc+1); /* find cell on image */
53	<	for (i = 0; i < 4; i++) {
54	<	viewloc(ip[i], &vdo, cp[i]);
55	<	if (ip[i][2] < 0.)
56	<	return(0);
52	>	/* compute front area */
53	>	af = (ip[1][0]-ip[0][0])*(ip[2][1]-ip[0][1]) -
54	>	(ip[2][0]-ip[0][0])*(ip[1][1]-ip[0][1]);
55	>	af += (ip[2][0]-ip[3][0])*(ip[1][1]-ip[3][1]) -
56	>	(ip[1][0]-ip[3][0])*(ip[2][1]-ip[3][1]);
57	>	af *= af >= 0 ? 0.5 : -0.5;
58	>	getback:
59	>	copystruct(&vrev, vp); /* compute reverse view */
60	>	for (i = 0; i < 3; i++) {
61	>	vrev.vdir[i] = -vp->vdir[i];
62	>	vrev.vup[i] = -vp->vup[i];
63	>	vrev.hvec[i] = -vp->hvec[i];
64	>	vrev.vvec[i] = -vp->vvec[i];
65	>	}
66	>	hdcell(cp, hp, gc); /* find cell on back image */
67	>	for (i = 3; i--; ) /* compute rear center */
68	>	pb[i] = 0.5*(cp[0][i] + cp[2][i]);
69	>	sb2 = 0.25dist2(cp[0], cp[2]); / compute half diagonal length */
70	>	for (i = 0; i < 4; i++) { /* compute visible quad */
71	>	viewloc(ip[i], &vrev, cp[i]);
72	>	if (ip[i][2] < 0.) {
73	>	ab = 0;
74	>	goto finish;
75	>	}
76		ip[i][0] = (double)hr; / scale by resolution */
77		ip[i][1] *= (double)vr;
78		}
79	<	/* compute quad area */
80	<	d = (ip[1][0]-ip[0][0])*(ip[2][1]-ip[0][1]) -
79	>	/* compute back area */
80	>	ab = (ip[1][0]-ip[0][0])*(ip[2][1]-ip[0][1]) -
81		(ip[2][0]-ip[0][0])*(ip[1][1]-ip[0][1]);
82	<	d += (ip[2][0]-ip[3][0])*(ip[1][1]-ip[3][1]) -
82	>	ab += (ip[2][0]-ip[3][0])*(ip[1][1]-ip[3][1]) -
83		(ip[1][0]-ip[3][0])*(ip[2][1]-ip[3][1]);
84	<	if (d < 0)
85	<	d = -d;
86	<	/* round off result */
87	<	return((int)(.5*d+.5));
84	>	ab *= ab >= 0 ? 0.5 : -0.5;
85	>	finish: /* compute penalty based on dist. sightline - viewpoint */
86	>	df2 = dist2(vp->vp, pf);
87	>	db2 = dist2(vp->vp, pb);
88	>	dfb2 = dist2(pf, pb);
89	>	penalty = dfb2 + df2 - db2;
90	>	penalty = df2 - 0.25penaltypenalty/dfb2;
91	>	if (df2 > db2) penalty /= df2 <= dfb2 ? sb2 : sb2*df2/dfb2;
92	>	else penalty /= db2 <= dfb2 ? sf2 : sf2*db2/dfb2;
93	>	if (penalty < 1.) penalty = 1.;
94	>	/* round off smaller non-zero area */
95	>	if (ab <= FTINY \|\| (af > FTINY && af <= ab))
96	>	return((int)(af/penalty + 0.5));
97	>	return((int)(ab/penalty + 0.5));
98		}
99
100
#	Line 71 \| Line 102 \| int bi;
102		* The ray directions that define the pyramid in visit_cells() needn't
103		* be normalized, but they must be given in clockwise order as seen
104		* from the pyramid's apex (origin).
105	+	* If no cell centers fall within the domain, the closest cell is visited.
106		*/
107		int
108		visit_cells(orig, pyrd, hp, vf, dp) /* visit cells within a pyramid */
109		FVECT orig, pyrd[4]; /* pyramid ray directions in clockwise order */
110	<	HOLO *hp;
110	>	register HOLO *hp;
111		int (*vf)();
112		char *dp;
113		{
114	<	int n = 0;
114	>	int ncalls = 0, n = 0;
115		int inflags = 0;
116		FVECT gp, pn[4], lo, ld;
117		double po[4], lbeg, lend, d, t;
118	<	GCOORD gc;
118	>	GCOORD gc, gc2[2];
119		register int i;
120		/* figure out whose side we're on */
121		hdgrid(gp, hp, orig);
#	Line 101 \| Line 133 \| *char dp;**
133		if (!(inflags & 1<<gc.w)) /* origin on wrong side */
134		continue;
135		/* scanline algorithm */
136	<	for (gc.i[1] = hp->grid[((gc.w>>1)+2)%3]; gc.i[1]--; ) {
136	>	for (gc.i[1] = hp->grid[hdwg1[gc.w]]; gc.i[1]--; ) {
137		/* compute scanline */
138		gp[gc.w>>1] = gc.w&1 ? hp->grid[gc.w>>1] : 0;
139	<	gp[((gc.w>>1)+1)%3] = 0;
140	<	gp[((gc.w>>1)+2)%3] = gc.i[1] + 0.5;
139	>	gp[hdwg0[gc.w]] = 0;
140	>	gp[hdwg1[gc.w]] = gc.i[1] + 0.5;
141		hdworld(lo, hp, gp);
142	<	gp[((gc.w>>1)+1)%3] = 1;
