src/cv/rad2mgf.c

/* Copyright (c) 1995 Regents of the University of California */

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

/*
 * Convert Radiance scene description to MGF
 */

#include <stdio.h>
#include <math.h>
#include <ctype.h>
#include <string.h>
#include "fvect.h"
#include "object.h"
#include "color.h"
#include "lookup.h"

#define PI      3.14159265358979323846

#define C_1SIDEDTHICK   0.005

int     o_face(), o_cone(), o_sphere(), o_ring(), o_cylinder();
int     o_instance(), o_illum();
int     o_plastic(), o_metal(), o_glass(), o_dielectric(),
        o_mirror(), o_trans(), o_light();

extern void     free();
extern char     *malloc();

LUTAB   rmats = LU_SINIT(free,NULL);            /* defined material table */

LUTAB   rdispatch = LU_SINIT(NULL,NULL);        /* function dispatch table */

char    curmat[80];                             /* current material */
char    curobj[128] = "Untitled";               /* current object name */

double  unit_mult = 1.;                         /* units multiplier */

#define hasmult         (unit_mult < .999 || unit_mult > 1.001)

/*
 * Stuff for tracking and reusing vertices:
 */

char    VKFMT[] = "%+16.9e %+16.9e %+16.9e";
#define VKLEN           64

#define mkvkey(k,v)     sprintf(k, VKFMT, (v)[0], (v)[1], (v)[2])

#define NVERTS          256

long    vclock;         /* incremented at each vertex request */

struct vert {
        long    lused;          /* when last used (0 if unassigned) */
        FVECT   p;              /* track point position only */
} vert[NVERTS];         /* our vertex cache */

LUTAB   vertab = LU_SINIT(free,NULL);   /* our vertex lookup table */


main(argc, argv)
int     argc;
char    **argv;
{
        int     i;

        for (i = 1; i < argc && argv[i][0] == '-'; i++)
                switch (argv[i][1]) {
                case 'd':                       /* units */
                        switch (argv[i][2]) {
                        case 'm':                       /* meters */
                                unit_mult = 1.;
                                break;
                        case 'c':                       /* centimeters */
                                unit_mult = .01;
                                break;
                        case 'f':                       /* feet */
                                unit_mult = 12.*.0254;
                                break;
                        case 'i':                       /* inches */
                                unit_mult = .0254;
                                break;
                        default:
                                goto unkopt;
                        }
                        break;
                default:
                        goto unkopt;
                }
        init();
        if (i >= argc)
                rad2mgf(NULL);
        else
                for ( ; i < argc; i++)
                        rad2mgf(argv[i]);
        uninit();
        exit(0);
unkopt:
        fprintf(stderr, "Usage: %s [-d{m|c|f|i}] file ..\n", argv[0]);
        exit(1);
}


rad2mgf(inp)            /* convert a Radiance file to MGF */
char    *inp;
{
#define mod     buf
#define typ     (buf+128)
#define id      (buf+256)
#define alias   (buf+384)
        char    buf[512];
        FUNARGS fa;
        register FILE   *fp;
        register int    c;

        if (inp == NULL) {
                inp = "standard input";
                fp = stdin;
        } else if (inp[0] == '!') {
                if ((fp = popen(inp+1, "r")) == NULL) {
                        fputs(inp, stderr);
                        fputs(": cannot execute\n", stderr);
                        exit(1);
                }
        } else if ((fp = fopen(inp, "r")) == NULL) {
                fputs(inp, stderr);
                fputs(": cannot open\n", stderr);
                exit(1);
        }
        printf("# Begin conversion from: %s\n", inp);
        while ((c = getc(fp)) != EOF)
                switch (c) {
                case ' ':               /* white space */
                case '\t':
                case '\n':
                case '\r':
                case '\f':
                        break;
                case '#':               /* comment */
                        if (fgets(buf, sizeof(buf), fp) != NULL)
                                printf("# %s", buf);
                        break;
                case '!':               /* inline command */
                        ungetc(c, fp);
                        fgetline(buf, sizeof(buf), fp);
                        rad2mgf(buf);
                        break;
                default:                /* Radiance primitive */
                        ungetc(c, fp);
                        if (fscanf(fp, "%s %s %s", mod, typ, id) != 3) {
                                fputs(inp, stderr);
                                fputs(": unexpected EOF\n", stderr);
                                exit(1);
                        }
                        if (!strcmp(typ, "alias")) {
                                strcpy(alias, "EOF");
                                fscanf(fp, "%s", alias);
                                newmat(id, alias);
                        } else {
                                if (!readfargs(&fa, fp)) {
                                        fprintf(stderr,
                                "%s: bad argument syntax for %s \"%s\"\n",
                                                        inp, typ, id);
                                        exit(1);
                                }
                                cvtprim(inp, mod, typ, id, &fa);
                                freefargs(&fa);
                        }
                        break;
                }
        printf("# End conversion from: %s\n", inp);
        if (inp[0] == '!')
                pclose(fp);
        else
                fclose(fp);
#undef mod
#undef typ
#undef id
#undef alias
}


cvtprim(inp, mod, typ, id, fa)  /* process Radiance primitive */
char    *inp, *mod, *typ, *id;
FUNARGS *fa;
{
        int     (*df)();

        df = (int (*)())lu_find(&rdispatch, typ)->data;
        if (df != NULL) {                               /* convert */
                if ((*df)(mod, typ, id, fa) < 0) {
                        fprintf(stderr, "%s: bad %s \"%s\"\n", typ, id);
                        exit(1);
                }
        } else {                                        /* unsupported */
                o_unsupported(mod, typ, id, fa);
                if (lu_find(&rmats, mod)->data != NULL) /* make alias */
                        newmat(id, mod);
        }
}


newmat(id, alias)               /* add a modifier to the alias list */
char    *id;
char    *alias;
{
        register LUENT  *lp, *lpa;

