src/rt/func.c

/* Copyright (c) 1991 Regents of the University of California */

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

/*
 *  func.c - interface to calcomp functions.
 *
 *     4/7/86
 */

#include  "ray.h"

#include  "otypes.h"


XF  unitxf = {                  /* identity transform */
        1.0, 0.0, 0.0, 0.0,
        0.0, 1.0, 0.0, 0.0,
        0.0, 0.0, 1.0, 0.0,
        0.0, 0.0, 0.0, 1.0,
        1.0
};

XF  funcxf;                     /* current transformation */
static OBJREC  *fobj = NULL;    /* current function object */
static RAY  *fray = NULL;       /* current function ray */


setmap(m, r, bx)                /* set channels for function call */
OBJREC  *m;
register RAY  *r;
XF  *bx;
{
        extern double  l_arg(), l_erf(), l_erfc();
        extern long  eclock;
        static char  *initfile = "rayinit.cal";
        static long  lastrno = -1;
                                        /* check to see if already set */
        if (m == fobj && r->rno == lastrno)
                return(0);
                                        /* initialize if first call */
        if (initfile != NULL) {
                scompile("Dx=$1;Dy=$2;Dz=$3;", NULL, 0);
                scompile("Nx=$4;Ny=$5;Nz=$6;", NULL, 0);
                scompile("Px=$7;Py=$8;Pz=$9;", NULL, 0);
                scompile("T=$10;Rdot=$11;", NULL, 0);
                scompile("S=$12;Tx=$13;Ty=$14;Tz=$15;", NULL, 0);
                scompile("Ix=$16;Iy=$17;Iz=$18;", NULL, 0);
                scompile("Jx=$19;Jy=$20;Jz=$21;", NULL, 0);
                scompile("Kx=$22;Ky=$23;Kz=$24;", NULL, 0);
                funset("arg", 1, '=', l_arg);
                funset("erf", 1, ':', l_erf);
                funset("erfc", 1, ':', l_erfc);
                setnoisefuncs();
                loadfunc(initfile);
                initfile = NULL;
        }
        fobj = m;
        fray = r;
        if (r->rox != NULL)
                if (bx != &unitxf) {
                        funcxf.sca = r->rox->b.sca * bx->sca;
                        multmat4(funcxf.xfm, r->rox->b.xfm, bx->xfm);
                } else
                        copystruct(&funcxf, &r->rox->b);
        else
                copystruct(&funcxf, bx);
        lastrno = r->rno;
        eclock++;               /* notify expression evaluator */
        return(1);
}


setfunc(m, r)                           /* simplified interface to setmap */
register OBJREC  *m;
RAY  *r;
{
        register XF  *mxf;

        if ((mxf = (XF *)m->os) == NULL) {
                register int  n;
                register char  **sa;

                for (n = m->oargs.nsargs, sa = m->oargs.sarg;
                                n > 0 && **sa != '-'; n--, sa++)
                        ;
                if (n == 0)
                        mxf = &unitxf;
                else {
                        mxf = (XF *)malloc(sizeof(XF));
                        if (mxf == NULL)
                                goto memerr;
                        if (invxf(mxf, n, sa) != n)
                                objerror(m, USER, "bad transform");
                        if (mxf->sca < 0.0)
                                mxf->sca = -mxf->sca;
                }
                m->os = (char *)mxf;
        }
        return(setmap(m, r, mxf));
memerr:
        error(SYSTEM, "out of memory in setfunc");
}


loadfunc(fname)                 /* load definition file */
char  *fname;
{
        extern char  *libpath;          /* library search path */
        char  *ffname;

        if ((ffname = getpath(fname, libpath, R_OK)) == NULL) {
                sprintf(errmsg, "cannot find function file \"%s\"", fname);
                error(USER, errmsg);
        }
        fcompile(ffname);
}


double
l_arg()                         /* return nth real argument */
{
        extern double  argument();
        register int  n;

        n = argument(1) + .5;           /* round to integer */

        if (n < 1)
                return(fobj->oargs.nfargs);

        if (n > fobj->oargs.nfargs) {
                sprintf(errmsg, "missing real argument %d", n);
                objerror(fobj, USER, errmsg);
        }
        return(fobj->oargs.farg[n-1]);
}


double
l_erf()                         /* error function */
{
        extern double  erf();

        return(erf(argument(1)));
}


double
l_erfc()                        /* cumulative error function */
{
        extern double  erfc();

        return(erfc(argument(1)));
}


double
chanvalue(n)                    /* return channel n to calcomp */
register int  n;
{
        double  sum;
        register RAY  *r;

