src/cv/bsdf2ttree.c

#ifndef lint
static const char RCSid[] = "$Id: bsdf2ttree.c,v 2.3 2012/10/23 05:10:42 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 "platform.h"
#include "bsdfrep.h"
                                /* global argv[0] */
char                    *progname;
                                /* percentage to cull (<0 to turn off) */
int                     pctcull = 90;
                                /* sampling order */
int                     samp_order = 6;

/* Interpolate and output isotropic BSDF data */
static void
interp_isotropic()
{
        const int       sqres = 1<<samp_order;
        FILE            *ofp = NULL;
        char            cmd[128];
        int             ix, ox, oy;
        FVECT           ivec, ovec;
        float           bsdf;
#if DEBUG
        fprintf(stderr, "Writing isotropic order %d ", samp_order);
        if (pctcull >= 0) fprintf(stderr, "data with %d%% culling\n", pctcull);
        else fputs("raw data\n", stderr);
#endif
        if (pctcull >= 0) {                     /* begin output */
                sprintf(cmd, "rttree_reduce -h -a -ff -r 3 -t %d -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);
        } else
                fputs("{\n", stdout);
                                                /* run through directions */
        for (ix = 0; ix < sqres/2; ix++) {
                RBFNODE *rbf;
                SDsquare2disk(ivec, (ix+.5)/sqres, .5);
                ivec[2] = input_orient *
                                sqrt(1. - ivec[0]*ivec[0] - ivec[1]*ivec[1]);
                rbf = advect_rbf(ivec);
                for (ox = 0; ox < sqres; ox++)
                    for (oy = 0; oy < sqres; oy++) {
                        SDsquare2disk(ovec, (ox+.5)/sqres, (oy+.5)/sqres);
                        ovec[2] = output_orient *
                                sqrt(1. - ovec[0]*ovec[0] - ovec[1]*ovec[1]);
                        bsdf = eval_rbfrep(rbf, ovec) / fabs(ovec[2]);
                        if (pctcull >= 0)
                                fwrite(&bsdf, sizeof(bsdf), 1, ofp);
                        else
                                printf("\t%.3e\n", bsdf);
                    }
                if (rbf != NULL)
                        free(rbf);
        }
        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);
        }
}

/* Interpolate and output anisotropic BSDF data */
static void
interp_anisotropic()
{
        const int       sqres = 1<<samp_order;
        FILE            *ofp = NULL;
        char            cmd[128];
        int             ix, iy, ox, oy;
        FVECT           ivec, ovec;
        float           bsdf;
#if DEBUG
        fprintf(stderr, "Writing anisotropic order %d ", samp_order);
        if (pctcull >= 0) fprintf(stderr, "data with %d%% culling\n", pctcull);
        else fputs("raw data\n", stderr);
#endif
        if (pctcull >= 0) {                     /* begin output */
                sprintf(cmd, "rttree_reduce -h -a -ff -r 4 -t %d -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);
                }
        } else
                fputs("{\n", stdout);
                                                /* run through directions */
        for (ix = 0; ix < sqres; ix++)
            for (iy = 0; iy < sqres; iy++) {
                RBFNODE *rbf;
                SDsquare2disk(ivec, (ix+.5)/sqres, (iy+.5)/sqres);
                ivec[2] = input_orient *
                                sqrt(1. - ivec[0]*ivec[0] - ivec[1]*ivec[1]);
                rbf = advect_rbf(ivec);
                for (ox = 0; ox < sqres; ox++)
                    for (oy = 0; oy < sqres; oy++) {
                        SDsquare2disk(ovec, (ox+.5)/sqres, (oy+.5)/sqres);
                        ovec[2] = output_orient *
                                sqrt(1. - ovec[0]*ovec[0] - ovec[1]*ovec[1]);
                        bsdf = eval_rbfrep(rbf, ovec) / fabs(ovec[2]);
                        if (pctcull >= 0)
                                fwrite(&bsdf, sizeof(bsdf), 1, ofp);
                        else
                                printf("\t%.3e\n", bsdf);
                    }
                if (rbf != NULL)
                        free(rbf);
            }
        if (pctcull >= 0) {                     /* finish output */
                if (pclose(ofp)) {
                        fprintf(stderr, "%s: error running '%s'\n",
                                        progname, cmd);
                        exit(1);
                }
        } else
                fputs("}\n", stdout);
}

