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

Comparing ray/src/cv/bsdf2rad.c (file contents):
Revision 2.23 by greg, Tue Apr 11 03:47:23 2017 UTC vs.
Revision 2.36 by greg, Fri Jul 19 17:37:56 2019 UTC

#	Line 5 \| Line 5 \| static const char RCSid[] = "$Id$";
5		* Plot 3-D BSDF output based on scattering interpolant or XML representation
6		*/
7
8	–	#include <stdio.h>
9	–	#include <string.h>
8		#include <stdlib.h>
9	+	#include "rtio.h"
10		#include "paths.h"
11		#include "rtmath.h"
13	–	#include "resolu.h"
12		#include "bsdfrep.h"
13
14	+	#ifndef NINCIDENT
15		#define NINCIDENT 37 /* number of samples/hemisphere */
16	<
16	>	#endif
17	>	#ifndef GRIDSTEP
18		#define GRIDSTEP 2 /* our grid step size */
19	+	#endif
20		#define SAMPRES (GRIDRES/GRIDSTEP)
21
22		int front_comp = 0; /* front component flags (SDsamp) /
#	Line 24 \| Line 25 \| *double overall_min = 1./PI; / overall minimum BSDF v**
25		double min_log10; /* smallest log10 value for plotting */
26		double overall_max = .0; /* overall maximum BSDF value */
27
28	<	char ourTempDir[TEMPLEN] = ""; /* our temporary directory */
28	>	char ourTempDir[TEMPLEN+1] = ""; /* our temporary directory */
29
30	<	const char frpref[] = "frefl";
31	<	const char ftpref[] = "ftrans";
32	<	const char brpref[] = "brefl";
33	<	const char btpref[] = "btrans";
30	>	const char frpref[] = "rf";
31	>	const char ftpref[] = "tf";
32	>	const char brpref[] = "rb";
33	>	const char btpref[] = "tb";
34		const char dsuffix[] = ".txt";
35
36	<	const char sph_mat[] = "BSDFmat";
36	>	const char sph_fmat[] = "fBSDFmat";
37	>	const char sph_bmat[] = "bBSDFmat";
38		const double sph_rad = 10.;
39		const double sph_xoffset = 15.;
40
#	Line 41 \| Line 43 \| const double sph_xoffset = 15.;
43
44		#define FEQ(a,b) ((a)-(b) <= 1e-7 && (b)-(a) <= 1e-7)
45
46	<	#define set_minlog() (min_log10 = log10(overall_min + 1e-5) - .1)
46	>	#define set_minlog() overall_min = (overall_min < 1e-5) ? 1e-5 : overall_min; \
47	>	min_log10 = log10(overall_min) - .1
48
49		char *progname;
50
#	Line 75 \| Line 78 \| cvt_sposition(FVECT sp, const FVECT iv, int inc_side)
78		static char *
79		tfile_name(const char prefix, const char suffix, int i)
80		{
81	<	static char buf[128];
81	>	static char buf[256];
82
83		if (!ourTempDir[0]) { /* create temporary directory */
84		mktemp(strcpy(ourTempDir,TEMPLATE));
#	Line 269 \| Line 272 \| build_wRBF(void)
272
273		/* Put out mirror arrow for the given incident vector */
274		static void
275	<	put_mirror_arrow(const FVECT ivec, int inc_side)
275	>	put_mirror_arrow(const FVECT origin, const FVECT nrm)
276		{
277		const double arrow_len = 1.2*bsdf_rad;
278		const double tip_len = 0.2*bsdf_rad;
279	<	FVECT origin, refl;
279	>	static int cnt = 1;
280	>	FVECT refl;
281		int i;
282
283	<	cvt_sposition(origin, ivec, inc_side);