        if (alias != NULL) {                    /* look up alias */
                if ((lpa = lu_find(&rmats, alias)) == NULL)
                        goto memerr;
                if (lpa->data == NULL)
                        alias = NULL;           /* doesn't exist! */
        }
        if ((lp = lu_find(&rmats, id)) == NULL) /* look up material */
                goto memerr;
        if (alias != NULL && lp->data == lpa->key)
                return;                 /* alias set already */
        if (lp->data == NULL) {                 /* allocate material */
                if ((lp->key = (char *)malloc(strlen(id)+1)) == NULL)
                        goto memerr;
                strcpy(lp->key, id);
        }
        if (alias == NULL) {                    /* set this material */
                lp->data = lp->key;
                printf("m %s =\n", id);
        } else {                                /* set this alias */
                lp->data = lpa->key;
                printf("m %s = %s\n", id, alias);
        }
        strcpy(curmat, id);
        return;
memerr:
        fputs("Out of memory in newmat!\n", stderr);
        exit(1);
}


setmat(id)                      /* set material to this one */
char    *id;
{
        if (!strcmp(id, curmat))        /* already set? */
                return;
        if (!strcmp(id, VOIDID))        /* cannot set */
                return;
        printf("m %s\n", id);
        strcpy(curmat, id);
}


setobj(id)                      /* set object name to this one */
char    *id;
{
        register char   *cp, *cp2;
        char    *end = NULL;
        int     diff = 0;
                                /* use all but final suffix */
        for (cp = id; *cp; cp++)
                if (*cp == '.')
                        end = cp;
        if (end == NULL)
                end = cp;
                                /* copy to current object */
        cp2 = curobj;
        if (!isalpha(*id)) {    /* start with letter */
                diff = *cp2 != 'O';
                *cp2++ = 'O';
        }
        for (cp = id; cp < end; *cp2++ = *cp++) {
                if (*cp < '!' | *cp > '~')      /* limit to visible chars */
                        *cp = '?';
                diff += *cp != *cp2;
        }
        if (!diff && !*cp2)
                return;
        *cp2 = '\0';
        fputs("o\no ", stdout);
        puts(curobj);
}


init()                  /* initialize dispatch table and output */
{
        lu_init(&vertab, NVERTS);
        lu_init(&rdispatch, 22);
        add2dispatch("polygon", o_face);
        add2dispatch("cone", o_cone);
        add2dispatch("cup", o_cone);
        add2dispatch("sphere", o_sphere);
        add2dispatch("bubble", o_sphere);
        add2dispatch("cylinder", o_cylinder);
        add2dispatch("tube", o_cylinder);
        add2dispatch("ring", o_ring);
        add2dispatch("instance", o_instance);
        add2dispatch("plastic", o_plastic);
        add2dispatch("plastic2", o_plastic);
        add2dispatch("metal", o_metal);
        add2dispatch("metal2", o_metal);
        add2dispatch("glass", o_glass);
        add2dispatch("dielectric", o_dielectric);
        add2dispatch("trans", o_trans);
        add2dispatch("trans2", o_trans);
        add2dispatch("mirror", o_mirror);
        add2dispatch("light", o_light);
        add2dispatch("spotlight", o_light);
        add2dispatch("glow", o_light);
        add2dispatch("illum", o_illum);
        puts("# The following was converted from RADIANCE scene input");
        if (hasmult)
                printf("xf -s %.4e\n", unit_mult);
        printf("o %s\n", curobj);
}


uninit()                        /* mark end of MGF file */
{
        puts("o");
        if (hasmult)
                puts("xf");
        puts("# End of data converted from RADIANCE scene input");
        lu_done(&rdispatch);
        lu_done(&rmats);
        lu_done(&vertab);
}


clrverts()                      /* clear vertex table */
{
        register int    i;

        lu_done(&vertab);
        for (i = 0; i < NVERTS; i++)
                vert[i].lused = 0;
        lu_init(&vertab, NVERTS);
}


add2dispatch(name, func)        /* add function to dispatch table */
char    *name;
int     (*func)();
{
        register LUENT  *lp;

        lp = lu_find(&rdispatch, name);
        if (lp->key != NULL) {
                fputs(name, stderr);
                fputs(": duplicate dispatch entry!\n", stderr);
                exit(1);
        }
        lp->key = name;
        lp->data = (char *)func;
}


char *
getvertid(vname, vp)            /* get/set vertex ID for this point */
char    *vname;
FVECT   vp;
{
        static char     vkey[VKLEN];
        register LUENT  *lp;
        register int    i, vndx;

        vclock++;                       /* increment counter */
        mkvkey(vkey, vp);
        if ((lp = lu_find(&vertab, vkey)) == NULL)
                goto memerr;
        if (lp->data == NULL) {         /* allocate new vertex entry */
                if (lp->key != NULL)            /* reclaim deleted entry */
                        vertab.ndel--;
                else {
                        if ((lp->key = (char *)malloc(VKLEN)) == NULL)
                                goto memerr;
                        strcpy(lp->key, vkey);
                }
                vndx = 0;                       /* find oldest vertex */
                for (i = 1; i < NVERTS; i++)
                        if (vert[i].lused < vert[vndx].lused)
                                vndx = i;
                if (vert[vndx].lused) {         /* free old entry first */
                        mkvkey(vkey, vert[vndx].p);
                        lu_delete(&vertab, vkey);
                }
                VCOPY(vert[vndx].p, vp);                        /* assign it */
                printf("v v%d =\n\tp %.15g %.15g %.15g\n",      /* print it */
                                vndx, vp[0], vp[1], vp[2]);
                lp->data = (char *)&vert[vndx];                 /* set it */
        } else
                vndx = (struct vert *)lp->data - vert;
        vert[vndx].lused = vclock;              /* record this use */
        sprintf(vname, "v%d", vndx);
        return(vname);
memerr:
        fputs("Out of memory in getvertid!\n", stderr);
        exit(1);
}


int
o_unsupported(mod, typ, id, fa)         /* mark unsupported primitive */
char    *mod, *typ, *id;
FUNARGS *fa;
{
        register int    i;

        fputs("\n# Unsupported RADIANCE primitive:\n", stdout);
        printf("# %s %s %s", mod, typ, id);
        printf("\n# %d", fa->nsargs);
        for (i = 0; i < fa->nsargs; i++)
                printf(" %s", fa->sarg[i]);
#ifdef IARGS
        printf("\n# %d", fa->niargs);
        for (i = 0; i < fa->niargs; i++)
                printf(" %ld", fa->iarg[i]);
#else
        fputs("\n# 0", stdout);
#endif
        printf("\n# %d", fa->nfargs);
        for (i = 0; i < fa->nfargs; i++)
                printf(" %g", fa->farg[i]);
        fputs("\n\n", stdout);
        return(0);
}


