src/cv/bsdf2ttree.c

#ifndef lint
static const char RCSid[] = "$Id: bsdf2ttree.c,v 2.28 2014/03/24 03:50:28 greg Exp $";
#endif
/*
 * Load measured BSDF interpolant and write out as XML file with tensor tree.
 *
 *      G. Ward
 */

#define _USE_MATH_DEFINES
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include "random.h"
#include "platform.h"
#include "rtprocess.h"
#include "calcomp.h"
#include "bsdfrep.h"
                                /* global argv[0] */
char                    *progname;
                                /* percentage to cull (<0 to turn off) */
double                  pctcull = 90.;
                                /* sampling order */
int                     samp_order = 6;
                                /* super-sampling threshold */
const double            ssamp_thresh = 0.35;
                                /* number of super-samples */
#ifndef NSSAMP
#define NSSAMP          100
#endif
                                /* limit on number of RBF lobes */
static int              lobe_lim = 15000;
                                /* progress bar length */
static int              do_prog = 79;


/* 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)
{
        char    pbar[256];
        int     nchars;

        if (do_prog <= 0) return;
        if (do_prog > sizeof(pbar)-2)
                do_prog = sizeof(pbar)-2;
        if (frac < 0) frac = 0;
        else if (frac > 1) frac = 1;
        nchars = do_prog*frac + .5;
        pbar[0] = '\r';
        memset(pbar+1, '*', nchars);
        memset(pbar+1+nchars, '-', do_prog-nchars);
        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);
}

/* Output XML prologue to stdout */
static void
xml_prologue(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(" -->");
        puts("<WindowElementType>System</WindowElementType>");
        puts("<FileType>BSDF</FileType>");
        puts("<Optical>");
        puts("<Layer>");
        puts("\t<Material>");
        printf("\t\t<Name>%s</Name>\n", bsdf_name[0] ? bsdf_name : "Unknown");
        printf("\t\t<Manufacturer>%s</Manufacturer>\n",
                        bsdf_manuf[0] ? bsdf_manuf : "Unknown");
        puts("\t\t<DeviceType>Other</DeviceType>");
        puts("\t</Material>");
        puts("\t<DataDefinition>");
        printf("\t\t<IncidentDataStructure>TensorTree%c</IncidentDataStructure>\n",
                        single_plane_incident ? '3' : '4');
        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)]);
        puts("\t\t\t<AngleBasis>LBNL/Shirley-Chiu</AngleBasis>");
        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>");
}

/* Compute absolute relative difference */
static double
abs_diff(double v1, double v0)
{
        if ((v0 < 0) | (v1 < 0))
                return(.0);
        v1 = (v1-v0)*2./(v0+v1+.0001);
        if (v1 < 0)
                return(-v1);
        return(v1);
}

/* Interpolate and output isotropic BSDF data */
static void
eval_isotropic(char *funame)
{
        const int       sqres = 1<<samp_order;
        FILE            *ofp = NULL;
        int             assignD = 0;
        char            cmd[128];
        int             ix, ox, oy;
        double          iovec[6];
        float           bsdf;

        data_prologue();                        /* begin output */
        if (pctcull >= 0) {
                sprintf(cmd, "rttree_reduce -a -h -ff -r 3 -t %f -g %d",
                                pctcull, samp_order);
                fflush(stdout);
                ofp = popen(cmd, "w");
                if (ofp == NULL) {
                        fprintf(stderr, "%s: cannot create pipe to rttree_reduce\n",
                                        progname);
                        exit(1);
                }
                SET_FILE_BINARY(ofp);
#ifdef getc_unlocked                            /* avoid lock/unlock overhead */
                flockfile(ofp);
#endif
        } else
                fputs("{\n", stdout);
                                                /* need to assign Dx, Dy, Dz? */
        if (funame != NULL)
                assignD = (fundefined(funame) < 6);
                                                /* run through directions */
        for (ix = 0; ix < sqres/2; ix++) {
                RBFNODE *rbf = NULL;
                iovec[0] = 2.*(ix+.5)/sqres - 1.;
                iovec[1] = .0;
                iovec[2] = input_orient * sqrt(1. - iovec[0]*iovec[0]);
                if (funame == NULL)
                        rbf = advect_rbf(iovec, lobe_lim);
                for (ox = 0; ox < sqres; ox++) {
                    float       last_bsdf = -1;
                    for (oy = 0; oy < sqres; oy++) {
                        SDsquare2disk(iovec+3, (ox+.5)/sqres, (oy+.5)/sqres);
                        iovec[5] = output_orient *
                                sqrt(1. - iovec[3]*iovec[3] - iovec[4]*iovec[4]);
                        if (funame == NULL)
                            bsdf = eval_rbfrep(rbf, iovec+3);
                        else {
                            if (assignD) {
