src/cv/pabopto2bsdf.c

#ifndef lint
static const char RCSid[] = "$Id: pabopto2bsdf.c,v 2.41 2021/04/05 21:06:32 greg Exp $";
#endif
/*
 * Load measured BSDF data in PAB-Opto format.
 * Assumes that surface-normal (Z-axis) faces into room unless -t option given.
 *
 *      G. Ward
 */

#define _USE_MATH_DEFINES
#include <stdlib.h>
#include <ctype.h>
#include <math.h>
#include "rtio.h"
#include "platform.h"
#include "paths.h"
#include "bsdfrep.h"
                                /* global argv[0] */
char                    *progname;

typedef struct {
        const char      *fname;         /* input file path */
        double          theta, phi;     /* input angles (degrees) */
        double          up_phi;         /* azimuth for "up" direction */
        int             igp[2];         /* input grid position */
        int             isDSF;          /* data is DSF (rather than BSDF)? */
        int             nspec;          /* number of spectral samples */
        long            dstart;         /* data start offset in file */
} PGINPUT;

PGINPUT         *inpfile;       /* input files sorted by incidence */

int             rev_orient = 0; /* shall we reverse surface orientation? */

double          lim_graze = 0;  /* limit scattering near grazing (deg above) */

/* Compare incident angles */
static int
cmp_indir(const void *p1, const void *p2)
{
        const PGINPUT   *inp1 = (const PGINPUT *)p1;
        const PGINPUT   *inp2 = (const PGINPUT *)p2;
        int             ydif = inp1->igp[1] - inp2->igp[1];
        
        if (ydif)
                return(ydif);

        return(inp1->igp[0] - inp2->igp[0]);
}

/* Assign grid position from theta and phi */
static void
set_grid_pos(PGINPUT *pip)
{
        FVECT   dv;

        if (pip->theta <= FTINY) {
                pip->igp[0] = pip->igp[1] = grid_res/2 - 1;
                return;
        }
        dv[2] = sin(M_PI/180.*pip->theta);
        dv[0] = cos(M_PI/180.*pip->phi)*dv[2];
        dv[1] = sin(M_PI/180.*pip->phi)*dv[2];
        dv[2] = sqrt(1. - dv[2]*dv[2]);
        pos_from_vec(pip->igp, dv);
}

/* Prepare a PAB-Opto input file by reading its header */
static int
init_pabopto_inp(const int i, const char *fname)
{
        FILE    *fp = fopen(fname, "r");
        char    buf[2048];
        int     c;
        
        if (fp == NULL) {
                fputs(fname, stderr);
                fputs(": cannot open\n", stderr);
                return(0);
        }
        inpfile[i].fname = fname;
        inpfile[i].isDSF = -1;
        inpfile[i].nspec = 0;
        inpfile[i].up_phi = 0;
        inpfile[i].theta = inpfile[i].phi = -10001.;
                                /* read header information */
        while ((c = getc(fp)) == '#' || c == EOF) {
                char    typ[64];
                if (fgets(buf, sizeof(buf), fp) == NULL) {
                        fputs(fname, stderr);
                        fputs(": unexpected EOF\n", stderr);
                        fclose(fp);
                        return(0);
                }
                if (sscanf(buf, "sample_name \"%[^\"]\"", bsdf_name) == 1)
                        continue;
                if (sscanf(buf, "colorimetry: %s", typ) == 1) {
                        if (!strcasecmp(typ, "CIE-XYZ"))
                                inpfile[i].nspec = 3;
                        else if (!strcasecmp(typ, "CIE-Y"))
                                inpfile[i].nspec = 1;
                        continue;
                }
                if (sscanf(buf, "format: theta phi %s", typ) == 1) {
                        if (!strcasecmp(typ, "DSF"))
                                inpfile[i].isDSF = 1;
                        else if (!strcasecmp(typ, "BSDF") ||
                                        !strcasecmp(typ, "BRDF") ||
                                        !strcasecmp(typ, "BTDF"))
                                inpfile[i].isDSF = 0;
                        continue;
                }
                if (sscanf(buf, "upphi %lf", &inpfile[i].up_phi) == 1)
                        continue;
                if (sscanf(buf, "intheta %lf", &inpfile[i].theta) == 1)
                        continue;
                if (sscanf(buf, "inphi %lf", &inpfile[i].phi) == 1)
                        continue;
                if (sscanf(buf, "incident_angle %lf %lf",
                                &inpfile[i].theta, &inpfile[i].phi) == 2)
                        continue;
        }
        inpfile[i].dstart = ftell(fp) - 1;
        fclose(fp);
        if (inpfile[i].isDSF < 0) {
                fputs(fname, stderr);
                fputs(": unknown format\n", stderr);
                return(0);
        }
        if ((inpfile[i].theta < -10000.) | (inpfile[i].phi < -10000.)) {
                fputs(fname, stderr);
                fputs(": unknown incident angle\n", stderr);
                return(0);
        }
        if (rev_orient) {       /* reverse Z-axis to face outside */
                inpfile[i].theta = 180. - inpfile[i].theta;
                inpfile[i].phi = 360. - inpfile[i].phi;
        }
                                /* convert to Y-up orientation */
        inpfile[i].phi += 90.-inpfile[i].up_phi;
                                /* convert angle to grid position */
        set_grid_pos(&inpfile[i]);
        return(1);
}