int
o_face(mod, typ, id, fa)                /* print out a polygon */
char    *mod, *typ, *id;
FUNARGS *fa;
{
        char    entbuf[2048];
        register char   *cp;
        register int    i;

        if (fa->nfargs < 9 | fa->nfargs % 3)
                return(-1);
        setmat(mod);
        setobj(id);
        cp = entbuf;
        *cp++ = 'f';
        for (i = 0; i < fa->nfargs; i += 3) {
                *cp++ = ' ';
                getvertid(cp, fa->farg + i);
                while (*cp)
                        cp++;
        }
        puts(entbuf);
        return(0);
}


int
o_cone(mod, typ, id, fa)        /* print out a cone */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        char    v1[6], v2[6];

        if (fa->nfargs != 8)
                return(-1);
        setmat(mod);
        setobj(id);
        getvertid(v1, fa->farg);
        getvertid(v2, fa->farg + 3);
        if (typ[1] == 'u')                      /* cup -> inverted cone */
                printf("cone %s %.12g %s %.12g\n",
                                v1, -fa->farg[6], v2, -fa->farg[7]);
        else
                printf("cone %s %.12g %s %.12g\n",
                                v1, fa->farg[6], v2, fa->farg[7]);
        return(0);
}


int
o_sphere(mod, typ, id, fa)      /* print out a sphere */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        char    cent[6];

        if (fa->nfargs != 4)
                return(-1);
        setmat(mod);
        setobj(id);
        printf("sph %s %.12g\n", getvertid(cent, fa->farg),
                        typ[0]=='b' ? -fa->farg[3] : fa->farg[3]);
        return(0);
}


int
o_cylinder(mod, typ, id, fa)    /* print out a cylinder */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        char    v1[6], v2[6];

        if (fa->nfargs != 7)
                return(-1);
        setmat(mod);
        setobj(id);
        getvertid(v1, fa->farg);
        getvertid(v2, fa->farg + 3);
        printf("cyl %s %.12g %s\n", v1,
                        typ[0]=='t' ? -fa->farg[6] : fa->farg[6], v2);
        return(0);
}


int
o_ring(mod, typ, id, fa)        /* print out a ring */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        if (fa->nfargs != 8)
                return(-1);
        setmat(mod);
        setobj(id);
        printf("v cent =\n\tp %.12g %.12g %.12g\n",
                        fa->farg[0], fa->farg[1], fa->farg[2]);
        printf("\tn %.12g %.12g %.12g\n",
                        fa->farg[3], fa->farg[4], fa->farg[5]);
        if (fa->farg[6] < fa->farg[7])
                printf("ring cent %.12g %.12g\n",
                                fa->farg[6], fa->farg[7]);
        else
                printf("ring cent %.12g %.12g\n",
                                fa->farg[7], fa->farg[6]);
        return(0);
}


int
o_instance(mod, typ, id, fa)    /* convert an instance */
char    *mod, *typ, *id;
FUNARGS *fa;
{
        register int    i;
        register char   *cp;
        char    *start = NULL, *end = NULL;
        /*
         * We don't really know how to do this, so we just create
         * a reference to an undefined MGF file and it's the user's
         * responsibility to create this file and put the appropriate
         * stuff into it.
         */
        if (fa->nsargs < 1)
                return(-1);
        setmat(mod);                    /* only works if surfaces are void */
        setobj(id);
        for (cp = fa->sarg[0]; *cp; cp++)       /* construct MGF file name */
                if (*cp == '/')
                        start = cp+1;
                else if (*cp == '.')
                        end = cp;
        if (start == NULL)
                start = fa->sarg[0];
        if (end == NULL || start >= end)
                end = cp;
        fputs("i ", stdout);                    /* print include entity */
        for (cp = start; cp < end; cp++)
                putchar(*cp);
        fputs(".mgf", stdout);                  /* add MGF suffix */
        for (i = 1; i < fa->nsargs; i++) {      /* add transform */
                putchar(' ');
                fputs(fa->sarg[i], stdout);
        }
        putchar('\n');
        clrverts();                     /* vertex id's no longer reliable */
        return(0);
}


int
o_illum(mod, typ, id, fa)       /* convert an illum material */
char    *mod, *typ, *id;
FUNARGS *fa;
{
        if (fa->nsargs == 1 && strcmp(fa->sarg[0], VOIDID)) {
                newmat(id, fa->sarg[0]);        /* just create alias */
                return(0);
        }
                                        /* else create invisible material */
        newmat(id, NULL);
        puts("\tts 1 0");
        return(0);
}


int
o_plastic(mod, typ, id, fa)     /* convert a plastic material */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        COLOR   cxyz, rrgb;
        double  d;

        if (fa->nfargs != (typ[7]=='2' ? 6 : 5))
                return(-1);
        newmat(id, NULL);
        rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
        rgb_cie(cxyz, rrgb);
        puts("\tc");                            /* put diffuse component */
        d = cxyz[0] + cxyz[1] + cxyz[2];
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\trd %.4f\n", cxyz[1]*(1. - fa->farg[3]));
        if (fa->farg[3] > FTINY) {              /* put specular component */
                puts("\tc");
                printf("\trs %.4f %.4f\n", fa->farg[3],
                                typ[7]=='2' ? .5*(fa->farg[4] + fa->farg[5]) :
                                                fa->farg[4]);
        }
        return(0);
}


int
o_metal(mod, typ, id, fa)       /* convert a metal material */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        COLOR   cxyz, rrgb;
        double  d;

        if (fa->nfargs != (typ[5]=='2' ? 6 : 5))
                return(-1);
        newmat(id, NULL);
        rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
        rgb_cie(cxyz, rrgb);
        puts("\tc");                            /* put diffuse component */
        d = cxyz[0] + cxyz[1] + cxyz[2];
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\trd %.4f\n", cxyz[1]*(1. - fa->farg[3]));
                                                /* put specular component */
        printf("\trs %.4f %.4f\n", cxyz[1]*fa->farg[3],
                        typ[5]=='2' ? .5*(fa->farg[4] + fa->farg[5]) :
                                        fa->farg[4]);
        return(0);
}


int
o_glass(mod, typ, id, fa)       /* convert a glass material */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        COLOR   cxyz, rrgb, trgb;
        double  nrfr = 1.52, F, d;
        register int    i;

