src/cv/checkBSDF.c

#ifndef lint
static const char RCSid[] = "$Id$";
#endif
/*
 *  checkBSDF.c
 *
 *  Load BSDF XML file and check Helmholtz reciprocity
 */

#define _USE_MATH_DEFINES
#include <math.h>
#include "rtio.h"
#include "bsdf.h"
#include "bsdf_m.h"
#include "bsdf_t.h"

#define F_IN_COLOR      0x1
#define F_ISOTROPIC     0x2
#define F_MATRIX        0x4
#define F_TTREE         0x8

/* Figure out BSDF type (and optionally determine if in color) */
const char *
getBSDFtype(const SDData *bsdf, int *flags)
{
        const SDSpectralDF      *df = bsdf->tb;

        if (flags) *flags = 0;
        if (!df) df = bsdf->tf;
        if (!df) df = bsdf->rf;
        if (!df) df = bsdf->rb;
        if (!df) return "Pure_Lambertian";
        if (df->comp[0].func == &SDhandleMtx) {
                const SDMat     *m = (const SDMat *)df->comp[0].dist;
                if (flags) {
                        *flags |= F_MATRIX;
                        *flags |= F_IN_COLOR*(m->chroma != NULL);
                }
                switch (m->ninc) {
                case 145:
                        return "Klems_Full";
                case  73:
                        return "Klems_Half";
                case  41:
                        return "Klems_Quarter";
                }
                return "Unknown_Matrix";
        }
        if (df->comp[0].func == &SDhandleTre) {
                const SDTre     *t = (const SDTre *)df->comp[0].dist;
                if (flags) {
                        *flags |= F_TTREE;
                        *flags |= F_IN_COLOR*(t->stc[1] != NULL);
                }
                switch (t->stc[0]->ndim) {
                case 4:
                        return "Anisotropic_Tensor_Tree";
                case 3:
                        if (flags) *flags |= F_ISOTROPIC;
                        return "Isotropic_Tensor_Tree";
                }
                return "Unknown_Tensor_Tree";
        }
        return "Unknown";
}

/* Report details related to one hemisphere distribution */
void
detailComponent(const char *nm, const SDValue *lamb, const SDSpectralDF *df)
{
        printf("%s\t%4.1f %4.1f %4.1f\t\t", nm, 100.*lamb->cieY*lamb->spec.cx/lamb->spec.cy,
                        100.*lamb->cieY,
                        100.*lamb->cieY*(1.f - lamb->spec.cx - lamb->spec.cy)/lamb->spec.cy);
        if (df)
                printf("%5.1f%%\t\t%.2f deg\n", 100.*df->maxHemi,
                                sqrt(df->minProjSA/M_PI)*(360./M_PI));
        else
                puts("0%\t\t180");
}

/* Report reciprocity errors for the given directions */
void
checkReciprocity(const char *nm, const int side1, const int side2,
                        const SDData *bsdf, const int fl)
{
        const SDSpectralDF      *df = bsdf->tf;
        double                  emin=FHUGE, emax=0, esum=0;
        int                     ntested=0;
        int                     ec;

        if (side1 == side2) {
                df = (side1 > 0) ? bsdf->rf : bsdf->rb;
                if (!df) goto nothing2do;
        } else if (!bsdf->tf | !bsdf->tb)
                goto nothing2do;

        if (fl & F_MATRIX) {                    /* special case for matrix BSDF */
                const SDMat     *m = (const SDMat *)df->comp[0].dist;
                int             i = m->ninc;
                FVECT           vin, vout;
                double          rerr;
                SDValue         vrev;
                while (i--) {
                    int o = m->nout;
                    if (!mBSDF_incvec(vin, m, i+.5))
                        continue;
                    while (o--) {
                        if (!mBSDF_outvec(vout, m, o+.5))
                                continue;
                        rerr = mBSDF_value(m, o, i);
                        if (rerr <= FTINY)
                                continue;
                        if (SDreportError( SDevalBSDF(&vrev, vout, vin, bsdf), stderr))
                                return;
                        rerr = 100.*fabs(rerr - vrev.cieY)/rerr;
                        if (rerr < emin) emin = rerr;
                        if (rerr > emax) emax = rerr;
                        esum += rerr;
                        ++ntested;
                    }
                }
        } else {
        }
        if (ntested) {
                printf("%s\t%.1f\t%.1f\t%.1f\n", nm, emin, esum/(double)ntested, emax);
                return;
        }
nothing2do:
        printf("%s\t0\t0\t0\n", nm);
}

