src/cv/bsdf2klems.c

#ifndef lint
static const char RCSid[] = "$Id: bsdf2klems.c,v 2.9 2013/08/11 14:32:34 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 "calcomp.h"
#include "bsdfrep.h"
#include "bsdf_m.h"
                                /* assumed maximum # Klems patches */
#define MAXPATCHES      145
                                /* global argv[0] */
char                    *progname;
                                /* selected basis function name */
static const char       *kbasis = "LBNL/Klems Full";
                                /* number of BSDF samples per patch */
static int              npsamps = 256;
                                /* limit on number of RBF lobes */
static int              lobe_lim = 15000;

/* Return angle basis corresponding to the given name */
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;
}

/* Output XML header to stdout */
static void
xml_header(int ac, char *av[])
{
        puts("<?xml version=\"1.0\" encoding=\"UTF-8\"?>");
        puts("<WindowElement xmlns=\"http://windows.lbl.gov\" xmlns:xsi=\"http://www.w3.org/2001/XMLSchema-instance\" xsi:schemaLocation=\"http://windows.lbl.gov/BSDF-v1.4.xsd\">");
        fputs("<!-- File produced by:", stdout);
        while (ac-- > 0) {
                fputc(' ', stdout);
                fputs(*av++, stdout);
        }
        puts(" -->");
}

/* Output XML prologue to stdout */
static void
xml_prologue(const SDData *sd)
{
        const char      *matn = (sd && sd->matn[0]) ? sd->matn : "Name";
        const char      *makr = (sd && sd->makr[0]) ? sd->makr : "Manufacturer";
        ANGLE_BASIS     *abp = get_basis(kbasis);
        int             i;

        if (abp == NULL) {
                fprintf(stderr, "%s: unknown angle basis '%s'\n", progname, kbasis);
                exit(1);
        }
        puts("<WindowElementType>System</WindowElementType>");
        puts("<FileType>BSDF</FileType>");
        puts("<Optical>");
        puts("<Layer>");
        puts("\t<Material>");
        printf("\t\t<Name>%s</Name>\n", matn);
        printf("\t\t<Manufacturer>%s</Manufacturer>\n", makr);
        if (sd && sd->dim[2] > .001) {
                printf("\t\t<Thickness unit=\"meter\">%.3f</Thickness>\n", sd->dim[2]);
                printf("\t\t<Width unit=\"meter\">%.3f</Width>\n", sd->dim[0]);
                printf("\t\t<Height unit=\"meter\">%.3f</Height>\n", sd->dim[1]);
        }
        puts("\t\t<DeviceType>Other</DeviceType>");
        puts("\t</Material>");
        if (sd && sd->mgf != NULL) {
                puts("\t<Geometry format=\"MGF\">");
                puts("\t\t<MGFblock unit=\"meter\">");
                fputs(sd->mgf, stdout);
                puts("</MGFblock>");
                puts("\t</Geometry>");
        }
        puts("\t<DataDefinition>");
        puts("\t\t<IncidentDataStructure>Columns</IncidentDataStructure>");
        puts("\t\t<AngleBasis>");
        printf("\t\t\t<AngleBasisName>%s</AngleBasisName>\n", kbasis);
        for (i = 0; abp->lat[i].nphis; i++) {
                puts("\t\t\t<AngleBasisBlock>");
                printf("\t\t\t<Theta>%g</Theta>\n", i ?
                                .5*(abp->lat[i].tmin + abp->lat[i+1].tmin) :
                                .0 );
                printf("\t\t\t<nPhis>%d</nPhis>\n", abp->lat[i].nphis);
                puts("\t\t\t<ThetaBounds>");
                printf("\t\t\t\t<LowerTheta>%g</LowerTheta>\n", abp->lat[i].tmin);
                printf("\t\t\t\t<UpperTheta>%g</UpperTheta>\n", abp->lat[i+1].tmin);
                puts("\t\t\t</ThetaBounds>");
                puts("\t\t\t</AngleBasisBlock>");
        }
        puts("\t\t</AngleBasis>");
        puts("\t</DataDefinition>");
}

