[ViewVC] Diff of: radiance/ray/src/common/fvect.c

Comparing ray/src/common/fvect.c (file contents):
Revision 2.7 by greg, Tue Feb 25 02:47:21 2003 UTC vs.
Revision 2.20 by greg, Thu Dec 4 05:26:27 2014 UTC

#	Line 7 \| Line 7 \| static const char RCSid[] = "$Id$";
7
8		#include "copyright.h"
9
10	+	#define _USE_MATH_DEFINES
11		#include <math.h>
12		#include "fvect.h"
13	+	#include "random.h"
14
15	+	double
16	+	Acos(double x) /* insurance for touchy math library */
17	+	{
18	+	if (x <= -1.+FTINY*FTINY)
19	+	return(M_PI);
20	+	if (x >= 1.-FTINY*FTINY)
21	+	return(.0);
22	+	return(acos(x));
23	+	}
24
25		double
26	<	fdot(v1, v2) /* return the dot product of two vectors */
16	<	register FVECT v1, v2;
26	>	Asin(double x) /* insurance for touchy math library */
27		{
28	+	if (x <= -1.+FTINY*FTINY)
29	+	return(-M_PI/2.);
30	+	if (x >= 1.-FTINY*FTINY)
31	+	return(M_PI/2);
32	+	return(asin(x));
33	+	}
34	+
35	+	double
36	+	fdot( /* return the dot product of two vectors */
37	+	const FVECT v1,
38	+	const FVECT v2
39	+	)
40	+	{
41		return(DOT(v1,v2));
42		}
43
44
45		double
46	<	dist2(p1, p2) /* return square of distance between points */
47	<	register FVECT p1, p2;
46	>	dist2( /* return square of distance between points */
47	>	const FVECT p1,
48	>	const FVECT p2
49	>	)
50		{
51		FVECT delta;
52
53	<	delta[0] = p2[0] - p1[0];
29	<	delta[1] = p2[1] - p1[1];
30	<	delta[2] = p2[2] - p1[2];
53	>	VSUB(delta, p2, p1);
54
55		return(DOT(delta, delta));
56		}
57
58
59		double
60	<	dist2line(p, ep1, ep2) /* return square of distance to line */
61	<	FVECT p; /* the point */
62	<	FVECT ep1, ep2; /* points on the line */
60	>	dist2line( /* return square of distance to line */
61	>	const FVECT p, /* the point */
62	>	const FVECT ep1,
63	>	const FVECT ep2 /* points on the line */
64	>	)
65		{
66	<	register double d, d1, d2;
66	>	double d, d1, d2;
67
68		d = dist2(ep1, ep2);
69		d1 = dist2(ep1, p);
#	Line 49 \| Line 74 \| *FVECT ep1, ep2; / points on the line /*
74
75
76		double
77	<	dist2lseg(p, ep1, ep2) /* return square of distance to line segment */
78	<	FVECT p; /* the point */
79	<	FVECT ep1, ep2; /* the end points */
77	>	dist2lseg( /* return square of distance to line segment */
78	>	const FVECT p, /* the point */
79	>	const FVECT ep1,
80	>	const FVECT ep2 /* the end points */
81	>	)
82		{
83	<	register double d, d1, d2;
83	>	double d, d1, d2;
84
85		d = dist2(ep1, ep2);
86		d1 = dist2(ep1, p);
#	Line 73 \| Line 100 \| *FVECT ep1, ep2; / the end points /*
100
101
102		void
103	<	fcross(vres, v1, v2) /* vres = v1 X v2 */
104	<	register FVECT vres, v1, v2;
103	>	fcross( /* vres = v1 X v2 */
104	>	FVECT vres,
105	>	const FVECT v1,
106	>	const FVECT v2
107	>	)
108		{
109	<	vres[0] = v1[1]v2[2] - v1[2]v2[1];
80	<	vres[1] = v1[2]v2[0] - v1[0]v2[2];
81	<	vres[2] = v1[0]v2[1] - v1[1]v2[0];
109	>	VCROSS(vres, v1, v2);
110		}
111
112
113		void
114	<	fvsum(vres, v0, v1, f) /* vres = v0 + fv1 /
115	<	register FVECT vres, v0, v1;
116	<	register double f;
114	>	fvsum( /* vres = v0 + fv1 /
115	>	FVECT vres,
116	>	const FVECT v0,
117	>	const FVECT v1,
118	>	double f
119	>	)
120		{
121	<	vres[0] = v0[0] + f*v1[0];
91	<	vres[1] = v0[1] + f*v1[1];
92	<	vres[2] = v0[2] + f*v1[2];
121	>	VSUM(vres, v0, v1, f);
122		}
123
124
125		double
126	<	normalize(v) /* normalize a vector, return old magnitude */
127	<	register FVECT v;
126	>	normalize( /* normalize a vector, return old magnitude */
127	>	FVECT v
128	>	)
129		{
130	<	register double len, d;
130	>	double len, d;
131
132		d = DOT(v, v);
133
134	<	if (d <= 0.0)
134	>	if (d == 0.0)
135		return(0.0);
136
137	<	if (d <= 1.0+FTINY && d >= 1.0-FTINY)
137	>	if ((d <= 1.0+FTINY) & (d >= 1.0-FTINY)) {
138		len = 0.5 + 0.5d; / first order approximation */
139	<	else
139	>	d = 2.0 - len;
140	>	} else {
141		len = sqrt(d);
142	<
143	<	v[0] *= d = 1.0/len;
142	>	d = 1.0/len;
143	>	}
144	>	v[0] *= d;
145		v[1] *= d;
146		v[2] *= d;
147
#	Line 117 \| Line 149 \| register FVECT v;
149		}
150
151
152	+	int
153	+	getperpendicular( /* choose random perpedicular direction */