/* Load a set of measurements corresponding to a particular incident angle */
static int
add_pabopto_inp(const int i)
{
        FILE            *fp = fopen(inpfile[i].fname, "r");
        double          theta_out, phi_out, val[3];
        int             n, c;
        
        if (fp == NULL || fseek(fp, inpfile[i].dstart, 0) == EOF) {
                fputs(inpfile[i].fname, stderr);
                fputs(": cannot open\n", stderr);
                return(0);
        }
                                        /* prepare input grid */
        if (!i || cmp_indir(&inpfile[i-1], &inpfile[i])) {
                if (i)                  /* process previous incidence */
                        make_rbfrep();
#ifdef DEBUG
                fprintf(stderr, "New incident (theta,phi)=(%.1f,%.1f)\n",
                                        inpfile[i].theta, inpfile[i].phi);
#endif
                if (inpfile[i].nspec)
                        set_spectral_samples(inpfile[i].nspec);
                new_bsdf_data(inpfile[i].theta, inpfile[i].phi);
        }
#ifdef DEBUG
        fprintf(stderr, "Loading measurements from '%s'...\n", inpfile[i].fname);
#endif
                                        /* read scattering data */
        while (fscanf(fp, "%lf %lf %lf", &theta_out, &phi_out, val) == 3) {
                for (n = 1; n < inpfile[i].nspec; n++)
                        if (fscanf(fp, "%lf", val+n) != 1) {
                                fprintf(stderr, "%s: warning: unexpected EOF\n",
                                                inpfile[i].fname);
                                fclose(fp);
                                return(1);
                        }
                                        /* check if scatter angle is too low */
                if (fabs(theta_out - 90.) < lim_graze-FTINY)
                        continue;
                if (rev_orient) {       /* reverse Z-axis to face outside? */
                        theta_out = 180. - theta_out;
                        phi_out = 360. - phi_out;
                }
                phi_out += 90.-inpfile[i].up_phi;
                add_bsdf_data(theta_out, phi_out, val, inpfile[i].isDSF);
        }
        n = 0;
        while ((c = getc(fp)) != EOF)
                n += !isspace(c);
        if (n) 
                fprintf(stderr,
                        "%s: warning: %d unexpected characters past EOD\n",
                                inpfile[i].fname, n);
        fclose(fp);
        return(1);
}

#ifndef TEST_MAIN

#define SYM_ILL         '?'             /* illegal symmetry value */
#define SYM_ISO         'I'             /* isotropic */
#define SYM_QUAD        'Q'             /* quadrilateral symmetry */
#define SYM_BILAT       'B'             /* bilateral symmetry */
#define SYM_ANISO       'A'             /* anisotropic */
#define SYM_UP          'U'             /* "up-down" (180°) symmetry */

static const char       quadrant_rep[16][16] = {
                                "in-plane","0-90","90-180","0-180",
                                "180-270","0-90+180-270","90-270",
                                "0-270","270-360","270-90",
                                "90-180+270-360","270-180","180-360",
                                "180-90","90-360","0-360"
                        };
static const char       quadrant_sym[16] = {
                                SYM_ISO, SYM_QUAD, SYM_QUAD, SYM_BILAT,
                                SYM_QUAD, SYM_ILL, SYM_BILAT, SYM_ILL,
                                SYM_QUAD, SYM_BILAT, SYM_ILL, SYM_ILL,
                                SYM_BILAT, SYM_ILL, SYM_ILL, SYM_ANISO
                        };

