[ViewVC] Diff of: radiance/ray/src/cv/bsdf2rad.c

Comparing ray/src/cv/bsdf2rad.c (file contents):
Revision 2.16 by greg, Sun Apr 9 21:39:26 2017 UTC vs.
Revision 2.33 by greg, Mon Oct 2 22:11:32 2017 UTC

#	Line 13 \| Line 13 \| static const char RCSid[] = "$Id$";
13		#include "resolu.h"
14		#include "bsdfrep.h"
15
16	<	#define NINCIDENT 25 /* number of samples/hemisphere */
17	<
16	>	#ifndef NINCIDENT
17	>	#define NINCIDENT 37 /* number of samples/hemisphere */
18	>	#endif
19	>	#ifndef GRIDSTEP
20		#define GRIDSTEP 2 /* our grid step size */
21	+	#endif
22		#define SAMPRES (GRIDRES/GRIDSTEP)
23
24		int front_comp = 0; /* front component flags (SDsamp) /
#	Line 24 \| Line 27 \| *double overall_min = 1./PI; / overall minimum BSDF v**
27		double min_log10; /* smallest log10 value for plotting */
28		double overall_max = .0; /* overall maximum BSDF value */
29
30	<	char ourTempDir[TEMPLEN] = ""; /* our temporary directory */
30	>	char ourTempDir[TEMPLEN+1] = ""; /* our temporary directory */
31
32	<	const FVECT Xaxis = {1., 0., 0.};
33	<	const FVECT Yaxis = {0., 1., 0.};
34	<	const FVECT Zaxis = {0., 0., 1.};
35	<
33	<	const char frpref[] = "frefl";
34	<	const char ftpref[] = "ftrans";
35	<	const char brpref[] = "brefl";
36	<	const char btpref[] = "btrans";
32	>	const char frpref[] = "rf";
33	>	const char ftpref[] = "tf";
34	>	const char brpref[] = "rb";
35	>	const char btpref[] = "tb";
36		const char dsuffix[] = ".txt";
37
38	<	const char sph_mat[] = "BSDFmat";
38	>	const char sph_fmat[] = "fBSDFmat";
39	>	const char sph_bmat[] = "bBSDFmat";
40		const double sph_rad = 10.;
41		const double sph_xoffset = 15.;
42
#	Line 45 \| Line 45 \| const double sph_xoffset = 15.;
45
46		#define FEQ(a,b) ((a)-(b) <= 1e-7 && (b)-(a) <= 1e-7)
47
48	<	#define set_minlog() (min_log10 = log10(overall_min + 1e-5) - .1)
48	>	#define set_minlog() overall_min = (overall_min < 1e-5) ? 1e-5 : overall_min; \
49	>	min_log10 = log10(overall_min) - .1
50
51		char *progname;
52
53		/* Get Fibonacci sphere vector (0 to NINCIDENT-1) */
54	<	static void
54	>	static RREAL *
55		get_ivector(FVECT iv, int i)
56		{
56	–	const double zstep = 1./(2*NINCIDENT-1);
57		const double phistep = PI*(3. - 2.236067978);
58		double r;
59
60	<	iv[2] = 1. - (i+.5)*zstep;
60	>	iv[2] = 1. - (i+.5)*(1./NINCIDENT);
61		r = sqrt(1. - iv[2]*iv[2]);
62		iv[0] = r * cos((i+1.)*phistep);
63		iv[1] = r * sin((i+1.)*phistep);
64	+
65	+	return(iv);
66		}
67
68	+	/* Convert incident vector into sphere position */
69	+	static RREAL *
70	+	cvt_sposition(FVECT sp, const FVECT iv, int inc_side)
71	+	{
72	+	sp[0] = -iv[0]sph_rad + inc_sidesph_xoffset;
73	+	sp[1] = -iv[1]*sph_rad;
74	+	sp[2] = iv[2]*sph_rad;
75	+
76	+	return(sp);
77	+	}
78	+
79		/* Get temporary file name */
80		static char *
81		tfile_name(const char prefix, const char suffix, int i)