        if (--n < 0)
                goto badchan;

        if (n < 3)                      /* ray direction */

                return( (       fray->rdir[0]*funcxf.xfm[0][n] +
                                fray->rdir[1]*funcxf.xfm[1][n] +
                                fray->rdir[2]*funcxf.xfm[2][n]  )
                         / funcxf.sca );

        if (n < 6)                      /* surface normal */

                return( (       fray->ron[0]*funcxf.xfm[0][n-3] +
                                fray->ron[1]*funcxf.xfm[1][n-3] +
                                fray->ron[2]*funcxf.xfm[2][n-3] )
                         / funcxf.sca );

        if (n < 9)                      /* intersection */

                return( fray->rop[0]*funcxf.xfm[0][n-6] +
                                fray->rop[1]*funcxf.xfm[1][n-6] +
                                fray->rop[2]*funcxf.xfm[2][n-6] +
                                             funcxf.xfm[3][n-6] );

        if (n == 9) {                   /* distance */

                sum = fray->rot;
                for (r = fray->parent; r != NULL; r = r->parent)
                        sum += r->rot;
                return(sum * funcxf.sca);

        }
        if (n == 10)                    /* dot product (range [-1,1]) */
                return( fray->rod <= -1.0 ? -1.0 :
                        fray->rod >= 1.0 ? 1.0 :
                        fray->rod );

        if (n == 11)                    /* scale */
                return(funcxf.sca);

        if (n < 15)                     /* origin */
                return(funcxf.xfm[3][n-12]);

        if (n < 18)                     /* i unit vector */
                return(funcxf.xfm[0][n-15] / funcxf.sca);

        if (n < 21)                     /* j unit vector */
                return(funcxf.xfm[1][n-15] / funcxf.sca);

