src/cv/mgf2rad.c

/* Copyright (c) 1994 Regents of the University of California */

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

/*
 * Convert MGF (Materials and Geometry Format) to Radiance
 */

#include <stdio.h>
#include <math.h>
#include <string.h>
#include "mgflib/parser.h"
#include "color.h"
#include "tmesh.h"

#define putv(v)         printf("%18.12g %18.12g %18.12g\n",(v)[0],(v)[1],(v)[2])

#define invert          (xf_context != NULL && xf_context->rev)

double  glowdist = FHUGE;               /* glow test distance */

double  emult = 1.;                     /* emitter multiplier */

FILE    *matfp = stdout;                /* material output file */

int     r_comment(), r_cone(), r_cyl(), r_face(), r_ies(), r_ring(), r_sph();
char    *material(), *object(), *addarg();


main(argc, argv)                /* convert files to stdout */
int     argc;
char    *argv[];
{
        int     i, rv;
                                /* initialize dispatch table */
        mg_ehand[MG_E_COMMENT] = r_comment;     /* we pass comments */
        mg_ehand[MG_E_COLOR] = c_hcolor;        /* they get color */
        mg_ehand[MG_E_CONE] = r_cone;           /* we do cones */
        mg_ehand[MG_E_CMIX] = c_hcolor;         /* they mix colors */
        mg_ehand[MG_E_CSPEC] = c_hcolor;        /* they get spectra */
        mg_ehand[MG_E_CXY] = c_hcolor;          /* they get chromaticities */
        mg_ehand[MG_E_CCT] = c_hcolor;          /* they get color temp's */
        mg_ehand[MG_E_CYL] = r_cyl;             /* we do cylinders */
        mg_ehand[MG_E_ED] = c_hmaterial;        /* they get emission */
        mg_ehand[MG_E_FACE] = r_face;           /* we do faces */
        mg_ehand[MG_E_IES] = r_ies;             /* we do IES files */
        mg_ehand[MG_E_IR] = c_hmaterial;        /* they get refractive index */
        mg_ehand[MG_E_MATERIAL] = c_hmaterial;  /* they get materials */
        mg_ehand[MG_E_NORMAL] = c_hvertex;      /* they get normals */
        mg_ehand[MG_E_OBJECT] = obj_handler;    /* they track object names */
        mg_ehand[MG_E_POINT] = c_hvertex;       /* they get points */
        mg_ehand[MG_E_RD] = c_hmaterial;        /* they get diffuse refl. */
        mg_ehand[MG_E_RING] = r_ring;           /* we do rings */
        mg_ehand[MG_E_RS] = c_hmaterial;        /* they get specular refl. */
        mg_ehand[MG_E_SIDES] = c_hmaterial;     /* they get # sides */
        mg_ehand[MG_E_SPH] = r_sph;             /* we do spheres */
        mg_ehand[MG_E_TD] = c_hmaterial;        /* they get diffuse trans. */
        mg_ehand[MG_E_TS] = c_hmaterial;        /* they get specular trans. */
        mg_ehand[MG_E_VERTEX] = c_hvertex;      /* they get vertices */
        mg_ehand[MG_E_XF] = xf_handler;         /* they track transforms */
        mg_init();              /* initialize the parser */
                                        /* get our options & print header */
        printf("## %s", argv[0]);
        for (i = 1; i < argc && argv[i][0] == '-'; i++) {
                printf(" %s", argv[i]);
                switch (argv[i][1]) {
                case 'g':                       /* glow distance (meters) */
                        if (argv[i][2] || badarg(argc-i-1, argv+i+1, "f"))
                                goto userr;
                        glowdist = atof(argv[++i]);
                        printf(" %s", argv[i]);
                        break;
                case 'e':                       /* emitter multiplier */
                        if (argv[i][2] || badarg(argc-i-1, argv+i+1, "f"))
                                goto userr;
                        emult = atof(argv[++i]);
                        printf(" %s", argv[i]);
                        break;
                case 'm':                       /* materials file */
                        matfp = fopen(argv[++i], "a");
                        if (matfp == NULL) {
                                fprintf(stderr, "%s: cannot append\n", argv[i]);
                                exit(1);
                        }
                        printf(" %s", argv[i]);
                        break;
                default:
                        goto userr;
                }
        }
        putchar('\n');
        if (i == argc) {                /* convert stdin */
                if ((rv = mg_load(NULL)) != MG_OK)
                        exit(1);
        } else                          /* convert each file */
                for ( ; i < argc; i++) {
                        printf("## %s %s ##############################\n",
                                        argv[0], argv[i]);
                        if ((rv = mg_load(argv[i])) != MG_OK)
                                exit(1);
                }
        exit(0);
userr:
        fprintf(stderr, "Usage: %s [-g dist][-e mult][-m matf] [file.mgf] ..\n",
                        argv[0]);
        exit(1);
}


int
r_comment(ac, av)               /* repeat a comment verbatim */
register int    ac;
register char   **av;
{
        putchar('#');           /* use Radiance comment character */
        while (--ac) {                  /* pass through verbatim */
                putchar(' ');
                fputs(*++av, stdout);
        }
        putchar('\n');
        return(MG_OK);
}