        if (fa->nfargs != 3 && fa->nfargs != 4)
                return(-1);
        newmat(id, NULL);
        if (fa->nfargs == 4)
                nrfr = fa->farg[3];
        printf("\tir %f 0\n", nrfr);
        F = (1. - nrfr)/(1. + nrfr);            /* use normal incidence */
        F *= F;
        for (i = 0; i < 3; i++) {
                trgb[i] = fa->farg[i] * (1. - F)*(1. - F) /
                                (1. - F*F*fa->farg[i]*fa->farg[i]);
                rrgb[i] = F * (1. + (1. - 2.*F)*fa->farg[i]) /
                                (1. - F*F*fa->farg[i]*fa->farg[i]);
        }
        rgb_cie(cxyz, rrgb);                    /* put reflected component */
        puts("\tc");
        d = cxyz[0] + cxyz[1] + cxyz[2];
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\trs %.4f 0\n", cxyz[1]);
        rgb_cie(cxyz, trgb);                    /* put transmitted component */
        puts("\tc");
        d = cxyz[0] + cxyz[1] + cxyz[2];
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\tts %.4f 0\n", cxyz[1]);
        return(0);
}


int
o_dielectric(mod, typ, id, fa)  /* convert a dielectric material */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        COLOR   cxyz, trgb;
        double  F, d;
        register int    i;

        if (fa->nfargs != 5)
                return(-1);
        newmat(id, NULL);
        F = (1. - fa->farg[3])/(1. + fa->farg[3]);      /* normal incidence */
        F *= F;
        for (i = 0; i < 3; i++)
                trgb[i] = (1. - F)*pow(fa->farg[i], C_1SIDEDTHICK/unit_mult);
        printf("\tir %f 0\n", fa->farg[3]);     /* put index of refraction */
        printf("\tsides 1\n");
        puts("\tc");                            /* put reflected component */
        printf("\trs %.4f 0\n", F);
        rgb_cie(cxyz, trgb);                    /* put transmitted component */
        puts("\tc");
        d = cxyz[0] + cxyz[1] + cxyz[2];
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\tts %.4f 0\n", cxyz[1]);
        return(0);
}


int
o_mirror(mod, typ, id, fa)      /* convert a mirror material */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        COLOR   cxyz, rrgb;
        double  d;

        if (fa->nsargs == 1) {                  /* use alternate material */
                newmat(id, fa->sarg[0]);
                return(0);
        }
        if (fa->nfargs != 3)
                return(-1);
        newmat(id, NULL);
        rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
        rgb_cie(cxyz, rrgb);
        puts("\tc");                            /* put specular component */
        d = cxyz[0] + cxyz[1] + cxyz[2];
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\trs %.4f 0\n", cxyz[1]);
        return(0);
}


int
o_trans(mod, typ, id, fa)       /* convert a trans material */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        COLOR   cxyz, rrgb;
        double  rough, trans, tspec, d;

        if (typ[4] == '2') {            /* trans2 */
                if (fa->nfargs != 8)
                        return(-1);
                rough = .5*(fa->farg[4] + fa->farg[5]);
                trans = fa->farg[6];
                tspec = fa->farg[7];
        } else {                        /* trans */
                if (fa->nfargs != 7)
                        return(-1);
                rough = fa->farg[4];
                trans = fa->farg[5];
                tspec = fa->farg[6];
        }
        newmat(id, NULL);
        rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
        rgb_cie(cxyz, rrgb);
        puts("\tc");                            /* put transmitted diffuse */
        d = cxyz[0] + cxyz[1] + cxyz[2];
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\ttd %.4f\n", cxyz[1]*trans*(1. - fa->farg[3])*(1. - tspec));
                                                /* put transmitted specular */
        printf("\tts %.4f %.4f\n", cxyz[1]*trans*tspec*(1. - fa->farg[3]), rough);
                                                /* put reflected diffuse */
        printf("\trd %.4f\n", cxyz[1]*(1. - fa->farg[3])*(1. - trans));
        puts("\tc");                            /* put reflected specular */
        printf("\trs %.4f %.4f\n", fa->farg[3], rough);
        return(0);
}


int
o_light(mod, typ, id, fa)               /* convert a light type */
char    *mod, *typ, *id;
register FUNARGS        *fa;
{
        COLOR   cxyz, rrgb;
        double  d;