/* Output XML data prologue to stdout */
static void
data_prologue()
{
        static const char       *bsdf_type[4] = {
                                        "Reflection Front",
                                        "Transmission Front",
                                        "Transmission Back",
                                        "Reflection Back"
                                };

        puts("\t<WavelengthData>");
        puts("\t\t<LayerNumber>System</LayerNumber>");
        puts("\t\t<Wavelength unit=\"Integral\">Visible</Wavelength>");
        puts("\t\t<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>");
        puts("\t\t<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>");
        puts("\t\t<WavelengthDataBlock>");
        printf("\t\t\t<WavelengthDataDirection>%s</WavelengthDataDirection>\n",
                        bsdf_type[(input_orient>0)<<1 | (output_orient>0)]);
        printf("\t\t\t<ColumnAngleBasis>%s</ColumnAngleBasis>\n", kbasis);
        printf("\t\t\t<RowAngleBasis>%s</RowAngleBasis>\n", kbasis);
        puts("\t\t\t<ScatteringDataType>BTDF</ScatteringDataType>");
        puts("\t\t\t<ScatteringData>");
}

/* Output XML data epilogue to stdout */
static void
data_epilogue(void)
{
        puts("\t\t\t</ScatteringData>");
        puts("\t\t</WavelengthDataBlock>");
        puts("\t</WavelengthData>");
}

/* Output XML epilogue to stdout */
static void
xml_epilogue(void)
{
        puts("</Layer>");
        puts("</Optical>");
        puts("</WindowElement>");
}

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

        SDclearBSDF(&bsd, fname);               /* load BSDF file */
        if ((ec = SDloadFile(&bsd, fname)) != SDEnone)
                goto err;
        xml_prologue(&bsd);                     /* pass geometry */
                                                /* front reflection */
        if (bsd.rf != NULL || bsd.rLambFront.cieY > .002) {
            input_orient = 1; output_orient = 1;
            data_prologue();
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;                    /* average over patches */
                    for (n = npsamps; n-- > 0; ) {
                        fo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        fi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sv.cieY;
                    }
                    printf("\t%.3e\n", sum/npsamps);
                }
                putchar('\n');                  /* extra space between rows */
            }
            data_epilogue();
        }
                                                /* back reflection */
        if (bsd.rb != NULL || bsd.rLambBack.cieY > .002) {
            input_orient = -1; output_orient = -1;
            data_prologue();
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;                    /* average over patches */
                    for (n = npsamps; n-- > 0; ) {
                        bo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        bi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sv.cieY;
                    }
                    printf("\t%.3e\n", sum/npsamps);
                }
                putchar('\n');                  /* extra space between rows */
            }
            data_epilogue();
        }
                                                /* front transmission */
        if (bsd.tf != NULL || bsd.tLamb.cieY > .002) {
            input_orient = 1; output_orient = -1;
            data_prologue();
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;                    /* average over patches */
                    for (n = npsamps; n-- > 0; ) {
                        bo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        fi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sv.cieY;
                    }
                    printf("\t%.3e\n", sum/npsamps);
                }
                putchar('\n');                  /* extra space between rows */
            }
            data_epilogue();
        }
                                                /* back transmission */
        if ((bsd.tb != NULL) | (bsd.tf != NULL)) {
            input_orient = -1; output_orient = 1;
            data_prologue();
            for (j = 0; j < abp->nangles; j++) {
                for (i = 0; i < abp->nangles; i++) {
                    sum = 0;            /* average over patches */
                    for (n = npsamps; n-- > 0; ) {
                        fo_getvec(vout, j+(n+frandom())/npsamps, abp);
                        bi_getvec(vin, i+urand(n), abp);
                        ec = SDevalBSDF(&sv, vout, vin, &bsd);
                        if (ec != SDEnone)
                                goto err;
                        sum += sv.cieY;
                    }
                    printf("\t%.3e\n", sum/npsamps);
                }
                putchar('\n');                  /* extra space between rows */
            }
            data_epilogue();
        }
        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);
        double          iovec[6];
        double          sum;
        int             i, j, n;

        initurand(npsamps);
        data_prologue();                        /* begin output */
        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);
                }
                printf("\t%.3e\n", sum/npsamps);
            }
            putchar('\n');
        }
        data_epilogue();                        /* finish output */
}