82		{
83	<	static char buf[128];
83	>	static char buf[256];
84
85		if (!ourTempDir[0]) { /* create temporary directory */
86		mktemp(strcpy(ourTempDir,TEMPLATE));
#	Line 249 \| Line 262 \| build_wRBF(void)
262		RBFNODE *rbf;
263		get_ivector(ivec, i);
264		if (input_orient < 0) {
265	<	ivec[0] = -ivec[0]; ivec[1] = -ivec[1]; ivec[2] = -ivec[2];
265	>	ivec[0] = -ivec[0]; ivec[2] = -ivec[2];
266		}
267		rbf = advect_rbf(ivec, 15000);
268		if (!plotRBF(tfile_name(pref, dsuffix, i), rbf))
#	Line 261 \| Line 274 \| build_wRBF(void)
274
275		/* Put out mirror arrow for the given incident vector */
276		static void
277	<	put_mirror_arrow(const FVECT ivec, int inc_side)
277	>	put_mirror_arrow(const FVECT origin, const FVECT nrm)
278		{
279		const double arrow_len = 1.2*bsdf_rad;
280		const double tip_len = 0.2*bsdf_rad;
281	<	FVECT origin, refl;
281	>	static int cnt = 1;
282	>	FVECT refl;
283		int i;
284
285	<	for (i = 3; i--; ) origin[i] = ivec[i]*sph_rad;
286	<	origin[0] -= inc_side*sph_xoffset;
285	>	refl[0] = 2.nrm[2]nrm[0];
286	>	refl[1] = 2.nrm[2]nrm[1];
287	>	refl[2] = 2.nrm[2]nrm[2] - 1.;
288
289	<	refl[0] = 2.ivec[2]ivec[0];
290	<	refl[1] = 2.ivec[2]ivec[1];
276	<	refl[2] = 2.ivec[2]ivec[2] - 1.;
277	<
278	<	printf("\n# Mirror arrow\n");
279	<	printf("\narrow_mat cylinder inc_dir\n0\n0\n7");
289	>	printf("\n# Mirror arrow #%d\n", cnt);
290	>	printf("\nshaft_mat cylinder inc_dir%d\n0\n0\n7", cnt);
291		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n",
292		origin[0], origin[1], origin[2]+arrow_len,
293		origin[0], origin[1], origin[2],
294		arrow_rad);
295	<	printf("\narrow_mat cylinder mir_dir\n0\n0\n7");
295	>	printf("\nshaft_mat cylinder mir_dir%d\n0\n0\n7", cnt);
296		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n",
297		origin[0], origin[1], origin[2],
298		origin[0] + arrow_len*refl[0],
299		origin[1] + arrow_len*refl[1],
300		origin[2] + arrow_len*refl[2],
301		arrow_rad);
302	<	printf("\narrow_mat cone mir_tip\n0\n0\n8");
302	>	printf("\ntip_mat cone mir_tip%d\n0\n0\n8", cnt);
303		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f 0\n",
304		origin[0] + (arrow_len-.5tip_len)refl[0],
305		origin[1] + (arrow_len-.5tip_len)refl[1],
#	Line 297 \| Line 308 \| put_mirror_arrow(const FVECT ivec, int inc_side)
308		origin[1] + (arrow_len+.5tip_len)refl[1],
309		origin[2] + (arrow_len+.5tip_len)refl[2],
310		2.*arrow_rad);
311	+	++cnt;
312		}
313
314		/* Put out transmitted direction arrow for the given incident vector */
315		static void
316	<	put_trans_arrow(const FVECT ivec, int inc_side)
316	>	put_trans_arrow(const FVECT origin)
317		{
318		const double arrow_len = 1.2*bsdf_rad;
319		const double tip_len = 0.2*bsdf_rad;
320	<	FVECT origin;
320	>	static int cnt = 1;
321		int i;
322
323	<	for (i = 3; i--; ) origin[i] = ivec[i]*sph_rad;