/* Read in PAB-Opto BSDF files and output RBF interpolant */
int
main(int argc, char *argv[])
{
        extern int      nprocs;
        static char     gval_buf[16];
        char *          auto_grazing = NULL;
        const char      *symmetry = "0";
        int             ninpfiles, totinc;
        int             a, i;

        progname = argv[0];                     /* get options */
        for (a = 1; a < argc && argv[a][0] == '-'; a++)
                switch (argv[a][1]) {
                case 't':
                        rev_orient = !rev_orient;
                        break;
                case 'n':
                        nprocs = atoi(argv[++a]);
                        break;
                case 's':
                        symmetry = argv[++a];
                        break;
                case 'g':
                        if (toupper(argv[a+1][0]) == 'A')
                                auto_grazing = argv[a+1] = gval_buf;
                        else
                                lim_graze = atof(argv[a+1]);
                        ++a;
                        break;
                default:
                        goto userr;
                }
        totinc = ninpfiles = argc - a;          /* initialize & sort inputs */
        if (ninpfiles < 2)
                goto userr;
        if (toupper(symmetry[0]) == SYM_UP)     /* special case for "up" symmetry */
                totinc += ninpfiles;
        inpfile = (PGINPUT *)malloc(sizeof(PGINPUT)*totinc);
        if (inpfile == NULL)
                return(1);
        if (auto_grazing)
                lim_graze = 90.;
        for (i = 0; i < ninpfiles; i++) {
                if (!init_pabopto_inp(i, argv[a+i]))
                        return(1);
                if (auto_grazing && fabs(inpfile[i].theta - 90.) < lim_graze)
                        lim_graze = fabs(inpfile[i].theta - 90.);
        }
        if (auto_grazing)
                sprintf(auto_grazing, "%.2f", lim_graze);
        for (i = ninpfiles; i < totinc; i++) {  /* copy for "up" symmetry */
                inpfile[i] = inpfile[i-ninpfiles];
                inpfile[i].phi += 180.;         /* invert duplicate data */
                inpfile[i].up_phi -= 180.;
                set_grid_pos(&inpfile[i]);      /* grid location for sorting */
        }
        qsort(inpfile, totinc, sizeof(PGINPUT), cmp_indir);
                                                /* compile measurements */
        for (i = 0; i < totinc; i++)
                if (!add_pabopto_inp(i))
                        return(1);
        make_rbfrep();                          /* process last data set */
                                                /* check input symmetry */
        switch (toupper(symmetry[0])) {
        case '0':                               /* unspecified symmetry */
                if (quadrant_sym[inp_coverage] != SYM_ILL)
                        break;                  /* anything legal goes */
                fprintf(stderr, "%s: unsupported phi coverage (%s)\n",
                                progname, quadrant_rep[inp_coverage]);
                return(1);
        case SYM_UP:                            /* faux "up" symmetry */
                if (quadrant_sym[inp_coverage] == SYM_ANISO)
                        break;
                /* fall through */
        case SYM_ISO:                           /* usual symmetry types */
        case SYM_QUAD:
        case SYM_BILAT:
        case SYM_ANISO:
                if (quadrant_sym[inp_coverage] == toupper(symmetry[0]))
                        break;                  /* matches spec */
                fprintf(stderr,
                "%s: phi coverage (%s) does not match requested '%s' symmetry\n",
                                progname, quadrant_rep[inp_coverage], symmetry);
                return(1);
        default:
                fprintf(stderr,
  "%s: -s option must be Isotropic, Quadrilateral, Bilateral, Up, or Anisotropic\n",
                                progname);
                return(1);
        }
#ifdef DEBUG
        fprintf(stderr, "Input phi coverage (%s) has '%c' symmetry\n",
                                quadrant_rep[inp_coverage],
                                quadrant_sym[inp_coverage]);
#endif
        build_mesh();                           /* create interpolation */
        SET_FILE_BINARY(stdout);                /* start header */
        newheader("RADIANCE", stdout);
        printargs(argc, argv, stdout);
        fputnow(stdout);
        save_bsdf_rep(stdout);                  /* complete header + data */
        return(0);
userr:
        fprintf(stderr, "Usage: %s [-t][-n nproc][-s symmetry][-g angle|'A'] meas1.dat meas2.dat .. > bsdf.sir\n",
                                        progname);
        return(1);
}