int
r_cone(ac, av)                  /* put out a cone */
int     ac;
char    **av;
{
        static int      ncones;
        char    *mat;
        double  r1, r2;
        C_VERTEX        *cv1, *cv2;
        FVECT   p1, p2;
        int     inv;
                                        /* check argument count and type */
        if (ac != 5)
                return(MG_EARGC);
        if (!isflt(av[2]) || !isflt(av[4]))
                return(MG_ETYPE);
                                        /* get the endpoint vertices */
        if ((cv1 = c_getvert(av[1])) == NULL ||
                        (cv2 = c_getvert(av[3])) == NULL)
                return(MG_EUNDEF);
        xf_xfmpoint(p1, cv1->p);        /* transform endpoints */
        xf_xfmpoint(p2, cv2->p);
        r1 = xf_scale(atof(av[2]));     /* scale radii */
        r2 = xf_scale(atof(av[4]));
        inv = r1 < 0.;                  /* check for inverted cone */
        if (r1 == 0.) {                 /* check for illegal radii */
                if (r2 == 0.)
                        return(MG_EILL);
                inv = r2 < 0.;
        } else if (r2 != 0. && inv ^ r2 < 0.)
                return(MG_EILL);
        if (inv) {
                r1 = -r1;
                r2 = -r2;
        }
        if ((mat = material()) == NULL) /* get material */
                return(MG_EBADMAT);
                                        /* spit the sucker out */
        printf("\n%s %s %sc%d\n", mat, inv ? "cup" : "cone",
                        object(), ++ncones);
        printf("0\n0\n8\n");
        putv(p1);
        putv(p2);
        printf("%18.12g %18.12g\n", r1, r2);
        return(MG_OK);
}


int
r_cyl(ac, av)                   /* put out a cylinder */
int     ac;
char    **av;
{
        static int      ncyls;
        char    *mat;
        double  rad;
        C_VERTEX        *cv1, *cv2;
        FVECT   p1, p2;
        int     inv;
                                        /* check argument count and type */
        if (ac != 4)
                return(MG_EARGC);
        if (!isflt(av[2]))
                return(MG_ETYPE);
                                        /* get the endpoint vertices */
        if ((cv1 = c_getvert(av[1])) == NULL ||
                        (cv2 = c_getvert(av[3])) == NULL)
                return(MG_EUNDEF);
        xf_xfmpoint(p1, cv1->p);        /* transform endpoints */
        xf_xfmpoint(p2, cv2->p);
        rad = xf_scale(atof(av[2]));    /* scale radius */
        if ((inv = rad < 0.))           /* check for inverted cylinder */
                rad = -rad;
        if ((mat = material()) == NULL) /* get material */
                return(MG_EBADMAT);
                                        /* spit out the primitive */
        printf("\n%s %s %scy%d\n", mat, inv ? "tube" : "cylinder",
                        object(), ++ncyls);
        printf("0\n0\n7\n");
        putv(p1);
        putv(p2);
        printf("%18.12g\n", rad);
        return(MG_OK);
}


int
r_sph(ac, av)                   /* put out a sphere */
int     ac;
char    **av;
{
        static int      nsphs;
        char    *mat;
        double  rad;
        C_VERTEX        *cv;
        FVECT   cent;
        int     inv;
                                        /* check argument count and type */
        if (ac != 3)
                return(MG_EARGC);
        if (!isflt(av[2]))
                return(MG_ETYPE);
        if ((cv = c_getvert(av[1])) == NULL)    /* get center vertex */
                return(MG_EUNDEF);
        xf_xfmpoint(cent, cv->p);               /* transform center */
        rad = xf_scale(atof(av[2]));            /* scale radius */
        if ((inv = rad < 0.))                   /* check for inversion */
                rad = -rad;
        if ((mat = material()) == NULL)         /* get material */
                return(MG_EBADMAT);
                                                /* spit out primitive */
        printf("\n%s %s %ss%d\n", mat, inv ? "bubble" : "sphere",
                        object(), ++nsphs);
        printf("0\n0\n4 %18.12g %18.12g %18.12g %18.12g\n",
                        cent[0], cent[1], cent[2], rad);
        return(MG_OK);
}


int
r_ring(ac, av)                  /* put out a ring */
int     ac;
char    **av;
{
        static int      nrings;
        char    *mat;
        double  r1, r2;
        C_VERTEX        *cv;
        FVECT   cent, norm;
                                        /* check argument count and type */
        if (ac != 4)
                return(MG_EARGC);
        if (!isflt(av[2]) || !isflt(av[3]))
                return(MG_ETYPE);
        if ((cv = c_getvert(av[1])) == NULL)    /* get center vertex */
                return(MG_EUNDEF);
        if (is0vect(cv->n))                     /* make sure we have normal */
                return(MG_EILL);
        xf_xfmpoint(cent, cv->p);               /* transform center */
        xf_rotvect(norm, cv->n);                /* rotate normal */
        r1 = xf_scale(atof(av[2]));             /* scale radii */
        r2 = xf_scale(atof(av[3]));
        if (r1 < 0. | r2 <= r1)
                return(MG_EILL);
        if ((mat = material()) == NULL)         /* get material */
                return(MG_EBADMAT);
                                                /* spit out primitive */
        printf("\n%s ring %sr%d\n", mat, object(), ++nrings);
        printf("0\n0\n8\n");
        putv(cent);
        putv(norm);
        printf("%18.12g %18.12g\n", r1, r2);
        return(MG_OK);
}


int
r_face(ac, av)                  /* convert a face */
int     ac;
char    **av;
{
        static int      nfaces;
        char    *mat;
        register int    i;
        register C_VERTEX       *cv;
        FVECT   v;
        int     rv;
                                        /* check argument count and type */
        if (ac < 4)
                return(MG_EARGC);
        if ((mat = material()) == NULL) /* get material */
                return(MG_EBADMAT);
        if (ac <= 5) {                          /* check for smoothing */
                for (i = 1; i < ac; i++) {
                        if ((cv = c_getvert(av[i])) == NULL)
                                return(MG_EUNDEF);
                        if (is0vect(cv->n))
                                break;
                }
                if (i == ac) {                  /* break into triangles */
                        do_tri(mat, av[1], av[2], av[3]);
                        if (ac == 5)
                                do_tri(mat, av[3], av[4], av[1]);
                        return(MG_OK);
                }
        }
                                        /* spit out unsmoothed primitive */
        printf("\n%s polygon %sf%d\n", mat, object(), ++nfaces);
        printf("0\n0\n%d\n", 3*(ac-1));
        for (i = 1; i < ac; i++) {      /* get, transform, print each vertex */
                if ((cv = c_getvert(av[invert ? ac-i : i])) == NULL)
                        return(MG_EUNDEF);
                xf_xfmpoint(v, cv->p);
                putv(v);
        }
        return(MG_OK);
}