324	<	origin[0] -= inc_side*sph_xoffset;
313	<
314	<	printf("\n# Transmission arrow\n");
315	<	printf("\narrow_mat cylinder trans_dir\n0\n0\n7");
323	>	printf("\n# Transmission arrow #%d\n", cnt);
324	>	printf("\nshaft_mat cylinder trans_dir%d\n0\n0\n7", cnt);
325		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n",
326		origin[0], origin[1], origin[2],
327		origin[0], origin[1], origin[2]-arrow_len,
328		arrow_rad);
329	<	printf("\narrow_mat cone trans_tip\n0\n0\n8");
329	>	printf("\ntip_mat cone trans_tip%d\n0\n0\n8", cnt);
330		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f 0\n",
331		origin[0], origin[1], origin[2]-arrow_len+.5*tip_len,
332		origin[0], origin[1], origin[2]-arrow_len-.5*tip_len,
333	<	2.*arrow_rad);
333	>	2.*arrow_rad);
334	>	++cnt;
335		}
336
337		/* Compute rotation (x,y,z) => (xp,yp,zp) */
#	Line 365 \| Line 375 \| static int
375		put_BSDFs(void)
376		{
377		const double scalef = bsdf_rad/(log10(overall_max) - min_log10);
378	<	FVECT ivec;
378	>	FVECT ivec, sorg, nrm, upv;
379		RREAL vMtx[3][3];
380		char *fname;
381		char cmdbuf[256];
382	<	char xfargs[128];
383	<	int nxfa;
382	>	char rotargs[64];
383	>	int nrota;
384		int i;
385
386		printf("\n# Gensurf output corresponding to %d incident directions\n",
387		NINCIDENT);
388
389	<	printf("\nvoid glow arrow_glow\n0\n0\n4 1 0 1 0\n");
390	<	printf("\nvoid mixfunc arrow_mat\n4 arrow_glow void .5 .\n0\n0\n");
389	>	printf("\nvoid glow tip_mat\n0\n0\n4 1 0 1 0\n");
390	>	printf("\nvoid mixfunc shaft_mat\n4 tip_mat void 0.25 .\n0\n0\n");
391
392	<	if (front_comp & SDsampR)
393	<	for (i = 0; i < NINCIDENT; i++) {
394	<	get_ivector(ivec, i);
395	<	put_mirror_arrow(ivec, 1);
396	<	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
397	<	ivec[0]*sph_rad - sph_xoffset,
398	<	ivec[1]sph_rad, ivec[2]sph_rad);
399	<	nxfa = 6;
392	>	for (i = 0; i < NINCIDENT; i++) {
393	>	get_ivector(ivec, i);
394	>	nrm[0] = -ivec[0]; nrm[1] = -ivec[1]; nrm[2] = ivec[2];
395	>	upv[0] = nrm[0]nrm[1](nrm[2] - 1.);
396	>	upv[1] = nrm[0]nrm[0] + nrm[1]nrm[1]*nrm[2];
397	>	upv[2] = -nrm[1](nrm[0]nrm[0] + nrm[1]*nrm[1]);
398	>	if (SDcompXform(vMtx, nrm, upv) != SDEnone)
399	>	continue;
400	>	nrota = addrot(rotargs, vMtx[0], vMtx[1], vMtx[2]);
401	>	if (front_comp) {
402	>	cvt_sposition(sorg, ivec, 1);
403		printf("\nvoid colorfunc scale_pat\n");
404	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
405	<	4+nxfa, xfargs);
404	>	printf("10 bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n");
405	>	printf("\t-s %f -t %f %f %f\n0\n0\n",
406	>	bsdf_rad, sorg[0], sorg[1], sorg[2]);
407		printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
408	<	SDcompXform(vMtx, ivec, Yaxis);
409	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
410	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
397	<	scalef, ivec[0]*sph_rad - sph_xoffset,
