src/common/mat4.c

/* Copyright (c) 1990 Regents of the University of California */

#ifndef lint
static char SCCSid[] = "$SunId$ LBL";
#endif

/*
 *  mat4.c - routines dealing with 4 X 4 homogeneous transformation matrices.
 *
 *     10/19/85
 */

#include  "mat4.h"

MAT4  m4ident = MAT4IDENT;

static MAT4  m4tmp;             /* for efficiency */


multmat4(m4a, m4b, m4c)         /* multiply m4b X m4c and put into m4a */
MAT4  m4a;
register MAT4  m4b, m4c;
{
        register int  i, j;
        
        for (i = 4; i--; )
                for (j = 4; j--; )
                        m4tmp[i][j] = m4b[i][0]*m4c[0][j] +
                                      m4b[i][1]*m4c[1][j] +
                                      m4b[i][2]*m4c[2][j] +
                                      m4b[i][3]*m4c[3][j];
        
        copymat4(m4a, m4tmp);
}


multv3(v3a, v3b, m4)    /* transform vector v3b by m4 and put into v3a */
FVECT  v3a;
register FVECT  v3b;
register MAT4  m4;
{
        m4tmp[0][0] = v3b[0]*m4[0][0] + v3b[1]*m4[1][0] + v3b[2]*m4[2][0];
        m4tmp[0][1] = v3b[0]*m4[0][1] + v3b[1]*m4[1][1] + v3b[2]*m4[2][1];
        m4tmp[0][2] = v3b[0]*m4[0][2] + v3b[1]*m4[1][2] + v3b[2]*m4[2][2];
        
        v3a[0] = m4tmp[0][0];
        v3a[1] = m4tmp[0][1];
        v3a[2] = m4tmp[0][2];
}


multp3(p3a, p3b, m4)            /* transform p3b by m4 and put into p3a */
register FVECT  p3a;
FVECT  p3b;
register MAT4  m4;
{
        multv3(p3a, p3b, m4);   /* transform as vector */
        p3a[0] += m4[3][0];     /* translate */
        p3a[1] += m4[3][1];
        p3a[2] += m4[3][2];
}


#ifdef  INVMAT
/*
 * invmat - computes the inverse of mat into inverse.  Returns 1
 * if there exists an inverse, 0 otherwise.  It uses Gaussian Elimination
 * method with partial pivoting.
 */

invmat(inverse,mat)
MAT4  mat, inverse;
{
#define SWAP(a,b,t) (t=a,a=b,b=t)
#define ABS(x) (x>=0?x:-(x))

        register int i,j,k;
        register double temp;

        copymat4(m4tmp, mat);
        setident(inverse);

        for(i = 0; i < 4; i++) {
                /* Look for row with largest pivot and swap rows */
                temp = 0; j = -1;
                for(k = i; k < 4; k++)
                        if(ABS(m4tmp[k][i]) > temp) {
                                temp = ABS(m4tmp[k][i]);
                                j = k;
                                }
                if(j == -1)     /* No replacing row -> no inverse */
                        return(0);
                if (j != i)
                        for(k = 0; k < 4; k++) {
                                SWAP(m4tmp[i][k],m4tmp[j][k],temp);
                                SWAP(inverse[i][k],inverse[j][k],temp);
                                }

                temp = m4tmp[i][i];
                for(k = 0; k < 4; k++) {
                        m4tmp[i][k] /= temp;
                        inverse[i][k] /= temp;
                        }
                for(j = 0; j < 4; j++) {
                        if(j != i) {
                                temp = m4tmp[j][i];
                                for(k = 0; k < 4; k++) {
                                        m4tmp[j][k] -= m4tmp[i][k]*temp;
                                        inverse[j][k] -= inverse[i][k]*temp;
                                        }
                                }
                        }
                }
        return(1);