int
r_ies(ac, av)                           /* convert an IES luminaire file */
int     ac;
char    **av;
{
        int     xa0 = 2;
        char    combuf[128];
        char    fname[48];
        char    *oname;
        register char   *op;
        register int    i;
                                        /* check argument count */
        if (ac < 2)
                return(MG_EARGC);
                                        /* construct output file name */
        if ((op = strrchr(av[1], '/')) == NULL)
                op = av[1];
        (void)strcpy(fname, op);
        if ((op = strrchr(fname, '.')) == NULL)
                op = fname + strlen(fname);
        (void)strcpy(op, ".rad");
                                        /* see if we need to run ies2rad */
        if (access(op, 0) == -1) {
                (void)strcpy(combuf, "ies2rad");/* build ies2rad command */
                op = combuf + 7;                /* get -m option (first) */
                if (ac-xa0 >= 2 && !strcmp(av[xa0], "-m")) {
                        if (!isflt(av[xa0+1]))
                                return(MG_ETYPE);
                        op = addarg(addarg(op, "-m"), av[xa0+1]);
                        xa0 += 2;
                }
                *op++ = ' ';                    /* build IES filename */
                i = 0;
                if (mg_file != NULL &&
                                (oname = strrchr(mg_file->fname,'/')) != NULL) {
                        i = oname - mg_file->fname + 1;
                        (void)strcpy(op, mg_file->fname);
                }
                (void)strcpy(op+i, av[1]);
                if (access(op, 0) == -1)        /* check for file existence */
                        return(MG_ENOFILE);
                system(combuf);                 /* run ies2rad */
                if (access(fname, 0) == -1)     /* check success */
                        return(MG_EINCL);
        }
        printf("\n!xform");                     /* put out xform command */
        oname = object();
        if (*oname) {
                printf(" -n ");
                for (op = oname; op[1]; op++)   /* remove trailing separator */
                        putchar(*op);
        }
        for (i = xa0; i < ac; i++)
                printf(" %s", av[i]);
        if (ac > xa0 && xf_argc > 0)
                printf(" -i 1");
        for (i = 0; i < xf_argc; i++)
                printf(" %s", xf_argv[i]);
        printf(" %s\n", fname);
        return(MG_OK);
}


do_tri(mat, vn1, vn2, vn3)              /* put out smoothed triangle */
char    *mat, *vn1, *vn2, *vn3;
{
        static int      ntris;
        BARYCCM bvecs;
        FLOAT   bcoor[3][3];
        C_VERTEX        *cv1, *cv2, *cv3;
        FVECT   v1, v2, v3;
        FVECT   n1, n2, n3;
        register int    i;
                        /* the following is repeat code, so assume it's OK */
        cv2 = c_getvert(vn2);
        if (invert) {
                cv3 = c_getvert(vn1);
                cv1 = c_getvert(vn3);
        } else {
                cv1 = c_getvert(vn1);
                cv3 = c_getvert(vn3);
        }
        xf_xfmpoint(v1, cv1->p);
        xf_xfmpoint(v2, cv2->p);
        xf_xfmpoint(v3, cv3->p);
                                        /* compute barycentric coords. */
        if (comp_baryc(&bvecs, v1, v2, v3) < 0)
                return;                         /* degenerate triangle! */
        printf("\n%s texfunc T-nor\n", mat);    /* put out texture */
        printf("4 dx dy dz %s\n0\n", TCALNAME);
        xf_rotvect(n1, cv1->n);
        xf_rotvect(n2, cv2->n);
        xf_rotvect(n3, cv3->n);
        for (i = 0; i < 3; i++) {
                bcoor[i][0] = n1[i];
                bcoor[i][1] = n2[i];
                bcoor[i][2] = n3[i];
        }
        put_baryc(&bvecs, bcoor, 3);
                                                /* put out triangle */
        printf("\nT-nor polygon %st%d\n", object(), ++ntris);
        printf("0\n0\n9\n");
        putv(v1);
        putv(v2);
        putv(v3);
}


char *
material()                      /* get (and print) current material */
{
        char    *mname = "mat";
        COLOR   radrgb, c2;
        double  d;
        register int    i;

        if (c_cmname != NULL)
                mname = c_cmname;
        if (!c_cmaterial->clock)
                return(mname);          /* already current */
                                /* else update output */
        c_cmaterial->clock = 0;
        if (c_cmaterial->ed > .1) {     /* emitter */
                cvtcolor(radrgb, &c_cmaterial->ed_c,
                                emult*c_cmaterial->ed/(PI*WHTEFFICACY));
                if (glowdist < FHUGE) {         /* do a glow */
                        fprintf(matfp, "\nvoid glow %s\n0\n0\n", mname);
                        fprintf(matfp, "4 %f %f %f %f\n", colval(radrgb,RED),
                                        colval(radrgb,GRN),
                                        colval(radrgb,BLU), glowdist);
                } else {
                        fprintf(matfp, "\nvoid light %s\n0\n0\n", mname);
                        fprintf(matfp, "3 %f %f %f\n", colval(radrgb,RED),
                                        colval(radrgb,GRN),
                                        colval(radrgb,BLU));
                }
                return(mname);
        }
        d = c_cmaterial->rd + c_cmaterial->td +
                        c_cmaterial->rs + c_cmaterial->ts;
        if (d < 0. | d > 1.)
                return(NULL);
                                        /* check for glass/dielectric */
        if (c_cmaterial->nr > 1.1 &&
                        c_cmaterial->ts > .25 && c_cmaterial->rs <= .125 &&
                        c_cmaterial->td <= .01 && c_cmaterial->rd <= .01 &&
                        c_cmaterial->rs_a <= .01 && c_cmaterial->ts_a <= .01) {
                cvtcolor(radrgb, &c_cmaterial->ts_c,
                                c_cmaterial->ts + c_cmaterial->rs);
                if (c_cmaterial->sided) {               /* dielectric */
                        colval(radrgb,RED) = pow(colval(radrgb,RED),
                                                        1./C_1SIDEDTHICK);
                        colval(radrgb,GRN) = pow(colval(radrgb,GRN),
                                                        1./C_1SIDEDTHICK);
                        colval(radrgb,BLU) = pow(colval(radrgb,BLU),
                                                        1./C_1SIDEDTHICK);
                        fprintf(matfp, "\nvoid dielectric %s\n0\n0\n", mname);
                        fprintf(matfp, "5 %g %g %g %f 0\n", colval(radrgb,RED),
                                        colval(radrgb,GRN), colval(radrgb,BLU),
                                        c_cmaterial->nr);
                        return(mname);
                }
                                                        /* glass */
                fprintf(matfp, "\nvoid glass %s\n0\n0\n", mname);
                fprintf(matfp, "4 %f %f %f %f\n", colval(radrgb,RED),
                                colval(radrgb,GRN), colval(radrgb,BLU),
                                c_cmaterial->nr);
                return(mname);
                }
                                        /* check for trans */
        if (c_cmaterial->td > .01 || c_cmaterial->ts > .01) {
                double  ts, a5, a6;