                                varset("Dx", '=', -iovec[3]);
                                varset("Dy", '=', -iovec[4]);
                                varset("Dz", '=', -iovec[5]);
                                ++eclock;
                            }
                            bsdf = funvalue(funame, 6, iovec);
#if (NSSAMP > 0)
                            if (abs_diff(bsdf, last_bsdf) > ssamp_thresh) {
                                int     ssi;
                                double  ssa[3], ssvec[6], sum = 0;
                                                /* super-sample voxel */
                                for (ssi = NSSAMP; ssi--; ) {
                                    SDmultiSamp(ssa, 3, (ssi+frandom()) *
                                                        (1./NSSAMP));
                                    ssvec[0] = 2.*(ix+ssa[0])/sqres - 1.;
                                    ssvec[1] = .0;
                                    ssvec[2] = input_orient *
                                                sqrt(1. - ssvec[0]*ssvec[0]);
                                    SDsquare2disk(ssvec+3, (ox+ssa[1])/sqres,
                                                (oy+ssa[2])/sqres);
                                    ssvec[5] = output_orient *
                                                sqrt(1. - ssvec[3]*ssvec[3] -
                                                        ssvec[4]*ssvec[4]);
                                    if (assignD) {
                                        varset("Dx", '=', -ssvec[3]);
                                        varset("Dy", '=', -ssvec[4]);
                                        varset("Dz", '=', -ssvec[5]);
                                        ++eclock;
                                    }
                                    sum += funvalue(funame, 6, ssvec);
                                }
                                bsdf = sum/NSSAMP;
                            }
#endif
                        }
                        if (pctcull >= 0)
                                fwrite(&bsdf, sizeof(bsdf), 1, ofp);
                        else
                                printf("\t%.3e\n", bsdf);
                        last_bsdf = bsdf;
                    }
                }
                if (rbf != NULL)
                        free(rbf);
                prog_show((ix+1.)*(2./sqres));
        }
        if (pctcull >= 0) {                     /* finish output */
                if (pclose(ofp)) {
                        fprintf(stderr, "%s: error running '%s'\n",
                                        progname, cmd);
                        exit(1);
                }
        } else {
                for (ix = sqres*sqres*sqres/2; ix--; )
                        fputs("\t0\n", stdout);
                fputs("}\n", stdout);
        }
        data_epilogue();
        prog_done();
}

/* Interpolate and output anisotropic BSDF data */
static void
eval_anisotropic(char *funame)
{
        const int       sqres = 1<<samp_order;
        FILE            *ofp = NULL;
        int             assignD = 0;
        char            cmd[128];
        int             ix, iy, ox, oy;
        double          iovec[6];
        float           bsdf;

        data_prologue();                        /* begin output */
        if (pctcull >= 0) {
                sprintf(cmd, "rttree_reduce%s -h -ff -r 4 -t %f -g %d",
                                (input_orient>0 ^ output_orient>0) ? "" : " -a",
                                pctcull, samp_order);
                fflush(stdout);
                ofp = popen(cmd, "w");
                if (ofp == NULL) {
                        fprintf(stderr, "%s: cannot create pipe to rttree_reduce\n",
                                        progname);
                        exit(1);
                }
                SET_FILE_BINARY(ofp);
#ifdef getc_unlocked                            /* avoid lock/unlock overhead */
                flockfile(ofp);
#endif
        } else
                fputs("{\n", stdout);
                                                /* need to assign Dx, Dy, Dz? */
        if (funame != NULL)
                assignD = (fundefined(funame) < 6);
                                                /* run through directions */
        for (ix = 0; ix < sqres; ix++)
            for (iy = 0; iy < sqres; iy++) {
                RBFNODE *rbf = NULL;            /* Klems reversal */
                SDsquare2disk(iovec, 1.-(ix+.5)/sqres, 1.-(iy+.5)/sqres);
                iovec[2] = input_orient *
                                sqrt(1. - iovec[0]*iovec[0] - iovec[1]*iovec[1]);
                if (funame == NULL)
                        rbf = advect_rbf(iovec, lobe_lim);
                for (ox = 0; ox < sqres; ox++) {
                    float       last_bsdf = -1;
                    for (oy = 0; oy < sqres; oy++) {
                        SDsquare2disk(iovec+3, (ox+.5)/sqres, (oy+.5)/sqres);
                        iovec[5] = output_orient *