#else           /* TEST_MAIN */

/* Test main produces a Radiance model from the given input file */
int
main(int argc, char *argv[])
{
        PGINPUT pginp;
        char    buf[128];
        FILE    *pfp;
        double  bsdf, min_log;
        FVECT   dir;
        int     i, j, n;

        progname = argv[0];
        if (argc != 2) {
                fprintf(stderr, "Usage: %s input.dat > output.rad\n", progname);
                return(1);
        }
        inpfile = &pginp;
        if (!init_pabopto_inp(0, argv[1]) || !add_pabopto_inp(0))
                return(1);
                                                /* reduce data set */
        if (make_rbfrep() == NULL) {
                fprintf(stderr, "%s: nothing to plot!\n", progname);
                exit(1);
        }
#ifdef DEBUG
        fprintf(stderr, "Minimum BSDF = %.4f\n", bsdf_min);
#endif
        min_log = log(bsdf_min*.5 + 1e-5);
#if 1                                           /* produce spheres at meas. */
        puts("void plastic yellow\n0\n0\n5 .6 .4 .01 .04 .08\n");
        n = 0;
        for (i = 0; i < grid_res; i++)
            for (j = 0; j < grid_res; j++)
                if (dsf_grid[i][j].sum.n > 0) {
                        ovec_from_pos(dir, i, j);
                        bsdf = dsf_grid[i][j].sum.v /
                           ((double)dsf_grid[i][j].sum.n*output_orient*dir[2]);
                        if (bsdf <= bsdf_min*.6)
                                continue;
                        bsdf = log(bsdf + 1e-5) - min_log;
                        ovec_from_pos(dir, i, j);
                        printf("yellow sphere s%04d\n0\n0\n", ++n);
                        printf("4 %.6g %.6g %.6g %.6g\n\n",
                                        dir[0]*bsdf, dir[1]*bsdf, dir[2]*bsdf,
                                        .007*bsdf);
                }
#endif
#if 1                                           /* spheres at RBF peaks */
        puts("void plastic red\n0\n0\n5 .8 .01 .01 .04 .08\n");
        for (n = 0; n < dsf_list->nrbf; n++) {
                RBFVAL  *rbf = &dsf_list->rbfa[n];
                ovec_from_pos(dir, rbf->gx, rbf->gy);
                bsdf = eval_rbfrep(dsf_list, dir);
                bsdf = log(bsdf + 1e-5) - min_log;
                printf("red sphere p%04d\n0\n0\n", ++n);
                printf("4 %.6g %.6g %.6g %.6g\n\n",
                                dir[0]*bsdf, dir[1]*bsdf, dir[2]*bsdf,
                                .011*bsdf);
        }
#endif
#if 1                                           /* output continuous surface */
        puts("void trans tgreen\n0\n0\n7 .7 1 .7 .04 .04 .9 1\n");
        fflush(stdout);
        sprintf(buf, "gensurf tgreen bsdf - - - %d %d", grid_res-1, grid_res-1);
        pfp = popen(buf, "w");
        if (pfp == NULL) {
                fprintf(stderr, "%s: cannot open '| %s'\n", progname, buf);
                return(1);
        }
        for (i = 0; i < grid_res; i++)
            for (j = 0; j < grid_res; j++) {
                ovec_from_pos(dir, i, j);
                bsdf = eval_rbfrep(dsf_list, dir);
                bsdf = log(bsdf + 1e-5) - min_log;
                fprintf(pfp, "%.8e %.8e %.8e\n",
                                dir[0]*bsdf, dir[1]*bsdf, dir[2]*bsdf);
            }
        if (pclose(pfp) != 0)
                return(1);
#endif
        return(0);
}

