[ViewVC] Diff of: Development/ray/src/cv/bsdf2klems.c

Comparing ray/src/cv/bsdf2klems.c (file contents):
Revision 2.10 by greg, Thu Sep 26 17:05:00 2013 UTC vs.
Revision 2.28 by greg, Sat Dec 28 18:05:14 2019 UTC

#	Line 8 \| Line 8 \| static const char RCSid[] = "$Id$";
8		*/
9
10		#define _USE_MATH_DEFINES
11	–	#include <stdio.h>
11		#include <stdlib.h>
13	–	#include <string.h>
12		#include <math.h>
13		#include "random.h"
14		#include "platform.h"
15	+	#include "paths.h"
16	+	#include "rtio.h"
17		#include "calcomp.h"
18		#include "bsdfrep.h"
19		#include "bsdf_m.h"
20	+	/* tristimulus components */
21	+	enum {CIE_X, CIE_Y, CIE_Z};
22		/* assumed maximum # Klems patches */
23		#define MAXPATCHES 145
24		/* global argv[0] */
25		char *progname;
26		/* selected basis function name */
27	<	static const char *kbasis = "LBNL/Klems Full";
27	>	static const char klems_full[] = "LBNL/Klems Full";
28	>	static const char klems_half[] = "LBNL/Klems Half";
29	>	static const char klems_quarter[] = "LBNL/Klems Quarter";
30	>	static const char *kbasis = klems_full;
31		/* number of BSDF samples per patch */
32	<	static int npsamps = 256;
32	>	static int npsamps = 1024;
33		/* limit on number of RBF lobes */
34		static int lobe_lim = 15000;
35	+	/* progress bar length */
36	+	static int do_prog = 79;
37
38	<	/* Return angle basis corresponding to the given name */
39	<	ANGLE_BASIS *
40	<	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	<	}
38	>	#define MAXCARG 512 /* wrapBSDF command */
39	>	static char *wrapBSDF[MAXCARG] = {"wrapBSDF", "-W", "-UU"};
40	>	static int wbsdfac = 3;
41
42	<	/* Output XML header to stdout */
42	>	/* Add argument to wrapBSDF, allocating space if !isstatic */
43		static void
44	<	xml_header(int ac, char *av[])
44	>	add_wbsdf(const char *arg, int isstatic)
45		{
46	<	puts("<?xml version=\"1.0\" encoding=\"UTF-8\"?>");
47	<	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\">");
48	<	fputs("<!-- File produced by:", stdout);
49	<	while (ac-- > 0) {
50	<	fputc(' ', stdout);
51	<	fputs(*av++, stdout);
46	>	if (arg == NULL)
47	>	return;
48	>	if (wbsdfac >= MAXCARG-1) {
49	>	fputs(progname, stderr);
50	>	fputs(": too many command arguments to wrapBSDF\n", stderr);
51	>	exit(1);
52		}
53	<	puts(" -->");
53	>	if (!*arg)
54	>	arg = "";
55	>	else if (!isstatic)
56	>	arg = savqstr((char *)arg);
57	>
58	>	wrapBSDF[wbsdfac++] = (char *)arg;
59		}
60
61	<	/* Output XML prologue to stdout */
61	>	/* Start new progress bar */
62	>	#define prog_start(s) if (do_prog) fprintf(stderr, "%s: %s...\n", progname, s); else
63	>
64	>	/* Draw progress bar of the appropriate length */
65		static void
66	<	xml_prologue(const SDData *sd)
66	>	prog_show(double frac)
67		{
68	<	const char *matn = (sd && sd->matn[0]) ? sd->matn : "Name";
69	<	const char *makr = (sd && sd->makr[0]) ? sd->makr : "Manufacturer";
70	<	ANGLE_BASIS *abp = get_basis(kbasis);
71	<	int i;
68	>	static unsigned call_cnt = 0;
69	>	static char lastc[] = "-\\\|/";
70	>	char pbar[256];
71	>	int nchars;
72
73	<	if (abp == NULL) {
74	<	fprintf(stderr, "%s: unknown angle basis '%s'\n", progname, kbasis);
75	<	exit(1);
76	<	}
77	<	puts("<WindowElementType>System</WindowElementType>");
78	<	puts("<FileType>BSDF</FileType>");
79	<	puts("<Optical>");
80	<	puts("<Layer>");
81	<	puts("\t<Material>");
82	<	printf("\t\t<Name>%s</Name>\n", matn);