283	>	refl[0] = 2.nrm[2]nrm[0];
284	>	refl[1] = 2.nrm[2]nrm[1];
285	>	refl[2] = 2.nrm[2]nrm[2] - 1.;
286
287	<	refl[0] = -2.ivec[2]ivec[0];
288	<	refl[1] = -2.ivec[2]ivec[1];
283	<	refl[2] = 2.ivec[2]ivec[2] - 1.;
284	<
285	<	printf("\n# Mirror arrow\n");
286	<	printf("\narrow_mat cylinder inc_dir\n0\n0\n7");
287	>	printf("\n# Mirror arrow #%d\n", cnt);
288	>	printf("\nshaft_mat cylinder inc_dir%d\n0\n0\n7", cnt);
289		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n",
290		origin[0], origin[1], origin[2]+arrow_len,
291		origin[0], origin[1], origin[2],
292		arrow_rad);
293	<	printf("\narrow_mat cylinder mir_dir\n0\n0\n7");
293	>	printf("\nshaft_mat cylinder mir_dir%d\n0\n0\n7", cnt);
294		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n",
295		origin[0], origin[1], origin[2],
296		origin[0] + arrow_len*refl[0],
297		origin[1] + arrow_len*refl[1],
298		origin[2] + arrow_len*refl[2],
299		arrow_rad);
300	<	printf("\narrow_mat cone mir_tip\n0\n0\n8");
300	>	printf("\ntip_mat cone mir_tip%d\n0\n0\n8", cnt);
301		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f 0\n",
302		origin[0] + (arrow_len-.5tip_len)refl[0],
303		origin[1] + (arrow_len-.5tip_len)refl[1],
#	Line 304 \| Line 306 \| put_mirror_arrow(const FVECT ivec, int inc_side)
306		origin[1] + (arrow_len+.5tip_len)refl[1],
307		origin[2] + (arrow_len+.5tip_len)refl[2],
308		2.*arrow_rad);
309	+	++cnt;
310		}
311
312		/* Put out transmitted direction arrow for the given incident vector */
313		static void
314	<	put_trans_arrow(const FVECT ivec, int inc_side)
314	>	put_trans_arrow(const FVECT origin)
315		{
316		const double arrow_len = 1.2*bsdf_rad;
317		const double tip_len = 0.2*bsdf_rad;
318	<	FVECT origin;
318	>	static int cnt = 1;
319		int i;
320
321	<	cvt_sposition(origin, ivec, inc_side);
322	<
320	<	printf("\n# Transmission arrow\n");
321	<	printf("\narrow_mat cylinder trans_dir\n0\n0\n7");
321	>	printf("\n# Transmission arrow #%d\n", cnt);
322	>	printf("\nshaft_mat cylinder trans_dir%d\n0\n0\n7", cnt);
323		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f\n",
324		origin[0], origin[1], origin[2],
325		origin[0], origin[1], origin[2]-arrow_len,
326		arrow_rad);
327	<	printf("\narrow_mat cone trans_tip\n0\n0\n8");
327	>	printf("\ntip_mat cone trans_tip%d\n0\n0\n8", cnt);
328		printf("\n\t%f %f %f\n\t%f %f %f\n\t%f 0\n",
329		origin[0], origin[1], origin[2]-arrow_len+.5*tip_len,
330		origin[0], origin[1], origin[2]-arrow_len-.5*tip_len,
331	<	2.*arrow_rad);
331	>	2.*arrow_rad);
332	>	++cnt;
333		}
334
335		/* Compute rotation (x,y,z) => (xp,yp,zp) */
#	Line 371 \| Line 373 \| static int
373		put_BSDFs(void)
374		{
375		const double scalef = bsdf_rad/(log10(overall_max) - min_log10);
376	<	FVECT ivec, sorg, upv;
376	>	FVECT ivec, sorg, nrm, upv;
377		RREAL vMtx[3][3];
378		char *fname;
379		char cmdbuf[256];