#endif          /* TEST_MAIN */
Revision:	2.42
Committed:	Mon Nov 21 18:28:24 2022 UTC (17 months ago) by greg
Content type:	text/plain
Branch:	MAIN
CVS Tags:	rad5R4, HEAD
Changes since 2.41:	+2 -1 lines
Log Message:	fix(pabopto2bsdf): Added declaration of popen() needed for Windows
#	Content
1	#ifndef lint
2	static const char RCSid[] = "$Id: pabopto2bsdf.c,v 2.41 2021/04/05 21:06:32 greg Exp $";
3	#endif
4	/*
5	* Load measured BSDF data in PAB-Opto format.
6	* Assumes that surface-normal (Z-axis) faces into room unless -t option given.
7	*
8	* G. Ward
9	*/
10
11	#define _USE_MATH_DEFINES
12	#include <stdlib.h>
13	#include <ctype.h>
14	#include <math.h>
15	#include "rtio.h"
16	#include "platform.h"
17	#include "paths.h"
18	#include "bsdfrep.h"
19	/* global argv[0] */
20	char *progname;
21
22	typedef struct {
23	const char fname; / input file path */
24	double theta, phi; /* input angles (degrees) */
25	double up_phi; /* azimuth for "up" direction */
26	int igp[2]; /* input grid position */
27	int isDSF; /* data is DSF (rather than BSDF)? */
28	int nspec; /* number of spectral samples */
29	long dstart; /* data start offset in file */
30	} PGINPUT;
31
32	PGINPUT inpfile; / input files sorted by incidence */
33
34	int rev_orient = 0; /* shall we reverse surface orientation? */
35
36	double lim_graze = 0; /* limit scattering near grazing (deg above) */
37
38	/* Compare incident angles */
39	static int
40	cmp_indir(const void p1, const void p2)
41	{
42	const PGINPUT inp1 = (const PGINPUT )p1;
43	const PGINPUT inp2 = (const PGINPUT )p2;
44	int ydif = inp1->igp[1] - inp2->igp[1];
45
46	if (ydif)
47	return(ydif);
48
49	return(inp1->igp[0] - inp2->igp[0]);
50	}
51
52	/* Assign grid position from theta and phi */
53	static void
54	set_grid_pos(PGINPUT *pip)
55	{
56	FVECT dv;
57
58	if (pip->theta <= FTINY) {
59	pip->igp[0] = pip->igp[1] = grid_res/2 - 1;
60	return;
61	}
62	dv[2] = sin(M_PI/180.*pip->theta);
63	dv[0] = cos(M_PI/180.pip->phi)dv[2];
64	dv[1] = sin(M_PI/180.pip->phi)dv[2];
65	dv[2] = sqrt(1. - dv[2]*dv[2]);
66	pos_from_vec(pip->igp, dv);
67	}
68
69	/* Prepare a PAB-Opto input file by reading its header */
70	static int
71	init_pabopto_inp(const int i, const char *fname)
72	{
73	FILE *fp = fopen(fname, "r");
74	char buf[2048];
75	int c;
76
77	if (fp == NULL) {
78	fputs(fname, stderr);
79	fputs(": cannot open\n", stderr);
80	return(0);
81	}
82	inpfile[i].fname = fname;
83	inpfile[i].isDSF = -1;
84	inpfile[i].nspec = 0;
85	inpfile[i].up_phi = 0;
86	inpfile[i].theta = inpfile[i].phi = -10001.;
87	/* read header information */
88	while ((c = getc(fp)) == '#' \|\| c == EOF) {
89	char typ[64];
90	if (fgets(buf, sizeof(buf), fp) == NULL) {
91	fputs(fname, stderr);
92	fputs(": unexpected EOF\n", stderr);
93	fclose(fp);
94	return(0);
95	}
96	if (sscanf(buf, "sample_name \"%[^\"]\"", bsdf_name) == 1)
97	continue;
98	if (sscanf(buf, "colorimetry: %s", typ) == 1) {
99	if (!strcasecmp(typ, "CIE-XYZ"))
100	inpfile[i].nspec = 3;
101	else if (!strcasecmp(typ, "CIE-Y"))
102	inpfile[i].nspec = 1;
103	continue;
104	}
105	if (sscanf(buf, "format: theta phi %s", typ) == 1) {
106	if (!strcasecmp(typ, "DSF"))
107	inpfile[i].isDSF = 1;
108	else if (!strcasecmp(typ, "BSDF") \|\|
