src/cv/bsdf2klems.c

#ifndef lint
static const char RCSid[] = "$Id: bsdf2klems.c,v 2.19 2016/01/24 14:28:51 greg Exp $";
#endif
/*
 * Load measured BSDF interpolant and write out as XML file with Klems matrix.
 *
 *      G. Ward
 */

#define _USE_MATH_DEFINES
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include "random.h"
#include "platform.h"
#include "paths.h"
#include "rtio.h"
#include "calcomp.h"
#include "bsdfrep.h"
#include "bsdf_m.h"
                                /* tristimulus components */
enum {CIE_X, CIE_Y, CIE_Z};
                                /* assumed maximum # Klems patches */
#define MAXPATCHES      145
                                /* global argv[0] */
char                    *progname;
                                /* selected basis function name */
static const char       klems_full[] = "LBNL/Klems Full";
static const char       klems_half[] = "LBNL/Klems Half";
static const char       klems_quarter[] = "LBNL/Klems Quarter";
static const char       *kbasis = klems_full;
                                /* number of BSDF samples per patch */
static int              npsamps = 256;
                                /* limit on number of RBF lobes */
static int              lobe_lim = 15000;
                                /* progress bar length */
static int              do_prog = 79;

#define MAXCARG         512     /* wrapBSDF command */
static char             *wrapBSDF[MAXCARG] = {"wrapBSDF", "-W", "-UU"};
static int              wbsdfac = 3;

/* Add argument to wrapBSDF, allocating space if isstatic */
static void
add_wbsdf(const char *arg, int isstatic)
{
        if (arg == NULL)
                return;
        if (wbsdfac >= MAXCARG-1) {
                fputs(progname, stderr);
                fputs(": too many command arguments to wrapBSDF\n", stderr);
                exit(1);
        }
        if (!*arg)
                arg = "";
        else if (!isstatic)
                arg = savqstr((char *)arg);

        wrapBSDF[wbsdfac++] = (char *)arg;
}

/* Start new progress bar */
#define prog_start(s)   if (do_prog) fprintf(stderr, "%s: %s...\n", progname, s); else

/* Draw progress bar of the appropriate length */
static void
prog_show(double frac)
{
        static unsigned call_cnt = 0;
        static char     lastc[] = "-\\|/";
        char            pbar[256];
        int             nchars;

        if (do_prog <= 1) return;
        if (do_prog > sizeof(pbar)-2)
                do_prog = sizeof(pbar)-2;
        if (frac < 0) frac = 0;
        else if (frac >= 1) frac = .9999;
        nchars = do_prog*frac;
        pbar[0] = '\r';
        memset(pbar+1, '*', nchars);
        pbar[nchars+1] = lastc[call_cnt++ & 3];
        memset(pbar+2+nchars, '-', do_prog-nchars-1);
        pbar[do_prog+1] = '\0';
        fputs(pbar, stderr);
}

/* Finish progress bar */
static void
prog_done(void)
{
        int     n = do_prog;

        if (n <= 1) return;
        fputc('\r', stderr);
        while (n--)
                fputc(' ', stderr);
        fputc('\r', stderr);
}

/* Return angle basis corresponding to the given name */
static ANGLE_BASIS *
get_basis(const char *bn)
{
        int     n = nabases;
        
        while (n-- > 0)
                if (!strcasecmp(bn, abase_list[n].name))
                        return &abase_list[n];
        return NULL;
}

/* Copy geometry string to file for wrapBSDF */
static char *
save_geom(const char *mgf)
{
        char    *tfname = mktemp(savqstr(TEMPLATE));
        int     fd = open(tfname, O_CREAT|O_WRONLY, 0600);

        if (fd < 0)
                return(NULL);
        write(fd, mgf, strlen(mgf));
        close(fd);
        add_wbsdf("-g", 1);
        add_wbsdf(tfname, 1);
        return(tfname);
}

/* Open XYZ component file for output and add appropriate arguments */
static FILE *
open_component_file(int c)
{
        static const char       sname[3][6] = {"CIE-X", "CIE-Y", "CIE-Z"};
        static const char       cname[4][4] = {"-rf", "-tf", "-tb", "-rb"};
        char                    *tfname = mktemp(savqstr(TEMPLATE));
        FILE                    *fp = fopen(tfname, "w");

        if (fp == NULL) {
                fprintf(stderr, "%s: cannot open '%s' for writing\n",
                                progname, tfname);
                exit(1);
        }
        add_wbsdf("-s", 1); add_wbsdf(sname[c], 1);
        add_wbsdf(cname[(input_orient>0)<<1 | (output_orient>0)], 1);
        add_wbsdf(tfname, 1);
        return(fp);
}

