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root/radiance/src/common/cone.c
Revision: 2.7
Committed: Sat Jun 7 12:50:20 2003 UTC (22 years, 4 months ago) by schorsch
Content type: text/plain
Branch: MAIN
Changes since 2.6: +2 -1 lines
Log Message: 
Various small changes to reduce compile warnings/errors on Windows.

File Contents

# User Rev Content
1 greg 1.1 #ifndef lint
2 schorsch 2.7 static const char RCSid[] = "$Id: cone.c,v 2.6 2003/02/25 02:47:21 greg Exp $";
3 greg 1.1 #endif
4     /*
5     * cone.c - routines for making cones
6 greg 2.5 */
7    
8 greg 2.6 #include "copyright.h"
9 greg 1.1
10     #include "standard.h"
11    
12     #include "object.h"
13    
14     #include "otypes.h"
15    
16     #include "cone.h"
17    
18     /*
19     * In general, a cone may be any one of a cone, a cylinder, a ring,
20     * a cup (inverted cone), or a tube (inverted cylinder).
21     * Most cones are specified with a starting point and radius and
22     * an ending point and radius. In the cases of a cylinder or tube,
23     * only one radius is needed. In the case of a ring, a normal direction
24     * is specified instead of a second endpoint.
25     *
26     * mtype (cone|cup) name
27     * 0
28     * 0
29     * 8 P0x P0y P0z P1x P1y P1z R0 R1
30     *
31     * mtype (cylinder|tube) name
32     * 0
33     * 0
34     * 7 P0x P0y P0z P1x P1y P1z R
35     *
36     * mtype ring name
37     * 0
38     * 0
39     * 8 Px Py Pz Nx Ny Nz R0 R1
40     */
41    
42    
43     CONE *
44     getcone(o, getxf) /* get cone structure */
45     register OBJREC *o;
46     int getxf;
47     {
48 greg 1.4 int sgn0, sgn1;
49 greg 1.1 register CONE *co;
50    
51     if ((co = (CONE *)o->os) == NULL) {
52    
53     co = (CONE *)malloc(sizeof(CONE));
54     if (co == NULL)
55     error(SYSTEM, "out of memory in makecone");
56    
57     co->ca = o->oargs.farg;
58     /* get radii */
59 greg 2.2 if (o->otype == OBJ_CYLINDER | o->otype == OBJ_TUBE) {
60 greg 1.1 if (o->oargs.nfargs != 7)
61     goto argcerr;
62 greg 1.4 if (co->ca[6] < -FTINY) {
63     objerror(o, WARNING, "negative radius");
64     o->otype = o->otype == OBJ_CYLINDER ?
65     OBJ_TUBE : OBJ_CYLINDER;
66     co->ca[6] = -co->ca[6];
67     } else if (co->ca[6] <= FTINY)
68 greg 1.1 goto raderr;
69 greg 2.2 co->p0 = 0; co->p1 = 3;
70 greg 1.1 co->r0 = co->r1 = 6;
71     } else {
72     if (o->oargs.nfargs != 8)
73     goto argcerr;
74 greg 1.4 if (co->ca[6] < -FTINY) sgn0 = -1;
75     else if (co->ca[6] > FTINY) sgn0 = 1;
76     else sgn0 = 0;
77     if (co->ca[7] < -FTINY) sgn1 = -1;
78     else if (co->ca[7] > FTINY) sgn1 = 1;
79     else sgn1 = 0;
80     if (sgn0+sgn1 == 0)
81 greg 1.1 goto raderr;
82 greg 2.2 if (sgn0 < 0 | sgn1 < 0) {
83 greg 1.4 objerror(o, o->otype==OBJ_RING?USER:WARNING,
84     "negative radii");
85     o->otype = o->otype == OBJ_CONE ?
86     OBJ_CUP : OBJ_CONE;
87     }
88     co->ca[6] = co->ca[6]*sgn0;
89     co->ca[7] = co->ca[7]*sgn1;
90 greg 2.2 if (co->ca[7] - co->ca[6] > FTINY) {
91 greg 1.4 if (o->otype == OBJ_RING)
92 greg 2.2 co->p0 = co->p1 = 0;
93     else {
94     co->p0 = 0; co->p1 = 3;
95     }
96     co->r0 = 6; co->r1 = 7;
97     } else if (co->ca[6] - co->ca[7] > FTINY) {
98     if (o->otype == OBJ_RING)
99     co->p0 = co->p1 = 0;
100     else {
101     co->p0 = 3; co->p1 = 0;
102     }
103     co->r0 = 7; co->r1 = 6;
104     } else {
105     if (o->otype == OBJ_RING)
106 greg 1.4 goto raderr;
107     o->otype = o->otype == OBJ_CONE ?