398	<	ivec[1]sph_rad, ivec[2]sph_rad);
399	<	nxfa += 6;
408	>	}
409	>	if (front_comp & SDsampR) {
410	>	put_mirror_arrow(sorg, nrm);
411		fname = tfile_name(frpref, dsuffix, i);
412	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform -mx -my %s",
413	<	frpref, i+1, fname, fname, fname, SAMPRES-1, SAMPRES-1,
414	<	xfargs);
412	>	sprintf(cmdbuf,
413	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform %s -s %f -t %f %f %f",
414	>	frpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
415	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
416		if (!run_cmd(cmdbuf))
417		return(0);
418		}
419	<	if (front_comp & SDsampT)
420	<	for (i = 0; i < NINCIDENT; i++) {
409	<	get_ivector(ivec, i);
410	<	put_trans_arrow(ivec, 1);
411	<	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
412	<	ivec[0]*sph_rad - sph_xoffset,
413	<	ivec[1]sph_rad, ivec[2]sph_rad);
414	<	nxfa = 6;
415	<	printf("\nvoid colorfunc scale_pat\n");
416	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
417	<	4+nxfa, xfargs);
418	<	printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
419	<	SDcompXform(vMtx, ivec, Yaxis);
420	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
421	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
422	<	scalef, ivec[0]*sph_rad - sph_xoffset,
423	<	ivec[1]sph_rad, ivec[2]sph_rad);
424	<	nxfa += 6;
419	>	if (front_comp & SDsampT) {
420	>	put_trans_arrow(sorg);
421		fname = tfile_name(ftpref, dsuffix, i);
422	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform -I -mx -my %s",
423	<	ftpref, i+1, fname, fname, fname, SAMPRES-1, SAMPRES-1,
424	<	xfargs);
422	>	sprintf(cmdbuf,
423	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform -I %s -s %f -t %f %f %f",
424	>	ftpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
425	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
426		if (!run_cmd(cmdbuf))
427		return(0);
428		}
429	<	if (back_comp & SDsampR)
430	<	for (i = 0; i < NINCIDENT; i++) {
434	<	get_ivector(ivec, i);
435	<	put_mirror_arrow(ivec, -1);
436	<	fname = tfile_name(brpref, dsuffix, i);
437	<	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
438	<	ivec[0]*sph_rad + sph_xoffset,
439	<	ivec[1]sph_rad, ivec[2]sph_rad);
440	<	nxfa = 6;
429	>	if (back_comp) {
430	>	cvt_sposition(sorg, ivec, -1);
431		printf("\nvoid colorfunc scale_pat\n");
432	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
433	<	4+nxfa, xfargs);
432	>	printf("10 bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n");
433	>	printf("\t-s %f -t %f %f %f\n0\n0\n",
434	>	bsdf_rad, sorg[0], sorg[1], sorg[2]);
435		printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
436	<	SDcompXform(vMtx, ivec, Yaxis);
437	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
438	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
448	<	scalef, ivec[0]*sph_rad + sph_xoffset,