380	<	char xfargs[128];
381	<	int nxfa;
380	>	char rotargs[64];
381	>	int nrota;
382		int i;
383
384		printf("\n# Gensurf output corresponding to %d incident directions\n",
385		NINCIDENT);
386
387	<	printf("\nvoid glow arrow_glow\n0\n0\n4 1 0 1 0\n");
388	<	printf("\nvoid mixfunc arrow_mat\n4 arrow_glow void 0.25 .\n0\n0\n");
387	>	printf("\nvoid glow tip_mat\n0\n0\n4 1 0 1 0\n");
388	>	printf("\nvoid mixfunc shaft_mat\n4 tip_mat void 0.25 .\n0\n0\n");
389
390	<	if (front_comp & SDsampR) /* front reflection */
391	<	for (i = 0; i < NINCIDENT; i++) {
392	<	get_ivector(ivec, i);
393	<	put_mirror_arrow(ivec, 1);
390	>	for (i = 0; i < NINCIDENT; i++) {
391	>	get_ivector(ivec, i);
392	>	nrm[0] = -ivec[0]; nrm[1] = -ivec[1]; nrm[2] = ivec[2];
393	>	upv[0] = nrm[0]nrm[1](nrm[2] - 1.);
394	>	upv[1] = nrm[0]nrm[0] + nrm[1]nrm[1]*nrm[2];
395	>	upv[2] = -nrm[1](nrm[0]nrm[0] + nrm[1]*nrm[1]);
396	>	if (SDcompXform(vMtx, nrm, upv) != SDEnone)
397	>	continue;
398	>	nrota = addrot(rotargs, vMtx[0], vMtx[1], vMtx[2]);
399	>	if (front_comp) {
400		cvt_sposition(sorg, ivec, 1);
393	–	ivec[0] = -ivec[0]; ivec[1] = -ivec[1]; /* normal */
394	–	upv[0] = ivec[0]ivec[1](ivec[2] - 1.);
395	–	upv[1] = ivec[0]ivec[0] + ivec[1]ivec[1]*ivec[2];
396	–	upv[2] = -ivec[1](ivec[0]ivec[0] + ivec[1]*ivec[1]);
397	–	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
398	–	sorg[0], sorg[1], sorg[2]);
399	–	nxfa = 6;
401		printf("\nvoid colorfunc scale_pat\n");
402	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
403	<	4+nxfa, xfargs);
402	>	printf("10 bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n");
403	>	printf("\t-s %f -t %f %f %f\n0\n0\n",
404	>	bsdf_rad, sorg[0], sorg[1], sorg[2]);
405		printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
406	<	if (SDcompXform(vMtx, ivec, upv) != SDEnone)
407	<	continue;
408	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
407	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
408	<	scalef, sorg[0], sorg[1], sorg[2]);
409	<	nxfa += 6;
406	>	}
407	>	if (front_comp & SDsampR) {
408	>	put_mirror_arrow(sorg, nrm);
409		fname = tfile_name(frpref, dsuffix, i);
410	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform %s",
410	>	sprintf(cmdbuf,
411	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform %s -s %f -t %f %f %f",
412		frpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
413	<	xfargs);
413	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
414		if (!run_cmd(cmdbuf))
415		return(0);
416		}
417	<	if (front_comp & SDsampT) /* front transmission */
418	<	for (i = 0; i < NINCIDENT; i++) {
419	<	get_ivector(ivec, i);
420	<	put_trans_arrow(ivec, 1);
421	<	cvt_sposition(sorg, ivec, 1);
422	<	ivec[0] = -ivec[0]; ivec[1] = -ivec[1]; /* normal */
423	<	upv[0] = ivec[0]ivec[1](ivec[2] - 1.);
424	<	upv[1] = ivec[0]ivec[0] + ivec[1]ivec[1]*ivec[2];