83	<	printf("\t\t<Manufacturer>%s</Manufacturer>\n", makr);
84	<	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	<	puts("\t\t<DeviceType>Other</DeviceType>");
83	<	puts("\t</Material>");
84	<	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	<	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	<	printf("\t\t\t<nPhis>%d</nPhis>\n", abp->lat[i].nphis);
101	<	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>");
73	>	if (do_prog <= 1) return;
74	>	if (do_prog > sizeof(pbar)-2)
75	>	do_prog = sizeof(pbar)-2;
76	>	if (frac < 0) frac = 0;
77	>	else if (frac >= 1) frac = .9999;
78	>	nchars = do_prog*frac;
79	>	pbar[0] = '\r';
80	>	memset(pbar+1, '*', nchars);
81	>	pbar[nchars+1] = lastc[call_cnt++ & 3];
82	>	memset(pbar+2+nchars, '-', do_prog-nchars-1);
83	>	pbar[do_prog+1] = '\0';
84	>	fputs(pbar, stderr);
85		}
86
87	<	/* Output XML data prologue to stdout */
87	>	/* Finish progress bar */
88		static void
89	<	data_prologue()
89	>	prog_done(void)
90		{
91	<	static const char *bsdf_type[4] = {
116	<	"Reflection Front",
117	<	"Transmission Front",
118	<	"Transmission Back",
119	<	"Reflection Back"
120	<	};
91	>	int n = do_prog;
92
93	<	puts("\t<WavelengthData>");
94	<	puts("\t\t<LayerNumber>System</LayerNumber>");
95	<	puts("\t\t<Wavelength unit=\"Integral\">Visible</Wavelength>");
96	<	puts("\t\t<SourceSpectrum>CIE Illuminant D65 1nm.ssp</SourceSpectrum>");
97	<	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>");
93	>	if (n <= 1) return;
94	>	fputc('\r', stderr);
95	>	while (n--)
96	>	fputc(' ', stderr);
97	>	fputc('\r', stderr);
98		}
99
100	<	/* Output XML data epilogue to stdout */
101	<	static void
102	<	data_epilogue(void)
100	>	/* Return angle basis corresponding to the given name */
101	>	static ANGLE_BASIS *
102	>	get_basis(const char *bn)
103		{
104	<	puts("\t\t\t</ScatteringData>");
105	<	puts("\t\t</WavelengthDataBlock>");
106	<	puts("\t</WavelengthData>");
104	>	int n = nabases;
105	>
106	>	while (n-- > 0)
107	>	if (!strcasecmp(bn, abase_list[n].name))
108	>	return &abase_list[n];
109	>	return NULL;
110		}
111
112	<	/* Output XML epilogue to stdout */
113	<	static void
114	<	xml_epilogue(void)
112	>	/* Copy geometry string to file for wrapBSDF */
113	>	static char *
114	>	save_geom(const char *mgf)
115		{
116	<	puts("</Layer>");
117	<	puts("</Optical>");
118	<	puts("</WindowElement>");
116	>	char *tfname = mktemp(savqstr(TEMPLATE));
117	>	int fd = open(tfname, O_CREAT\|O_WRONLY, 0600);
118	>
119	>	if (fd < 0)
120	>	return(NULL);
121	>	write(fd, mgf, strlen(mgf));
122	>	close(fd);
123	>	add_wbsdf("-g", 1);
124	>	add_wbsdf(tfname, 1);
125	>	return(tfname);
126		}
127
128	+	/* Open XYZ component file for output and add appropriate arguments */
129	+	static FILE *
130	+	open_component_file(int c)
131	+	{
132	+	static const char sname[3][6] = {"CIE-X", "CIE-Y", "CIE-Z"};
133	+	static const char cname[4][4] = {"-rf", "-tf", "-tb", "-rb"};
134	+	char *tfname = mktemp(savqstr(TEMPLATE));
135	+	FILE *fp = fopen(tfname, "w");
136	+
137	+	if (fp == NULL) {
138	+	fprintf(stderr, "%s: cannot open '%s' for writing\n",
139	+	progname, tfname);
140	+	exit(1);
141	+	}
142	+	add_wbsdf("-s", 1); add_wbsdf(sname[c], 1);
143	+	add_wbsdf(cname[(input_orient>0)<<1 \| (output_orient>0)], 1);
144	+	add_wbsdf(tfname, 1);
145	+	return(fp);
146	+	}
147	+
148		/* Load and resample XML BSDF description using Klems basis */
149		static void