/* Interpolate and output a radial basis function BSDF representation */
static void
eval_rbf(void)
{
        ANGLE_BASIS     *abp = get_basis(kbasis);
        float           bsdfarr[MAXPATCHES*MAXPATCHES];
        FVECT           vin, vout;
        RBFNODE         *rbf;
        double          sum;
        int             i, j, n;
                                                /* sanity check */
        if (abp->nangles > MAXPATCHES) {
                fprintf(stderr, "%s: too many patches!\n", progname);
                exit(1);
        }
        data_prologue();                        /* begin output */
        for (i = 0; i < abp->nangles; i++) {
            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 */
                for (n = npsamps; n--; ) {
                    if (output_orient > 0)
                        fo_getvec(vout, j+(n+frandom())/npsamps, abp);
                    else
                        bo_getvec(vout, j+(n+frandom())/npsamps, abp);

                    sum += eval_rbfrep(rbf, vout) / vout[2];
                }
                bsdfarr[j*abp->nangles + i] = sum*output_orient/npsamps;
            }
            if (rbf != NULL)
                free(rbf);
        }
        n = 0;                                  /* write out our matrix */
        for (j = 0; j < abp->nangles; j++) {
            for (i = 0; i < abp->nangles; i++)
                printf("\t%.3e\n", bsdfarr[n++]);
            putchar('\n');
        }
        data_epilogue();                        /* finish output */
}