154	+	FVECT vp, /* returns normalized */
155	+	const FVECT v /* input vector must be normalized */
156	+	)
157	+	{
158	+	FVECT v1;
159	+	int i;
160	+	/* randomize other coordinates */
161	+	v1[0] = 0.5 - frandom();
162	+	v1[1] = 0.5 - frandom();
163	+	v1[2] = 0.5 - frandom();
164	+	for (i = 3; i--; )
165	+	if ((-0.6 < v[i]) & (v[i] < 0.6))
166	+	break;
167	+	if (i < 0)
168	+	return(0);
169	+	v1[i] = 1.0;
170	+	VCROSS(vp, v1, v);
171	+	return(normalize(vp) > 0.0);
172	+	}
173	+
174	+	int
175	+	closestapproach( /* closest approach of two rays */
176	+	RREAL t[2], /* returned distances along each ray */
177	+	const FVECT rorg0, /* first origin */
178	+	const FVECT rdir0, /* first direction (normalized) */
179	+	const FVECT rorg1, /* second origin */
180	+	const FVECT rdir1 /* second direction (normalized) */
181	+	)
182	+	{
183	+	double dotprod = DOT(rdir0, rdir1);
184	+	double denom = 1. - dotprod*dotprod;
185	+	double o1o2_d1;
186	+	FVECT o0o1;
187	+
188	+	if (denom <= FTINY) { /* check if lines are parallel */
189	+	t[0] = t[1] = 0.0;
190	+	return(0);
191	+	}
192	+	VSUB(o0o1, rorg0, rorg1);
193	+	o1o2_d1 = DOT(o0o1, rdir1);
194	+	t[0] = (o1o2_d1*dotprod - DOT(o0o1,rdir0)) / denom;
195	+	t[1] = o1o2_d1 + t[0]*dotprod;
196	+	return(1);
197	+	}
198	+
199	+
200		void
201	<	spinvector(vres, vorig, vnorm, theta) /* rotate vector around normal */
202	<	FVECT vres, vorig, vnorm;
203	<	double theta;
201	>	spinvector( /* rotate vector around normal */
202	>	FVECT vres, /* returned vector (same magnitude as vorig) */
203	>	const FVECT vorig, /* original vector */
204	>	const FVECT vnorm, /* normalized vector for rotation */
205	>	double theta /* right-hand radians */
206	>	)
207		{
208		double sint, cost, normprod;
209		FVECT vperp;
210	<	register int i;
210	>	int i;
211
212		if (theta == 0.0) {
213		if (vres != vorig)
#	Line 134 \| Line 217 \| double theta;
217		cost = cos(theta);
218		sint = sin(theta);
219		normprod = DOT(vorig, vnorm)*(1.-cost);
220	<	fcross(vperp, vnorm, vorig);
220	>	VCROSS(vperp, vnorm, vorig);
221		for (i = 0; i < 3; i++)
222		vres[i] = vorig[i]cost + vnorm[i]normprod + vperp[i]*sint;
223	+	}
224	+
225	+	double
226	+	geodesic( /* rotate vector on great circle towards target */
227	+	FVECT vres, /* returned vector (same magnitude as vorig) */
228	+	const FVECT vorig, /* original vector */
229	+	const FVECT vtarg, /* vector we are rotating towards */
230	+	double t, /* amount along arc directed towards vtarg */
231	+	int meas /* distance measure (radians, absolute, relative) */
232	+	)
233	+	{
234	+	FVECT normtarg;
235	+	double volen, dotprod, sintr, cost;
236	+	int i;
237	+
238	+	VCOPY(normtarg, vtarg); /* in case vtarg==vres */
239	+	if (vres != vorig)
240	+	VCOPY(vres, vorig);
241	+	if (t == 0.0)
242	+	return(VLEN(vres)); /* no rotation requested */
243	+	if ((volen = normalize(vres)) == 0.0)
244	+	return(0.0);
245	+	if (normalize(normtarg) == 0.0)
246	+	return(0.0); /* target vector is zero */
247	+	dotprod = DOT(vres, normtarg);
248	+	/* check for colinear */
249	+	if (dotprod >= 1.0-FTINY*FTINY) {
250	+	if (meas != GEOD_REL)
251	+	return(0.0);
252	+	vres[0] = volen; vres[1] = volen; vres[2] *= volen;
253	+	return(volen);
254	+	}
255	+	if (dotprod <= -1.0+FTINY*FTINY)
256	+	return(0.0);
257	+	if (meas == GEOD_ABS)
258	+	t /= volen;
259	+	else if (meas == GEOD_REL)
260	+	t *= acos(dotprod);
261	+	cost = cos(t);
262	+	sintr = sin(t) / sqrt(1. - dotprod*dotprod);
263	+	for (i = 0; i < 3; i++)
264	+	vres[i] = volen( costvres[i] +
265	+	sintr(normtarg[i] - dotprodvres[i]) );
266	+
267	+	return(volen); /* return vector length */
268		}

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Comparing ray/src/common/fvect.c (file contents): Revision 2.7 by greg, Tue Feb 25 02:47:21 2003 UTC vs. Revision 2.20 by greg, Thu Dec 4 05:26:27 2014 UTC

Diff Legend

Comparing ray/src/common/fvect.c (file contents):
Revision 2.7 by greg, Tue Feb 25 02:47:21 2003 UTC vs.
Revision 2.20 by greg, Thu Dec 4 05:26:27 2014 UTC