/* Load and resample XML BSDF description using Klems basis */
static void
eval_bsdf(const char *fname)
{
        ANGLE_BASIS     *abp = get_basis(kbasis);
        FILE            *cfp[3];
        SDData          bsd;
        SDError         ec;
        FVECT           vin, vout;
        SDValue         sdv;
        double          sum, xsum, ysum;
        int             i, j, n;

        initurand(npsamps);
        SDclearBSDF(&bsd, fname);               /* load BSDF file */
        if ((ec = SDloadFile(&bsd, fname)) != SDEnone)
                goto err;
        if (bsd.mgf != NULL)                    /* save geometry */
                save_geom(bsd.mgf);
        if (bsd.matn[0])                        /* save identifier(s) */
                strcpy(bsdf_name, bsd.matn);
        if (bsd.makr[0])
                strcpy(bsdf_manuf, bsd.makr);
        if (bsd.dim[2] > 0) {                   /* save dimension(s) */
                char    buf[64];
                if ((bsd.dim[0] > 0) & (bsd.dim[1] > 0))
                        sprintf(buf, "w=%g;h=%g;t=%g",
                                        bsd.dim[0], bsd.dim[1], bsd.dim[2]);
                else
                        sprintf(buf, "t=%g", bsd.dim[2]);
                add_wbsdf("-f", 1);
                add_wbsdf(buf, 0);
        }
                                                /* front reflection */
        if (bsd.rf != NULL || bsd.rLambFront.cieY > .002) {
            input_orient = 1; output_orient = 1;
            cfp[CIE_Y] = open_component_file(CIE_Y);
            if (bsd.rf != NULL && bsd.rf->comp[0].cspec[2].flags) {
                rbf_colorimetry = RBCtristimulus;
                cfp[CIE_X] = open_component_file(CIE_X);
                cfp[CIE_Z] = open_component_file(CIE_Z);
            } else
                rbf_colorimetry = RBCphotopic;
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;                    /* average over patches */
                    xsum = ysum = 0;
                    for (n = npsamps; n-- > 0; ) {
                        fo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        fi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sdv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sdv.cieY;
                        if (rbf_colorimetry == RBCtristimulus) {
                                c_ccvt(&sdv.spec, C_CSXY);
                                xsum += sdv.cieY*sdv.spec.cx;
                                ysum += sdv.cieY*sdv.spec.cy;
                        }
                    }
                    fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
                    if (rbf_colorimetry == RBCtristimulus) {
                        fprintf(cfp[CIE_X], "\t%3e\n", xsum*sum/(npsamps*ysum));
                        fprintf(cfp[CIE_Z], "\t%3e\n",
                                (sum - xsum - ysum)*sum/(npsamps*ysum));
                    }
                }
                fputc('\n', cfp[CIE_Y]);        /* extra space between rows */
                if (rbf_colorimetry == RBCtristimulus) {
                        fputc('\n', cfp[CIE_X]);
                        fputc('\n', cfp[CIE_Z]);
                }
            }
            if (fclose(cfp[CIE_Y])) {
                fprintf(stderr, "%s: error writing Y output\n", progname);
                exit(1);
            }
            if (rbf_colorimetry == RBCtristimulus &&
                        (fclose(cfp[CIE_X]) || fclose(cfp[CIE_Z]))) {
                fprintf(stderr, "%s: error writing X/Z output\n", progname);
                exit(1);
            }
        }
                                                /* back reflection */
        if (bsd.rb != NULL || bsd.rLambBack.cieY > .002) {
            input_orient = -1; output_orient = -1;
            cfp[CIE_Y] = open_component_file(CIE_Y);
            if (bsd.rb != NULL && bsd.rb->comp[0].cspec[2].flags) {
                rbf_colorimetry = RBCtristimulus;
                cfp[CIE_X] = open_component_file(CIE_X);
                cfp[CIE_Z] = open_component_file(CIE_Z);
            } else
                rbf_colorimetry = RBCphotopic;
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;                    /* average over patches */
                    xsum = ysum = 0;
                    for (n = npsamps; n-- > 0; ) {
                        bo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        bi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sdv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sdv.cieY;
                        if (rbf_colorimetry == RBCtristimulus) {
                                c_ccvt(&sdv.spec, C_CSXY);
                                xsum += sdv.cieY*sdv.spec.cx;
                                ysum += sdv.cieY*sdv.spec.cy;
                        }
                    }
                    fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
                    if (rbf_colorimetry == RBCtristimulus) {
                        fprintf(cfp[CIE_X], "\t%3e\n", xsum*sum/(npsamps*ysum));
                        fprintf(cfp[CIE_Z], "\t%3e\n",
                                (sum - xsum - ysum)*sum/(npsamps*ysum));