/* Read in BSDF and interpolate as Klems matrix representation */
int
main(int argc, char *argv[])
{
        int     dofwd = 0, dobwd = 1;
        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]) {
                                fcompile(argv[++i]);
                                single_plane_incident = 0;
                        } else
                                dofwd = (argv[i][0] == '+');
                        break;
                case 'b':
                        dobwd = (argv[i][0] == '+');
                        break;
                case 'h':
                        kbasis = "LBNL/Klems Half";
                        break;
                case 'q':
                        kbasis = "LBNL/Klems Quarter";
                        break;
                case 'l':
                        lobe_lim = atoi(argv[++i]);
                        break;
                default:
                        goto userr;
                }
        if (single_plane_incident >= 0) {       /* function-based BSDF? */
                if (i != argc-1 || fundefined(argv[i]) != 6) {
                        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",
                                        progname);
                        goto userr;
                }
                ++eclock;
                xml_header(argc, argv);                 /* start XML output */
                xml_prologue(NULL);
                if (dofwd) {
                        input_orient = -1;
                        output_orient = -1;
                        eval_function(argv[i]);         /* outside reflectance */
                        output_orient = 1;
                        eval_function(argv[i]);         /* outside -> inside */
                }
                if (dobwd) {
                        input_orient = 1;
                        output_orient = 1;
                        eval_function(argv[i]);         /* inside reflectance */
                        output_orient = -1;
                        eval_function(argv[i]);         /* inside -> outside */
                }
                xml_epilogue();                 /* finish XML output & exit */
                return(0);
        }
                                                /* XML input? */
        if (i == argc-1 && (cp = argv[i]+strlen(argv[i])-4) > argv[i] &&
                                !strcasecmp(cp, ".xml")) {
                xml_header(argc, argv);         /* start XML output */
                eval_bsdf(argv[i]);             /* load & resample BSDF */
                xml_epilogue();                 /* finish XML output & exit */
                return(0);
        }
        if (i < argc) {                         /* open input files if given */
                int     nbsdf = 0;
                for ( ; i < argc; i++) {        /* interpolate each component */
                        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);
                        if (!nbsdf++) {         /* start XML on first dist. */
                                xml_header(argc, argv);
                                xml_prologue(NULL);
                        }
                        eval_rbf();
                }
                xml_epilogue();                 /* finish XML output & exit */
                return(0);
        }
        SET_FILE_BINARY(stdin);                 /* load from stdin */
        if (!load_bsdf_rep(stdin))
                return(1);
        xml_header(argc, argv);                 /* start XML output */
        xml_prologue(NULL);
        eval_rbf();                             /* resample dist. */
        xml_epilogue();                         /* finish XML output & exit */
        return(0);
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:	2.10