        if (fa->nfargs < 3)
                return(-1);
        newmat(id, NULL);
        rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
        rgb_cie(cxyz, rrgb);
        d = cxyz[0] + cxyz[1] + cxyz[2];
        puts("\tc");
        if (d > FTINY)
                printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
        printf("\ted %.4g\n", cxyz[1]*(PI*WHTEFFICACY));
        return(0);
}
Revision:	2.13
Committed:	Mon Nov 20 11:06:21 1995 UTC (28 years, 5 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.12:	+1 -1 lines
Log Message:	increased size of face argument buffer, which ran out on big polys
#	Content
1	/* Copyright (c) 1995 Regents of the University of California */
2
3	#ifndef lint
4	static char SCCSid[] = "$SunId$ LBL";
5	#endif
6
7	/*
8	* Convert Radiance scene description to MGF
9	*/
10
11	#include <stdio.h>
12	#include <math.h>
13	#include <ctype.h>
14	#include <string.h>
15	#include "fvect.h"
16	#include "object.h"
17	#include "color.h"
18	#include "lookup.h"
19
20	#define PI 3.14159265358979323846
21
22	#define C_1SIDEDTHICK 0.005
23
24	int o_face(), o_cone(), o_sphere(), o_ring(), o_cylinder();
25	int o_instance(), o_illum();
26	int o_plastic(), o_metal(), o_glass(), o_dielectric(),
27	o_mirror(), o_trans(), o_light();
28
29	extern void free();
30	extern char *malloc();
31
32	LUTAB rmats = LU_SINIT(free,NULL); /* defined material table */
33
34	LUTAB rdispatch = LU_SINIT(NULL,NULL); /* function dispatch table */
35
36	char curmat[80]; /* current material */
37	char curobj[128] = "Untitled"; /* current object name */
38
39	double unit_mult = 1.; /* units multiplier */
40
41	#define hasmult (unit_mult < .999 \|\| unit_mult > 1.001)
42
43	/*
44	* Stuff for tracking and reusing vertices:
45	*/
46
47	char VKFMT[] = "%+16.9e %+16.9e %+16.9e";
48	#define VKLEN 64
49
50	#define mkvkey(k,v) sprintf(k, VKFMT, (v)[0], (v)[1], (v)[2])
51
52	#define NVERTS 256
53
54	long vclock; /* incremented at each vertex request */
55
56	struct vert {
57	long lused; /* when last used (0 if unassigned) */
58	FVECT p; /* track point position only */
59	} vert[NVERTS]; /* our vertex cache */
60
61	LUTAB vertab = LU_SINIT(free,NULL); /* our vertex lookup table */
62
63
64	main(argc, argv)
65	int argc;
66	char **argv;
67	{
68	int i;
69
70	for (i = 1; i < argc && argv[i][0] == '-'; i++)
71	switch (argv[i][1]) {
72	case 'd': /* units */
73	switch (argv[i][2]) {
74	case 'm': /* meters */
75	unit_mult = 1.;
76	break;
77	case 'c': /* centimeters */
78	unit_mult = .01;
79	break;
80	case 'f': /* feet */
81	unit_mult = 12.*.0254;
82	break;
83	case 'i': /* inches */
84	unit_mult = .0254;
85	break;
86	default:
87	goto unkopt;
88	}
89	break;
90	default:
91	goto unkopt;
92	}
93	init();
94	if (i >= argc)
95	rad2mgf(NULL);
96	else
97	for ( ; i < argc; i++)
98	rad2mgf(argv[i]);
99	uninit();
100	exit(0);
101	unkopt:
102	fprintf(stderr, "Usage: %s [-d{m\|c\|f\|i}] file ..\n", argv[0]);
103	exit(1);
104	}
105
106
107	rad2mgf(inp) /* convert a Radiance file to MGF */
108	char *inp;
109	{
110	#define mod buf
111	#define typ (buf+128)
112	#define id (buf+256)
113	#define alias (buf+384)
114	char buf[512];
115	FUNARGS fa;
116	register FILE *fp;
117	register int c;
118
119	if (inp == NULL) {
120	inp = "standard input";
121	fp = stdin;
122	} else if (inp[0] == '!') {
123	if ((fp = popen(inp+1, "r")) == NULL) {
124	fputs(inp, stderr);
125	fputs(": cannot execute\n", stderr);
126	exit(1);
127	}
128	} else if ((fp = fopen(inp, "r")) == NULL) {
129	fputs(inp, stderr);
130	fputs(": cannot open\n", stderr);
131	exit(1);
132	}
133	printf("# Begin conversion from: %s\n", inp);
134	while ((c = getc(fp)) != EOF)
135	switch (c) {
136	case ' ': /* white space */
137	case '\t':
138	case '\n':
139	case '\r':
140	case '\f':
141	break;
142	case '#': /* comment */
143	if (fgets(buf, sizeof(buf), fp) != NULL)
144	printf("# %s", buf);
145	break;
146	case '!': /* inline command */
147	ungetc(c, fp);
148	fgetline(buf, sizeof(buf), fp);
149	rad2mgf(buf);
150	break;
151	default: /* Radiance primitive */
152	ungetc(c, fp);
153	if (fscanf(fp, "%s %s %s", mod, typ, id) != 3) {
154	fputs(inp, stderr);
155	fputs(": unexpected EOF\n", stderr);
156	exit(1);
157	}
158	if (!strcmp(typ, "alias")) {
159	strcpy(alias, "EOF");
160	fscanf(fp, "%s", alias);
161	newmat(id, alias);
162	} else {
163	if (!readfargs(&fa, fp)) {
164	fprintf(stderr,
165	"%s: bad argument syntax for %s \"%s\"\n",
166	inp, typ, id);
167	exit(1);
168	}
169	cvtprim(inp, mod, typ, id, &fa);
170	freefargs(&fa);
171	}
172	break;
173	}
174	printf("# End conversion from: %s\n", inp);
175	if (inp[0] == '!')
176	pclose(fp);
177	else
178	fclose(fp);
179	#undef mod
180	#undef typ
181	#undef id
182	#undef alias
183	}
184
185
186	cvtprim(inp, mod, typ, id, fa) /* process Radiance primitive */
187	char inp, mod, typ, id;
188	FUNARGS *fa;
189	{
190	int (*df)();
191
192	df = (int (*)())lu_find(&rdispatch, typ)->data;
193	if (df != NULL) { /* convert */
194	if ((*df)(mod, typ, id, fa) < 0) {
195	fprintf(stderr, "%s: bad %s \"%s\"\n", typ, id);
196	exit(1);
197	}
198	} else { /* unsupported */
199	o_unsupported(mod, typ, id, fa);