108     OBJ_CYLINDER : OBJ_TUBE;
109     o->oargs.nfargs = 7;
110 greg 2.2 co->p0 = 0; co->p1 = 3;
111     co->r0 = co->r1 = 6;
112 greg 1.4 }
113 greg 1.1 }
114     /* get axis orientation */
115 greg 2.2 if (o->otype == OBJ_RING)
116 greg 1.1 VCOPY(co->ad, o->oargs.farg+3);
117 greg 2.2 else {
118     co->ad[0] = CO_P1(co)[0] - CO_P0(co)[0];
119     co->ad[1] = CO_P1(co)[1] - CO_P0(co)[1];
120     co->ad[2] = CO_P1(co)[2] - CO_P0(co)[2];
121 greg 1.1 }
122     co->al = normalize(co->ad);
123     if (co->al == 0.0)
124     objerror(o, USER, "zero orientation");
125     /* compute axis and side lengths */
126     if (o->otype == OBJ_RING) {
127     co->al = 0.0;
128 greg 2.2 co->sl = CO_R1(co) - CO_R0(co);
129     } else if (o->otype == OBJ_CONE | o->otype == OBJ_CUP) {
130 greg 1.1 co->sl = co->ca[7] - co->ca[6];
131     co->sl = sqrt(co->sl*co->sl + co->al*co->al);
132 greg 2.2 } else { /* OBJ_CYLINDER or OBJ_TUBE */
133 greg 1.1 co->sl = co->al;
134     }
135     co->tm = NULL;
136 greg 1.2 o->os = (char *)co;
137 greg 1.1 }
138     if (getxf && co->tm == NULL)
139     conexform(co);
140     return(co);
141    
142     argcerr:
143     objerror(o, USER, "bad # arguments");
144     raderr:
145     objerror(o, USER, "illegal radii");
146 schorsch 2.7 return NULL; /* pro forma return */
147 greg 1.1 }
148    
149    
150 greg 2.5 void
151 greg 1.1 freecone(o) /* free memory associated with cone */
152     OBJREC *o;
153     {
154     register CONE *co = (CONE *)o->os;
155    
156 greg 2.4 if (co == NULL)
157 greg 1.5 return;
158 greg 1.1 if (co->tm != NULL)
159 greg 2.5 free((void *)co->tm);
160     free((void *)co);
161 greg 1.1 o->os = NULL;
162     }
163    
164    
165 greg 2.5 void
166 greg 1.1 conexform(co) /* get cone transformation matrix */
167     register CONE *co;
168     {
169 greg 1.6 MAT4 m4;
170 greg 1.1 register double d;
171     register int i;
172    
173 greg 2.2 co->tm = (FLOAT (*)[4])malloc(sizeof(MAT4));
174 greg 1.1 if (co->tm == NULL)
175     error(SYSTEM, "out of memory in conexform");
176    
177     /* translate to origin */
178     setident4(co->tm);
179     if (co->r0 == co->r1)
180     d = 0.0;
181     else
182 greg 2.2 d = CO_R0(co) / (CO_R1(co) - CO_R0(co));
183 greg 1.1 for (i = 0; i < 3; i++)
184 greg 2.2 co->tm[3][i] = d*(CO_P1(co)[i] - CO_P0(co)[i])
185     - CO_P0(co)[i];
186 greg 1.1
187     /* rotate to positive z-axis */
188     setident4(m4);
189     d = co->ad[1]*co->ad[1] + co->ad[2]*co->ad[2];
190     if (d <= FTINY*FTINY) {
191     m4[0][0] = 0.0;
192     m4[0][2] = co->ad[0];
193     m4[2][0] = -co->ad[0];
194     m4[2][2] = 0.0;
195     } else {
196     d = sqrt(d);
197     m4[0][0] = d;
198     m4[1][0] = -co->ad[0]*co->ad[1]/d;
199     m4[2][0] = -co->ad[0]*co->ad[2]/d;
200     m4[1][1] = co->ad[2]/d;
201     m4[2][1] = -co->ad[1]/d;
202     m4[0][2] = co->ad[0];
203     m4[1][2] = co->ad[1];
204     m4[2][2] = co->ad[2];
205     }
206     multmat4(co->tm, co->tm, m4);
207    
208     /* scale z-axis */
209 greg 2.2 if (co->p0 != co->p1 & co->r0 != co->r1) {
210     setident4(m4);
211     m4[2][2] = (CO_R1(co) - CO_R0(co)) / co->al;
212     multmat4(co->tm, co->tm, m4);
213 greg 1.1 }
214     }