Committed:	Thu Sep 26 17:05:00 2013 UTC (12 years, 1 month ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.9:	+8 -3 lines
Log Message:	Added -l option to limit maximum number of RBF lobes for interpolation
#	User	Rev	Content
1	greg	2.1	#ifndef lint
2	greg	2.10	static const char RCSid[] = "$Id: bsdf2klems.c,v 2.9 2013/08/11 14:32:34 greg Exp $";
3	greg	2.1	#endif
4			/*
5			* Load measured BSDF interpolant and write out as XML file with Klems matrix.
6			*
7			* G. Ward
8			*/
9
10			#define _USE_MATH_DEFINES
11			#include <stdio.h>
12			#include <stdlib.h>
13			#include <string.h>
14			#include <math.h>
15			#include "random.h"
16			#include "platform.h"
17			#include "calcomp.h"
18			#include "bsdfrep.h"
19			#include "bsdf_m.h"
20	greg	2.4	/* assumed maximum # Klems patches */
21			#define MAXPATCHES 145
22	greg	2.1	/* global argv[0] */
23			char *progname;
24			/* selected basis function name */
25			static const char *kbasis = "LBNL/Klems Full";
26			/* number of BSDF samples per patch */
27			static int npsamps = 256;
28	greg	2.10	/* limit on number of RBF lobes */
29			static int lobe_lim = 15000;
30	greg	2.1
31			/* Return angle basis corresponding to the given name */
32			ANGLE_BASIS *
33			get_basis(const char *bn)
34			{
35			int n = nabases;
36
37			while (n-- > 0)
38			if (!strcasecmp(bn, abase_list[n].name))
39			return &abase_list[n];
40			return NULL;
41			}
42
43	greg	2.3	/* Output XML header to stdout */
44			static void
45			xml_header(int ac, char *av[])
46			{
47			puts("<?xml version=\"1.0\" encoding=\"UTF-8\"?>");
48			puts("<WindowElement xmlns=\"http://windows.lbl.gov\" xmlns:xsi=\"http://www.w3.org/2001/XMLSchema-instance\" xsi:schemaLocation=\"http://windows.lbl.gov/BSDF-v1.4.xsd\">");
49			fputs("<!-- File produced by:", stdout);
50			while (ac-- > 0) {
51			fputc(' ', stdout);
52			fputs(*av++, stdout);
53			}
54			puts(" -->");
55			}
56
57	greg	2.1	/* Output XML prologue to stdout */
58			static void
59	greg	2.3	xml_prologue(const SDData *sd)
60	greg	2.1	{
61	greg	2.3	const char *matn = (sd && sd->matn[0]) ? sd->matn : "Name";
62			const char *makr = (sd && sd->makr[0]) ? sd->makr : "Manufacturer";
63	greg	2.1	ANGLE_BASIS *abp = get_basis(kbasis);
64			int i;
65
66			if (abp == NULL) {
67			fprintf(stderr, "%s: unknown angle basis '%s'\n", progname, kbasis);
68			exit(1);
69			}
70			puts("<WindowElementType>System</WindowElementType>");
71			puts("<FileType>BSDF</FileType>");
72			puts("<Optical>");
73			puts("<Layer>");
74			puts("\t<Material>");
75	greg	2.3	printf("\t\t<Name>%s</Name>\n", matn);
76			printf("\t\t<Manufacturer>%s</Manufacturer>\n", makr);
77			if (sd && sd->dim[2] > .001) {
78			printf("\t\t<Thickness unit=\"meter\">%.3f</Thickness>\n", sd->dim[2]);
79			printf("\t\t<Width unit=\"meter\">%.3f</Width>\n", sd->dim[0]);
80			printf("\t\t<Height unit=\"meter\">%.3f</Height>\n", sd->dim[1]);
81			}
82	greg	2.1	puts("\t\t<DeviceType>Other</DeviceType>");
83			puts("\t</Material>");
84	greg	2.3	if (sd && sd->mgf != NULL) {
85			puts("\t<Geometry format=\"MGF\">");
86			puts("\t\t<MGFblock unit=\"meter\">");
87			fputs(sd->mgf, stdout);
88			puts("</MGFblock>");
89			puts("\t</Geometry>");
90			}
91	greg	2.1	puts("\t<DataDefinition>");
92			puts("\t\t<IncidentDataStructure>Columns</IncidentDataStructure>");
93			puts("\t\t<AngleBasis>");
94			printf("\t\t\t<AngleBasisName>%s</AngleBasisName>\n", kbasis);
95			for (i = 0; abp->lat[i].nphis; i++) {
96			puts("\t\t\t<AngleBasisBlock>");
97			printf("\t\t\t<Theta>%g</Theta>\n", i ?
98			.5*(abp->lat[i].tmin + abp->lat[i+1].tmin) :
99			.0 );
100	greg	2.3	printf("\t\t\t<nPhis>%d</nPhis>\n", abp->lat[i].nphis);
101	greg	2.1	puts("\t\t\t<ThetaBounds>");
102			printf("\t\t\t\t<LowerTheta>%g</LowerTheta>\n", abp->lat[i].tmin);
103			printf("\t\t\t\t<UpperTheta>%g</UpperTheta>\n", abp->lat[i+1].tmin);
104			puts("\t\t\t</ThetaBounds>");