/* Report on the given BSDF XML file */
int
checkXML(char *fname)
{
        int             flags;
        SDError         ec;
        SDData          myBSDF;
        char            *pth;

        printf("File: '%s'\n", fname);
        SDclearBSDF(&myBSDF, fname);
        pth = getpath(fname, getrlibpath(), R_OK);
        if (!pth) {
                fprintf(stderr, "Cannot find file '%s'\n", fname);
                return 0;
        }
        ec = SDloadFile(&myBSDF, pth);
        if (ec) goto err;
        printf("Manufacturer: '%s'\n", myBSDF.makr);
        printf("BSDF Name: '%s'\n", myBSDF.matn);
        printf("Dimensions (W x H x Thickness): %g x %g x %g cm\n", 100.*myBSDF.dim[0],
                                100.*myBSDF.dim[1], 100.*myBSDF.dim[2]);
        printf("Type: %s\n", getBSDFtype(&myBSDF, &flags));
        printf("Color: %d\n", (flags & F_IN_COLOR) != 0);
        printf("Has Geometry: %d\n", (myBSDF.mgf != NULL));
        puts("Component\tLambertian XYZ %\tMax. Dir\tMin. Angle");
        detailComponent("Internal Refl", &myBSDF.rLambFront, myBSDF.rf);
        detailComponent("External Refl", &myBSDF.rLambBack, myBSDF.rb);
        detailComponent("Int->Ext Trans", &myBSDF.tLambFront, myBSDF.tf);
        detailComponent("Ext->Int Trans", &myBSDF.tLambBack, myBSDF.tb);
        puts("Component\tReciprocity Error (min/avg/max %)");
        checkReciprocity("Front Refl", 1, 1, &myBSDF, flags);
        checkReciprocity("Back Refl", -1, -1, &myBSDF, flags);
        checkReciprocity("Transmission", -1, 1, &myBSDF, flags);
        SDfreeBSDF(&myBSDF);
        return 1;
err:
        SDreportError(ec, stderr);
        SDfreeBSDF(&myBSDF);
        return 0;
}

int
main(int argc, char *argv[])
{
        int     i;