/* Read in BSDF and interpolate as tensor tree representation */
int
main(int argc, char *argv[])
{
        FILE    *fpin = stdin;
        int     i;

        progname = argv[0];                     /* get options */
        while (argc > 2 && argv[1][0] == '-') {
                switch (argv[1][1]) {
                case 't':
                        pctcull = atoi(argv[2]);
                        break;
                case 'g':
                        samp_order = atoi(argv[2]);
                        break;
                default:
                        goto userr;
                }
                argv += 2; argc -= 2;
        }
        if (argc == 2) {                        /* open input if given */
                fpin = fopen(argv[1], "r");
                if (fpin == NULL) {
                        fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
                                        progname, argv[1]);
                        return(1);
                }
        } else if (argc != 1)
                goto userr;
        SET_FILE_BINARY(fpin);                  /* load BSDF interpolant */
        if (!load_bsdf_rep(fpin))
                return(1);
        /* xml_prologue();                              /* start XML output */
        if (single_plane_incident)              /* resample dist. */
                interp_isotropic();
        else
                interp_anisotropic();
        /* xml_epilogue();                              /* finish XML output */
        return(0);
userr:
        fprintf(stderr,
        "Usage: %s [-t pctcull][-g log2grid] [bsdf.sir] > bsdf.xml\n",
                                progname);
        return(1);
}
Revision:	2.4
Committed:	Wed Nov 7 03:04:23 2012 UTC (12 years, 11 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Changes since 2.3:	+5 -5 lines
Log Message:	Added GRIDRES to saved BSDF representation
#	User	Rev	Content
1	greg	2.1	#ifndef lint
2	greg	2.4	static const char RCSid[] = "$Id: bsdf2ttree.c,v 2.3 2012/10/23 05:10:42 greg Exp $";
3	greg	2.1	#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 "platform.h"
15			#include "bsdfrep.h"
16			/* global argv[0] */
17			char *progname;
18			/* percentage to cull (<0 to turn off) */
19			int pctcull = 90;
20			/* sampling order */
21			int samp_order = 6;
22
23			/* Interpolate and output isotropic BSDF data */
24			static void
25			interp_isotropic()
26			{
27			const int sqres = 1<<samp_order;
28			FILE *ofp = NULL;
29			char cmd[128];
30			int ix, ox, oy;
31			FVECT ivec, ovec;
32	greg	2.4	float bsdf;
33	greg	2.1	#if DEBUG
34			fprintf(stderr, "Writing isotropic order %d ", samp_order);
35			if (pctcull >= 0) fprintf(stderr, "data with %d%% culling\n", pctcull);
36			else fputs("raw data\n", stderr);
37			#endif
38			if (pctcull >= 0) { /* begin output */
39	greg	2.4	sprintf(cmd, "rttree_reduce -h -a -ff -r 3 -t %d -g %d",
40	greg	2.1	pctcull, samp_order);
41			fflush(stdout);
42			ofp = popen(cmd, "w");
43			if (ofp == NULL) {
44			fprintf(stderr, "%s: cannot create pipe to rttree_reduce\n",
45			progname);
46			exit(1);
47			}
48			SET_FILE_BINARY(ofp);
49			} else
50			fputs("{\n", stdout);
51			/* run through directions */
52			for (ix = 0; ix < sqres/2; ix++) {
53			RBFNODE *rbf;
54			SDsquare2disk(ivec, (ix+.5)/sqres, .5);
55			ivec[2] = input_orient *
56			sqrt(1. - ivec[0]ivec[0] - ivec[1]ivec[1]);
57			rbf = advect_rbf(ivec);
58			for (ox = 0; ox < sqres; ox++)
59			for (oy = 0; oy < sqres; oy++) {
60			SDsquare2disk(ovec, (ox+.5)/sqres, (oy+.5)/sqres);
61			ovec[2] = output_orient *
62			sqrt(1. - ovec[0]ovec[0] - ovec[1]ovec[1]);