105			puts("\t\t\t</AngleBasisBlock>");
106			}
107			puts("\t\t</AngleBasis>");
108			puts("\t</DataDefinition>");
109			}
110
111			/* Output XML data prologue to stdout */
112			static void
113			data_prologue()
114			{
115			static const char *bsdf_type[4] = {
116			"Reflection Front",
117			"Transmission Front",
118			"Transmission Back",
119			"Reflection Back"
120			};
121
122			puts("\t<WavelengthData>");
123			puts("\t\t<LayerNumber>System</LayerNumber>");
124			puts("\t\t<Wavelength unit=\"Integral\">Visible</Wavelength>");
125			puts("\t\t<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>");
126			puts("\t\t<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>");
127			puts("\t\t<WavelengthDataBlock>");
128			printf("\t\t\t<WavelengthDataDirection>%s</WavelengthDataDirection>\n",
129			bsdf_type[(input_orient>0)<<1 \| (output_orient>0)]);
130			printf("\t\t\t<ColumnAngleBasis>%s</ColumnAngleBasis>\n", kbasis);
131			printf("\t\t\t<RowAngleBasis>%s</RowAngleBasis>\n", kbasis);
132			puts("\t\t\t<ScatteringDataType>BTDF</ScatteringDataType>");
133			puts("\t\t\t<ScatteringData>");
134			}
135
136			/* Output XML data epilogue to stdout */
137			static void
138			data_epilogue(void)
139			{
140			puts("\t\t\t</ScatteringData>");
141			puts("\t\t</WavelengthDataBlock>");
142			puts("\t</WavelengthData>");
143			}
144
145			/* Output XML epilogue to stdout */
146			static void
147			xml_epilogue(void)
148			{
149			puts("</Layer>");
150			puts("</Optical>");
151			puts("</WindowElement>");
152			}
153
154	greg	2.2	/* Load and resample XML BSDF description using Klems basis */
155	greg	2.1	static void
156			eval_bsdf(const char *fname)
157			{
158			ANGLE_BASIS *abp = get_basis(kbasis);
159			SDData bsd;
160			SDError ec;
161			FVECT vin, vout;
162			SDValue sv;
163			double sum;
164			int i, j, n;
165
166			SDclearBSDF(&bsd, fname); /* load BSDF file */
167			if ((ec = SDloadFile(&bsd, fname)) != SDEnone)
168			goto err;
169	greg	2.3	xml_prologue(&bsd); /* pass geometry */
170	greg	2.1	/* front reflection */
171			if (bsd.rf != NULL \|\| bsd.rLambFront.cieY > .002) {
172			input_orient = 1; output_orient = 1;
173			data_prologue();
174			for (j = 0; j < abp->nangles; j++) {
175			for (i = 0; i < abp->nangles; i++) {
176			sum = 0; /* average over patches */
177			for (n = npsamps; n-- > 0; ) {
178			fo_getvec(vout, j+(n+frandom())/npsamps, abp);
179	greg	2.5	fi_getvec(vin, i+urand(n), abp);
180	greg	2.1	ec = SDevalBSDF(&sv, vout, vin, &bsd);
181			if (ec != SDEnone)
182			goto err;
183			sum += sv.cieY;
184			}
185			printf("\t%.3e\n", sum/npsamps);
186			}
187			putchar('\n'); /* extra space between rows */
188			}
189			data_epilogue();
190			}
191			/* back reflection */
192			if (bsd.rb != NULL \|\| bsd.rLambBack.cieY > .002) {
193			input_orient = -1; output_orient = -1;
194			data_prologue();
195			for (j = 0; j < abp->nangles; j++) {
196			for (i = 0; i < abp->nangles; i++) {
197			sum = 0; /* average over patches */
198			for (n = npsamps; n-- > 0; ) {
199			bo_getvec(vout, j+(n+frandom())/npsamps, abp);
200	greg	2.5	bi_getvec(vin, i+urand(n), abp);
201	greg	2.1	ec = SDevalBSDF(&sv, vout, vin, &bsd);
202			if (ec != SDEnone)
203			goto err;
204			sum += sv.cieY;
205			}
206			printf("\t%.3e\n", sum/npsamps);
207			}
208			putchar('\n'); /* extra space between rows */
209			}
210			data_epilogue();
211			}
212			/* front transmission */
213			if (bsd.tf != NULL \|\| bsd.tLamb.cieY > .002) {
214			input_orient = 1; output_orient = -1;
215			data_prologue();
216			for (j = 0; j < abp->nangles; j++) {
217			for (i = 0; i < abp->nangles; i++) {
218			sum = 0; /* average over patches */
219			for (n = npsamps; n-- > 0; ) {
220			bo_getvec(vout, j+(n+frandom())/npsamps, abp);
221	greg	2.5	fi_getvec(vin, i+urand(n), abp);
222	greg	2.1	ec = SDevalBSDF(&sv, vout, vin, &bsd);