200	if (lu_find(&rmats, mod)->data != NULL) /* make alias */
201	newmat(id, mod);
202	}
203	}
204
205
206	newmat(id, alias) /* add a modifier to the alias list */
207	char *id;
208	char *alias;
209	{
210	register LUENT lp, lpa;
211
212	if (alias != NULL) { /* look up alias */
213	if ((lpa = lu_find(&rmats, alias)) == NULL)
214	goto memerr;
215	if (lpa->data == NULL)
216	alias = NULL; /* doesn't exist! */
217	}
218	if ((lp = lu_find(&rmats, id)) == NULL) /* look up material */
219	goto memerr;
220	if (alias != NULL && lp->data == lpa->key)
221	return; /* alias set already */
222	if (lp->data == NULL) { /* allocate material */
223	if ((lp->key = (char *)malloc(strlen(id)+1)) == NULL)
224	goto memerr;
225	strcpy(lp->key, id);
226	}
227	if (alias == NULL) { /* set this material */
228	lp->data = lp->key;
229	printf("m %s =\n", id);
230	} else { /* set this alias */
231	lp->data = lpa->key;
232	printf("m %s = %s\n", id, alias);
233	}
234	strcpy(curmat, id);
235	return;
236	memerr:
237	fputs("Out of memory in newmat!\n", stderr);
238	exit(1);
239	}
240
241
242	setmat(id) /* set material to this one */
243	char *id;
244	{
245	if (!strcmp(id, curmat)) /* already set? */
246	return;
247	if (!strcmp(id, VOIDID)) /* cannot set */
248	return;
249	printf("m %s\n", id);
250	strcpy(curmat, id);
251	}
252
253
254	setobj(id) /* set object name to this one */
255	char *id;
256	{
257	register char cp, cp2;
258	char *end = NULL;
259	int diff = 0;
260	/* use all but final suffix */
261	for (cp = id; *cp; cp++)
262	if (*cp == '.')
263	end = cp;
264	if (end == NULL)
265	end = cp;
266	/* copy to current object */
267	cp2 = curobj;
268	if (!isalpha(id)) { / start with letter */
269	diff = *cp2 != 'O';
270	*cp2++ = 'O';
271	}
272	for (cp = id; cp < end; cp2++ = cp++) {
273	if (cp < '!' \| cp > '~') /* limit to visible chars */
274	*cp = '?';
275	diff += cp != cp2;
276	}
277	if (!diff && !*cp2)
278	return;
279	*cp2 = '\0';
280	fputs("o\no ", stdout);
281	puts(curobj);
282	}
283
284
285	init() /* initialize dispatch table and output */
286	{
287	lu_init(&vertab, NVERTS);
288	lu_init(&rdispatch, 22);
289	add2dispatch("polygon", o_face);
290	add2dispatch("cone", o_cone);
291	add2dispatch("cup", o_cone);
292	add2dispatch("sphere", o_sphere);
293	add2dispatch("bubble", o_sphere);
294	add2dispatch("cylinder", o_cylinder);
295	add2dispatch("tube", o_cylinder);
296	add2dispatch("ring", o_ring);
297	add2dispatch("instance", o_instance);
298	add2dispatch("plastic", o_plastic);
299	add2dispatch("plastic2", o_plastic);
300	add2dispatch("metal", o_metal);
301	add2dispatch("metal2", o_metal);
302	add2dispatch("glass", o_glass);
303	add2dispatch("dielectric", o_dielectric);
304	add2dispatch("trans", o_trans);
305	add2dispatch("trans2", o_trans);
306	add2dispatch("mirror", o_mirror);
307	add2dispatch("light", o_light);
308	add2dispatch("spotlight", o_light);
309	add2dispatch("glow", o_light);
310	add2dispatch("illum", o_illum);
311	puts("# The following was converted from RADIANCE scene input");
312	if (hasmult)
313	printf("xf -s %.4e\n", unit_mult);
314	printf("o %s\n", curobj);
315	}
316
317
318	uninit() /* mark end of MGF file */
319	{
320	puts("o");
321	if (hasmult)
322	puts("xf");
323	puts("# End of data converted from RADIANCE scene input");
324	lu_done(&rdispatch);
325	lu_done(&rmats);
326	lu_done(&vertab);
327	}
328
329
330	clrverts() /* clear vertex table */
331	{
332	register int i;
333
334	lu_done(&vertab);
335	for (i = 0; i < NVERTS; i++)
336	vert[i].lused = 0;
337	lu_init(&vertab, NVERTS);
338	}
339
340
341	add2dispatch(name, func) /* add function to dispatch table */
342	char *name;
343	int (*func)();
344	{
345	register LUENT *lp;
346
347	lp = lu_find(&rdispatch, name);
348	if (lp->key != NULL) {
349	fputs(name, stderr);
350	fputs(": duplicate dispatch entry!\n", stderr);
351	exit(1);
352	}
353	lp->key = name;
354	lp->data = (char *)func;
355	}
356
357
358	char *
359	getvertid(vname, vp) /* get/set vertex ID for this point */
360	char *vname;
361	FVECT vp;
362	{
363	static char vkey[VKLEN];
364	register LUENT *lp;
365	register int i, vndx;
366
367	vclock++; /* increment counter */
368	mkvkey(vkey, vp);
369	if ((lp = lu_find(&vertab, vkey)) == NULL)
370	goto memerr;
371	if (lp->data == NULL) { /* allocate new vertex entry */
372	if (lp->key != NULL) /* reclaim deleted entry */
373	vertab.ndel--;
374	else {
375	if ((lp->key = (char *)malloc(VKLEN)) == NULL)
376	goto memerr;
377	strcpy(lp->key, vkey);
378	}
379	vndx = 0; /* find oldest vertex */
380	for (i = 1; i < NVERTS; i++)
381	if (vert[i].lused < vert[vndx].lused)
382	vndx = i;
383	if (vert[vndx].lused) { /* free old entry first */
384	mkvkey(vkey, vert[vndx].p);
385	lu_delete(&vertab, vkey);
386	}
387	VCOPY(vert[vndx].p, vp); /* assign it */
388	printf("v v%d =\n\tp %.15g %.15g %.15g\n", /* print it */
389	vndx, vp[0], vp[1], vp[2]);
390	lp->data = (char )&vert[vndx]; / set it */
391	} else
392	vndx = (struct vert *)lp->data - vert;
393	vert[vndx].lused = vclock; /* record this use */
394	sprintf(vname, "v%d", vndx);
395	return(vname);
396	memerr:
397	fputs("Out of memory in getvertid!\n", stderr);
398	exit(1);
399	}
400
401
402	int
403	o_unsupported(mod, typ, id, fa) /* mark unsupported primitive */