109	!strcasecmp(typ, "BRDF") \|\|
110	!strcasecmp(typ, "BTDF"))
111	inpfile[i].isDSF = 0;
112	continue;
113	}
114	if (sscanf(buf, "upphi %lf", &inpfile[i].up_phi) == 1)
115	continue;
116	if (sscanf(buf, "intheta %lf", &inpfile[i].theta) == 1)
117	continue;
118	if (sscanf(buf, "inphi %lf", &inpfile[i].phi) == 1)
119	continue;
120	if (sscanf(buf, "incident_angle %lf %lf",
121	&inpfile[i].theta, &inpfile[i].phi) == 2)
122	continue;
123	}
124	inpfile[i].dstart = ftell(fp) - 1;
125	fclose(fp);
126	if (inpfile[i].isDSF < 0) {
127	fputs(fname, stderr);
128	fputs(": unknown format\n", stderr);
129	return(0);
130	}
131	if ((inpfile[i].theta < -10000.) \| (inpfile[i].phi < -10000.)) {
132	fputs(fname, stderr);
133	fputs(": unknown incident angle\n", stderr);
134	return(0);
135	}
136	if (rev_orient) { /* reverse Z-axis to face outside */
137	inpfile[i].theta = 180. - inpfile[i].theta;
138	inpfile[i].phi = 360. - inpfile[i].phi;
139	}
140	/* convert to Y-up orientation */
141	inpfile[i].phi += 90.-inpfile[i].up_phi;
142	/* convert angle to grid position */
143	set_grid_pos(&inpfile[i]);
144	return(1);
145	}
146
147	/* Load a set of measurements corresponding to a particular incident angle */
148	static int
149	add_pabopto_inp(const int i)
150	{
151	FILE *fp = fopen(inpfile[i].fname, "r");
152	double theta_out, phi_out, val[3];
153	int n, c;
154
155	if (fp == NULL \|\| fseek(fp, inpfile[i].dstart, 0) == EOF) {
156	fputs(inpfile[i].fname, stderr);
157	fputs(": cannot open\n", stderr);
158	return(0);
159	}
160	/* prepare input grid */
161	if (!i \|\| cmp_indir(&inpfile[i-1], &inpfile[i])) {
162	if (i) /* process previous incidence */
163	make_rbfrep();
164	#ifdef DEBUG
165	fprintf(stderr, "New incident (theta,phi)=(%.1f,%.1f)\n",
166	inpfile[i].theta, inpfile[i].phi);
167	#endif
168	if (inpfile[i].nspec)
169	set_spectral_samples(inpfile[i].nspec);
170	new_bsdf_data(inpfile[i].theta, inpfile[i].phi);
171	}
172	#ifdef DEBUG
173	fprintf(stderr, "Loading measurements from '%s'...\n", inpfile[i].fname);
174	#endif
175	/* read scattering data */
176	while (fscanf(fp, "%lf %lf %lf", &theta_out, &phi_out, val) == 3) {
177	for (n = 1; n < inpfile[i].nspec; n++)
178	if (fscanf(fp, "%lf", val+n) != 1) {
179	fprintf(stderr, "%s: warning: unexpected EOF\n",
180	inpfile[i].fname);
181	fclose(fp);
182	return(1);
183	}
184	/* check if scatter angle is too low */
185	if (fabs(theta_out - 90.) < lim_graze-FTINY)
186	continue;
187	if (rev_orient) { /* reverse Z-axis to face outside? */
188	theta_out = 180. - theta_out;
189	phi_out = 360. - phi_out;
190	}
191	phi_out += 90.-inpfile[i].up_phi;
192	add_bsdf_data(theta_out, phi_out, val, inpfile[i].isDSF);
193	}
194	n = 0;
195	while ((c = getc(fp)) != EOF)
196	n += !isspace(c);
197	if (n)
198	fprintf(stderr,
199	"%s: warning: %d unexpected characters past EOD\n",
200	inpfile[i].fname, n);
201	fclose(fp);
202	return(1);
203	}
204
205	#ifndef TEST_MAIN
206
207	#define SYM_ILL '?' /* illegal symmetry value */
208	#define SYM_ISO 'I' /* isotropic */
209	#define SYM_QUAD 'Q' /* quadrilateral symmetry */
210	#define SYM_BILAT 'B' /* bilateral symmetry */
211	#define SYM_ANISO 'A' /* anisotropic */