        if (n < 24)                     /* k unit vector */
                return(funcxf.xfm[2][n-21] / funcxf.sca);
badchan:
        error(USER, "illegal channel number");
}
Revision:	1.20
Committed:	Wed Jul 17 10:09:24 1991 UTC (32 years, 9 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 1.19:	+1 -1 lines
Log Message:	changed position of initfile loading to catch conflicts
#	Content
1	/* Copyright (c) 1991 Regents of the University of California */
2
3	#ifndef lint
4	static char SCCSid[] = "$SunId$ LBL";
5	#endif
6
7	/*
8	* func.c - interface to calcomp functions.
9	*
10	* 4/7/86
11	*/
12
13	#include "ray.h"
14
15	#include "otypes.h"
16
17
18	XF unitxf = { /* identity transform */
19	1.0, 0.0, 0.0, 0.0,
20	0.0, 1.0, 0.0, 0.0,
21	0.0, 0.0, 1.0, 0.0,
22	0.0, 0.0, 0.0, 1.0,
23	1.0
24	};
25
26	XF funcxf; /* current transformation */
27	static OBJREC fobj = NULL; / current function object */
28	static RAY fray = NULL; / current function ray */
29
30
31	setmap(m, r, bx) /* set channels for function call */
32	OBJREC *m;
33	register RAY *r;
34	XF *bx;
35	{
36	extern double l_arg(), l_erf(), l_erfc();
37	extern long eclock;
38	static char *initfile = "rayinit.cal";
39	static long lastrno = -1;
40	/* check to see if already set */
41	if (m == fobj && r->rno == lastrno)
42	return(0);
43	/* initialize if first call */
44	if (initfile != NULL) {
45	scompile("Dx=$1;Dy=$2;Dz=$3;", NULL, 0);
46	scompile("Nx=$4;Ny=$5;Nz=$6;", NULL, 0);
47	scompile("Px=$7;Py=$8;Pz=$9;", NULL, 0);
48	scompile("T=$10;Rdot=$11;", NULL, 0);
49	scompile("S=$12;Tx=$13;Ty=$14;Tz=$15;", NULL, 0);
50	scompile("Ix=$16;Iy=$17;Iz=$18;", NULL, 0);
51	scompile("Jx=$19;Jy=$20;Jz=$21;", NULL, 0);
52	scompile("Kx=$22;Ky=$23;Kz=$24;", NULL, 0);
53	funset("arg", 1, '=', l_arg);
54	funset("erf", 1, ':', l_erf);
55	funset("erfc", 1, ':', l_erfc);
56	setnoisefuncs();
57	loadfunc(initfile);
58	initfile = NULL;
59	}
60	fobj = m;
61	fray = r;
62	if (r->rox != NULL)
63	if (bx != &unitxf) {
64	funcxf.sca = r->rox->b.sca * bx->sca;
65	multmat4(funcxf.xfm, r->rox->b.xfm, bx->xfm);
66	} else
67	copystruct(&funcxf, &r->rox->b);
68	else
69	copystruct(&funcxf, bx);
70	lastrno = r->rno;
71	eclock++; /* notify expression evaluator */
72	return(1);
73	}
74
75
76	setfunc(m, r) /* simplified interface to setmap */
77	register OBJREC *m;
78	RAY *r;
79	{
80	register XF *mxf;
81
82	if ((mxf = (XF *)m->os) == NULL) {
83	register int n;
84	register char **sa;
85
86	for (n = m->oargs.nsargs, sa = m->oargs.sarg;
87	n > 0 && **sa != '-'; n--, sa++)
88	;
89	if (n == 0)
90	mxf = &unitxf;
91	else {
92	mxf = (XF *)malloc(sizeof(XF));
93	if (mxf == NULL)
94	goto memerr;
95	if (invxf(mxf, n, sa) != n)
96	objerror(m, USER, "bad transform");
97	if (mxf->sca < 0.0)
98	mxf->sca = -mxf->sca;
99	}
100	m->os = (char *)mxf;
101	}
102	return(setmap(m, r, mxf));
103	memerr:
104	error(SYSTEM, "out of memory in setfunc");
105	}
106
107
108	loadfunc(fname) /* load definition file */
109	char *fname;
110	{
111	extern char libpath; / library search path */
112	char *ffname;
113
114	if ((ffname = getpath(fname, libpath, R_OK)) == NULL) {
115	sprintf(errmsg, "cannot find function file \"%s\"", fname);
116	error(USER, errmsg);
117	}
118	fcompile(ffname);
119	}
120
121
122	double
123	l_arg() /* return nth real argument */
124	{
125	extern double argument();
126	register int n;
127
128	n = argument(1) + .5; /* round to integer */
129
130	if (n < 1)
131	return(fobj->oargs.nfargs);
132
133	if (n > fobj->oargs.nfargs) {
134	sprintf(errmsg, "missing real argument %d", n);
135	objerror(fobj, USER, errmsg);
136	}
137	return(fobj->oargs.farg[n-1]);
138	}
139
140
141	double
142	l_erf() /* error function */
143	{
144	extern double erf();
145
146	return(erf(argument(1)));
147	}
148
149
150	double
151	l_erfc() /* cumulative error function */
152	{
153	extern double erfc();
154
155	return(erfc(argument(1)));
156	}
157
158
159	double
160	chanvalue(n) /* return channel n to calcomp */
161	register int n;
162	{
163	double sum;
164	register RAY *r;
165
166	if (--n < 0)
167	goto badchan;
168
169	if (n < 3) /* ray direction */
170
171	return( ( fray->rdir[0]*funcxf.xfm[0][n] +
172	fray->rdir[1]*funcxf.xfm[1][n] +
173	fray->rdir[2]*funcxf.xfm[2][n] )
174	/ funcxf.sca );
175
176	if (n < 6) /* surface normal */
177
178	return( ( fray->ron[0]*funcxf.xfm[0][n-3] +
179	fray->ron[1]*funcxf.xfm[1][n-3] +
180	fray->ron[2]*funcxf.xfm[2][n-3] )
181	/ funcxf.sca );
182
183	if (n < 9) /* intersection */
184
185	return( fray->rop[0]*funcxf.xfm[0][n-6] +
186	fray->rop[1]*funcxf.xfm[1][n-6] +
187	fray->rop[2]*funcxf.xfm[2][n-6] +
188	funcxf.xfm[3][n-6] );
189
190	if (n == 9) { /* distance */
191
192	sum = fray->rot;
193	for (r = fray->parent; r != NULL; r = r->parent)
194	sum += r->rot;
195	return(sum * funcxf.sca);
196
197	}
198	if (n == 10) /* dot product (range [-1,1]) */
199	return( fray->rod <= -1.0 ? -1.0 :
200	fray->rod >= 1.0 ? 1.0 :
201	fray->rod );
202
203	if (n == 11) /* scale */
204	return(funcxf.sca);
205
206	if (n < 15) /* origin */
207	return(funcxf.xfm[3][n-12]);
208
209	if (n < 18) /* i unit vector */
210	return(funcxf.xfm[0][n-15] / funcxf.sca);
211
212	if (n < 21) /* j unit vector */
213	return(funcxf.xfm[1][n-15] / funcxf.sca);
214
215	if (n < 24) /* k unit vector */
216	return(funcxf.xfm[2][n-21] / funcxf.sca);
217	badchan:
218	error(USER, "illegal channel number");
219	}