                                sqrt(1. - iovec[3]*iovec[3] - iovec[4]*iovec[4]);
                        if (funame == NULL)
                            bsdf = eval_rbfrep(rbf, iovec+3);
                        else {
                            if (assignD) {
                                varset("Dx", '=', -iovec[3]);
                                varset("Dy", '=', -iovec[4]);
                                varset("Dz", '=', -iovec[5]);
                                ++eclock;
                            }
                            bsdf = funvalue(funame, 6, iovec);
#if (NSSAMP > 0)
                            if (abs_diff(bsdf, last_bsdf) > ssamp_thresh) {
                                int     ssi;
                                double  ssa[4], ssvec[6], sum = 0;
                                                /* super-sample voxel */
                                for (ssi = NSSAMP; ssi--; ) {
                                    SDmultiSamp(ssa, 4, (ssi+frandom()) *
                                                        (1./NSSAMP));
                                    SDsquare2disk(ssvec, 1.-(ix+ssa[0])/sqres,
                                                1.-(iy+ssa[1])/sqres);
                                    ssvec[2] = input_orient *
                                                sqrt(1. - ssvec[0]*ssvec[0] -
                                                        ssvec[1]*ssvec[1]);
                                    SDsquare2disk(ssvec+3, (ox+ssa[2])/sqres,
                                                (oy+ssa[3])/sqres);
                                    ssvec[5] = output_orient *
                                                sqrt(1. - ssvec[3]*ssvec[3] -
                                                        ssvec[4]*ssvec[4]);
                                    if (assignD) {
                                        varset("Dx", '=', -ssvec[3]);
                                        varset("Dy", '=', -ssvec[4]);
                                        varset("Dz", '=', -ssvec[5]);
                                        ++eclock;
                                    }
                                    sum += funvalue(funame, 6, ssvec);
                                }
                                bsdf = sum/NSSAMP;
                            }
#endif
                        }
                        if (pctcull >= 0)
                                fwrite(&bsdf, sizeof(bsdf), 1, ofp);
                        else
                                printf("\t%.3e\n", bsdf);
                        last_bsdf = bsdf;
                    }
                }
                if (rbf != NULL)
                        free(rbf);
                prog_show((ix*sqres+iy+1.)/(sqres*sqres));
            }
        if (pctcull >= 0) {                     /* finish output */
                if (pclose(ofp)) {
                        fprintf(stderr, "%s: error running '%s'\n",
                                        progname, cmd);
                        exit(1);
                }
        } else
                fputs("}\n", stdout);
        data_epilogue();
        prog_done();
}

/* Read in BSDF and interpolate as tensor tree representation */
int
main(int argc, char *argv[])
{
        int     dofwd = 0, dobwd = 1;
        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-1 && (argv[i][0] == '-') | (argv[i][0] == '+'); i++)
                switch (argv[i][1]) {           /* get options */
                case 'e':
                        scompile(argv[++i], NULL, 0);
                        break;
                case 'f':
                        if (!argv[i][2])
                                fcompile(argv[++i]);
                        else
                                dofwd = (argv[i][0] == '+');
                        break;
                case 'b':
                        dobwd = (argv[i][0] == '+');
                        break;
                case 't':
                        switch (argv[i][2]) {
                        case '3':
                                single_plane_incident = 1;
                                break;
                        case '4':
                                single_plane_incident = 0;
                                break;
                        case '\0':
                                pctcull = atof(argv[++i]);
                                break;
                        default:
                                goto userr;
                        }
                        break;
                case 'g':
                        samp_order = atoi(argv[++i]);
                        break;
                case 'l':
                        lobe_lim = atoi(argv[++i]);
                        break;
                case 'p':
                        do_prog = atoi(argv[i]+2);
                        break;
                default:
                        goto userr;
                }
        if (single_plane_incident >= 0) {       /* function-based BSDF? */
                void    (*evf)(char *s) = single_plane_incident ?