223			if (ec != SDEnone)
224			goto err;
225			sum += sv.cieY;
226			}
227			printf("\t%.3e\n", sum/npsamps);
228			}
229			putchar('\n'); /* extra space between rows */
230			}
231			data_epilogue();
232			}
233			/* back transmission */
234	greg	2.9	if ((bsd.tb != NULL) \| (bsd.tf != NULL)) {
235	greg	2.1	input_orient = -1; output_orient = 1;
236			data_prologue();
237			for (j = 0; j < abp->nangles; j++) {
238	greg	2.9	for (i = 0; i < abp->nangles; i++) {
239			sum = 0; /* average over patches */
240			for (n = npsamps; n-- > 0; ) {
241			fo_getvec(vout, j+(n+frandom())/npsamps, abp);
242			bi_getvec(vin, i+urand(n), abp);
243			ec = SDevalBSDF(&sv, vout, vin, &bsd);
244			if (ec != SDEnone)
245	greg	2.1	goto err;
246	greg	2.9	sum += sv.cieY;
247	greg	2.1	}
248	greg	2.9	printf("\t%.3e\n", sum/npsamps);
249			}
250	greg	2.1	putchar('\n'); /* extra space between rows */
251			}
252			data_epilogue();
253			}
254			SDfreeBSDF(&bsd); /* all done */
255			return;
256			err:
257			SDreportError(ec, stderr);
258			exit(1);
259			}
260
261	greg	2.2	/* Interpolate and output a BSDF function using Klems basis */
262	greg	2.1	static void
263			eval_function(char *funame)
264			{
265			ANGLE_BASIS *abp = get_basis(kbasis);
266	greg	2.8	int assignD = (fundefined(funame) < 6);
267	greg	2.1	double iovec[6];
268			double sum;
269			int i, j, n;
270
271	greg	2.4	initurand(npsamps);
272	greg	2.1	data_prologue(); /* begin output */
273			for (j = 0; j < abp->nangles; j++) { /* run through directions */
274			for (i = 0; i < abp->nangles; i++) {
275			sum = 0;
276			for (n = npsamps; n--; ) { /* average over patches */
277			if (output_orient > 0)
278			fo_getvec(iovec+3, j+(n+frandom())/npsamps, abp);
279			else
280			bo_getvec(iovec+3, j+(n+frandom())/npsamps, abp);
281
282			if (input_orient > 0)
283	greg	2.4	fi_getvec(iovec, i+urand(n), abp);
284	greg	2.1	else
285	greg	2.4	bi_getvec(iovec, i+urand(n), abp);
286	greg	2.1
287	greg	2.8	if (assignD) {
288			varset("Dx", '=', -iovec[3]);
289			varset("Dy", '=', -iovec[4]);
290			varset("Dz", '=', -iovec[5]);
291			++eclock;
292			}
293	greg	2.1	sum += funvalue(funame, 6, iovec);
294			}
295			printf("\t%.3e\n", sum/npsamps);
296			}
297			putchar('\n');
298			}
299			data_epilogue(); /* finish output */
300			}
301
302			/* Interpolate and output a radial basis function BSDF representation */
303			static void
304			eval_rbf(void)
305			{
306			ANGLE_BASIS *abp = get_basis(kbasis);
307	greg	2.2	float bsdfarr[MAXPATCHES*MAXPATCHES];
308			FVECT vin, vout;
309			RBFNODE *rbf;
310	greg	2.1	double sum;
311			int i, j, n;
312	greg	2.2	/* sanity check */
313			if (abp->nangles > MAXPATCHES) {
314			fprintf(stderr, "%s: too many patches!\n", progname);
315			exit(1);
316			}
317			data_prologue(); /* begin output */
318			for (i = 0; i < abp->nangles; i++) {
319			if (input_orient > 0) /* use incident patch center */
320			fi_getvec(vin, i+.5*(i>0), abp);
321			else
322			bi_getvec(vin, i+.5*(i>0), abp);
323
324	greg	2.10	rbf = advect_rbf(vin, lobe_lim); /* compute radial basis func */
325	greg	2.2
326			for (j = 0; j < abp->nangles; j++) {
327			sum = 0; /* sample over exiting patch */
328			for (n = npsamps; n--; ) {
329			if (output_orient > 0)
330			fo_getvec(vout, j+(n+frandom())/npsamps, abp);
331			else
332			bo_getvec(vout, j+(n+frandom())/npsamps, abp);
333	greg	2.1
334	greg	2.2	sum += eval_rbfrep(rbf, vout) / vout[2];
335			}
336			bsdfarr[jabp->nangles + i] = sumoutput_orient/npsamps;
337			}
338	greg	2.6	if (rbf != NULL)
339			free(rbf);
340	greg	2.2	}
341			n = 0; /* write out our matrix */
342			for (j = 0; j < abp->nangles; j++) {
343			for (i = 0; i < abp->nangles; i++)
344			printf("\t%.3e\n", bsdfarr[n++]);
345			putchar('\n');
346			}
347			data_epilogue(); /* finish output */
348	greg	2.1	}
349