150		eval_bsdf(const char *fname)
151		{
152		ANGLE_BASIS *abp = get_basis(kbasis);
153	+	FILE *cfp[3];
154		SDData bsd;
155		SDError ec;
156		FVECT vin, vout;
157	<	SDValue sv;
158	<	double sum;
157	>	SDValue sdv;
158	>	double sum, xsum, ysum;
159		int i, j, n;
160
161	+	initurand(npsamps);
162		SDclearBSDF(&bsd, fname); /* load BSDF file */
163		if ((ec = SDloadFile(&bsd, fname)) != SDEnone)
164		goto err;
165	<	xml_prologue(&bsd); /* pass geometry */
165	>	if (bsd.mgf != NULL) /* save geometry */
166	>	save_geom(bsd.mgf);
167	>	if (bsd.matn[0]) /* save identifier(s) */
168	>	strcpy(bsdf_name, bsd.matn);
169	>	if (bsd.makr[0])
170	>	strcpy(bsdf_manuf, bsd.makr);
171	>	if (bsd.dim[2] > 0) { /* save dimension(s) */
172	>	char buf[64];
173	>	if ((bsd.dim[0] > 0) & (bsd.dim[1] > 0))
174	>	sprintf(buf, "w=%g;h=%g;t=%g",
175	>	bsd.dim[0], bsd.dim[1], bsd.dim[2]);
176	>	else
177	>	sprintf(buf, "t=%g", bsd.dim[2]);
178	>	add_wbsdf("-f", 1);
179	>	add_wbsdf(buf, 0);
180	>	}
181		/* front reflection */
182		if (bsd.rf != NULL \|\| bsd.rLambFront.cieY > .002) {
183		input_orient = 1; output_orient = 1;
184	<	data_prologue();
184	>	cfp[CIE_Y] = open_component_file(CIE_Y);
185	>	if (bsd.rf != NULL && bsd.rf->comp[0].cspec[2].flags) {
186	>	rbf_colorimetry = RBCtristimulus;
187	>	cfp[CIE_X] = open_component_file(CIE_X);
188	>	cfp[CIE_Z] = open_component_file(CIE_Z);
189	>	} else
190	>	rbf_colorimetry = RBCphotopic;
191		for (j = 0; j < abp->nangles; j++) {
192		for (i = 0; i < abp->nangles; i++) {
193		sum = 0; /* average over patches */
194	+	xsum = ysum = 0;
195		for (n = npsamps; n-- > 0; ) {
196		fo_getvec(vout, j+(n+frandom())/npsamps, abp);
197		fi_getvec(vin, i+urand(n), abp);
198	<	ec = SDevalBSDF(&sv, vout, vin, &bsd);
198	>	ec = SDevalBSDF(&sdv, vout, vin, &bsd);
199		if (ec != SDEnone)
200		goto err;
201	<	sum += sv.cieY;
201	>	sum += sdv.cieY;
202	>	if (rbf_colorimetry == RBCtristimulus) {
203	>	xsum += sdv.cieY * sdv.spec.cx;
204	>	ysum += sdv.cieY * sdv.spec.cy;
205	>	}
206		}
207	<	printf("\t%.3e\n", sum/npsamps);
207	>	fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
208	>	if (rbf_colorimetry == RBCtristimulus) {
209	>	fprintf(cfp[CIE_X], "\t%.3e\n", xsumsum/(npsampsysum));
210	>	fprintf(cfp[CIE_Z], "\t%.3e\n",
211	>	(sum - xsum - ysum)sum/(npsampsysum));
212	>	}
213		}
214	<	putchar('\n'); /* extra space between rows */
214	>	fputc('\n', cfp[CIE_Y]); /* extra space between rows */
215	>	if (rbf_colorimetry == RBCtristimulus) {
216	>	fputc('\n', cfp[CIE_X]);
217	>	fputc('\n', cfp[CIE_Z]);
218	>	}
219		}
220	<	data_epilogue();
220	>	if (fclose(cfp[CIE_Y])) {
221	>	fprintf(stderr, "%s: error writing Y output\n", progname);
222	>	exit(1);
223	>	}
224	>	if (rbf_colorimetry == RBCtristimulus &&
225	>	(fclose(cfp[CIE_X]) \|\| fclose(cfp[CIE_Z]))) {
226	>	fprintf(stderr, "%s: error writing X/Z output\n", progname);
227	>	exit(1);
228	>	}
229		}
230		/* back reflection */
231		if (bsd.rb != NULL \|\| bsd.rLambBack.cieY > .002) {
232		input_orient = -1; output_orient = -1;
233	<	data_prologue();
233	>	cfp[CIE_Y] = open_component_file(CIE_Y);
234	>	if (bsd.rb != NULL && bsd.rb->comp[0].cspec[2].flags) {
235	>	rbf_colorimetry = RBCtristimulus;
236	>	cfp[CIE_X] = open_component_file(CIE_X);
237	>	cfp[CIE_Z] = open_component_file(CIE_Z);
238	>	} else
239	>	rbf_colorimetry = RBCphotopic;
240		for (j = 0; j < abp->nangles; j++) {