                    }
                }
                if (rbf_colorimetry == RBCtristimulus) {
                        fputc('\n', cfp[CIE_X]);
                        fputc('\n', cfp[CIE_Z]);
                }
            }
            if (fclose(cfp[CIE_Y])) {
                fprintf(stderr, "%s: error writing Y output\n", progname);
                exit(1);
            }
            if (rbf_colorimetry == RBCtristimulus &&
                        (fclose(cfp[CIE_X]) || fclose(cfp[CIE_Z]))) {
                fprintf(stderr, "%s: error writing X/Z output\n", progname);
                exit(1);
            }
        }
                                                /* front transmission */
        if (bsd.tf != NULL || bsd.tLamb.cieY > .002) {
            input_orient = 1; output_orient = -1;
            cfp[CIE_Y] = open_component_file(CIE_Y);
            if (bsd.tf != NULL && bsd.tf->comp[0].cspec[2].flags) {
                rbf_colorimetry = RBCtristimulus;
                cfp[CIE_X] = open_component_file(CIE_X);
                cfp[CIE_Z] = open_component_file(CIE_Z);
            } else
                rbf_colorimetry = RBCphotopic;
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;                    /* average over patches */
                    xsum = ysum = 0;
                    for (n = npsamps; n-- > 0; ) {
                        bo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        fi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sdv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sdv.cieY;
                        if (rbf_colorimetry == RBCtristimulus) {
                                c_ccvt(&sdv.spec, C_CSXY);
                                xsum += sdv.cieY*sdv.spec.cx;
                                ysum += sdv.cieY*sdv.spec.cy;
                        }
                    }
                    fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
                    if (rbf_colorimetry == RBCtristimulus) {
                        fprintf(cfp[CIE_X], "\t%3e\n", xsum*sum/(npsamps*ysum));
                        fprintf(cfp[CIE_Z], "\t%3e\n",
                                (sum - xsum - ysum)*sum/(npsamps*ysum));
                    }
                }
                if (rbf_colorimetry == RBCtristimulus) {
                        fputc('\n', cfp[CIE_X]);
                        fputc('\n', cfp[CIE_Z]);
                }
            }
            if (fclose(cfp[CIE_Y])) {
                fprintf(stderr, "%s: error writing Y output\n", progname);
                exit(1);
            }
            if (rbf_colorimetry == RBCtristimulus &&
                        (fclose(cfp[CIE_X]) || fclose(cfp[CIE_Z]))) {
                fprintf(stderr, "%s: error writing X/Z output\n", progname);
                exit(1);
            }
        }
                                                /* back transmission */
        if ((bsd.tb != NULL) | (bsd.tf != NULL)) {
            input_orient = -1; output_orient = 1;
            cfp[CIE_Y] = open_component_file(CIE_Y);
            if (bsd.tb != NULL && bsd.tb->comp[0].cspec[2].flags) {
                rbf_colorimetry = RBCtristimulus;
                cfp[CIE_X] = open_component_file(CIE_X);
                cfp[CIE_Z] = open_component_file(CIE_Z);
            } else
                rbf_colorimetry = RBCphotopic;
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;            /* average over patches */
                    xsum = ysum = 0;
                    for (n = npsamps; n-- > 0; ) {
                        fo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        bi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sdv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sdv.cieY;
                        if (rbf_colorimetry == RBCtristimulus) {
                                c_ccvt(&sdv.spec, C_CSXY);
                                xsum += sdv.cieY*sdv.spec.cx;
                                ysum += sdv.cieY*sdv.spec.cy;
                        }
                    }
                    fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
                    if (rbf_colorimetry == RBCtristimulus) {
                        fprintf(cfp[CIE_X], "\t%3e\n", xsum*sum/(npsamps*ysum));
                        fprintf(cfp[CIE_Z], "\t%3e\n",
                                (sum - xsum - ysum)*sum/(npsamps*ysum));
                    }
                }
                if (rbf_colorimetry == RBCtristimulus) {
                        fputc('\n', cfp[CIE_X]);
                        fputc('\n', cfp[CIE_Z]);
                }
            }
            if (fclose(cfp[CIE_Y])) {
                fprintf(stderr, "%s: error writing Y output\n", progname);
                exit(1);
            }
            if (rbf_colorimetry == RBCtristimulus &&
                        (fclose(cfp[CIE_X]) || fclose(cfp[CIE_Z]))) {
                fprintf(stderr, "%s: error writing X/Z output\n", progname);
                exit(1);
            }
        }
        SDfreeBSDF(&bsd);                       /* all done */
        return;
err:
        SDreportError(ec, stderr);
        exit(1);
}