63			bsdf = eval_rbfrep(rbf, ovec) / fabs(ovec[2]);
64			if (pctcull >= 0)
65			fwrite(&bsdf, sizeof(bsdf), 1, ofp);
66			else
67			printf("\t%.3e\n", bsdf);
68			}
69	greg	2.3	if (rbf != NULL)
70			free(rbf);
71	greg	2.1	}
72			if (pctcull >= 0) { /* finish output */
73			if (pclose(ofp)) {
74			fprintf(stderr, "%s: error running '%s'\n",
75			progname, cmd);
76			exit(1);
77			}
78			} else {
79			for (ix = sqressqressqres/2; ix--; )
80			fputs("\t0\n", stdout);
81			fputs("}\n", stdout);
82			}
83			}
84
85			/* Interpolate and output anisotropic BSDF data */
86			static void
87			interp_anisotropic()
88			{
89			const int sqres = 1<<samp_order;
90			FILE *ofp = NULL;
91			char cmd[128];
92			int ix, iy, ox, oy;
93			FVECT ivec, ovec;
94	greg	2.4	float bsdf;
95	greg	2.1	#if DEBUG
96			fprintf(stderr, "Writing anisotropic order %d ", samp_order);
97			if (pctcull >= 0) fprintf(stderr, "data with %d%% culling\n", pctcull);
98			else fputs("raw data\n", stderr);
99			#endif
100			if (pctcull >= 0) { /* begin output */
101	greg	2.4	sprintf(cmd, "rttree_reduce -h -a -ff -r 4 -t %d -g %d",
102	greg	2.1	pctcull, samp_order);
103			fflush(stdout);
104			ofp = popen(cmd, "w");
105			if (ofp == NULL) {
106			fprintf(stderr, "%s: cannot create pipe to rttree_reduce\n",
107			progname);
108			exit(1);
109			}
110			} else
111			fputs("{\n", stdout);
112			/* run through directions */
113			for (ix = 0; ix < sqres; ix++)
114			for (iy = 0; iy < sqres; iy++) {
115			RBFNODE *rbf;
116			SDsquare2disk(ivec, (ix+.5)/sqres, (iy+.5)/sqres);
117			ivec[2] = input_orient *
118			sqrt(1. - ivec[0]ivec[0] - ivec[1]ivec[1]);
119			rbf = advect_rbf(ivec);
120			for (ox = 0; ox < sqres; ox++)
121			for (oy = 0; oy < sqres; oy++) {
122			SDsquare2disk(ovec, (ox+.5)/sqres, (oy+.5)/sqres);
123			ovec[2] = output_orient *
124			sqrt(1. - ovec[0]ovec[0] - ovec[1]ovec[1]);
125			bsdf = eval_rbfrep(rbf, ovec) / fabs(ovec[2]);
126			if (pctcull >= 0)
127			fwrite(&bsdf, sizeof(bsdf), 1, ofp);
128			else
129			printf("\t%.3e\n", bsdf);
130			}
131	greg	2.3	if (rbf != NULL)
132			free(rbf);
133	greg	2.1	}
134			if (pctcull >= 0) { /* finish output */
135			if (pclose(ofp)) {
136			fprintf(stderr, "%s: error running '%s'\n",
137			progname, cmd);
138			exit(1);
139			}
140			} else
141			fputs("}\n", stdout);
142			}
143
144			/* Read in BSDF and interpolate as tensor tree representation */
145			int
146			main(int argc, char *argv[])
147			{
148			FILE *fpin = stdin;
149			int i;
150
151			progname = argv[0]; /* get options */
152			while (argc > 2 && argv[1][0] == '-') {
153			switch (argv[1][1]) {
154			case 't':
155			pctcull = atoi(argv[2]);
156			break;
157			case 'g':
158			samp_order = atoi(argv[2]);
159			break;
160			default:
161			goto userr;
162			}
163			argv += 2; argc -= 2;
164			}
165	greg	2.2	if (argc == 2) { /* open input if given */
166	greg	2.1	fpin = fopen(argv[1], "r");
167	greg	2.2	if (fpin == NULL) {
168			fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
169			progname, argv[1]);
170			return(1);
171			}
172			} else if (argc != 1)
173	greg	2.1	goto userr;
174			SET_FILE_BINARY(fpin); /* load BSDF interpolant */
175			if (!load_bsdf_rep(fpin))
176			return(1);
177			/* xml_prologue(); /* start XML output */
178			if (single_plane_incident) /* resample dist. */
179			interp_isotropic();
180			else
181			interp_anisotropic();
182			/* xml_epilogue(); /* finish XML output */
183			return(0);
184			userr:
185			fprintf(stderr,
186			"Usage: %s [-t pctcull][-g log2grid] [bsdf.sir] > bsdf.xml\n",
187			progname);
188			return(1);
189			}