                if (c_cmaterial->sided) {
                        ts = sqrt(c_cmaterial->ts);     /* approximate */
                        a5 = .5;
                } else {
                        ts = c_cmaterial->ts;
                        a5 = 1.;
                }
                                                /* average colors */
                d = c_cmaterial->rd + c_cmaterial->td + ts;
                cvtcolor(radrgb, &c_cmaterial->rd_c, c_cmaterial->rd/d);
                cvtcolor(c2, &c_cmaterial->td_c, c_cmaterial->td/d);
                addcolor(radrgb, c2);
                cvtcolor(c2, &c_cmaterial->ts_c, ts/d);
                addcolor(radrgb, c2);
                if (c_cmaterial->rs + ts > .0001)
                        a5 = (c_cmaterial->rs*c_cmaterial->rs_a +
                                        ts*a5*c_cmaterial->ts_a) /
                                        (c_cmaterial->rs + ts);
                a6 = (c_cmaterial->td + ts) /
                                (c_cmaterial->rd + c_cmaterial->td + ts);
                if (a6 < .999)
                        d = c_cmaterial->rd/(1. - c_cmaterial->rs)/(1. - a6);
                else
                        d = c_cmaterial->td + ts;
                scalecolor(radrgb, d);
                fprintf(matfp, "\nvoid trans %s\n0\n0\n", mname);
                fprintf(matfp, "7 %f %f %f\n", colval(radrgb,RED),
                                colval(radrgb,GRN), colval(radrgb,BLU));
                fprintf(matfp, "\t%f %f %f %f\n", c_cmaterial->rs, a5, a6,
                                ts/(ts + c_cmaterial->td));
                return(mname);
        }
                                        /* check for plastic */
        if (c_cmaterial->rs < .1 && (c_cmaterial->rs < .01 ||
                                        c_isgrey(&c_cmaterial->rs_c))) {
                cvtcolor(radrgb, &c_cmaterial->rd_c,
                                        c_cmaterial->rd/(1.-c_cmaterial->rs));
                fprintf(matfp, "\nvoid plastic %s\n0\n0\n", mname);
                fprintf(matfp, "5 %f %f %f %f %f\n", colval(radrgb,RED),
                                colval(radrgb,GRN), colval(radrgb,BLU),
                                c_cmaterial->rs, c_cmaterial->rs_a);
                return(mname);
        }
                                        /* else it's metal */
                                                /* average colors */
        cvtcolor(radrgb, &c_cmaterial->rd_c, c_cmaterial->rd);
        cvtcolor(c2, &c_cmaterial->rs_c, c_cmaterial->rs);
        addcolor(radrgb, c2);
        fprintf(matfp, "\nvoid metal %s\n0\n0\n", mname);
        fprintf(matfp, "5 %f %f %f %f %f\n", colval(radrgb,RED),
                        colval(radrgb,GRN), colval(radrgb,BLU),
                        c_cmaterial->rs/(c_cmaterial->rd + c_cmaterial->rs),
                        c_cmaterial->rs_a);
        return(mname);
}


cvtcolor(radrgb, ciec, intensity)       /* convert a CIE XYZ color to RGB */
COLOR   radrgb;
register C_COLOR        *ciec;
double  intensity;
{
        static COLOR    ciexyz;

        c_ccvt(ciec, C_CSXY);           /* get xy representation */
        ciexyz[1] = intensity;
        ciexyz[0] = ciec->cx/ciec->cy*ciexyz[1];
        ciexyz[2] = ciexyz[1]*(1./ciec->cy - 1.) - ciexyz[0];
        cie_rgb(radrgb, ciexyz);
}


char *
object()                        /* return current object name */
{
        static char     objbuf[64];
        register int    i;
        register char   *cp;
        int     len;
                                                /* tracked by obj_handler */
        i = obj_nnames - sizeof(objbuf)/16;
        if (i < 0)
                i = 0;
        for (cp = objbuf; i < obj_nnames &&
                cp + (len=strlen(obj_name[i])) < objbuf+sizeof(objbuf)-1;
                        i++, *cp++ = '.') {
                strcpy(cp, obj_name[i]);
                cp += len;
        }
        *cp = '\0';
        return(objbuf);
}