241		for (i = 0; i < abp->nangles; i++) {
242		sum = 0; /* average over patches */
243	+	xsum = ysum = 0;
244		for (n = npsamps; n-- > 0; ) {
245		bo_getvec(vout, j+(n+frandom())/npsamps, abp);
246		bi_getvec(vin, i+urand(n), abp);
247	<	ec = SDevalBSDF(&sv, vout, vin, &bsd);
247	>	ec = SDevalBSDF(&sdv, vout, vin, &bsd);
248		if (ec != SDEnone)
249		goto err;
250	<	sum += sv.cieY;
250	>	sum += sdv.cieY;
251	>	if (rbf_colorimetry == RBCtristimulus) {
252	>	xsum += sdv.cieY * sdv.spec.cx;
253	>	ysum += sdv.cieY * sdv.spec.cy;
254	>	}
255		}
256	<	printf("\t%.3e\n", sum/npsamps);
256	>	fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
257	>	if (rbf_colorimetry == RBCtristimulus) {
258	>	fprintf(cfp[CIE_X], "\t%.3e\n", xsumsum/(npsampsysum));
259	>	fprintf(cfp[CIE_Z], "\t%.3e\n",
260	>	(sum - xsum - ysum)sum/(npsampsysum));
261	>	}
262		}
263	<	putchar('\n'); /* extra space between rows */
263	>	if (rbf_colorimetry == RBCtristimulus) {
264	>	fputc('\n', cfp[CIE_X]);
265	>	fputc('\n', cfp[CIE_Z]);
266	>	}
267		}
268	<	data_epilogue();
268	>	if (fclose(cfp[CIE_Y])) {
269	>	fprintf(stderr, "%s: error writing Y output\n", progname);
270	>	exit(1);
271	>	}
272	>	if (rbf_colorimetry == RBCtristimulus &&
273	>	(fclose(cfp[CIE_X]) \|\| fclose(cfp[CIE_Z]))) {
274	>	fprintf(stderr, "%s: error writing X/Z output\n", progname);
275	>	exit(1);
276	>	}
277		}
278		/* front transmission */
279		if (bsd.tf != NULL \|\| bsd.tLamb.cieY > .002) {
280		input_orient = 1; output_orient = -1;
281	<	data_prologue();
281	>	cfp[CIE_Y] = open_component_file(CIE_Y);
282	>	if (bsd.tf != NULL && bsd.tf->comp[0].cspec[2].flags) {
283	>	rbf_colorimetry = RBCtristimulus;
284	>	cfp[CIE_X] = open_component_file(CIE_X);
285	>	cfp[CIE_Z] = open_component_file(CIE_Z);
286	>	} else
287	>	rbf_colorimetry = RBCphotopic;
288		for (j = 0; j < abp->nangles; j++) {
289		for (i = 0; i < abp->nangles; i++) {
290		sum = 0; /* average over patches */
291	+	xsum = ysum = 0;
292		for (n = npsamps; n-- > 0; ) {
293		bo_getvec(vout, j+(n+frandom())/npsamps, abp);
294		fi_getvec(vin, i+urand(n), abp);
295	<	ec = SDevalBSDF(&sv, vout, vin, &bsd);
295	>	ec = SDevalBSDF(&sdv, vout, vin, &bsd);
296		if (ec != SDEnone)
297		goto err;
298	<	sum += sv.cieY;
298	>	sum += sdv.cieY;
299	>	if (rbf_colorimetry == RBCtristimulus) {
300	>	xsum += sdv.cieY * sdv.spec.cx;
301	>	ysum += sdv.cieY * sdv.spec.cy;
302	>	}
303		}
304	<	printf("\t%.3e\n", sum/npsamps);
304	>	fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
305	>	if (rbf_colorimetry == RBCtristimulus) {
306	>	fprintf(cfp[CIE_X], "\t%.3e\n", xsumsum/(npsampsysum));
307	>	fprintf(cfp[CIE_Z], "\t%.3e\n",
308	>	(sum - xsum - ysum)sum/(npsampsysum));
309	>	}
310		}
311	<	putchar('\n'); /* extra space between rows */
311	>	if (rbf_colorimetry == RBCtristimulus) {
312	>	fputc('\n', cfp[CIE_X]);
313	>	fputc('\n', cfp[CIE_Z]);
314	>	}
315		}
316	<	data_epilogue();
316	>	if (fclose(cfp[CIE_Y])) {
317	>	fprintf(stderr, "%s: error writing Y output\n", progname);
318	>	exit(1);
319	>	}
320	>	if (rbf_colorimetry == RBCtristimulus &&
321	>	(fclose(cfp[CIE_X]) \|\| fclose(cfp[CIE_Z]))) {
322	>	fprintf(stderr, "%s: error writing X/Z output\n", progname);
323	>	exit(1);
324	>	}
325		}
326		/* back transmission */
327		if ((bsd.tb != NULL) \| (bsd.tf != NULL)) {
328		input_orient = -1; output_orient = 1;
329	<	data_prologue();