                                &eval_isotropic : &eval_anisotropic;
                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;
                xml_prologue(argc, argv);       /* start XML output */
                if (dofwd) {
                        input_orient = -1;
                        output_orient = -1;
                        prog_start("Evaluating outside reflectance");
                        (*evf)(argv[i]);
                        output_orient = 1;
                        prog_start("Evaluating outside->inside transmission");
                        (*evf)(argv[i]);
                }
                if (dobwd) {
                        input_orient = 1;
                        output_orient = 1;
                        prog_start("Evaluating inside reflectance");
                        (*evf)(argv[i]);
                        output_orient = -1;
                        prog_start("Evaluating inside->outside transmission");
                        (*evf)(argv[i]);
                }
                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 */
                        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);
                        if (!nbsdf++)           /* start XML on first dist. */
                                xml_prologue(argc, argv);
                        sprintf(pbuf, "Interpolating component '%s'", argv[i]);
                        prog_start(pbuf);
                        if (single_plane_incident)
                                eval_isotropic(NULL);
                        else
                                eval_anisotropic(NULL);
                }
                xml_epilogue();                 /* finish XML output & exit */
                return(0);
        }
        SET_FILE_BINARY(stdin);                 /* load from stdin */
        if (!load_bsdf_rep(stdin))
                return(1);
        xml_prologue(argc, argv);               /* start XML output */
        prog_start("Interpolating from standard input");
        if (single_plane_incident)              /* resample dist. */
                eval_isotropic(NULL);
        else
                eval_anisotropic(NULL);
        xml_epilogue();                         /* finish XML output & exit */
        return(0);
userr:
        fprintf(stderr,
        "Usage: %s [-g Nlog2][-t pctcull][-l maxlobes] [bsdf.sir ..] > bsdf.xml\n",
                                progname);
        fprintf(stderr,
        "   or: %s -t{3|4} [-g Nlog2][-t pctcull][{+|-}for[ward]][{+|-}b[ackward]][-e expr][-f file] bsdf_func > bsdf.xml\n",
                                progname);
        return(1);
}
Revision:	2.29
Committed:	Thu Aug 21 10:33:48 2014 UTC (11 years, 2 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad4R2P1, rad4R2P2
Changes since 2.28:	+3 -5 lines
Log Message:	Added grazing angle extrapolation to BSDF interpolation
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: bsdf2ttree.c,v 2.28 2014/03/24 03:50:28 greg Exp $";
3	#endif
4	/*
5	* Load measured BSDF interpolant and write out as XML file with tensor tree.
6	*
7	* G. Ward
8	*/
9
10	#define _USE_MATH_DEFINES
11	#include <stdio.h>
12	#include <stdlib.h>
13	#include <math.h>
14	#include "random.h"
15	#include "platform.h"
16	#include "rtprocess.h"
17	#include "calcomp.h"