char *
addarg(op, arg)                         /* add argument and advance pointer */
register char   *op, *arg;
{
        *op = ' ';
        while (*++op = *arg++)
                ;
        return(op);
}
Revision:	2.16
Committed:	Fri Apr 14 19:03:20 1995 UTC (29 years ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.15:	+94 -83 lines
Log Message:	added lots of comments and added file precheck to r_ies()
#	Content
1	/* Copyright (c) 1994 Regents of the University of California */
2
3	#ifndef lint
4	static char SCCSid[] = "$SunId$ LBL";
5	#endif
6
7	/*
8	* Convert MGF (Materials and Geometry Format) to Radiance
9	*/
10
11	#include <stdio.h>
12	#include <math.h>
13	#include <string.h>
14	#include "mgflib/parser.h"
15	#include "color.h"
16	#include "tmesh.h"
17
18	#define putv(v) printf("%18.12g %18.12g %18.12g\n",(v)[0],(v)[1],(v)[2])
19
20	#define invert (xf_context != NULL && xf_context->rev)
21
22	double glowdist = FHUGE; /* glow test distance */
23
24	double emult = 1.; /* emitter multiplier */
25
26	FILE matfp = stdout; / material output file */
27
28	int r_comment(), r_cone(), r_cyl(), r_face(), r_ies(), r_ring(), r_sph();
29	char material(), object(), *addarg();
30
31
32	main(argc, argv) /* convert files to stdout */
33	int argc;
34	char *argv[];
35	{
36	int i, rv;
37	/* initialize dispatch table */
38	mg_ehand[MG_E_COMMENT] = r_comment; /* we pass comments */
39	mg_ehand[MG_E_COLOR] = c_hcolor; /* they get color */
40	mg_ehand[MG_E_CONE] = r_cone; /* we do cones */
41	mg_ehand[MG_E_CMIX] = c_hcolor; /* they mix colors */
42	mg_ehand[MG_E_CSPEC] = c_hcolor; /* they get spectra */
43	mg_ehand[MG_E_CXY] = c_hcolor; /* they get chromaticities */
44	mg_ehand[MG_E_CCT] = c_hcolor; /* they get color temp's */
45	mg_ehand[MG_E_CYL] = r_cyl; /* we do cylinders */
46	mg_ehand[MG_E_ED] = c_hmaterial; /* they get emission */
47	mg_ehand[MG_E_FACE] = r_face; /* we do faces */
48	mg_ehand[MG_E_IES] = r_ies; /* we do IES files */
49	mg_ehand[MG_E_IR] = c_hmaterial; /* they get refractive index */
50	mg_ehand[MG_E_MATERIAL] = c_hmaterial; /* they get materials */
51	mg_ehand[MG_E_NORMAL] = c_hvertex; /* they get normals */
52	mg_ehand[MG_E_OBJECT] = obj_handler; /* they track object names */
53	mg_ehand[MG_E_POINT] = c_hvertex; /* they get points */
54	mg_ehand[MG_E_RD] = c_hmaterial; /* they get diffuse refl. */
55	mg_ehand[MG_E_RING] = r_ring; /* we do rings */
56	mg_ehand[MG_E_RS] = c_hmaterial; /* they get specular refl. */
57	mg_ehand[MG_E_SIDES] = c_hmaterial; /* they get # sides */
58	mg_ehand[MG_E_SPH] = r_sph; /* we do spheres */
59	mg_ehand[MG_E_TD] = c_hmaterial; /* they get diffuse trans. */
60	mg_ehand[MG_E_TS] = c_hmaterial; /* they get specular trans. */
61	mg_ehand[MG_E_VERTEX] = c_hvertex; /* they get vertices */
62	mg_ehand[MG_E_XF] = xf_handler; /* they track transforms */
63	mg_init(); /* initialize the parser */
64	/* get our options & print header */
65	printf("## %s", argv[0]);
66	for (i = 1; i < argc && argv[i][0] == '-'; i++) {
67	printf(" %s", argv[i]);
68	switch (argv[i][1]) {
69	case 'g': /* glow distance (meters) */
70	if (argv[i][2] \|\| badarg(argc-i-1, argv+i+1, "f"))
71	goto userr;
72	glowdist = atof(argv[++i]);
73	printf(" %s", argv[i]);
74	break;
75	case 'e': /* emitter multiplier */
76	if (argv[i][2] \|\| badarg(argc-i-1, argv+i+1, "f"))
77	goto userr;
78	emult = atof(argv[++i]);
79	printf(" %s", argv[i]);
80	break;
81	case 'm': /* materials file */
82	matfp = fopen(argv[++i], "a");
83	if (matfp == NULL) {
84	fprintf(stderr, "%s: cannot append\n", argv[i]);
85	exit(1);
86	}
87	printf(" %s", argv[i]);
88	break;
89	default:
90	goto userr;
91	}
92	}
93	putchar('\n');
94	if (i == argc) { /* convert stdin */
95	if ((rv = mg_load(NULL)) != MG_OK)
96	exit(1);
97	} else /* convert each file */
98	for ( ; i < argc; i++) {
99	printf("## %s %s ##############################\n",
100	argv[0], argv[i]);
101	if ((rv = mg_load(argv[i])) != MG_OK)
102	exit(1);
103	}
104	exit(0);
105	userr:
106	fprintf(stderr, "Usage: %s [-g dist][-e mult][-m matf] [file.mgf] ..\n",
107	argv[0]);
108	exit(1);
109	}
110
111
112	int
113	r_comment(ac, av) /* repeat a comment verbatim */
114	register int ac;
115	register char **av;
116	{
117	putchar('#'); /* use Radiance comment character */
118	while (--ac) { /* pass through verbatim */
119	putchar(' ');
120	fputs(*++av, stdout);
121	}
122	putchar('\n');
123	return(MG_OK);
124	}
125
126
127	int