425	<	upv[2] = -ivec[1](ivec[0]ivec[0] + ivec[1]*ivec[1]);
426	<	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
427	<	sorg[0], sorg[1], sorg[2]);
428	<	nxfa = 6;
429	<	printf("\nvoid colorfunc scale_pat\n");
430	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
431	<	4+nxfa, xfargs);
432	<	printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
433	<	if (SDcompXform(vMtx, ivec, upv) != SDEnone)
434	<	continue;
435	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
436	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
437	<	scalef, sorg[0], sorg[1], sorg[2]);
438	<	nxfa += 6;
417	>	if (front_comp & SDsampT) {
418	>	put_trans_arrow(sorg);
419		fname = tfile_name(ftpref, dsuffix, i);
420	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform -I %s",
420	>	sprintf(cmdbuf,
421	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform -I %s -s %f -t %f %f %f",
422		ftpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
423	<	xfargs);
423	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
424		if (!run_cmd(cmdbuf))
425		return(0);
426		}
427	<	if (back_comp & SDsampR) /* rear reflection */
447	<	for (i = 0; i < NINCIDENT; i++) {
448	<	get_ivector(ivec, i);
449	<	put_mirror_arrow(ivec, -1);
427	>	if (back_comp) {
428		cvt_sposition(sorg, ivec, -1);
451	–	ivec[0] = -ivec[0]; ivec[1] = -ivec[1]; /* normal */
452	–	upv[0] = ivec[0]ivec[1](ivec[2] - 1.);
453	–	upv[1] = ivec[0]ivec[0] + ivec[1]ivec[1]*ivec[2];
454	–	upv[2] = -ivec[1](ivec[0]ivec[0] + ivec[1]*ivec[1]);
455	–	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
456	–	sorg[0], sorg[1], sorg[2]);
457	–	nxfa = 6;
429		printf("\nvoid colorfunc scale_pat\n");
430	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
431	<	4+nxfa, xfargs);
430	>	printf("10 bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n");
431	>	printf("\t-s %f -t %f %f %f\n0\n0\n",
432	>	bsdf_rad, sorg[0], sorg[1], sorg[2]);
433		printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
434	<	if (SDcompXform(vMtx, ivec, upv) != SDEnone)
435	<	continue;
436	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
465	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
466	<	scalef, sorg[0], sorg[1], sorg[2]);
467	<	nxfa += 6;
434	>	}
435	>	if (back_comp & SDsampR) {
436	>	put_mirror_arrow(sorg, nrm);
437		fname = tfile_name(brpref, dsuffix, i);
438	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform -I -ry 180 %s",
438	>	sprintf(cmdbuf,
439	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform -I -ry 180 %s -s %f -t %f %f %f",
440		brpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
441	<	xfargs);
441	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
442		if (!run_cmd(cmdbuf))
443		return(0);
444		}
445	<	if (back_comp & SDsampT) /* rear transmission */
446	<	for (i = 0; i < NINCIDENT; i++) {