18	#include "bsdfrep.h"
19	/* global argv[0] */
20	char *progname;
21	/* percentage to cull (<0 to turn off) */
22	double pctcull = 90.;
23	/* sampling order */
24	int samp_order = 6;
25	/* super-sampling threshold */
26	const double ssamp_thresh = 0.35;
27	/* number of super-samples */
28	#ifndef NSSAMP
29	#define NSSAMP 100
30	#endif
31	/* limit on number of RBF lobes */
32	static int lobe_lim = 15000;
33	/* progress bar length */
34	static int do_prog = 79;
35
36
37	/* Start new progress bar */
38	#define prog_start(s) if (do_prog) fprintf(stderr, "%s: %s...\n", progname, s); else
39
40	/* Draw progress bar of the appropriate length */
41	static void
42	prog_show(double frac)
43	{
44	char pbar[256];
45	int nchars;
46
47	if (do_prog <= 0) return;
48	if (do_prog > sizeof(pbar)-2)
49	do_prog = sizeof(pbar)-2;
50	if (frac < 0) frac = 0;
51	else if (frac > 1) frac = 1;
52	nchars = do_prog*frac + .5;
53	pbar[0] = '\r';
54	memset(pbar+1, '*', nchars);
55	memset(pbar+1+nchars, '-', do_prog-nchars);
56	pbar[do_prog+1] = '\0';
57	fputs(pbar, stderr);
58	}
59
60	/* Finish progress bar */
61	static void
62	prog_done(void)
63	{
64	int n = do_prog;
65
66	if (n <= 1) return;
67	fputc('\r', stderr);
68	while (n--)
69	fputc(' ', stderr);
70	fputc('\r', stderr);
71	}
72
73	/* Output XML prologue to stdout */
74	static void
75	xml_prologue(int ac, char *av[])
76	{
77	puts("<?xml version=\"1.0\" encoding=\"UTF-8\"?>");
78	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\">");
79	fputs("<!-- File produced by:", stdout);
80	while (ac-- > 0) {
81	fputc(' ', stdout);
82	fputs(*av++, stdout);
83	}
84	puts(" -->");
85	puts("<WindowElementType>System</WindowElementType>");
86	puts("<FileType>BSDF</FileType>");
87	puts("<Optical>");
88	puts("<Layer>");
89	puts("\t<Material>");
90	printf("\t\t<Name>%s</Name>\n", bsdf_name[0] ? bsdf_name : "Unknown");
91	printf("\t\t<Manufacturer>%s</Manufacturer>\n",
92	bsdf_manuf[0] ? bsdf_manuf : "Unknown");
93	puts("\t\t<DeviceType>Other</DeviceType>");
94	puts("\t</Material>");
95	puts("\t<DataDefinition>");
96	printf("\t\t<IncidentDataStructure>TensorTree%c</IncidentDataStructure>\n",
97	single_plane_incident ? '3' : '4');
98	puts("\t</DataDefinition>");
99	}
100
101	/* Output XML data prologue to stdout */
102	static void
103	data_prologue()
104	{
105	static const char *bsdf_type[4] = {
106	"Reflection Front",
107	"Transmission Front",
108	"Transmission Back",
109	"Reflection Back"
110	};
111
112	puts("\t<WavelengthData>");
113	puts("\t\t<LayerNumber>System</LayerNumber>");
114	puts("\t\t<Wavelength unit=\"Integral\">Visible</Wavelength>");
115	puts("\t\t<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>");
116	puts("\t\t<DetectorSpectrum>ASTM E308 1931 Y.dsp</DetectorSpectrum>");
117	puts("\t\t<WavelengthDataBlock>");
118	printf("\t\t\t<WavelengthDataDirection>%s</WavelengthDataDirection>\n",
119	bsdf_type[(input_orient>0)<<1 \| (output_orient>0)]);
120	puts("\t\t\t<AngleBasis>LBNL/Shirley-Chiu</AngleBasis>");
121	puts("\t\t\t<ScatteringDataType>BTDF</ScatteringDataType>");
122	puts("\t\t\t<ScatteringData>");
123	}
124
125	/* Output XML data epilogue to stdout */
126	static void
127	data_epilogue(void)
128	{
129	puts("\t\t\t</ScatteringData>");
130	puts("\t\t</WavelengthDataBlock>");
131	puts("\t</WavelengthData>");
132	}
133