        if (argc < 2) {
                fprintf(stderr, "Usage: %s bsdf.xml ..\n", argv[0]);
                return 1;
        }
        for (i = 1; i < argc; i++) {
                puts("=====================================================");
                if (!checkXML(argv[i]))
                        return 1;
        }
        return 0;
}
Revision:	2.1
Committed:	Tue Dec 14 02:33:18 2021 UTC (3 years, 10 months ago) by greg
Content type:	text/plain
Branch:	MAIN
Log Message:	feat(checkBSDF): created new checkBSDF tool to check XML data reciprocity
#	User	Rev	Content
1	greg	2.1	#ifndef lint
2			static const char RCSid[] = "$Id$";
3			#endif
4			/*
5			* checkBSDF.c
6			*
7			* Load BSDF XML file and check Helmholtz reciprocity
8			*/
9
10			#define _USE_MATH_DEFINES
11			#include <math.h>
12			#include "rtio.h"
13			#include "bsdf.h"
14			#include "bsdf_m.h"
15			#include "bsdf_t.h"
16
17			#define F_IN_COLOR 0x1
18			#define F_ISOTROPIC 0x2
19			#define F_MATRIX 0x4
20			#define F_TTREE 0x8
21
22			/* Figure out BSDF type (and optionally determine if in color) */
23			const char *
24			getBSDFtype(const SDData bsdf, int flags)
25			{
26			const SDSpectralDF *df = bsdf->tb;
27
28			if (flags) *flags = 0;
29			if (!df) df = bsdf->tf;
30			if (!df) df = bsdf->rf;
31			if (!df) df = bsdf->rb;
32			if (!df) return "Pure_Lambertian";
33			if (df->comp[0].func == &SDhandleMtx) {
34			const SDMat m = (const SDMat )df->comp[0].dist;
35			if (flags) {
36			*flags \|= F_MATRIX;
37			flags \|= F_IN_COLOR(m->chroma != NULL);
38			}
39			switch (m->ninc) {
40			case 145:
41			return "Klems_Full";
42			case 73:
43			return "Klems_Half";
44			case 41:
45			return "Klems_Quarter";
46			}
47			return "Unknown_Matrix";
48			}
49			if (df->comp[0].func == &SDhandleTre) {
50			const SDTre t = (const SDTre )df->comp[0].dist;
51			if (flags) {
52			*flags \|= F_TTREE;
53			flags \|= F_IN_COLOR(t->stc[1] != NULL);
54			}
55			switch (t->stc[0]->ndim) {
56			case 4:
57			return "Anisotropic_Tensor_Tree";
58			case 3:
59			if (flags) *flags \|= F_ISOTROPIC;
60			return "Isotropic_Tensor_Tree";
61			}
62			return "Unknown_Tensor_Tree";
63			}
64			return "Unknown";
65			}
66
67			/* Report details related to one hemisphere distribution */
68			void
69			detailComponent(const char nm, const SDValue lamb, const SDSpectralDF *df)
70			{
71			printf("%s\t%4.1f %4.1f %4.1f\t\t", nm, 100.lamb->cieYlamb->spec.cx/lamb->spec.cy,
72			100.*lamb->cieY,
73			100.lamb->cieY(1.f - lamb->spec.cx - lamb->spec.cy)/lamb->spec.cy);
74			if (df)
75			printf("%5.1f%%\t\t%.2f deg\n", 100.*df->maxHemi,
76			sqrt(df->minProjSA/M_PI)*(360./M_PI));
77			else
78			puts("0%\t\t180");
79			}
80
81			/* Report reciprocity errors for the given directions */
82			void
83			checkReciprocity(const char *nm, const int side1, const int side2,
84			const SDData *bsdf, const int fl)
85			{
86			const SDSpectralDF *df = bsdf->tf;
87			double emin=FHUGE, emax=0, esum=0;
88			int ntested=0;
89			int ec;
90
91			if (side1 == side2) {
92			df = (side1 > 0) ? bsdf->rf : bsdf->rb;
93			if (!df) goto nothing2do;
94			} else if (!bsdf->tf \| !bsdf->tb)
95			goto nothing2do;
96
97			if (fl & F_MATRIX) { /* special case for matrix BSDF */
98			const SDMat m = (const SDMat )df->comp[0].dist;
99			int i = m->ninc;
100			FVECT vin, vout;
101			double rerr;
102			SDValue vrev;
103			while (i--) {
104			int o = m->nout;
105			if (!mBSDF_incvec(vin, m, i+.5))
106			continue;
107			while (o--) {
108			if (!mBSDF_outvec(vout, m, o+.5))
109			continue;
110			rerr = mBSDF_value(m, o, i);
111			if (rerr <= FTINY)
112			continue;
113			if (SDreportError( SDevalBSDF(&vrev, vout, vin, bsdf), stderr))
114			return;
115			rerr = 100.*fabs(rerr - vrev.cieY)/rerr;
116			if (rerr < emin) emin = rerr;
117			if (rerr > emax) emax = rerr;
118			esum += rerr;
119			++ntested;
120			}
121			}
122			} else {
123			}
124			if (ntested) {
125			printf("%s\t%.1f\t%.1f\t%.1f\n", nm, emin, esum/(double)ntested, emax);
126			return;
127			}
128			nothing2do:
129			printf("%s\t0\t0\t0\n", nm);
130			}
131
132			/* Report on the given BSDF XML file */
133			int
134			checkXML(char *fname)
135			{
136			int flags;
137			SDError ec;
138			SDData myBSDF;
139			char *pth;
140
141			printf("File: '%s'\n", fname);
142			SDclearBSDF(&myBSDF, fname);
143			pth = getpath(fname, getrlibpath(), R_OK);
144			if (!pth) {
145			fprintf(stderr, "Cannot find file '%s'\n", fname);
146			return 0;
147			}
148			ec = SDloadFile(&myBSDF, pth);
149			if (ec) goto err;
150			printf("Manufacturer: '%s'\n", myBSDF.makr);
151			printf("BSDF Name: '%s'\n", myBSDF.matn);
152			printf("Dimensions (W x H x Thickness): %g x %g x %g cm\n", 100.*myBSDF.dim[0],
153			100.myBSDF.dim[1], 100.myBSDF.dim[2]);
154			printf("Type: %s\n", getBSDFtype(&myBSDF, &flags));
155			printf("Color: %d\n", (flags & F_IN_COLOR) != 0);
156			printf("Has Geometry: %d\n", (myBSDF.mgf != NULL));
157			puts("Component\tLambertian XYZ %\tMax. Dir\tMin. Angle");
158			detailComponent("Internal Refl", &myBSDF.rLambFront, myBSDF.rf);
159			detailComponent("External Refl", &myBSDF.rLambBack, myBSDF.rb);
160			detailComponent("Int->Ext Trans", &myBSDF.tLambFront, myBSDF.tf);
161			detailComponent("Ext->Int Trans", &myBSDF.tLambBack, myBSDF.tb);
162			puts("Component\tReciprocity Error (min/avg/max %)");
163			checkReciprocity("Front Refl", 1, 1, &myBSDF, flags);
164			checkReciprocity("Back Refl", -1, -1, &myBSDF, flags);
165			checkReciprocity("Transmission", -1, 1, &myBSDF, flags);
166			SDfreeBSDF(&myBSDF);
167			return 1;
168			err:
169			SDreportError(ec, stderr);
170			SDfreeBSDF(&myBSDF);
171			return 0;
172			}
173
174			int
175			main(int argc, char *argv[])
176			{
177			int i;
178
179			if (argc < 2) {
180			fprintf(stderr, "Usage: %s bsdf.xml ..\n", argv[0]);
181			return 1;
182			}
183			for (i = 1; i < argc; i++) {
184			puts("=====================================================");
185			if (!checkXML(argv[i]))
186			return 1;
187			}
188			return 0;
189			}