128	r_cone(ac, av) /* put out a cone */
129	int ac;
130	char **av;
131	{
132	static int ncones;
133	char *mat;
134	double r1, r2;
135	C_VERTEX cv1, cv2;
136	FVECT p1, p2;
137	int inv;
138	/* check argument count and type */
139	if (ac != 5)
140	return(MG_EARGC);
141	if (!isflt(av[2]) \|\| !isflt(av[4]))
142	return(MG_ETYPE);
143	/* get the endpoint vertices */
144	if ((cv1 = c_getvert(av[1])) == NULL \|\|
145	(cv2 = c_getvert(av[3])) == NULL)
146	return(MG_EUNDEF);
147	xf_xfmpoint(p1, cv1->p); /* transform endpoints */
148	xf_xfmpoint(p2, cv2->p);
149	r1 = xf_scale(atof(av[2])); /* scale radii */
150	r2 = xf_scale(atof(av[4]));
151	inv = r1 < 0.; /* check for inverted cone */
152	if (r1 == 0.) { /* check for illegal radii */
153	if (r2 == 0.)
154	return(MG_EILL);
155	inv = r2 < 0.;
156	} else if (r2 != 0. && inv ^ r2 < 0.)
157	return(MG_EILL);
158	if (inv) {
159	r1 = -r1;
160	r2 = -r2;
161	}
162	if ((mat = material()) == NULL) /* get material */
163	return(MG_EBADMAT);
164	/* spit the sucker out */
165	printf("\n%s %s %sc%d\n", mat, inv ? "cup" : "cone",
166	object(), ++ncones);
167	printf("0\n0\n8\n");
168	putv(p1);
169	putv(p2);
170	printf("%18.12g %18.12g\n", r1, r2);
171	return(MG_OK);
172	}
173
174
175	int
176	r_cyl(ac, av) /* put out a cylinder */
177	int ac;
178	char **av;
179	{
180	static int ncyls;
181	char *mat;
182	double rad;
183	C_VERTEX cv1, cv2;
184	FVECT p1, p2;
185	int inv;
186	/* check argument count and type */
187	if (ac != 4)
188	return(MG_EARGC);
189	if (!isflt(av[2]))
190	return(MG_ETYPE);
191	/* get the endpoint vertices */
192	if ((cv1 = c_getvert(av[1])) == NULL \|\|
193	(cv2 = c_getvert(av[3])) == NULL)
194	return(MG_EUNDEF);
195	xf_xfmpoint(p1, cv1->p); /* transform endpoints */
196	xf_xfmpoint(p2, cv2->p);
197	rad = xf_scale(atof(av[2])); /* scale radius */
198	if ((inv = rad < 0.)) /* check for inverted cylinder */
199	rad = -rad;
200	if ((mat = material()) == NULL) /* get material */
201	return(MG_EBADMAT);
202	/* spit out the primitive */
203	printf("\n%s %s %scy%d\n", mat, inv ? "tube" : "cylinder",
204	object(), ++ncyls);
205	printf("0\n0\n7\n");
206	putv(p1);
207	putv(p2);
208	printf("%18.12g\n", rad);
209	return(MG_OK);
210	}
211
212
213	int
214	r_sph(ac, av) /* put out a sphere */
215	int ac;
216	char **av;
217	{
218	static int nsphs;
219	char *mat;
220	double rad;
221	C_VERTEX *cv;
222	FVECT cent;
223	int inv;
224	/* check argument count and type */
225	if (ac != 3)
226	return(MG_EARGC);
227	if (!isflt(av[2]))
228	return(MG_ETYPE);
229	if ((cv = c_getvert(av[1])) == NULL) /* get center vertex */
230	return(MG_EUNDEF);
231	xf_xfmpoint(cent, cv->p); /* transform center */
232	rad = xf_scale(atof(av[2])); /* scale radius */
233	if ((inv = rad < 0.)) /* check for inversion */
234	rad = -rad;
235	if ((mat = material()) == NULL) /* get material */
236	return(MG_EBADMAT);
237	/* spit out primitive */
238	printf("\n%s %s %ss%d\n", mat, inv ? "bubble" : "sphere",
239	object(), ++nsphs);
240	printf("0\n0\n4 %18.12g %18.12g %18.12g %18.12g\n",
241	cent[0], cent[1], cent[2], rad);
242	return(MG_OK);
243	}
244
245
246	int
247	r_ring(ac, av) /* put out a ring */
248	int ac;
249	char **av;
250	{
251	static int nrings;
252	char *mat;
253	double r1, r2;
254	C_VERTEX *cv;
255	FVECT cent, norm;
256	/* check argument count and type */
257	if (ac != 4)
258	return(MG_EARGC);
259	if (!isflt(av[2]) \|\| !isflt(av[3]))
260	return(MG_ETYPE);
261	if ((cv = c_getvert(av[1])) == NULL) /* get center vertex */
262	return(MG_EUNDEF);
263	if (is0vect(cv->n)) /* make sure we have normal */
264	return(MG_EILL);
265	xf_xfmpoint(cent, cv->p); /* transform center */
266	xf_rotvect(norm, cv->n); /* rotate normal */
267	r1 = xf_scale(atof(av[2])); /* scale radii */
268	r2 = xf_scale(atof(av[3]));
269	if (r1 < 0. \| r2 <= r1)
270	return(MG_EILL);
271	if ((mat = material()) == NULL) /* get material */
272	return(MG_EBADMAT);
273	/* spit out primitive */
274	printf("\n%s ring %sr%d\n", mat, object(), ++nrings);
275	printf("0\n0\n8\n");
276	putv(cent);
277	putv(norm);
278	printf("%18.12g %18.12g\n", r1, r2);
279	return(MG_OK);
280	}
281
282
283	int
284	r_face(ac, av) /* convert a face */
285	int ac;
286	char **av;
287	{
288	static int nfaces;
289	char *mat;
290	register int i;
291	register C_VERTEX *cv;
292	FVECT v;
293	int rv;
294	/* check argument count and type */
295	if (ac < 4)
296	return(MG_EARGC);
297	if ((mat = material()) == NULL) /* get material */