477	<	get_ivector(ivec, i);
478	<	put_trans_arrow(ivec, -1);
479	<	cvt_sposition(sorg, ivec, -1);
480	<	ivec[0] = -ivec[0]; ivec[1] = -ivec[1]; /* normal */
481	<	upv[0] = ivec[0]ivec[1](ivec[2] - 1.);
482	<	upv[1] = ivec[0]ivec[0] + ivec[1]ivec[1]*ivec[2];
483	<	upv[2] = -ivec[1](ivec[0]ivec[0] + ivec[1]*ivec[1]);
484	<	sprintf(xfargs, "-s %f -t %f %f %f", bsdf_rad,
485	<	sorg[0], sorg[1], sorg[2]);
486	<	nxfa = 6;
487	<	printf("\nvoid colorfunc scale_pat\n");
488	<	printf("%d bsdf_red bsdf_grn bsdf_blu bsdf2rad.cal\n\t%s\n0\n0\n",
489	<	4+nxfa, xfargs);
490	<	printf("\nscale_pat glow scale_mat\n0\n0\n4 1 1 1 0\n");
491	<	if (SDcompXform(vMtx, ivec, upv) != SDEnone)
492	<	continue;
493	<	nxfa = addrot(xfargs, vMtx[0], vMtx[1], vMtx[2]);
494	<	sprintf(xfargs+strlen(xfargs), " -s %f -t %f %f %f",
495	<	scalef, sorg[0], sorg[1], sorg[2]);
496	<	nxfa += 6;
445	>	if (back_comp & SDsampT) {
446	>	put_trans_arrow(sorg);
447		fname = tfile_name(btpref, dsuffix, i);
448	<	sprintf(cmdbuf, "gensurf scale_mat %s%d %s %s %s %d %d \| xform -ry 180 %s",
448	>	sprintf(cmdbuf,
449	>	"gensurf scale_mat %s%d %s %s %s %d %d \| xform -ry 180 %s -s %f -t %f %f %f",
450		btpref, i, fname, fname, fname, SAMPRES-1, SAMPRES-1,
451	<	xfargs);
451	>	rotargs, scalef, sorg[0], sorg[1], sorg[2]);
452		if (!run_cmd(cmdbuf))
453		return(0);
454		}
455	+	}
456		return(1);
457		}
458
#	Line 515 \| Line 467 \| *put_matBSDF(const char XMLfile)**
467		printf("\nvoid brightfunc latlong\n2 latlong bsdf2rad.cal\n0\n0\n");
468		if ((front_comp\|back_comp) & SDsampT)
469		printf("\nlatlong trans %s\n0\n0\n7 .75 .75 .75 0 .04 .5 .8\n",
470	<	sph_mat);
470	>	sph_fmat);
471		else
472		printf("\nlatlong plastic %s\n0\n0\n5 .5 .5 .5 0 0\n",
473	<	sph_mat);
473	>	sph_fmat);
474	>	printf("\ninherit alias %s %s\n", sph_bmat, sph_fmat);
475		return;
476		}
477		switch (XMLfile[0]) { /* avoid RAYPATH search */
478		case '.':
479	+	case '~':
480		CASEDIRSEP:
481		curdir = "";
482		break;
#	Line 531 \| Line 485 \| *put_matBSDF(const char XMLfile)**
485		exit(1);
486		break;
487		}
488	<	printf("\n# Actual BSDF material for rendering the hemispheres\n");
489	<	printf("\nvoid BSDF BSDFmat\n6 0 \"%s%s\" upx upy upz bsdf2rad.cal\n0\n0\n",
488	>	printf("\n# Actual BSDF materials for rendering the hemispheres\n");
489	>	printf("\nvoid BSDF BSDF_f\n6 0 \"%s%s\" upx upy upz bsdf2rad.cal\n0\n0\n",
490		curdir, XMLfile);
491		printf("\nvoid plastic black\n0\n0\n5 0 0 0 0 0\n");
492	<	printf("\nvoid mixfunc %s\n4 BSDFmat black latlong bsdf2rad.cal\n0\n0\n",
493	<	sph_mat);
492	>	printf("\nvoid mixfunc %s\n4 BSDF_f black latlong bsdf2rad.cal\n0\n0\n",
493	>	sph_fmat);
494	>	printf("\nvoid BSDF BSDF_b\n8 0 \"%s%s\" upx upy upz bsdf2rad.cal -ry 180\n0\n0\n",
495	>	curdir, XMLfile);
496	>	printf("\nvoid mixfunc %s\n4 BSDF_b black latlong bsdf2rad.cal\n0\n0\n",