#undef ABS
#undef SWAP
}
#endif
Revision:	1.6
Committed:	Tue Jun 18 12:01:16 1991 UTC (32 years, 10 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 1.5:	+2 -13 lines
Log Message:	changed setident4() into a macro
#	User	Rev	Content
1	greg	1.5	/* Copyright (c) 1990 Regents of the University of California */
2	greg	1.1
3			#ifndef lint
4			static char SCCSid[] = "$SunId$ LBL";
5			#endif
6
7			/*
8			* mat4.c - routines dealing with 4 X 4 homogeneous transformation matrices.
9			*
10			* 10/19/85
11			*/
12
13	greg	1.5	#include "mat4.h"
14	greg	1.1
15	greg	1.6	MAT4 m4ident = MAT4IDENT;
16
17	greg	1.5	static MAT4 m4tmp; /* for efficiency */
18	greg	1.1
19
20			multmat4(m4a, m4b, m4c) /* multiply m4b X m4c and put into m4a */
21	greg	1.5	MAT4 m4a;
22			register MAT4 m4b, m4c;
23	greg	1.1	{
24			register int i, j;
25
26			for (i = 4; i--; )
27			for (j = 4; j--; )
28			m4tmp[i][j] = m4b[i][0]*m4c[0][j] +
29			m4b[i][1]*m4c[1][j] +
30			m4b[i][2]*m4c[2][j] +
31			m4b[i][3]*m4c[3][j];
32
33			copymat4(m4a, m4tmp);
34			}
35
36
37			multv3(v3a, v3b, m4) /* transform vector v3b by m4 and put into v3a */
38	greg	1.5	FVECT v3a;
39			register FVECT v3b;
40			register MAT4 m4;
41	greg	1.1	{
42	greg	1.3	m4tmp[0][0] = v3b[0]m4[0][0] + v3b[1]m4[1][0] + v3b[2]*m4[2][0];
43			m4tmp[0][1] = v3b[0]m4[0][1] + v3b[1]m4[1][1] + v3b[2]*m4[2][1];
44			m4tmp[0][2] = v3b[0]m4[0][2] + v3b[1]m4[1][2] + v3b[2]*m4[2][2];
45	greg	1.1
46			v3a[0] = m4tmp[0][0];
47			v3a[1] = m4tmp[0][1];
48			v3a[2] = m4tmp[0][2];
49			}
50
51
52			multp3(p3a, p3b, m4) /* transform p3b by m4 and put into p3a */
53	greg	1.5	register FVECT p3a;
54			FVECT p3b;
55			register MAT4 m4;
56	greg	1.1	{
57			multv3(p3a, p3b, m4); /* transform as vector */
58			p3a[0] += m4[3][0]; /* translate */
59			p3a[1] += m4[3][1];
60			p3a[2] += m4[3][2];
61			}
62
63
64			#ifdef INVMAT
65			/*
66			* invmat - computes the inverse of mat into inverse. Returns 1
67	greg	1.2	* if there exists an inverse, 0 otherwise. It uses Gaussian Elimination
68			* method with partial pivoting.
69	greg	1.1	*/
70
71			invmat(inverse,mat)
72	greg	1.5	MAT4 mat, inverse;
73	greg	1.1	{
74			#define SWAP(a,b,t) (t=a,a=b,b=t)
75	greg	1.2	#define ABS(x) (x>=0?x:-(x))
76	greg	1.1
77			register int i,j,k;
78			register double temp;
79
80			copymat4(m4tmp, mat);
81	greg	1.2	setident(inverse);
82	greg	1.1
83			for(i = 0; i < 4; i++) {
84	greg	1.2	/* Look for row with largest pivot and swap rows */
85			temp = 0; j = -1;
86			for(k = i; k < 4; k++)
87			if(ABS(m4tmp[k][i]) > temp) {
88			temp = ABS(m4tmp[k][i]);
89			j = k;
90			}
91			if(j == -1) /* No replacing row -> no inverse */
92			return(0);
93			if (j != i)
94			for(k = 0; k < 4; k++) {
95			SWAP(m4tmp[i][k],m4tmp[j][k],temp);
96			SWAP(inverse[i][k],inverse[j][k],temp);
97			}
98	greg	1.1
99			temp = m4tmp[i][i];
100			for(k = 0; k < 4; k++) {
101			m4tmp[i][k] /= temp;
102			inverse[i][k] /= temp;
103			}
104			for(j = 0; j < 4; j++) {
105			if(j != i) {
106			temp = m4tmp[j][i];
107			for(k = 0; k < 4; k++) {
108			m4tmp[j][k] -= m4tmp[i][k]*temp;
109			inverse[j][k] -= inverse[i][k]*temp;
110			}
111			}
112			}
113			}
114			return(1);
115	greg	1.2
116			#undef ABS
117			#undef SWAP
118	greg	1.1	}
119			#endif