/* Interpolate and output a BSDF function using Klems basis */
static void
eval_function(char *funame)
{
        ANGLE_BASIS     *abp = get_basis(kbasis);
        int             assignD = (fundefined(funame) < 6);
        FILE            *ofp = open_component_file(CIE_Y);
        double          iovec[6];
        double          sum;
        int             i, j, n;

        initurand(npsamps);
        for (j = 0; j < abp->nangles; j++) {    /* run through directions */
            for (i = 0; i < abp->nangles; i++) {
                sum = 0;
                for (n = npsamps; n--; ) {      /* average over patches */
                    if (output_orient > 0)
                        fo_getvec(iovec+3, j+(n+frandom())/npsamps, abp);
                    else
                        bo_getvec(iovec+3, j+(n+frandom())/npsamps, abp);

                    if (input_orient > 0)
                        fi_getvec(iovec, i+urand(n), abp);
                    else
                        bi_getvec(iovec, i+urand(n), abp);

                    if (assignD) {
                        varset("Dx", '=', -iovec[3]);
                        varset("Dy", '=', -iovec[4]);
                        varset("Dz", '=', -iovec[5]);
                        ++eclock;
                    }
                    sum += funvalue(funame, 6, iovec);
                }
                fprintf(ofp, "\t%.3e\n", sum/npsamps);
            }
            fputc('\n', ofp);
            prog_show((j+1.)/abp->nangles);
        }
        prog_done();
        if (fclose(ofp)) {
                fprintf(stderr, "%s: error writing Y output\n", progname);
                exit(1);
        }
}

/* Interpolate and output a radial basis function BSDF representation */
static void
eval_rbf(void)
{
        ANGLE_BASIS     *abp = get_basis(kbasis);
        float           (*XZarr)[2] = NULL;
        float           bsdfarr[MAXPATCHES*MAXPATCHES];
        FILE            *cfp[3];
        FVECT           vin, vout;
        double          sum, xsum, ysum;
        int             i, j, n;
                                                /* sanity check */
        if (abp->nangles > MAXPATCHES) {
                fprintf(stderr, "%s: too many patches!\n", progname);
                exit(1);
        }
        if (rbf_colorimetry == RBCtristimulus)
                XZarr = (float (*)[2])malloc(sizeof(float)*2*abp->nangles*abp->nangles);
        for (i = 0; i < abp->nangles; i++) {
            RBFNODE     *rbf;
            if (input_orient > 0)               /* use incident patch center */
                fi_getvec(vin, i+.5*(i>0), abp);
            else
                bi_getvec(vin, i+.5*(i>0), abp);

            rbf = advect_rbf(vin, lobe_lim);    /* compute radial basis func */

            for (j = 0; j < abp->nangles; j++) {
                sum = 0;                        /* sample over exiting patch */
                xsum = ysum = 0;
                for (n = npsamps; n--; ) {
                    SDValue     sdv;
                    if (output_orient > 0)
                        fo_getvec(vout, j+(n+frandom())/npsamps, abp);
                    else
                        bo_getvec(vout, j+(n+frandom())/npsamps, abp);