497	>	sph_bmat);
498		}
499
500		/* Put out overhead parallel light source */
#	Line 560 \| Line 518 \| put_hemispheres(void)
518		if (front_comp) {
519		printf(
520		"\n!genrev %s Front \"Rsin(At)\" \"Rcos(At)\" %d -e \"R:%g;A:%f\" -s \| xform -t %g 0 0\n",
521	<	sph_mat, nsegs, sph_rad, 0.495*PI, sph_xoffset);
521	>	sph_fmat, nsegs, sph_rad, 0.5*PI, sph_xoffset);
522		printf("\nvoid brighttext front_text\n3 helvet.fnt . FRONT\n0\n");
523		printf("12\n\t%f %f 0\n\t%f 0 0\n\t0 %f 0\n\t.01 1 -.1\n",
524		-.22sph_rad + sph_xoffset, -1.4sph_rad,
#	Line 576 \| Line 534 \| put_hemispheres(void)
534		if (back_comp) {
535		printf(
536		"\n!genrev %s Back \"Rcos(At)\" \"Rsin(At)\" %d -e \"R:%g;A:%f\" -s \| xform -t %g 0 0\n",
537	<	sph_mat, nsegs, sph_rad, 0.495*PI, -sph_xoffset);
537	>	sph_bmat, nsegs, sph_rad, 0.5*PI, -sph_xoffset);
538		printf("\nvoid brighttext back_text\n3 helvet.fnt . BACK\n0\n");
539		printf("12\n\t%f %f 0\n\t%f 0 0\n\t0 %f 0\n\t.01 1 -.1\n",
540		-.22sph_rad - sph_xoffset, -1.4sph_rad,
#	Line 716 \| Line 674 \| *convert_mgf(const char mgfdata)**
674		static int
675		rbf_headline(char s, void p)
676		{
677	<	char fmt[64];
677	>	char fmt[MAXFMTLEN];
678
679		if (formatval(fmt, s)) {
680		if (strcmp(fmt, BSDFREP_FMT))
#	Line 750 \| Line 708 \| int
708		main(int argc, char *argv[])
709		{
710		int inpXML = -1;
711	+	double myLim[2];
712		SDData myBSDF;
713	<	int n;
713	>	int a, n;
714		/* check arguments */
715		progname = argv[0];
716	<	if (argc > 1 && (n = strlen(argv[1])-4) > 0) {
717	<	if (!strcasecmp(argv[1]+n, ".xml"))
716	>	a = 1;
717	>	myLim[0] = -1; myLim[1] = -2; /* specified BSDF range? */
718	>	if (argc > a+3 && argv[a][0] == '-' && argv[a][1] == 'r') {
719	>	myLim[0] = atof(argv[++a]);
720	>	myLim[1] = atof(argv[++a]);
721	>	++a;
722	>	}
723	>	if (argc > a && (n = strlen(argv[a])-4) > 0) {
724	>	if (!strcasecmp(argv[a]+n, ".xml"))
725		inpXML = 1;
726	<	else if (!strcasecmp(argv[1]+n, ".sir"))
726	>	else if (!strcasecmp(argv[a]+n, ".sir"))
727		inpXML = 0;
728		}
729	<	if (inpXML < 0 \|\| inpXML & (argc > 2)) {
730	<	fprintf(stderr, "Usage: %s bsdf.xml > output.rad\n", progname);
731	<	fprintf(stderr, " Or: %s hemi1.sir hemi2.sir .. > output.rad\n", progname);
729	>	if (inpXML < 0 \|\| inpXML & (argc > a+1)) {
730	>	fprintf(stderr, "Usage: %s [-r min max] bsdf.xml > output.rad\n", progname);
731	>	fprintf(stderr, " Or: %s [-r min max] hemi1.sir hemi2.sir .. > output.rad\n", progname);
732		return(1);
733		}
734		fputs("# ", stdout); /* copy our command */
735		printargs(argc, argv, stdout);
736		/* evaluate BSDF */
737		if (inpXML) {
738	<	SDclearBSDF(&myBSDF, argv[1]);
739	<	if (SDreportError(SDloadFile(&myBSDF, argv[1]), stderr))
738	>	SDclearBSDF(&myBSDF, argv[a]);
739	>	if (SDreportError(SDloadFile(&myBSDF, argv[a]), stderr))