134	/* Output XML epilogue to stdout */
135	static void
136	xml_epilogue(void)
137	{
138	puts("</Layer>");
139	puts("</Optical>");
140	puts("</WindowElement>");
141	}
142
143	/* Compute absolute relative difference */
144	static double
145	abs_diff(double v1, double v0)
146	{
147	if ((v0 < 0) \| (v1 < 0))
148	return(.0);
149	v1 = (v1-v0)*2./(v0+v1+.0001);
150	if (v1 < 0)
151	return(-v1);
152	return(v1);
153	}
154
155	/* Interpolate and output isotropic BSDF data */
156	static void
157	eval_isotropic(char *funame)
158	{
159	const int sqres = 1<<samp_order;
160	FILE *ofp = NULL;
161	int assignD = 0;
162	char cmd[128];
163	int ix, ox, oy;
164	double iovec[6];
165	float bsdf;
166
167	data_prologue(); /* begin output */
168	if (pctcull >= 0) {
169	sprintf(cmd, "rttree_reduce -a -h -ff -r 3 -t %f -g %d",
170	pctcull, samp_order);
171	fflush(stdout);
172	ofp = popen(cmd, "w");
173	if (ofp == NULL) {
174	fprintf(stderr, "%s: cannot create pipe to rttree_reduce\n",
175	progname);
176	exit(1);
177	}
178	SET_FILE_BINARY(ofp);
179	#ifdef getc_unlocked /* avoid lock/unlock overhead */
180	flockfile(ofp);
181	#endif
182	} else
183	fputs("{\n", stdout);
184	/* need to assign Dx, Dy, Dz? */
185	if (funame != NULL)
186	assignD = (fundefined(funame) < 6);
187	/* run through directions */
188	for (ix = 0; ix < sqres/2; ix++) {
189	RBFNODE *rbf = NULL;
190	iovec[0] = 2.*(ix+.5)/sqres - 1.;
191	iovec[1] = .0;
192	iovec[2] = input_orient * sqrt(1. - iovec[0]*iovec[0]);
193	if (funame == NULL)
194	rbf = advect_rbf(iovec, lobe_lim);
195	for (ox = 0; ox < sqres; ox++) {
196	float last_bsdf = -1;
197	for (oy = 0; oy < sqres; oy++) {
198	SDsquare2disk(iovec+3, (ox+.5)/sqres, (oy+.5)/sqres);
199	iovec[5] = output_orient *
200	sqrt(1. - iovec[3]iovec[3] - iovec[4]iovec[4]);
201	if (funame == NULL)
202	bsdf = eval_rbfrep(rbf, iovec+3);
203	else {
204	if (assignD) {
205	varset("Dx", '=', -iovec[3]);
206	varset("Dy", '=', -iovec[4]);
207	varset("Dz", '=', -iovec[5]);
208	++eclock;
209	}
210	bsdf = funvalue(funame, 6, iovec);
211	#if (NSSAMP > 0)
212	if (abs_diff(bsdf, last_bsdf) > ssamp_thresh) {
213	int ssi;
214	double ssa[3], ssvec[6], sum = 0;
215	/* super-sample voxel */
216	for (ssi = NSSAMP; ssi--; ) {
217	SDmultiSamp(ssa, 3, (ssi+frandom()) *
218	(1./NSSAMP));
219	ssvec[0] = 2.*(ix+ssa[0])/sqres - 1.;
220	ssvec[1] = .0;
221	ssvec[2] = input_orient *
222	sqrt(1. - ssvec[0]*ssvec[0]);
223	SDsquare2disk(ssvec+3, (ox+ssa[1])/sqres,
224	(oy+ssa[2])/sqres);
225	ssvec[5] = output_orient *
226	sqrt(1. - ssvec[3]*ssvec[3] -
227	ssvec[4]*ssvec[4]);
228	if (assignD) {
229	varset("Dx", '=', -ssvec[3]);
230	varset("Dy", '=', -ssvec[4]);
231	varset("Dz", '=', -ssvec[5]);
232	++eclock;
233	}
234	sum += funvalue(funame, 6, ssvec);
235	}
236	bsdf = sum/NSSAMP;
237	}
238	#endif
239	}
240	if (pctcull >= 0)
241	fwrite(&bsdf, sizeof(bsdf), 1, ofp);
242	else
243	printf("\t%.3e\n", bsdf);
244	last_bsdf = bsdf;
245	}
246	}
247	if (rbf != NULL)
248	free(rbf);
249	prog_show((ix+1.)*(2./sqres));
250	}
251	if (pctcull >= 0) { /* finish output */
252	if (pclose(ofp)) {
253	fprintf(stderr, "%s: error running '%s'\n",
254	progname, cmd);
255	exit(1);
256	}
257	} else {
258	for (ix = sqressqressqres/2; ix--; )
259	fputs("\t0\n", stdout);
260	fputs("}\n", stdout);
261	}
262	data_epilogue();
263	prog_done();
264	}