                    eval_rbfcol(&sdv, rbf, vout);
                    sum += sdv.cieY;
                    if (XZarr != NULL) {
                        c_ccvt(&sdv.spec, C_CSXY);
                        xsum += sdv.cieY*sdv.spec.cx;
                        ysum += sdv.cieY*sdv.spec.cy;
                    }
                }
                n = j*abp->nangles + i;
                bsdfarr[n] = sum / (double)npsamps;
                if (XZarr != NULL) {
                    XZarr[n][0] = xsum*sum/(npsamps*ysum);
                    XZarr[n][1] = (sum - xsum - ysum)*sum/(npsamps*ysum);
                }
            }
            if (rbf != NULL)
                free(rbf);
            prog_show((i+1.)/abp->nangles);
        }
                                                /* write out our matrix */
        cfp[CIE_Y] = open_component_file(CIE_Y);
        n = 0;
        for (j = 0; j < abp->nangles; j++) {
            for (i = 0; i < abp->nangles; i++, n++)
                fprintf(cfp[CIE_Y], "\t%.3e\n", bsdfarr[n]);
            fputc('\n', cfp[CIE_Y]);
        }
        prog_done();
        if (fclose(cfp[CIE_Y])) {
                fprintf(stderr, "%s: error writing Y output\n", progname);
                exit(1);
        }
        if (XZarr == NULL)                      /* no color? */
                return;
        cfp[CIE_X] = open_component_file(CIE_X);
        cfp[CIE_Z] = open_component_file(CIE_Z);
        n = 0;
        for (j = 0; j < abp->nangles; j++) {
            for (i = 0; i < abp->nangles; i++, n++) {
                fprintf(cfp[CIE_X], "\t%.3e\n", XZarr[n][0]);
                fprintf(cfp[CIE_Z], "\t%.3e\n", XZarr[n][1]);
            }
            fputc('\n', cfp[CIE_X]);
            fputc('\n', cfp[CIE_Z]);
        }
        free(XZarr);
        if (fclose(cfp[CIE_X]) || fclose(cfp[CIE_Z])) {
                fprintf(stderr, "%s: error writing X/Z output\n", progname);
                exit(1);
        }
}

#ifdef _WIN32
/* Execute wrapBSDF command (may never return) */
static int
wrap_up(void)
{
        char    cmd[8192];

        if (bsdf_manuf[0]) {
                add_wbsdf("-f", 1);
                strcpy(cmd, "m=");
                strcpy(cmd+2, bsdf_manuf);
                add_wbsdf(cmd, 0);
        }
        if (bsdf_name[0]) {
                add_wbsdf("-f", 1);
                strcpy(cmd, "n=");
                strcpy(cmd+2, bsdf_name);
                add_wbsdf(cmd, 0);
        }
        if (!convert_commandline(cmd, sizeof(cmd), wrapBSDF)) {
                fputs(progname, stderr);
                fputs(": command line too long in wrap_up()\n", stderr);
                return(1);
        }
        return(system(cmd));
}
#else
/* Execute wrapBSDF command (may never return) */
static int
wrap_up(void)
{
        char    buf[256];
        char    *compath = getpath((char *)wrapBSDF[0], getenv("PATH"), X_OK);

        if (compath == NULL) {
                fprintf(stderr, "%s: cannot locate %s\n", progname, wrapBSDF[0]);
                return(1);
        }
        if (bsdf_manuf[0]) {
                add_wbsdf("-f", 1);
                strcpy(buf, "m=");
                strcpy(buf+2, bsdf_manuf);
                add_wbsdf(buf, 0);
        }
        if (bsdf_name[0]) {
                add_wbsdf("-f", 1);
                strcpy(buf, "n=");
                strcpy(buf+2, bsdf_name);
                add_wbsdf(buf, 0);
        }
        execv(compath, wrapBSDF);       /* successful call never returns */
        perror(compath);
        return(1);
}
#endif

/* Read in BSDF and interpolate as Klems matrix representation */
int
main(int argc, char *argv[])
{
        int     dofwd = 0, dobwd = 1;
        char    buf[2048];
        char    *cp;
        int     i, na;