212	#define SYM_UP 'U' /* "up-down" (180°) symmetry */
213
214	static const char quadrant_rep[16][16] = {
215	"in-plane","0-90","90-180","0-180",
216	"180-270","0-90+180-270","90-270",
217	"0-270","270-360","270-90",
218	"90-180+270-360","270-180","180-360",
219	"180-90","90-360","0-360"
220	};
221	static const char quadrant_sym[16] = {
222	SYM_ISO, SYM_QUAD, SYM_QUAD, SYM_BILAT,
223	SYM_QUAD, SYM_ILL, SYM_BILAT, SYM_ILL,
224	SYM_QUAD, SYM_BILAT, SYM_ILL, SYM_ILL,
225	SYM_BILAT, SYM_ILL, SYM_ILL, SYM_ANISO
226	};
227
228	/* Read in PAB-Opto BSDF files and output RBF interpolant */
229	int
230	main(int argc, char *argv[])
231	{
232	extern int nprocs;
233	static char gval_buf[16];
234	char * auto_grazing = NULL;
235	const char *symmetry = "0";
236	int ninpfiles, totinc;
237	int a, i;
238
239	progname = argv[0]; /* get options */
240	for (a = 1; a < argc && argv[a][0] == '-'; a++)
241	switch (argv[a][1]) {
242	case 't':
243	rev_orient = !rev_orient;
244	break;
245	case 'n':
246	nprocs = atoi(argv[++a]);
247	break;
248	case 's':
249	symmetry = argv[++a];
250	break;
251	case 'g':
252	if (toupper(argv[a+1][0]) == 'A')
253	auto_grazing = argv[a+1] = gval_buf;
254	else
255	lim_graze = atof(argv[a+1]);
256	++a;
257	break;
258	default:
259	goto userr;
260	}
261	totinc = ninpfiles = argc - a; /* initialize & sort inputs */
262	if (ninpfiles < 2)
263	goto userr;
264	if (toupper(symmetry[0]) == SYM_UP) /* special case for "up" symmetry */
265	totinc += ninpfiles;
266	inpfile = (PGINPUT )malloc(sizeof(PGINPUT)totinc);
267	if (inpfile == NULL)
268	return(1);
269	if (auto_grazing)
270	lim_graze = 90.;
271	for (i = 0; i < ninpfiles; i++) {
272	if (!init_pabopto_inp(i, argv[a+i]))
273	return(1);
274	if (auto_grazing && fabs(inpfile[i].theta - 90.) < lim_graze)
275	lim_graze = fabs(inpfile[i].theta - 90.);
276	}
277	if (auto_grazing)
278	sprintf(auto_grazing, "%.2f", lim_graze);
279	for (i = ninpfiles; i < totinc; i++) { /* copy for "up" symmetry */
280	inpfile[i] = inpfile[i-ninpfiles];
281	inpfile[i].phi += 180.; /* invert duplicate data */
282	inpfile[i].up_phi -= 180.;
283	set_grid_pos(&inpfile[i]); /* grid location for sorting */
284	}
285	qsort(inpfile, totinc, sizeof(PGINPUT), cmp_indir);
286	/* compile measurements */
287	for (i = 0; i < totinc; i++)
288	if (!add_pabopto_inp(i))
289	return(1);
290	make_rbfrep(); /* process last data set */
291	/* check input symmetry */
292	switch (toupper(symmetry[0])) {
293	case '0': /* unspecified symmetry */
294	if (quadrant_sym[inp_coverage] != SYM_ILL)
295	break; /* anything legal goes */
296	fprintf(stderr, "%s: unsupported phi coverage (%s)\n",
297	progname, quadrant_rep[inp_coverage]);
298	return(1);
299	case SYM_UP: /* faux "up" symmetry */
300	if (quadrant_sym[inp_coverage] == SYM_ANISO)
301	break;
302	/* fall through */
303	case SYM_ISO: /* usual symmetry types */
304	case SYM_QUAD:
305	case SYM_BILAT:
306	case SYM_ANISO:
307	if (quadrant_sym[inp_coverage] == toupper(symmetry[0]))
308	break; /* matches spec */
309	fprintf(stderr,
310	"%s: phi coverage (%s) does not match requested '%s' symmetry\n",
311	progname, quadrant_rep[inp_coverage], symmetry);
312	return(1);
313	default:
314	fprintf(stderr,