265
266	/* Interpolate and output anisotropic BSDF data */
267	static void
268	eval_anisotropic(char *funame)
269	{
270	const int sqres = 1<<samp_order;
271	FILE *ofp = NULL;
272	int assignD = 0;
273	char cmd[128];
274	int ix, iy, ox, oy;
275	double iovec[6];
276	float bsdf;
277
278	data_prologue(); /* begin output */
279	if (pctcull >= 0) {
280	sprintf(cmd, "rttree_reduce%s -h -ff -r 4 -t %f -g %d",
281	(input_orient>0 ^ output_orient>0) ? "" : " -a",
282	pctcull, samp_order);
283	fflush(stdout);
284	ofp = popen(cmd, "w");
285	if (ofp == NULL) {
286	fprintf(stderr, "%s: cannot create pipe to rttree_reduce\n",
287	progname);
288	exit(1);
289	}
290	SET_FILE_BINARY(ofp);
291	#ifdef getc_unlocked /* avoid lock/unlock overhead */
292	flockfile(ofp);
293	#endif
294	} else
295	fputs("{\n", stdout);
296	/* need to assign Dx, Dy, Dz? */
297	if (funame != NULL)
298	assignD = (fundefined(funame) < 6);
299	/* run through directions */
300	for (ix = 0; ix < sqres; ix++)
301	for (iy = 0; iy < sqres; iy++) {
302	RBFNODE rbf = NULL; / Klems reversal */
303	SDsquare2disk(iovec, 1.-(ix+.5)/sqres, 1.-(iy+.5)/sqres);
304	iovec[2] = input_orient *
305	sqrt(1. - iovec[0]iovec[0] - iovec[1]iovec[1]);
306	if (funame == NULL)
307	rbf = advect_rbf(iovec, lobe_lim);
308	for (ox = 0; ox < sqres; ox++) {
309	float last_bsdf = -1;
310	for (oy = 0; oy < sqres; oy++) {
311	SDsquare2disk(iovec+3, (ox+.5)/sqres, (oy+.5)/sqres);
312	iovec[5] = output_orient *
313	sqrt(1. - iovec[3]iovec[3] - iovec[4]iovec[4]);
314	if (funame == NULL)
315	bsdf = eval_rbfrep(rbf, iovec+3);
316	else {
317	if (assignD) {
318	varset("Dx", '=', -iovec[3]);
319	varset("Dy", '=', -iovec[4]);
320	varset("Dz", '=', -iovec[5]);
321	++eclock;
322	}
323	bsdf = funvalue(funame, 6, iovec);
324	#if (NSSAMP > 0)
325	if (abs_diff(bsdf, last_bsdf) > ssamp_thresh) {
326	int ssi;
327	double ssa[4], ssvec[6], sum = 0;
328	/* super-sample voxel */
329	for (ssi = NSSAMP; ssi--; ) {
330	SDmultiSamp(ssa, 4, (ssi+frandom()) *
331	(1./NSSAMP));
332	SDsquare2disk(ssvec, 1.-(ix+ssa[0])/sqres,
333	1.-(iy+ssa[1])/sqres);
334	ssvec[2] = input_orient *
335	sqrt(1. - ssvec[0]*ssvec[0] -
336	ssvec[1]*ssvec[1]);
337	SDsquare2disk(ssvec+3, (ox+ssa[2])/sqres,
338	(oy+ssa[3])/sqres);
339	ssvec[5] = output_orient *
340	sqrt(1. - ssvec[3]*ssvec[3] -
341	ssvec[4]*ssvec[4]);
342	if (assignD) {
343	varset("Dx", '=', -ssvec[3]);
344	varset("Dy", '=', -ssvec[4]);
345	varset("Dz", '=', -ssvec[5]);
346	++eclock;
347	}
348	sum += funvalue(funame, 6, ssvec);
349	}
350	bsdf = sum/NSSAMP;
351	}
352	#endif
353	}
354	if (pctcull >= 0)
355	fwrite(&bsdf, sizeof(bsdf), 1, ofp);
356	else
357	printf("\t%.3e\n", bsdf);
358	last_bsdf = bsdf;
359	}
360	}
361	if (rbf != NULL)
362	free(rbf);
363	prog_show((ixsqres+iy+1.)/(sqressqres));
364	}
365	if (pctcull >= 0) { /* finish output */
366	if (pclose(ofp)) {
367	fprintf(stderr, "%s: error running '%s'\n",
368	progname, cmd);
369	exit(1);
370	}
371	} else
372	fputs("}\n", stdout);
373	data_epilogue();
374	prog_done();
375	}
376
377	/* Read in BSDF and interpolate as tensor tree representation */
378	int
379	main(int argc, char *argv[])
380	{
381	int dofwd = 0, dobwd = 1;
382	int i, na;
383
384	progname = argv[0];
385	esupport \|= E_VARIABLE\|E_FUNCTION\|E_RCONST;
386	esupport &= ~(E_INCHAN\|E_OUTCHAN);