298	return(MG_EBADMAT);
299	if (ac <= 5) { /* check for smoothing */
300	for (i = 1; i < ac; i++) {
301	if ((cv = c_getvert(av[i])) == NULL)
302	return(MG_EUNDEF);
303	if (is0vect(cv->n))
304	break;
305	}
306	if (i == ac) { /* break into triangles */
307	do_tri(mat, av[1], av[2], av[3]);
308	if (ac == 5)
309	do_tri(mat, av[3], av[4], av[1]);
310	return(MG_OK);
311	}
312	}
313	/* spit out unsmoothed primitive */
314	printf("\n%s polygon %sf%d\n", mat, object(), ++nfaces);
315	printf("0\n0\n%d\n", 3*(ac-1));
316	for (i = 1; i < ac; i++) { /* get, transform, print each vertex */
317	if ((cv = c_getvert(av[invert ? ac-i : i])) == NULL)
318	return(MG_EUNDEF);
319	xf_xfmpoint(v, cv->p);
320	putv(v);
321	}
322	return(MG_OK);
323	}
324
325
326	int
327	r_ies(ac, av) /* convert an IES luminaire file */
328	int ac;
329	char **av;
330	{
331	int xa0 = 2;
332	char combuf[128];
333	char fname[48];
334	char *oname;
335	register char *op;
336	register int i;
337	/* check argument count */
338	if (ac < 2)
339	return(MG_EARGC);
340	/* construct output file name */
341	if ((op = strrchr(av[1], '/')) == NULL)
342	op = av[1];
343	(void)strcpy(fname, op);
344	if ((op = strrchr(fname, '.')) == NULL)
345	op = fname + strlen(fname);
346	(void)strcpy(op, ".rad");
347	/* see if we need to run ies2rad */
348	if (access(op, 0) == -1) {
349	(void)strcpy(combuf, "ies2rad");/* build ies2rad command */
350	op = combuf + 7; /* get -m option (first) */
351	if (ac-xa0 >= 2 && !strcmp(av[xa0], "-m")) {
352	if (!isflt(av[xa0+1]))
353	return(MG_ETYPE);
354	op = addarg(addarg(op, "-m"), av[xa0+1]);
355	xa0 += 2;
356	}
357	op++ = ' '; / build IES filename */
358	i = 0;
359	if (mg_file != NULL &&
360	(oname = strrchr(mg_file->fname,'/')) != NULL) {
361	i = oname - mg_file->fname + 1;
362	(void)strcpy(op, mg_file->fname);
363	}
364	(void)strcpy(op+i, av[1]);
365	if (access(op, 0) == -1) /* check for file existence */
366	return(MG_ENOFILE);
367	system(combuf); /* run ies2rad */
368	if (access(fname, 0) == -1) /* check success */
369	return(MG_EINCL);
370	}
371	printf("\n!xform"); /* put out xform command */
372	oname = object();
373	if (*oname) {
374	printf(" -n ");
375	for (op = oname; op[1]; op++) /* remove trailing separator */
376	putchar(*op);
377	}
378	for (i = xa0; i < ac; i++)
379	printf(" %s", av[i]);
380	if (ac > xa0 && xf_argc > 0)
381	printf(" -i 1");
382	for (i = 0; i < xf_argc; i++)
383	printf(" %s", xf_argv[i]);
384	printf(" %s\n", fname);
385	return(MG_OK);
386	}
387
388
389	do_tri(mat, vn1, vn2, vn3) /* put out smoothed triangle */
390	char mat, vn1, vn2, vn3;
391	{
392	static int ntris;
393	BARYCCM bvecs;
394	FLOAT bcoor[3][3];
395	C_VERTEX cv1, cv2, *cv3;
396	FVECT v1, v2, v3;
397	FVECT n1, n2, n3;
398	register int i;
399	/* the following is repeat code, so assume it's OK */
400	cv2 = c_getvert(vn2);
401	if (invert) {
402	cv3 = c_getvert(vn1);
403	cv1 = c_getvert(vn3);
404	} else {
405	cv1 = c_getvert(vn1);
406	cv3 = c_getvert(vn3);
407	}
408	xf_xfmpoint(v1, cv1->p);
409	xf_xfmpoint(v2, cv2->p);
410	xf_xfmpoint(v3, cv3->p);
411	/* compute barycentric coords. */
412	if (comp_baryc(&bvecs, v1, v2, v3) < 0)
413	return; /* degenerate triangle! */
414	printf("\n%s texfunc T-nor\n", mat); /* put out texture */
415	printf("4 dx dy dz %s\n0\n", TCALNAME);
416	xf_rotvect(n1, cv1->n);
417	xf_rotvect(n2, cv2->n);
418	xf_rotvect(n3, cv3->n);
419	for (i = 0; i < 3; i++) {
420	bcoor[i][0] = n1[i];
421	bcoor[i][1] = n2[i];
422	bcoor[i][2] = n3[i];
423	}
424	put_baryc(&bvecs, bcoor, 3);
425	/* put out triangle */
426	printf("\nT-nor polygon %st%d\n", object(), ++ntris);
427	printf("0\n0\n9\n");
428	putv(v1);
429	putv(v2);
430	putv(v3);
431	}
432
433
434	char *
435	material() /* get (and print) current material */
436	{
437	char *mname = "mat";
438	COLOR radrgb, c2;
439	double d;
440	register int i;
441
442	if (c_cmname != NULL)
443	mname = c_cmname;
444	if (!c_cmaterial->clock)
445	return(mname); /* already current */
446	/* else update output */
447	c_cmaterial->clock = 0;
448	if (c_cmaterial->ed > .1) { /* emitter */
449	cvtcolor(radrgb, &c_cmaterial->ed_c,
450	emultc_cmaterial->ed/(PIWHTEFFICACY));
451	if (glowdist < FHUGE) { /* do a glow */
452	fprintf(matfp, "\nvoid glow %s\n0\n0\n", mname);
453	fprintf(matfp, "4 %f %f %f %f\n", colval(radrgb,RED),
454	colval(radrgb,GRN),
455	colval(radrgb,BLU), glowdist);
456	} else {
457	fprintf(matfp, "\nvoid light %s\n0\n0\n", mname);