329	>	cfp[CIE_Y] = open_component_file(CIE_Y);
330	>	if (bsd.tb != NULL)
331	>	rbf_colorimetry = bsd.tb->comp[0].cspec[2].flags
332	>	? RBCtristimulus : RBCphotopic ;
333	>	if (rbf_colorimetry == RBCtristimulus) {
334	>	cfp[CIE_X] = open_component_file(CIE_X);
335	>	cfp[CIE_Z] = open_component_file(CIE_Z);
336	>	}
337		for (j = 0; j < abp->nangles; j++) {
338		for (i = 0; i < abp->nangles; i++) {
339		sum = 0; /* average over patches */
340	+	xsum = ysum = 0;
341		for (n = npsamps; n-- > 0; ) {
342		fo_getvec(vout, j+(n+frandom())/npsamps, abp);
343		bi_getvec(vin, i+urand(n), abp);
344	<	ec = SDevalBSDF(&sv, vout, vin, &bsd);
344	>	ec = SDevalBSDF(&sdv, vout, vin, &bsd);
345		if (ec != SDEnone)
346		goto err;
347	<	sum += sv.cieY;
347	>	sum += sdv.cieY;
348	>	if (rbf_colorimetry == RBCtristimulus) {
349	>	xsum += sdv.cieY * sdv.spec.cx;
350	>	ysum += sdv.cieY * sdv.spec.cy;
351	>	}
352		}
353	<	printf("\t%.3e\n", sum/npsamps);
353	>	fprintf(cfp[CIE_Y], "\t%.3e\n", sum/npsamps);
354	>	if (rbf_colorimetry == RBCtristimulus) {
355	>	fprintf(cfp[CIE_X], "\t%.3e\n", xsumsum/(npsampsysum));
356	>	fprintf(cfp[CIE_Z], "\t%.3e\n",
357	>	(sum - xsum - ysum)sum/(npsampsysum));
358	>	}
359		}
360	<	putchar('\n'); /* extra space between rows */
360	>	if (rbf_colorimetry == RBCtristimulus) {
361	>	fputc('\n', cfp[CIE_X]);
362	>	fputc('\n', cfp[CIE_Z]);
363	>	}
364		}
365	<	data_epilogue();
365	>	if (fclose(cfp[CIE_Y])) {
366	>	fprintf(stderr, "%s: error writing Y output\n", progname);
367	>	exit(1);
368	>	}
369	>	if (rbf_colorimetry == RBCtristimulus &&
370	>	(fclose(cfp[CIE_X]) \|\| fclose(cfp[CIE_Z]))) {
371	>	fprintf(stderr, "%s: error writing X/Z output\n", progname);
372	>	exit(1);
373	>	}
374		}
375		SDfreeBSDF(&bsd); /* all done */
376		return;
#	Line 264 \| Line 385 \| *eval_function(char funame)**
385		{
386		ANGLE_BASIS *abp = get_basis(kbasis);
387		int assignD = (fundefined(funame) < 6);
388	+	FILE *ofp = open_component_file(CIE_Y);
389		double iovec[6];
390		double sum;
391		int i, j, n;
392
393		initurand(npsamps);
272	–	data_prologue(); /* begin output */
394		for (j = 0; j < abp->nangles; j++) { /* run through directions */
395		for (i = 0; i < abp->nangles; i++) {
396		sum = 0;
#	Line 292 \| Line 413 \| *eval_function(char funame)**
413		}
414		sum += funvalue(funame, 6, iovec);
415		}
416	<	printf("\t%.3e\n", sum/npsamps);
416	>	fprintf(ofp, "\t%.3e\n", sum/npsamps);
417		}
418	<	putchar('\n');
418	>	fputc('\n', ofp);
419	>	prog_show((j+1.)/abp->nangles);
420		}
421	<	data_epilogue(); /* finish output */
421	>	prog_done();
422	>	if (fclose(ofp)) {
423	>	fprintf(stderr, "%s: error writing Y output\n", progname);
424	>	exit(1);
425	>	}
426		}
427
428		/* Interpolate and output a radial basis function BSDF representation */
429		static void
430		eval_rbf(void)
431		{
432	<	ANGLE_BASIS *abp = get_basis(kbasis);
433	<	float bsdfarr[MAXPATCHES*MAXPATCHES];
434	<	FVECT vin, vout;
435	<	RBFNODE *rbf;
436	<	double sum;
437	<	int i, j, n;
438	<	/* sanity check */
439	<	if (abp->nangles > MAXPATCHES) {
440	<	fprintf(stderr, "%s: too many patches!\n", progname);
441	<	exit(1);
442	<	}
443	<	data_prologue(); /* begin output */
444	<	for (i = 0; i < abp->nangles; i++) {
445	<	if (input_orient > 0) /* use incident patch center */
446	<	fi_getvec(vin, i+.5*(i>0), abp);
447	<	else
448	<	bi_getvec(vin, i+.5*(i>0), abp);
432	>	ANGLE_BASIS *abp = get_basis(kbasis);