449	<	ivec[1]sph_rad, ivec[2]sph_rad);
450	<	nxfa += 6;
436	>	}
437	>	if (back_comp & SDsampR) {
438	>	put_mirror_arrow(sorg, nrm);
439		fname = tfile_name(brpref, dsuffix, i);
440	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform -I -ry 180 -mx -my %s",
441	<	brpref, i+1, fname, fname, fname, SAMPRES-1, SAMPRES-1,
442	<	xfargs);
440	>	sprintf(cmdbuf,
441	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform -I -ry 180 %s -s %f -t %f %f %f",
442	>	brpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
443	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
444		if (!run_cmd(cmdbuf))
445		return(0);
446		}
447	<	if (back_comp & SDsampT)
448	<	for (i = 0; i < NINCIDENT; i++) {
460	<	get_ivector(ivec, i);
461	<	put_trans_arrow(ivec, -1);
447	>	if (back_comp & SDsampT) {
448	>	put_trans_arrow(sorg);
449		fname = tfile_name(btpref, dsuffix, i);
450	<	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
451	<	ivec[0]*sph_rad + sph_xoffset,
452	<	ivec[1]sph_rad, ivec[2]sph_rad);
453	<	nxfa = 6;
467	<	printf("\nvoid colorfunc scale_pat\n");
468	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
469	<	4+nxfa, xfargs);
470	<	printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
471	<	SDcompXform(vMtx, ivec, Yaxis);
472	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
473	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
474	<	scalef, ivec[0]*sph_rad + sph_xoffset,
475	<	ivec[1]sph_rad, ivec[2]sph_rad);
476	<	nxfa += 6;
477	<	fname = tfile_name(btpref, dsuffix, i);
478	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform -ry 180 -mx -my %s",
479	<	btpref, i+1, fname, fname, fname, SAMPRES-1, SAMPRES-1,
480	<	xfargs);
450	>	sprintf(cmdbuf,
451	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform -ry 180 %s -s %f -t %f %f %f",
452	>	btpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
453	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
454		if (!run_cmd(cmdbuf))
455		return(0);
456		}
457	+	}
458		return(1);
459		}
460
#	Line 494 \| Line 468 \| *put_matBSDF(const char XMLfile)**
468		printf("\n# Simplified material because we have no XML input\n");
469		printf("\nvoid brightfunc latlong\n2 latlong bsdf2rad.cal\n0\n0\n");
470		if ((front_comp\|back_comp) & SDsampT)
471	<	printf("\nlatlong trans %s\n0\n0\n7 .75 .75 .75 0 0 .5 .8\n",
472	<	sph_mat);
471	>	printf("\nlatlong trans %s\n0\n0\n7 .75 .75 .75 0 .04 .5 .8\n",
472	>	sph_fmat);
473		else
474		printf("\nlatlong plastic %s\n0\n0\n5 .5 .5 .5 0 0\n",
475	<	sph_mat);
475	>	sph_fmat);
476	>	printf("\ninherit alias %s %s\n", sph_bmat, sph_fmat);
477		return;
478		}
479		switch (XMLfile[0]) { /* avoid RAYPATH search */
480		case '.':
481	+	case '~':
482		CASEDIRSEP:
483		curdir = "";
484		break;
#	Line 511 \| Line 487 \| *put_matBSDF(const char XMLfile)**
487		exit(1);
488		break;