458	fprintf(matfp, "3 %f %f %f\n", colval(radrgb,RED),
459	colval(radrgb,GRN),
460	colval(radrgb,BLU));
461	}
462	return(mname);
463	}
464	d = c_cmaterial->rd + c_cmaterial->td +
465	c_cmaterial->rs + c_cmaterial->ts;
466	if (d < 0. \| d > 1.)
467	return(NULL);
468	/* check for glass/dielectric */
469	if (c_cmaterial->nr > 1.1 &&
470	c_cmaterial->ts > .25 && c_cmaterial->rs <= .125 &&
471	c_cmaterial->td <= .01 && c_cmaterial->rd <= .01 &&
472	c_cmaterial->rs_a <= .01 && c_cmaterial->ts_a <= .01) {
473	cvtcolor(radrgb, &c_cmaterial->ts_c,
474	c_cmaterial->ts + c_cmaterial->rs);
475	if (c_cmaterial->sided) { /* dielectric */
476	colval(radrgb,RED) = pow(colval(radrgb,RED),
477	1./C_1SIDEDTHICK);
478	colval(radrgb,GRN) = pow(colval(radrgb,GRN),
479	1./C_1SIDEDTHICK);
480	colval(radrgb,BLU) = pow(colval(radrgb,BLU),
481	1./C_1SIDEDTHICK);
482	fprintf(matfp, "\nvoid dielectric %s\n0\n0\n", mname);
483	fprintf(matfp, "5 %g %g %g %f 0\n", colval(radrgb,RED),
484	colval(radrgb,GRN), colval(radrgb,BLU),
485	c_cmaterial->nr);
486	return(mname);
487	}
488	/* glass */
489	fprintf(matfp, "\nvoid glass %s\n0\n0\n", mname);
490	fprintf(matfp, "4 %f %f %f %f\n", colval(radrgb,RED),
491	colval(radrgb,GRN), colval(radrgb,BLU),
492	c_cmaterial->nr);
493	return(mname);
494	}
495	/* check for trans */
496	if (c_cmaterial->td > .01 \|\| c_cmaterial->ts > .01) {
497	double ts, a5, a6;
498
499	if (c_cmaterial->sided) {
500	ts = sqrt(c_cmaterial->ts); /* approximate */
501	a5 = .5;
502	} else {
503	ts = c_cmaterial->ts;
504	a5 = 1.;
505	}
506	/* average colors */
507	d = c_cmaterial->rd + c_cmaterial->td + ts;
508	cvtcolor(radrgb, &c_cmaterial->rd_c, c_cmaterial->rd/d);
509	cvtcolor(c2, &c_cmaterial->td_c, c_cmaterial->td/d);
510	addcolor(radrgb, c2);
511	cvtcolor(c2, &c_cmaterial->ts_c, ts/d);
512	addcolor(radrgb, c2);
513	if (c_cmaterial->rs + ts > .0001)
514	a5 = (c_cmaterial->rs*c_cmaterial->rs_a +
515	tsa5c_cmaterial->ts_a) /
516	(c_cmaterial->rs + ts);
517	a6 = (c_cmaterial->td + ts) /
518	(c_cmaterial->rd + c_cmaterial->td + ts);
519	if (a6 < .999)
520	d = c_cmaterial->rd/(1. - c_cmaterial->rs)/(1. - a6);
521	else
522	d = c_cmaterial->td + ts;
523	scalecolor(radrgb, d);
524	fprintf(matfp, "\nvoid trans %s\n0\n0\n", mname);
525	fprintf(matfp, "7 %f %f %f\n", colval(radrgb,RED),
526	colval(radrgb,GRN), colval(radrgb,BLU));
527	fprintf(matfp, "\t%f %f %f %f\n", c_cmaterial->rs, a5, a6,
528	ts/(ts + c_cmaterial->td));
529	return(mname);
530	}
531	/* check for plastic */
532	if (c_cmaterial->rs < .1 && (c_cmaterial->rs < .01 \|\|
533	c_isgrey(&c_cmaterial->rs_c))) {
534	cvtcolor(radrgb, &c_cmaterial->rd_c,
535	c_cmaterial->rd/(1.-c_cmaterial->rs));
536	fprintf(matfp, "\nvoid plastic %s\n0\n0\n", mname);
537	fprintf(matfp, "5 %f %f %f %f %f\n", colval(radrgb,RED),
538	colval(radrgb,GRN), colval(radrgb,BLU),
539	c_cmaterial->rs, c_cmaterial->rs_a);
540	return(mname);
541	}
542	/* else it's metal */
543	/* average colors */
544	cvtcolor(radrgb, &c_cmaterial->rd_c, c_cmaterial->rd);
545	cvtcolor(c2, &c_cmaterial->rs_c, c_cmaterial->rs);
546	addcolor(radrgb, c2);
547	fprintf(matfp, "\nvoid metal %s\n0\n0\n", mname);
548	fprintf(matfp, "5 %f %f %f %f %f\n", colval(radrgb,RED),
549	colval(radrgb,GRN), colval(radrgb,BLU),
550	c_cmaterial->rs/(c_cmaterial->rd + c_cmaterial->rs),
551	c_cmaterial->rs_a);
552	return(mname);
553	}
554
555
556	cvtcolor(radrgb, ciec, intensity) /* convert a CIE XYZ color to RGB */
557	COLOR radrgb;
558	register C_COLOR *ciec;
559	double intensity;
560	{
561	static COLOR ciexyz;
562
563	c_ccvt(ciec, C_CSXY); /* get xy representation */
564	ciexyz[1] = intensity;
565	ciexyz[0] = ciec->cx/ciec->cy*ciexyz[1];
566	ciexyz[2] = ciexyz[1]*(1./ciec->cy - 1.) - ciexyz[0];
567	cie_rgb(radrgb, ciexyz);
568	}
569
570
571	char *
572	object() /* return current object name */
573	{
574	static char objbuf[64];
575	register int i;
576	register char *cp;
577	int len;
578	/* tracked by obj_handler */
579	i = obj_nnames - sizeof(objbuf)/16;
580	if (i < 0)
581	i = 0;
582	for (cp = objbuf; i < obj_nnames &&
583	cp + (len=strlen(obj_name[i])) < objbuf+sizeof(objbuf)-1;
584	i++, *cp++ = '.') {
585	strcpy(cp, obj_name[i]);
586	cp += len;
587	}
588	*cp = '\0';
589	return(objbuf);
590	}
591
592
593	char *
594	addarg(op, arg) /* add argument and advance pointer */
595	register char op, arg;
596	{
597	*op = ' ';
598	while (++op = arg++)
599	;
600	return(op);
601	}