350			/* Read in BSDF and interpolate as Klems matrix representation */
351			int
352			main(int argc, char *argv[])
353			{
354			int dofwd = 0, dobwd = 1;
355			char *cp;
356			int i, na;
357
358			progname = argv[0];
359			esupport \|= E_VARIABLE\|E_FUNCTION\|E_RCONST;
360			esupport &= ~(E_INCHAN\|E_OUTCHAN);
361			scompile("PI:3.14159265358979323846", NULL, 0);
362			biggerlib();
363	greg	2.2	for (i = 1; i < argc && (argv[i][0] == '-') \| (argv[i][0] == '+'); i++)
364	greg	2.1	switch (argv[i][1]) { /* get options */
365			case 'n':
366			npsamps = atoi(argv[++i]);
367			if (npsamps <= 0)
368			goto userr;
369			break;
370			case 'e':
371			scompile(argv[++i], NULL, 0);
372			single_plane_incident = 0;
373			break;
374			case 'f':
375			if (!argv[i][2]) {
376			fcompile(argv[++i]);
377			single_plane_incident = 0;
378			} else
379			dofwd = (argv[i][0] == '+');
380			break;
381			case 'b':
382			dobwd = (argv[i][0] == '+');
383			break;
384			case 'h':
385			kbasis = "LBNL/Klems Half";
386			break;
387			case 'q':
388			kbasis = "LBNL/Klems Quarter";
389			break;
390	greg	2.10	case 'l':
391			lobe_lim = atoi(argv[++i]);
392			break;
393	greg	2.1	default:
394			goto userr;
395			}
396			if (single_plane_incident >= 0) { /* function-based BSDF? */
397			if (i != argc-1 \|\| fundefined(argv[i]) != 6) {
398			fprintf(stderr,
399			"%s: need single function with 6 arguments: bsdf(ix,iy,iz,ox,oy,oz)\n",
400			progname);
401	greg	2.8	fprintf(stderr, "\tor 3 arguments using Dx,Dy,Dz: bsdf(ix,iy,iz)\n",
402			progname);
403	greg	2.1	goto userr;
404			}
405	greg	2.8	++eclock;
406	greg	2.3	xml_header(argc, argv); /* start XML output */
407			xml_prologue(NULL);
408	greg	2.1	if (dofwd) {
409			input_orient = -1;
410			output_orient = -1;
411			eval_function(argv[i]); /* outside reflectance */
412			output_orient = 1;
413			eval_function(argv[i]); /* outside -> inside */
414			}
415			if (dobwd) {
416			input_orient = 1;
417			output_orient = 1;
418			eval_function(argv[i]); /* inside reflectance */
419			output_orient = -1;
420			eval_function(argv[i]); /* inside -> outside */
421			}
422			xml_epilogue(); /* finish XML output & exit */
423			return(0);
424			}
425	greg	2.2	/* XML input? */
426			if (i == argc-1 && (cp = argv[i]+strlen(argv[i])-4) > argv[i] &&
427			!strcasecmp(cp, ".xml")) {
428	greg	2.3	xml_header(argc, argv); /* start XML output */
429	greg	2.1	eval_bsdf(argv[i]); /* load & resample BSDF */
430			xml_epilogue(); /* finish XML output & exit */
431			return(0);
432			}
433			if (i < argc) { /* open input files if given */
434			int nbsdf = 0;
435			for ( ; i < argc; i++) { /* interpolate each component */
436			FILE *fpin = fopen(argv[i], "rb");
437			if (fpin == NULL) {
438			fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
439			progname, argv[i]);
440			return(1);
441			}
442			if (!load_bsdf_rep(fpin))
443			return(1);
444			fclose(fpin);
445	greg	2.3	if (!nbsdf++) { /* start XML on first dist. */
446			xml_header(argc, argv);
447			xml_prologue(NULL);
448			}
449	greg	2.1	eval_rbf();
450			}
451			xml_epilogue(); /* finish XML output & exit */
452			return(0);
453			}
454			SET_FILE_BINARY(stdin); /* load from stdin */
455			if (!load_bsdf_rep(stdin))
456			return(1);
457	greg	2.3	xml_header(argc, argv); /* start XML output */
458			xml_prologue(NULL);
459	greg	2.1	eval_rbf(); /* resample dist. */
460			xml_epilogue(); /* finish XML output & exit */
461			return(0);
462			userr:
463			fprintf(stderr,
464	greg	2.10	"Usage: %s [-n spp][-h\|-q][-l maxlobes] [bsdf.sir ..] > bsdf.xml\n", progname);
465	greg	2.1	fprintf(stderr,
466	greg	2.3	" or: %s [-n spp][-h\|-q] bsdf_in.xml > bsdf_out.xml\n", progname);
467	greg	2.1	fprintf(stderr,
468			" or: %s [-n spp][-h\|-q][{+\|-}for[ward]][{+\|-}b[ackward]][-e expr][-f file] bsdf_func > bsdf.xml\n",
469			progname);
470			return(1);
471			}