489		}
490	<	printf("\n# Actual BSDF material for rendering the hemispheres\n");
491	<	printf("\nvoid BSDF BSDFmat\n6 0 \"%s%s\" 0 1 0 .\n0\n0\n",
490	>	printf("\n# Actual BSDF materials for rendering the hemispheres\n");
491	>	printf("\nvoid BSDF BSDF_f\n6 0 \"%s%s\" upx upy upz bsdf2rad.cal\n0\n0\n",
492		curdir, XMLfile);
493		printf("\nvoid plastic black\n0\n0\n5 0 0 0 0 0\n");
494	<	printf("\nvoid mixfunc %s\n4 BSDFmat black latlong bsdf2rad.cal\n0\n0\n",
495	<	sph_mat);
494	>	printf("\nvoid mixfunc %s\n4 BSDF_f black latlong bsdf2rad.cal\n0\n0\n",
495	>	sph_fmat);
496	>	printf("\nvoid BSDF BSDF_b\n8 0 \"%s%s\" upx upy upz bsdf2rad.cal -ry 180\n0\n0\n",
497	>	curdir, XMLfile);
498	>	printf("\nvoid mixfunc %s\n4 BSDF_b black latlong bsdf2rad.cal\n0\n0\n",
499	>	sph_bmat);
500		}
501
502		/* Put out overhead parallel light source */
#	Line 524 \| Line 504 \| static void
504		put_source(void)
505		{
506		printf("\n# Overhead parallel light source\n");
507	<	printf("\nvoid light bright\n0\n0\n3 1000 1000 1000\n");
507	>	printf("\nvoid light bright\n0\n0\n3 2500 2500 2500\n");
508		printf("\nbright source light\n0\n0\n4 0 0 1 2\n");
509		printf("\n# Material used for labels\n");
510		printf("\nvoid trans vellum\n0\n0\n7 1 1 1 0 0 .5 0\n");
#	Line 534 \| Line 514 \| put_source(void)
514		static void
515		put_hemispheres(void)
516		{
517	+	const int nsegs = 131;
518	+
519		printf("\n# Hemisphere(s) for showing BSDF appearance (if XML file)\n");
538	–	printf("\nvoid antimatter anti_sph\n2 void %s\n0\n0\n", sph_mat);
520		if (front_comp) {
521	<	printf("\n%s sphere Front\n0\n0\n4 %f 0 0 %f\n",
522	<	sph_mat, -sph_xoffset, sph_rad);
523	<	printf("\n!genbox anti_sph sph_eraser %f %f %f \| xform -t %f %f %f\n",
543	<	2.02sph_rad, 2.02sph_rad, 1.02*sph_rad,
544	<	-1.01sph_rad - sph_xoffset, -1.01sph_rad, -1.01*sph_rad);
521	>	printf(
522	>	"\n!genrev %s Front \"Rsin(At)\" \"Rcos(At)\" %d -e \"R:%g;A:%f\" -s \| xform -t %g 0 0\n",
523	>	sph_fmat, nsegs, sph_rad, 0.5*PI, sph_xoffset);
524		printf("\nvoid brighttext front_text\n3 helvet.fnt . FRONT\n0\n");
525		printf("12\n\t%f %f 0\n\t%f 0 0\n\t0 %f 0\n\t.01 1 -.1\n",
526	<	-.22sph_rad - sph_xoffset, -1.2sph_rad,
526	>	-.22sph_rad + sph_xoffset, -1.4sph_rad,
527		.35/5.sph_rad, -1.6.35/5.*sph_rad);
528		printf("\nfront_text alias front_label_mat vellum\n");
529		printf("\nfront_label_mat polygon front_label\n0\n0\n12");
530		printf("\n\t%f %f 0\n\t%f %f 0\n\t%f %f 0\n\t%f %f 0\n",
531	<	-.25sph_rad - sph_xoffset, -1.1sph_rad,
532	<	-.25sph_rad - sph_xoffset, (-1.2-1.6.35/5.-.1)*sph_rad,
533	<	.25sph_rad - sph_xoffset, (-1.2-1.6.35/5.-.1)*sph_rad,
534	<	.25sph_rad - sph_xoffset, -1.1sph_rad );
531	>	-.25sph_rad + sph_xoffset, -1.3sph_rad,
532	>	-.25sph_rad + sph_xoffset, (-1.4-1.6.35/5.-.1)*sph_rad,
533	>	.25sph_rad + sph_xoffset, (-1.4-1.6.35/5.-.1)*sph_rad,