433	>	float (*XZarr)[2] = NULL;
434	>	float bsdfarr[MAXPATCHES*MAXPATCHES];
435	>	FILE *cfp[3];
436	>	FVECT vin, vout;
437	>	double sum, xsum, ysum, normf;
438	>	int i, j, ni, no, nisamps, nosamps;
439	>	/* sanity check */
440	>	if (abp->nangles > MAXPATCHES) {
441	>	fprintf(stderr, "%s: too many patches!\n", progname);
442	>	exit(1);
443	>	}
444	>	memset(bsdfarr, 0, sizeof(bsdfarr));
445	>	if (rbf_colorimetry == RBCtristimulus)
446	>	XZarr = (float ()[2])calloc(abp->nanglesabp->nangles, 2*sizeof(float));
447	>	nosamps = (int)(pow((double)npsamps, 0.67) + .5);
448	>	nisamps = (npsamps + (nosamps>>1)) / nosamps;
449	>	normf = 1./(double)(nisamps*nosamps);
450	>	for (i = 0; i < abp->nangles; i++) {
451	>	for (ni = nisamps; ni--; ) { /* sample over incident patch */
452	>	RBFNODE *rbf;
453	>	if (input_orient > 0) /* vary incident patch loc. */
454	>	fi_getvec(vin, i+urand(ni), abp);
455	>	else
456	>	bi_getvec(vin, i+urand(ni), abp);
457
458	<	rbf = advect_rbf(vin, lobe_lim); /* compute radial basis func */
458	>	rbf = advect_rbf(vin, lobe_lim); /* compute radial basis func */
459
460	<	for (j = 0; j < abp->nangles; j++) {
461	<	sum = 0; /* sample over exiting patch */
462	<	for (n = npsamps; n--; ) {
460	>	for (j = 0; j < abp->nangles; j++) {
461	>	sum = 0; /* sample over exiting patch */
462	>	xsum = ysum = 0;
463	>	for (no = nosamps; no--; ) {
464	>	SDValue sdv;
465		if (output_orient > 0)
466	<	fo_getvec(vout, j+(n+frandom())/npsamps, abp);
466	>	fo_getvec(vout, j+(no+frandom())/nosamps, abp);
467		else
468	<	bo_getvec(vout, j+(n+frandom())/npsamps, abp);
468	>	bo_getvec(vout, j+(no+frandom())/nosamps, abp);
469
470	<	sum += eval_rbfrep(rbf, vout) / vout[2];
470	>	eval_rbfcol(&sdv, rbf, vout);
471	>	sum += sdv.cieY;
472	>	if (rbf_colorimetry == RBCtristimulus) {
473	>	xsum += sdv.cieY * sdv.spec.cx;
474	>	ysum += sdv.cieY * sdv.spec.cy;
475	>	}
476		}
477	<	bsdfarr[jabp->nangles + i] = sumoutput_orient/npsamps;
477	>	no = j*abp->nangles + i;
478	>	bsdfarr[no] += sum * normf;
479	>	if (rbf_colorimetry == RBCtristimulus) {
480	>	XZarr[no][0] += xsumsumnormf/ysum;
481	>	XZarr[no][1] += (sum - xsum - ysum)sumnormf/ysum;
482	>	}
483		}
484	<	if (rbf != NULL)
484	>	if (rbf != NULL)
485		free(rbf);
486		}
487	<	n = 0; /* write out our matrix */
488	<	for (j = 0; j < abp->nangles; j++) {
489	<	for (i = 0; i < abp->nangles; i++)
490	<	printf("\t%.3e\n", bsdfarr[n++]);
491	<	putchar('\n');
487	>	prog_show((i+1.)/abp->nangles);
488	>	}
489	>	/* write out our matrix */
490	>	cfp[CIE_Y] = open_component_file(CIE_Y);
491	>	no = 0;
492	>	for (j = 0; j < abp->nangles; j++) {
493	>	for (i = 0; i < abp->nangles; i++, no++)
494	>	fprintf(cfp[CIE_Y], "\t%.3e\n", bsdfarr[no]);
495	>	fputc('\n', cfp[CIE_Y]);
496	>	}
497	>	prog_done();
498	>	if (fclose(cfp[CIE_Y])) {
499	>	fprintf(stderr, "%s: error writing Y output\n", progname);
500	>	exit(1);
501	>	}
502	>	if (XZarr == NULL) /* no color? */
503	>	return;
504	>	cfp[CIE_X] = open_component_file(CIE_X);
505	>	cfp[CIE_Z] = open_component_file(CIE_Z);
506	>	no = 0;
507	>	for (j = 0; j < abp->nangles; j++) {
508	>	for (i = 0; i < abp->nangles; i++, no++) {
509	>	fprintf(cfp[CIE_X], "\t%.3e\n", XZarr[no][0]);
510	>	fprintf(cfp[CIE_Z], "\t%.3e\n", XZarr[no][1]);
511	>	}
512	>	fputc('\n', cfp[CIE_X]);
513	>	fputc('\n', cfp[CIE_Z]);
514	>	}
515	>	free(XZarr);