315	"%s: -s option must be Isotropic, Quadrilateral, Bilateral, Up, or Anisotropic\n",
316	progname);
317	return(1);
318	}
319	#ifdef DEBUG
320	fprintf(stderr, "Input phi coverage (%s) has '%c' symmetry\n",
321	quadrant_rep[inp_coverage],
322	quadrant_sym[inp_coverage]);
323	#endif
324	build_mesh(); /* create interpolation */
325	SET_FILE_BINARY(stdout); /* start header */
326	newheader("RADIANCE", stdout);
327	printargs(argc, argv, stdout);
328	fputnow(stdout);
329	save_bsdf_rep(stdout); /* complete header + data */
330	return(0);
331	userr:
332	fprintf(stderr, "Usage: %s [-t][-n nproc][-s symmetry][-g angle\|'A'] meas1.dat meas2.dat .. > bsdf.sir\n",
333	progname);
334	return(1);
335	}
336
337	#else /* TEST_MAIN */
338
339	/* Test main produces a Radiance model from the given input file */
340	int
341	main(int argc, char *argv[])
342	{
343	PGINPUT pginp;
344	char buf[128];
345	FILE *pfp;
346	double bsdf, min_log;
347	FVECT dir;
348	int i, j, n;
349
350	progname = argv[0];
351	if (argc != 2) {
352	fprintf(stderr, "Usage: %s input.dat > output.rad\n", progname);
353	return(1);
354	}
355	inpfile = &pginp;
356	if (!init_pabopto_inp(0, argv[1]) \|\| !add_pabopto_inp(0))
357	return(1);
358	/* reduce data set */
359	if (make_rbfrep() == NULL) {
360	fprintf(stderr, "%s: nothing to plot!\n", progname);
361	exit(1);
362	}
363	#ifdef DEBUG
364	fprintf(stderr, "Minimum BSDF = %.4f\n", bsdf_min);
365	#endif
366	min_log = log(bsdf_min*.5 + 1e-5);
367	#if 1 /* produce spheres at meas. */
368	puts("void plastic yellow\n0\n0\n5 .6 .4 .01 .04 .08\n");
369	n = 0;
370	for (i = 0; i < grid_res; i++)
371	for (j = 0; j < grid_res; j++)
372	if (dsf_grid[i][j].sum.n > 0) {
373	ovec_from_pos(dir, i, j);
374	bsdf = dsf_grid[i][j].sum.v /
375	((double)dsf_grid[i][j].sum.noutput_orientdir[2]);
376	if (bsdf <= bsdf_min*.6)
377	continue;
378	bsdf = log(bsdf + 1e-5) - min_log;
379	ovec_from_pos(dir, i, j);
380	printf("yellow sphere s%04d\n0\n0\n", ++n);
381	printf("4 %.6g %.6g %.6g %.6g\n\n",
382	dir[0]bsdf, dir[1]bsdf, dir[2]*bsdf,
383	.007*bsdf);
384	}
385	#endif
386	#if 1 /* spheres at RBF peaks */
387	puts("void plastic red\n0\n0\n5 .8 .01 .01 .04 .08\n");
388	for (n = 0; n < dsf_list->nrbf; n++) {
389	RBFVAL *rbf = &dsf_list->rbfa[n];
390	ovec_from_pos(dir, rbf->gx, rbf->gy);
391	bsdf = eval_rbfrep(dsf_list, dir);
392	bsdf = log(bsdf + 1e-5) - min_log;
393	printf("red sphere p%04d\n0\n0\n", ++n);
394	printf("4 %.6g %.6g %.6g %.6g\n\n",
395	dir[0]bsdf, dir[1]bsdf, dir[2]*bsdf,
396	.011*bsdf);
397	}
398	#endif
399	#if 1 /* output continuous surface */
400	puts("void trans tgreen\n0\n0\n7 .7 1 .7 .04 .04 .9 1\n");
401	fflush(stdout);
402	sprintf(buf, "gensurf tgreen bsdf - - - %d %d", grid_res-1, grid_res-1);
403	pfp = popen(buf, "w");
404	if (pfp == NULL) {
405	fprintf(stderr, "%s: cannot open '\| %s'\n", progname, buf);
406	return(1);
407	}
408	for (i = 0; i < grid_res; i++)
409	for (j = 0; j < grid_res; j++) {
410	ovec_from_pos(dir, i, j);
411	bsdf = eval_rbfrep(dsf_list, dir);
412	bsdf = log(bsdf + 1e-5) - min_log;
413	fprintf(pfp, "%.8e %.8e %.8e\n",
414	dir[0]bsdf, dir[1]bsdf, dir[2]*bsdf);
415	}
416	if (pclose(pfp) != 0)
417	return(1);
418	#endif
419	return(0);
420	}
421
422	#endif /* TEST_MAIN */