534	>	.25sph_rad + sph_xoffset, -1.3sph_rad );
535		}
536		if (back_comp) {
537	<	printf("\n%s bubble Back\n0\n0\n4 %f 0 0 %f\n",
538	<	sph_mat, sph_xoffset, sph_rad);
539	<	printf("\n!genbox anti_sph sph_eraser %f %f %f \| xform -t %f %f %f\n",
561	<	2.02sph_rad, 2.02sph_rad, 1.02*sph_rad,
562	<	-1.01sph_rad + sph_xoffset, -1.01sph_rad, -1.01*sph_rad);
537	>	printf(
538	>	"\n!genrev %s Back \"Rcos(At)\" \"Rsin(At)\" %d -e \"R:%g;A:%f\" -s \| xform -t %g 0 0\n",
539	>	sph_bmat, nsegs, sph_rad, 0.5*PI, -sph_xoffset);
540		printf("\nvoid brighttext back_text\n3 helvet.fnt . BACK\n0\n");
541		printf("12\n\t%f %f 0\n\t%f 0 0\n\t0 %f 0\n\t.01 1 -.1\n",
542	<	-.22sph_rad + sph_xoffset, -1.2sph_rad,
542	>	-.22sph_rad - sph_xoffset, -1.4sph_rad,
543		.35/4.sph_rad, -1.6.35/4.*sph_rad);
544		printf("\nback_text alias back_label_mat vellum\n");
545		printf("\nback_label_mat polygon back_label\n0\n0\n12");
546		printf("\n\t%f %f 0\n\t%f %f 0\n\t%f %f 0\n\t%f %f 0\n",
547	<	-.25sph_rad + sph_xoffset, -1.1sph_rad,
548	<	-.25sph_rad + sph_xoffset, (-1.2-1.6.35/4.-.1)*sph_rad,
549	<	.25sph_rad + sph_xoffset, (-1.2-1.6.35/4.-.1)*sph_rad,
550	<	.25sph_rad + sph_xoffset, -1.1sph_rad );
547	>	-.25sph_rad - sph_xoffset, -1.3sph_rad,
548	>	-.25sph_rad - sph_xoffset, (-1.4-1.6.35/4.-.1)*sph_rad,
549	>	.25sph_rad - sph_xoffset, (-1.4-1.6.35/4.-.1)*sph_rad,
550	>	.25sph_rad - sph_xoffset, -1.3sph_rad );
551		}
552		}
553
#	Line 579 \| Line 556 \| static void
556		put_scale(void)
557		{
558		const double max_log10 = log10(overall_max);
559	<	const double leg_width = 2..75(sph_xoffset - sph_rad);
559	>	const double leg_width = 2..75(fabs(sph_xoffset) - sph_rad);
560		const double leg_height = 2.*sph_rad;
561		const int text_lines = 6;
562	<	const int text_digits = 7;
562	>	const int text_digits = 8;
563		char fmt[16];
564		int i;
565
566		printf("\n# BSDF legend with falsecolor scale\n");
567		printf("\nvoid colorfunc lscale\n10 sca_red(Py) sca_grn(Py) sca_blu(Py)");
568		printf("\n\tbsdf2rad.cal -s %f -t 0 %f 0\n0\n0\n", leg_height, -.5*leg_height);
569	<	sprintf(fmt, "%%%dg", text_digits-2);
569	>	sprintf(fmt, "%%.%df", text_digits-3);
570		for (i = 0; i < text_lines; i++) {
571		char vbuf[16];
572		sprintf(vbuf, fmt, pow(10., (i+.5)/text_lines*(max_log10-min_log10)+min_log10));
573		printf("\nlscale brighttext lscale\n");
574		printf("3 helvet.fnt . %s\n0\n12\n", vbuf);
575		printf("\t%f %f 0\n", -.45leg_width, ((i+.9)/text_lines-.5)leg_height);
576	<	printf("\t%f 0 0\n", .9*leg_width/strlen(vbuf));
576	>	printf("\t%f 0 0\n", .8*leg_width/strlen(vbuf));
577		printf("\t0 %f 0\n", -.9/text_lines*leg_height);
578		printf("\t.01 1 -.1\n");
579		}
#	Line 623 \| Line 600 \| put_scale(void)
600		return;
601		printf("\nvoid brighttext BSDFname\n3 helvet.fnt . \"%s\"\n0\n12\n", bsdf_name);