516	>	if (fclose(cfp[CIE_X]) \|\| fclose(cfp[CIE_Z])) {
517	>	fprintf(stderr, "%s: error writing X/Z output\n", progname);
518	>	exit(1);
519	>	}
520	>	}
521	>
522	>	#if defined(_WIN32) \|\| defined(_WIN64)
523	>	/* Execute wrapBSDF command (may never return) */
524	>	static int
525	>	wrap_up(void)
526	>	{
527	>	char cmd[8192];
528	>
529	>	if (bsdf_manuf[0]) {
530	>	add_wbsdf("-f", 1);
531	>	strcpy(cmd, "m=");
532	>	strcpy(cmd+2, bsdf_manuf);
533	>	add_wbsdf(cmd, 0);
534		}
535	<	data_epilogue(); /* finish output */
535	>	if (bsdf_name[0]) {
536	>	add_wbsdf("-f", 1);
537	>	strcpy(cmd, "n=");
538	>	strcpy(cmd+2, bsdf_name);
539	>	add_wbsdf(cmd, 0);
540	>	}
541	>	if (!convert_commandline(cmd, sizeof(cmd), wrapBSDF)) {
542	>	fputs(progname, stderr);
543	>	fputs(": command line too long in wrap_up()\n", stderr);
544	>	return(1);
545	>	}
546	>	return(system(cmd));
547		}
548	+	#else
549	+	/* Execute wrapBSDF command (may never return) */
550	+	static int
551	+	wrap_up(void)
552	+	{
553	+	char buf[256];
554	+	char compath = getpath((char )wrapBSDF[0], getenv("PATH"), X_OK);
555
556	+	if (compath == NULL) {
557	+	fprintf(stderr, "%s: cannot locate %s\n", progname, wrapBSDF[0]);
558	+	return(1);
559	+	}
560	+	if (bsdf_manuf[0]) {
561	+	add_wbsdf("-f", 1);
562	+	strcpy(buf, "m=");
563	+	strcpy(buf+2, bsdf_manuf);
564	+	add_wbsdf(buf, 0);
565	+	}
566	+	if (bsdf_name[0]) {
567	+	add_wbsdf("-f", 1);
568	+	strcpy(buf, "n=");
569	+	strcpy(buf+2, bsdf_name);
570	+	add_wbsdf(buf, 0);
571	+	}
572	+	execv(compath, wrapBSDF); /* successful call never returns */
573	+	perror(compath);
574	+	return(1);
575	+	}
576	+	#endif
577	+
578		/* Read in BSDF and interpolate as Klems matrix representation */
579		int
580		main(int argc, char *argv[])
581		{
582		int dofwd = 0, dobwd = 1;
583	+	char buf[2048];
584		char *cp;
585		int i, na;
586
#	Line 373 \| Line 602 \| *main(int argc, char argv[])**
602		break;
603		case 'f':
604		if (!argv[i][2]) {
605	<	fcompile(argv[++i]);
606	<	single_plane_incident = 0;
605	>	if (strchr(argv[++i], '=') != NULL) {
606	>	add_wbsdf("-f", 1);
607	>	add_wbsdf(argv[i], 1);
608	>	} else {
609	>	char *fpath = getpath(argv[i],
610	>	getrlibpath(), 0);
611	>	if (fpath == NULL) {
612	>	fprintf(stderr,
613	>	"%s: cannot find file '%s'\n",
614	>	argv[0], argv[i]);
615	>	return(1);
616	>	}
617	>	fcompile(fpath);
618	>	single_plane_incident = 0;
619	>	}
620		} else
621		dofwd = (argv[i][0] == '+');
622		break;
#	Line 382 \| Line 624 \| *main(int argc, char argv[])**
624		dobwd = (argv[i][0] == '+');
625		break;
626		case 'h':
627	<	kbasis = "LBNL/Klems Half";
627	>	kbasis = klems_half;
628	>	add_wbsdf("-a", 1);
629	>	add_wbsdf("kh", 1);
630		break;
631		case 'q':
632	<	kbasis = "LBNL/Klems Quarter";
632	>	kbasis = klems_quarter;
633	>	add_wbsdf("-a", 1);
634	>	add_wbsdf("kq", 1);
635		break;
636		case 'l':
637		lobe_lim = atoi(argv[++i]);
638		break;
639	+	case 'p':
640	+	do_prog = atoi(argv[i]+2);
641	+	break;
642	+	case 'C':
643	+	add_wbsdf(argv[i], 1);
644	+	add_wbsdf(argv[++i], 1);
645	+	break;
646		default:
647		goto userr;
648		}
649	+	if (kbasis == klems_full) { /* default (full) basis? */
650	+	add_wbsdf("-a", 1);
651	+	add_wbsdf("kf", 1);
652	+	}
653	+	strcpy(buf, "File produced by: ");
654	+	if (convert_commandline(buf+18, sizeof(buf)-18, argv) != NULL) {
655	+	add_wbsdf("-C", 1); add_wbsdf(buf, 0);
656	+	}