404	char mod, typ, *id;
405	FUNARGS *fa;
406	{
407	register int i;
408
409	fputs("\n# Unsupported RADIANCE primitive:\n", stdout);
410	printf("# %s %s %s", mod, typ, id);
411	printf("\n# %d", fa->nsargs);
412	for (i = 0; i < fa->nsargs; i++)
413	printf(" %s", fa->sarg[i]);
414	#ifdef IARGS
415	printf("\n# %d", fa->niargs);
416	for (i = 0; i < fa->niargs; i++)
417	printf(" %ld", fa->iarg[i]);
418	#else
419	fputs("\n# 0", stdout);
420	#endif
421	printf("\n# %d", fa->nfargs);
422	for (i = 0; i < fa->nfargs; i++)
423	printf(" %g", fa->farg[i]);
424	fputs("\n\n", stdout);
425	return(0);
426	}
427
428
429	int
430	o_face(mod, typ, id, fa) /* print out a polygon */
431	char mod, typ, *id;
432	FUNARGS *fa;
433	{
434	char entbuf[2048];
435	register char *cp;
436	register int i;
437
438	if (fa->nfargs < 9 \| fa->nfargs % 3)
439	return(-1);
440	setmat(mod);
441	setobj(id);
442	cp = entbuf;
443	*cp++ = 'f';
444	for (i = 0; i < fa->nfargs; i += 3) {
445	*cp++ = ' ';
446	getvertid(cp, fa->farg + i);
447	while (*cp)
448	cp++;
449	}
450	puts(entbuf);
451	return(0);
452	}
453
454
455	int
456	o_cone(mod, typ, id, fa) /* print out a cone */
457	char mod, typ, *id;
458	register FUNARGS *fa;
459	{
460	char v1[6], v2[6];
461
462	if (fa->nfargs != 8)
463	return(-1);
464	setmat(mod);
465	setobj(id);
466	getvertid(v1, fa->farg);
467	getvertid(v2, fa->farg + 3);
468	if (typ[1] == 'u') /* cup -> inverted cone */
469	printf("cone %s %.12g %s %.12g\n",
470	v1, -fa->farg[6], v2, -fa->farg[7]);
471	else
472	printf("cone %s %.12g %s %.12g\n",
473	v1, fa->farg[6], v2, fa->farg[7]);
474	return(0);
475	}
476
477
478	int
479	o_sphere(mod, typ, id, fa) /* print out a sphere */
480	char mod, typ, *id;
481	register FUNARGS *fa;
482	{
483	char cent[6];
484
485	if (fa->nfargs != 4)
486	return(-1);
487	setmat(mod);
488	setobj(id);
489	printf("sph %s %.12g\n", getvertid(cent, fa->farg),
490	typ[0]=='b' ? -fa->farg[3] : fa->farg[3]);
491	return(0);
492	}
493
494
495	int
496	o_cylinder(mod, typ, id, fa) /* print out a cylinder */
497	char mod, typ, *id;
498	register FUNARGS *fa;
499	{
500	char v1[6], v2[6];
501
502	if (fa->nfargs != 7)
503	return(-1);
504	setmat(mod);
505	setobj(id);
506	getvertid(v1, fa->farg);
507	getvertid(v2, fa->farg + 3);
508	printf("cyl %s %.12g %s\n", v1,
509	typ[0]=='t' ? -fa->farg[6] : fa->farg[6], v2);
510	return(0);
511	}
512
513
514	int
515	o_ring(mod, typ, id, fa) /* print out a ring */
516	char mod, typ, *id;
517	register FUNARGS *fa;
518	{
519	if (fa->nfargs != 8)
520	return(-1);
521	setmat(mod);
522	setobj(id);
523	printf("v cent =\n\tp %.12g %.12g %.12g\n",
524	fa->farg[0], fa->farg[1], fa->farg[2]);
525	printf("\tn %.12g %.12g %.12g\n",
526	fa->farg[3], fa->farg[4], fa->farg[5]);
527	if (fa->farg[6] < fa->farg[7])
528	printf("ring cent %.12g %.12g\n",
529	fa->farg[6], fa->farg[7]);
530	else
531	printf("ring cent %.12g %.12g\n",
532	fa->farg[7], fa->farg[6]);
533	return(0);
534	}
535
536
537	int
538	o_instance(mod, typ, id, fa) /* convert an instance */
539	char mod, typ, *id;
540	FUNARGS *fa;
541	{
542	register int i;
543	register char *cp;
544	char start = NULL, end = NULL;
545	/*
546	* We don't really know how to do this, so we just create
547	* a reference to an undefined MGF file and it's the user's
548	* responsibility to create this file and put the appropriate
549	* stuff into it.
550	*/
551	if (fa->nsargs < 1)
552	return(-1);
553	setmat(mod); /* only works if surfaces are void */
554	setobj(id);
555	for (cp = fa->sarg[0]; cp; cp++) / construct MGF file name */
556	if (*cp == '/')
557	start = cp+1;
558	else if (*cp == '.')
559	end = cp;
560	if (start == NULL)
561	start = fa->sarg[0];
562	if (end == NULL \|\| start >= end)
563	end = cp;
564	fputs("i ", stdout); /* print include entity */
565	for (cp = start; cp < end; cp++)
566	putchar(*cp);
567	fputs(".mgf", stdout); /* add MGF suffix */
568	for (i = 1; i < fa->nsargs; i++) { /* add transform */
569	putchar(' ');
570	fputs(fa->sarg[i], stdout);
571	}
572	putchar('\n');
573	clrverts(); /* vertex id's no longer reliable */
574	return(0);
575	}
576
577
578	int
579	o_illum(mod, typ, id, fa) /* convert an illum material */
580	char mod, typ, *id;
581	FUNARGS *fa;
582	{
583	if (fa->nsargs == 1 && strcmp(fa->sarg[0], VOIDID)) {
584	newmat(id, fa->sarg[0]); /* just create alias */
585	return(0);
586	}
587	/* else create invisible material */
588	newmat(id, NULL);
589	puts("\tts 1 0");
590	return(0);
591	}
592
593
594	int
595	o_plastic(mod, typ, id, fa) /* convert a plastic material */
596	char mod, typ, *id;
597	register FUNARGS *fa;
598	{
599	COLOR cxyz, rrgb;
600	double d;
601
602	if (fa->nfargs != (typ[7]=='2' ? 6 : 5))
603	return(-1);
604	newmat(id, NULL);
605	rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
606	rgb_cie(cxyz, rrgb);
607	puts("\tc"); /* put diffuse component */
608	d = cxyz[0] + cxyz[1] + cxyz[2];
609	if (d > FTINY)
610	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
611	printf("\trd %.4f\n", cxyz[1]*(1. - fa->farg[3]));
612	if (fa->farg[3] > FTINY) { /* put specular component */
613	puts("\tc");
614	printf("\trs %.4f %.4f\n", fa->farg[3],