602		printf("\t%f %f 0\n", -.95leg_width, -.6leg_height);
603	<	printf("\t%f 0 0\n", .4/strlen(bsdf_name)*leg_width);
603	>	printf("\t%f 0 0\n", 1.8/strlen(bsdf_name)*leg_width);
604		printf("\t0 %f 0\n", -.1*leg_height);
605		printf("\t.01 1 -.1\n");
606		printf("\nBSDFname alias name_mat vellum\n");
#	Line 678 \| Line 655 \| *convert_mgf(const char mgfdata)**
655		sprintf(cmdbuf, "xform -t %f %f %f -s %f -t %f %f 0 %s",
656		-.5(xmin+xmax), -.5(ymin+ymax), -zmax,
657		1.5*sph_rad/max_dim,
658	<	-sph_xoffset, -2.5*sph_rad,
658	>	sph_xoffset, -2.5*sph_rad,
659		radfn);
660		if (!run_cmd(cmdbuf))
661		return;
#	Line 688 \| Line 665 \| *convert_mgf(const char mgfdata)**
665		sprintf(cmdbuf, "xform -t %f %f %f -s %f -ry 180 -t %f %f 0 %s",
666		-.5(xmin+xmax), -.5(ymin+ymax), -zmin,
667		1.5*sph_rad/max_dim,
668	<	sph_xoffset, -2.5*sph_rad,
668	>	-sph_xoffset, -2.5*sph_rad,
669		radfn);
670		if (!run_cmd(cmdbuf))
671		return;
#	Line 781 \| Line 758 \| *main(int argc, char argv[])**
758		strcpy(bsdf_manuf, myBSDF.makr);
759		put_matBSDF(argv[1]);
760		} else {
761	<	FILE *fp;
761	>	FILE *fp[4];
762	>	if (argc > 5) {
763	>	fprintf(stderr, "%s: more than 4 hemispheres!\n", progname);
764	>	return(1);
765	>	}
766		for (n = 1; n < argc; n++) {
767	<	fp = fopen(argv[n], "rb");
768	<	if (fp == NULL) {
767	>	fp[n-1] = fopen(argv[n], "rb");
768	>	if (fp[n-1] == NULL) {
769		fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
770		progname, argv[n]);
771		return(1);
772		}
773	<	if (getheader(fp, rbf_headline, NULL) < 0) {
773	>	if (getheader(fp[n-1], rbf_headline, NULL) < 0) {
774		fprintf(stderr, "%s: bad BSDF interpolant '%s'\n",
775		progname, argv[n]);
776		return(1);
777		}
797	–	fclose(fp);
778		}
779		set_minlog();
780		for (n = 1; n < argc; n++) {
781	<	fp = fopen(argv[n], "rb");
782	<	if (!load_bsdf_rep(fp))
781	>	if (fseek(fp[n-1], 0L, SEEK_SET) < 0) {
782	>	fprintf(stderr, "%s: cannot seek on '%s'\n",
783	>	progname, argv[n]);
784		return(1);
785	<	fclose(fp);
785	>	}
786	>	if (!load_bsdf_rep(fp[n-1]))
787	>	return(1);
788	>	fclose(fp[n-1]);
789		if (!build_wRBF())
790		return(1);
791		}
#	Line 812 \| Line 796 \| *main(int argc, char argv[])**
796		put_scale();
797		if (inpXML && myBSDF.mgf)
798		convert_mgf(myBSDF.mgf);
799	<	if (!put_BSDFs())
799	>	if (!put_BSDFs()) /* most of the output happens here */
800		return(1);
801		cleanup_tmp();
802		return(0);

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Comparing ray/src/cv/bsdf2rad.c (file contents): Revision 2.16 by greg, Sun Apr 9 21:39:26 2017 UTC vs. Revision 2.33 by greg, Mon Oct 2 22:11:32 2017 UTC

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Comparing ray/src/cv/bsdf2rad.c (file contents):
Revision 2.16 by greg, Sun Apr 9 21:39:26 2017 UTC vs.
Revision 2.33 by greg, Mon Oct 2 22:11:32 2017 UTC