657		if (single_plane_incident >= 0) { /* function-based BSDF? */
658	<	if (i != argc-1 \|\| fundefined(argv[i]) != 6) {
658	>	if (i != argc-1 \|\| fundefined(argv[i]) < 3) {
659		fprintf(stderr,
660		"%s: need single function with 6 arguments: bsdf(ix,iy,iz,ox,oy,oz)\n",
661		progname);
662	<	fprintf(stderr, "\tor 3 arguments using Dx,Dy,Dz: bsdf(ix,iy,iz)\n",
402	<	progname);
662	>	fprintf(stderr, "\tor 3 arguments using Dx,Dy,Dz: bsdf(ix,iy,iz)\n");
663		goto userr;
664		}
665		++eclock;
406	–	xml_header(argc, argv); /* start XML output */
407	–	xml_prologue(NULL);
666		if (dofwd) {
667		input_orient = -1;
668		output_orient = -1;
669	<	eval_function(argv[i]); /* outside reflectance */
669	>	prog_start("Evaluating outside reflectance");
670	>	eval_function(argv[i]);
671		output_orient = 1;
672	<	eval_function(argv[i]); /* outside -> inside */
672	>	prog_start("Evaluating outside->inside transmission");
673	>	eval_function(argv[i]);
674		}
675		if (dobwd) {
676		input_orient = 1;
677		output_orient = 1;
678	<	eval_function(argv[i]); /* inside reflectance */
678	>	prog_start("Evaluating inside reflectance");
679	>	eval_function(argv[i]);
680		output_orient = -1;
681	<	eval_function(argv[i]); /* inside -> outside */
681	>	prog_start("Evaluating inside->outside transmission");
682	>	eval_function(argv[i]);
683		}
684	<	xml_epilogue(); /* finish XML output & exit */
423	<	return(0);
684	>	return(wrap_up());
685		}
686		/* XML input? */
687		if (i == argc-1 && (cp = argv[i]+strlen(argv[i])-4) > argv[i] &&
688		!strcasecmp(cp, ".xml")) {
428	–	xml_header(argc, argv); /* start XML output */
689		eval_bsdf(argv[i]); /* load & resample BSDF */
690	<	xml_epilogue(); /* finish XML output & exit */
431	<	return(0);
690	>	return(wrap_up());
691		}
692		if (i < argc) { /* open input files if given */
693		int nbsdf = 0;
694		for ( ; i < argc; i++) { /* interpolate each component */
695	+	char pbuf[256];
696		FILE *fpin = fopen(argv[i], "rb");
697		if (fpin == NULL) {
698		fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
#	Line 442 \| Line 702 \| *main(int argc, char argv[])**
702		if (!load_bsdf_rep(fpin))
703		return(1);
704		fclose(fpin);
705	<	if (!nbsdf++) { /* start XML on first dist. */
706	<	xml_header(argc, argv);
447	<	xml_prologue(NULL);
448	<	}
705	>	sprintf(pbuf, "Interpolating component '%s'", argv[i]);
706	>	prog_start(pbuf);
707		eval_rbf();
708		}
709	<	xml_epilogue(); /* finish XML output & exit */
452	<	return(0);
709	>	return(wrap_up());
710		}
711		SET_FILE_BINARY(stdin); /* load from stdin */
712		if (!load_bsdf_rep(stdin))
713		return(1);
714	<	xml_header(argc, argv); /* start XML output */
458	<	xml_prologue(NULL);
714	>	prog_start("Interpolating from standard input");
715		eval_rbf(); /* resample dist. */
716	<	xml_epilogue(); /* finish XML output & exit */
461	<	return(0);
716	>	return(wrap_up());
717		userr:
718		fprintf(stderr,
719		"Usage: %s [-n spp][-h\|-q][-l maxlobes] [bsdf.sir ..] > bsdf.xml\n", progname);

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Comparing ray/src/cv/bsdf2klems.c (file contents): Revision 2.10 by greg, Thu Sep 26 17:05:00 2013 UTC vs. Revision 2.28 by greg, Sat Dec 28 18:05:14 2019 UTC

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Comparing ray/src/cv/bsdf2klems.c (file contents):
Revision 2.10 by greg, Thu Sep 26 17:05:00 2013 UTC vs.
Revision 2.28 by greg, Sat Dec 28 18:05:14 2019 UTC