615	typ[7]=='2' ? .5*(fa->farg[4] + fa->farg[5]) :
616	fa->farg[4]);
617	}
618	return(0);
619	}
620
621
622	int
623	o_metal(mod, typ, id, fa) /* convert a metal material */
624	char mod, typ, *id;
625	register FUNARGS *fa;
626	{
627	COLOR cxyz, rrgb;
628	double d;
629
630	if (fa->nfargs != (typ[5]=='2' ? 6 : 5))
631	return(-1);
632	newmat(id, NULL);
633	rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
634	rgb_cie(cxyz, rrgb);
635	puts("\tc"); /* put diffuse component */
636	d = cxyz[0] + cxyz[1] + cxyz[2];
637	if (d > FTINY)
638	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
639	printf("\trd %.4f\n", cxyz[1]*(1. - fa->farg[3]));
640	/* put specular component */
641	printf("\trs %.4f %.4f\n", cxyz[1]*fa->farg[3],
642	typ[5]=='2' ? .5*(fa->farg[4] + fa->farg[5]) :
643	fa->farg[4]);
644	return(0);
645	}
646
647
648	int
649	o_glass(mod, typ, id, fa) /* convert a glass material */
650	char mod, typ, *id;
651	register FUNARGS *fa;
652	{
653	COLOR cxyz, rrgb, trgb;
654	double nrfr = 1.52, F, d;
655	register int i;
656
657	if (fa->nfargs != 3 && fa->nfargs != 4)
658	return(-1);
659	newmat(id, NULL);
660	if (fa->nfargs == 4)
661	nrfr = fa->farg[3];
662	printf("\tir %f 0\n", nrfr);
663	F = (1. - nrfr)/(1. + nrfr); /* use normal incidence */
664	F *= F;
665	for (i = 0; i < 3; i++) {
666	trgb[i] = fa->farg[i] * (1. - F)*(1. - F) /
667	(1. - FFfa->farg[i]*fa->farg[i]);
668	rrgb[i] = F * (1. + (1. - 2.F)fa->farg[i]) /
669	(1. - FFfa->farg[i]*fa->farg[i]);
670	}
671	rgb_cie(cxyz, rrgb); /* put reflected component */
672	puts("\tc");
673	d = cxyz[0] + cxyz[1] + cxyz[2];
674	if (d > FTINY)
675	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
676	printf("\trs %.4f 0\n", cxyz[1]);
677	rgb_cie(cxyz, trgb); /* put transmitted component */
678	puts("\tc");
679	d = cxyz[0] + cxyz[1] + cxyz[2];
680	if (d > FTINY)
681	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
682	printf("\tts %.4f 0\n", cxyz[1]);
683	return(0);
684	}
685
686
687	int
688	o_dielectric(mod, typ, id, fa) /* convert a dielectric material */
689	char mod, typ, *id;
690	register FUNARGS *fa;
691	{
692	COLOR cxyz, trgb;
693	double F, d;
694	register int i;
695
696	if (fa->nfargs != 5)
697	return(-1);
698	newmat(id, NULL);
699	F = (1. - fa->farg[3])/(1. + fa->farg[3]); /* normal incidence */
700	F *= F;
701	for (i = 0; i < 3; i++)
702	trgb[i] = (1. - F)*pow(fa->farg[i], C_1SIDEDTHICK/unit_mult);
703	printf("\tir %f 0\n", fa->farg[3]); /* put index of refraction */
704	printf("\tsides 1\n");
705	puts("\tc"); /* put reflected component */
706	printf("\trs %.4f 0\n", F);
707	rgb_cie(cxyz, trgb); /* put transmitted component */
708	puts("\tc");
709	d = cxyz[0] + cxyz[1] + cxyz[2];
710	if (d > FTINY)
711	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
712	printf("\tts %.4f 0\n", cxyz[1]);
713	return(0);
714	}
715
716
717	int
718	o_mirror(mod, typ, id, fa) /* convert a mirror material */
719	char mod, typ, *id;
720	register FUNARGS *fa;
721	{
722	COLOR cxyz, rrgb;
723	double d;
724
725	if (fa->nsargs == 1) { /* use alternate material */
726	newmat(id, fa->sarg[0]);
727	return(0);
728	}
729	if (fa->nfargs != 3)
730	return(-1);
731	newmat(id, NULL);
732	rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
733	rgb_cie(cxyz, rrgb);
734	puts("\tc"); /* put specular component */
735	d = cxyz[0] + cxyz[1] + cxyz[2];
736	if (d > FTINY)
737	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
738	printf("\trs %.4f 0\n", cxyz[1]);
739	return(0);
740	}
741
742
743	int
744	o_trans(mod, typ, id, fa) /* convert a trans material */
745	char mod, typ, *id;
746	register FUNARGS *fa;
747	{
748	COLOR cxyz, rrgb;
749	double rough, trans, tspec, d;
750
751	if (typ[4] == '2') { /* trans2 */
752	if (fa->nfargs != 8)
753	return(-1);
754	rough = .5*(fa->farg[4] + fa->farg[5]);
755	trans = fa->farg[6];
756	tspec = fa->farg[7];
757	} else { /* trans */
758	if (fa->nfargs != 7)
759	return(-1);
760	rough = fa->farg[4];
761	trans = fa->farg[5];
762	tspec = fa->farg[6];
763	}
764	newmat(id, NULL);
765	rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
766	rgb_cie(cxyz, rrgb);
767	puts("\tc"); /* put transmitted diffuse */
768	d = cxyz[0] + cxyz[1] + cxyz[2];
769	if (d > FTINY)
770	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
771	printf("\ttd %.4f\n", cxyz[1]trans(1. - fa->farg[3])*(1. - tspec));
772	/* put transmitted specular */
773	printf("\tts %.4f %.4f\n", cxyz[1]transtspec*(1. - fa->farg[3]), rough);
774	/* put reflected diffuse */
775	printf("\trd %.4f\n", cxyz[1](1. - fa->farg[3])(1. - trans));
776	puts("\tc"); /* put reflected specular */
777	printf("\trs %.4f %.4f\n", fa->farg[3], rough);
778	return(0);
779	}
780
781
782	int
783	o_light(mod, typ, id, fa) /* convert a light type */
784	char mod, typ, *id;
785	register FUNARGS *fa;
786	{
787	COLOR cxyz, rrgb;
788	double d;
789
790	if (fa->nfargs < 3)
791	return(-1);
792	newmat(id, NULL);
793	rrgb[0] = fa->farg[0]; rrgb[1] = fa->farg[1]; rrgb[2] = fa->farg[2];
794	rgb_cie(cxyz, rrgb);
795	d = cxyz[0] + cxyz[1] + cxyz[2];
796	puts("\tc");
797	if (d > FTINY)
798	printf("\t\tcxy %.4f %.4f\n", cxyz[0]/d, cxyz[1]/d);
799	printf("\ted %.4g\n", cxyz[1](PIWHTEFFICACY));
800	return(0);
801	}