        progname = argv[0];
        esupport |= E_VARIABLE|E_FUNCTION|E_RCONST;
        esupport &= ~(E_INCHAN|E_OUTCHAN);
        scompile("PI:3.14159265358979323846", NULL, 0);
        biggerlib();
        for (i = 1; i < argc && (argv[i][0] == '-') | (argv[i][0] == '+'); i++)
                switch (argv[i][1]) {           /* get options */
                case 'n':
                        npsamps = atoi(argv[++i]);
                        if (npsamps <= 0)
                                goto userr;
                        break;
                case 'e':
                        scompile(argv[++i], NULL, 0);
                        single_plane_incident = 0;
                        break;
                case 'f':
                        if (!argv[i][2]) {
                                if (strchr(argv[++i], '=') != NULL) {
                                        add_wbsdf("-f", 1);
                                        add_wbsdf(argv[i], 1);
                                } else {
                                        fcompile(argv[i]);
                                        single_plane_incident = 0;
                                }
                        } else
                                dofwd = (argv[i][0] == '+');
                        break;
                case 'b':
                        dobwd = (argv[i][0] == '+');
                        break;
                case 'h':
                        kbasis = klems_half;
                        add_wbsdf("-a", 1);
                        add_wbsdf("kh", 1);
                        break;
                case 'q':
                        kbasis = klems_quarter;
                        add_wbsdf("-a", 1);
                        add_wbsdf("kq", 1);
                        break;
                case 'l':
                        lobe_lim = atoi(argv[++i]);
                        break;
                case 'p':
                        do_prog = atoi(argv[i]+2);
                        break;
                case 'C':
                        add_wbsdf(argv[i], 1);
                        add_wbsdf(argv[++i], 1);
                        break;
                default:
                        goto userr;
                }
        if (kbasis == klems_full) {             /* default (full) basis? */
                add_wbsdf("-a", 1);
                add_wbsdf("kf", 1);
        }
        strcpy(buf, "File produced by: ");
        if (convert_commandline(buf+18, sizeof(buf)-18, argv) != NULL) {
                add_wbsdf("-C", 1); add_wbsdf(buf, 0);
        }
        if (single_plane_incident >= 0) {       /* function-based BSDF? */
                if (i != argc-1 || fundefined(argv[i]) < 3) {
                        fprintf(stderr,
        "%s: need single function with 6 arguments: bsdf(ix,iy,iz,ox,oy,oz)\n",
                                        progname);
                        fprintf(stderr, "\tor 3 arguments using Dx,Dy,Dz: bsdf(ix,iy,iz)\n");
                        goto userr;
                }
                ++eclock;
                if (dofwd) {
                        input_orient = -1;
                        output_orient = -1;
                        prog_start("Evaluating outside reflectance");
                        eval_function(argv[i]);
                        output_orient = 1;
                        prog_start("Evaluating outside->inside transmission");
                        eval_function(argv[i]);
                }
                if (dobwd) {
                        input_orient = 1;
                        output_orient = 1;
                        prog_start("Evaluating inside reflectance");
                        eval_function(argv[i]);
                        output_orient = -1;
                        prog_start("Evaluating inside->outside transmission");
                        eval_function(argv[i]);
                }
                return(wrap_up());
        }
                                                /* XML input? */
        if (i == argc-1 && (cp = argv[i]+strlen(argv[i])-4) > argv[i] &&
                                !strcasecmp(cp, ".xml")) {
                eval_bsdf(argv[i]);             /* load & resample BSDF */
                return(wrap_up());
        }
        if (i < argc) {                         /* open input files if given */
                int     nbsdf = 0;
                for ( ; i < argc; i++) {        /* interpolate each component */
                        char    pbuf[256];
                        FILE    *fpin = fopen(argv[i], "rb");
                        if (fpin == NULL) {
                                fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
                                                progname, argv[i]);
                                return(1);
                        }
                        if (!load_bsdf_rep(fpin))
                                return(1);
                        fclose(fpin);
                        sprintf(pbuf, "Interpolating component '%s'", argv[i]);
                        prog_start(pbuf);
                        eval_rbf();
                }
                return(wrap_up());
        }
        SET_FILE_BINARY(stdin);                 /* load from stdin */
        if (!load_bsdf_rep(stdin))
                return(1);
        prog_start("Interpolating from standard input");
        eval_rbf();                             /* resample dist. */
        return(wrap_up());
userr:
        fprintf(stderr,
        "Usage: %s [-n spp][-h|-q][-l maxlobes] [bsdf.sir ..] > bsdf.xml\n", progname);
        fprintf(stderr,
        "   or: %s [-n spp][-h|-q] bsdf_in.xml > bsdf_out.xml\n", progname);
        fprintf(stderr,
        "   or: %s [-n spp][-h|-q][{+|-}for[ward]][{+|-}b[ackward]][-e expr][-f file] bsdf_func > bsdf.xml\n",
                                progname);
        return(1);
}
Revision:	2.20
Committed:	Wed Feb 3 01:57:06 2016 UTC (8 years, 3 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.19:	+361 -173 lines
Log Message:	Added tristimulus color support for RBF and XML input