387	scompile("PI:3.14159265358979323846", NULL, 0);
388	biggerlib();
389	for (i = 1; i < argc-1 && (argv[i][0] == '-') \| (argv[i][0] == '+'); i++)
390	switch (argv[i][1]) { /* get options */
391	case 'e':
392	scompile(argv[++i], NULL, 0);
393	break;
394	case 'f':
395	if (!argv[i][2])
396	fcompile(argv[++i]);
397	else
398	dofwd = (argv[i][0] == '+');
399	break;
400	case 'b':
401	dobwd = (argv[i][0] == '+');
402	break;
403	case 't':
404	switch (argv[i][2]) {
405	case '3':
406	single_plane_incident = 1;
407	break;
408	case '4':
409	single_plane_incident = 0;
410	break;
411	case '\0':
412	pctcull = atof(argv[++i]);
413	break;
414	default:
415	goto userr;
416	}
417	break;
418	case 'g':
419	samp_order = atoi(argv[++i]);
420	break;
421	case 'l':
422	lobe_lim = atoi(argv[++i]);
423	break;
424	case 'p':
425	do_prog = atoi(argv[i]+2);
426	break;
427	default:
428	goto userr;
429	}
430	if (single_plane_incident >= 0) { /* function-based BSDF? */
431	void (evf)(char s) = single_plane_incident ?
432	&eval_isotropic : &eval_anisotropic;
433	if (i != argc-1 \|\| fundefined(argv[i]) < 3) {
434	fprintf(stderr,
435	"%s: need single function with 6 arguments: bsdf(ix,iy,iz,ox,oy,oz)\n",
436	progname);
437	fprintf(stderr, "\tor 3 arguments using Dx,Dy,Dz: bsdf(ix,iy,iz)\n");
438	goto userr;
439	}
440	++eclock;
441	xml_prologue(argc, argv); /* start XML output */
442	if (dofwd) {
443	input_orient = -1;
444	output_orient = -1;
445	prog_start("Evaluating outside reflectance");
446	(*evf)(argv[i]);
447	output_orient = 1;
448	prog_start("Evaluating outside->inside transmission");
449	(*evf)(argv[i]);
450	}
451	if (dobwd) {
452	input_orient = 1;
453	output_orient = 1;
454	prog_start("Evaluating inside reflectance");
455	(*evf)(argv[i]);
456	output_orient = -1;
457	prog_start("Evaluating inside->outside transmission");
458	(*evf)(argv[i]);
459	}
460	xml_epilogue(); /* finish XML output & exit */
461	return(0);
462	}
463	if (i < argc) { /* open input files if given */
464	int nbsdf = 0;
465	for ( ; i < argc; i++) { /* interpolate each component */
466	char pbuf[256];
467	FILE *fpin = fopen(argv[i], "rb");
468	if (fpin == NULL) {
469	fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
470	progname, argv[i]);
471	return(1);
472	}
473	if (!load_bsdf_rep(fpin))
474	return(1);
475	fclose(fpin);
476	if (!nbsdf++) /* start XML on first dist. */
477	xml_prologue(argc, argv);
478	sprintf(pbuf, "Interpolating component '%s'", argv[i]);
479	prog_start(pbuf);
480	if (single_plane_incident)
481	eval_isotropic(NULL);
482	else
483	eval_anisotropic(NULL);
484	}
485	xml_epilogue(); /* finish XML output & exit */
486	return(0);
487	}
488	SET_FILE_BINARY(stdin); /* load from stdin */
489	if (!load_bsdf_rep(stdin))
490	return(1);
491	xml_prologue(argc, argv); /* start XML output */
492	prog_start("Interpolating from standard input");
493	if (single_plane_incident) /* resample dist. */
494	eval_isotropic(NULL);
495	else
496	eval_anisotropic(NULL);
497	xml_epilogue(); /* finish XML output & exit */
498	return(0);
499	userr:
500	fprintf(stderr,
501	"Usage: %s [-g Nlog2][-t pctcull][-l maxlobes] [bsdf.sir ..] > bsdf.xml\n",
502	progname);
503	fprintf(stderr,
504	" or: %s -t{3\|4} [-g Nlog2][-t pctcull][{+\|-}for[ward]][{+\|-}b[ackward]][-e expr][-f file] bsdf_func > bsdf.xml\n",
505	progname);
506	return(1);
507	}