142	>	gp[hdwg0[gc.w]] = 1;
143		hdworld(ld, hp, gp);
144		ld[0] -= lo[0]; ld[1] -= lo[1]; ld[2] -= lo[2];
145		/* find scanline limits */
146	<	lbeg = 0; lend = hp->grid[((gc.w>>1)+1)%3];
146	>	lbeg = 0; lend = hp->grid[hdwg0[gc.w]];
147		for (i = 0; i < 4; i++) {
148		t = DOT(pn[i], lo) - po[i];
149		d = -DOT(pn[i], ld);
#	Line 129 \| Line 161 \| *char dp;**
161		if (lbeg >= lend)
162		continue;
163		i = lend + .5; /* visit cells on this scan */
164	<	for (gc.i[0] = lbeg + .5; gc.i[0] < i; gc.i[0]++)
164	>	for (gc.i[0] = lbeg + .5; gc.i[0] < i; gc.i[0]++) {
165		n += (*vf)(&gc, dp);
166	+	ncalls++;
167	+	}
168		}
169		}
170	<	return(n);
170	>	if (ncalls) /* got one at least */
171	>	return(n);
172	>	/* else find closest cell */
173	>	VSUM(ld, pyrd[0], pyrd[1], 1.);
174	>	VSUM(ld, ld, pyrd[2], 1.);
175	>	VSUM(ld, ld, pyrd[3], 1.);
176	>	#if 0
177	>	if (normalize(ld) == 0.0) /* technically not necessary */
178	>	return(0);
179	>	#endif
180	>	d = hdinter(gc2, NULL, &t, hp, orig, ld);
181	>	if (d >= FHUGE \|\| t <= 0.)
182	>	return(0);
183	>	return((vf)(gc2+1, dp)); / visit it */
184		}
185
186
#	Line 237 \| Line 284 \| *VIEW vp;**
284		if (cl.cl == NULL)
285		goto memerr;
286		cl.n = 0; /* add cells within pyramid */
287	<	visit_cells(org, dir, hp, addcell, &cl);
287	>	visit_cells(org, dir, hp, addcell, (char *)&cl);
288		if (!cl.n) {
289		free((char *)cl.cl);
290		return(NULL);
#	Line 257 \| Line 304 \| *VIEW vp;**
304		return(cl.cl);
305		memerr:
306		error(SYSTEM, "out of memory in getviewcells");
307	+	}
308	+
309	+
310	+	gridlines(f) /* run through holodeck section grid lines */
311	+	int (*f)();
312	+	{
313	+	register int hd, w, i;
314	+	int g0, g1;
315	+	FVECT wp[2], mov;
316	+	double d;
317	+	/* do each wall on each section */
318	+	for (hd = 0; hdlist[hd] != NULL; hd++)
319	+	for (w = 0; w < 6; w++) {
320	+	g0 = hdwg0[w];
321	+	g1 = hdwg1[w];
322	+	d = 1.0/hdlist[hd]->grid[g0];
323	+	mov[0] = d * hdlist[hd]->xv[g0][0];
324	+	mov[1] = d * hdlist[hd]->xv[g0][1];
325	+	mov[2] = d * hdlist[hd]->xv[g0][2];
326	+	if (w & 1) {
327	+	VSUM(wp[0], hdlist[hd]->orig,
328	+	hdlist[hd]->xv[w>>1], 1.);
329	+	VSUM(wp[0], wp[0], mov, 1.);
330	+	} else
331	+	VCOPY(wp[0], hdlist[hd]->orig);
332	+	VSUM(wp[1], wp[0], hdlist[hd]->xv[g1], 1.);
333	+	for (i = hdlist[hd]->grid[g0]; ; ) { /* g0 lines */
334	+	(*f)(wp);
335	+	if (!--i) break;
336	+	wp[0][0] += mov[0]; wp[0][1] += mov[1];
337	+	wp[0][2] += mov[2]; wp[1][0] += mov[0];
338	+	wp[1][1] += mov[1]; wp[1][2] += mov[2];
339	+	}
340	+	d = 1.0/hdlist[hd]->grid[g1];
341	+	mov[0] = d * hdlist[hd]->xv[g1][0];
342	+	mov[1] = d * hdlist[hd]->xv[g1][1];
343	+	mov[2] = d * hdlist[hd]->xv[g1][2];
344	+	if (w & 1)
345	+	VSUM(wp[0], hdlist[hd]->orig,
346	+	hdlist[hd]->xv[w>>1], 1.);
347	+	else
348	+	VSUM(wp[0], hdlist[hd]->orig, mov, 1.);
349	+	VSUM(wp[1], wp[0], hdlist[hd]->xv[g0], 1.);
350	+	for (i = hdlist[hd]->grid[g1]; ; ) { /* g1 lines */
351	+	(*f)(wp);
352	+	if (!--i) break;
353	+	wp[0][0] += mov[0]; wp[0][1] += mov[1];
354	+	wp[0][2] += mov[2]; wp[1][0] += mov[0];
355	+	wp[1][1] += mov[1]; wp[1][2] += mov[2];
356	+	}
357	+	}
358		}

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Comparing ray/src/hd/rhdisp3.c (file contents): Revision 3.4 by gregl, Fri Nov 21 18:17:37 1997 UTC vs. Revision 3.11 by gwlarson, Thu Nov 5 13:58:37 1998 UTC

Diff Legend

Comparing ray/src/hd/rhdisp3.c (file contents):
Revision 3.4 by gregl, Fri Nov 21 18:17:37 1997 UTC vs.
Revision 3.11 by gwlarson, Thu Nov 5 13:58:37 1998 UTC