740		return(1);
741		if (myBSDF.rf != NULL) front_comp \|= SDsampR;
742		if (myBSDF.tf != NULL) front_comp \|= SDsampT;
#	Line 778 \| Line 744 \| *main(int argc, char argv[])**
744		if (myBSDF.tb != NULL) back_comp \|= SDsampT;
745		if (!front_comp & !back_comp) {
746		fprintf(stderr, "%s: nothing to plot in '%s'\n",
747	<	progname, argv[1]);
747	>	progname, argv[a]);
748		return(1);
749		}
750	<	if (front_comp & SDsampR && myBSDF.rLambFront.cieY < overall_min*PI)
751	<	overall_min = myBSDF.rLambFront.cieY/PI;
752	<	if (back_comp & SDsampR && myBSDF.rLambBack.cieY < overall_min*PI)
753	<	overall_min = myBSDF.rLambBack.cieY/PI;
754	<	if ((front_comp\|back_comp) & SDsampT &&
755	<	myBSDF.tLamb.cieY < overall_min*PI)
756	<	overall_min = myBSDF.tLamb.cieY/PI;
750	>	if (myLim[0] >= 0)
751	>	overall_min = myLim[0];
752	>	else {
753	>	if (front_comp & SDsampR && myBSDF.rLambFront.cieY < overall_min*PI)
754	>	overall_min = myBSDF.rLambFront.cieY/PI;
755	>	if (back_comp & SDsampR && myBSDF.rLambBack.cieY < overall_min*PI)
756	>	overall_min = myBSDF.rLambBack.cieY/PI;
757	>	if ((front_comp\|back_comp) & SDsampT &&
758	>	myBSDF.tLamb.cieY < overall_min*PI)
759	>	overall_min = myBSDF.tLamb.cieY/PI;
760	>	}
761		set_minlog();
762		if (!build_wBSDF(&myBSDF))
763		return(1);
#	Line 796 \| Line 766 \| *main(int argc, char argv[])**
766		else
767		strcpy(bsdf_name, myBSDF.name);
768		strcpy(bsdf_manuf, myBSDF.makr);
769	<	put_matBSDF(argv[1]);
769	>	put_matBSDF(argv[a]);
770		} else {
771	<	FILE *fp;
772	<	for (n = 1; n < argc; n++) {
773	<	fp = fopen(argv[n], "rb");
774	<	if (fp == NULL) {
771	>	FILE *fp[4];
772	>	if (argc > a+4) {
773	>	fprintf(stderr, "%s: more than 4 hemispheres!\n", progname);
774	>	return(1);
775	>	}
776	>	for (n = a; n < argc; n++) {
777	>	fp[n-a] = fopen(argv[n], "rb");
778	>	if (fp[n-a] == NULL) {
779		fprintf(stderr, "%s: cannot open BSDF interpolant '%s'\n",
780		progname, argv[n]);
781		return(1);
782		}
783	<	if (getheader(fp, rbf_headline, NULL) < 0) {
783	>	if (getheader(fp[n-a], rbf_headline, NULL) < 0) {
784		fprintf(stderr, "%s: bad BSDF interpolant '%s'\n",
785		progname, argv[n]);
786		return(1);
787		}
814	–	fclose(fp);
788		}
789	+	if (myLim[0] >= 0)
790	+	overall_min = myLim[0];
791		set_minlog();
792	<	for (n = 1; n < argc; n++) {
793	<	fp = fopen(argv[n], "rb");
794	<	if (!load_bsdf_rep(fp))
792	>	for (n = a; n < argc; n++) {
793	>	if (fseek(fp[n-a], 0L, SEEK_SET) < 0) {
794	>	fprintf(stderr, "%s: cannot seek on '%s'\n",
795	>	progname, argv[n]);
796		return(1);
797	<	fclose(fp);
797	>	}
798	>	if (!load_bsdf_rep(fp[n-a]))
799	>	return(1);
800	>	fclose(fp[n-a]);
801		if (!build_wRBF())
802		return(1);
803		}
804		put_matBSDF(NULL);
805		}
806	+	if (myLim[1] > myLim[0]) /* override maximum BSDF? */
807	+	overall_max = myLim[1];
808		put_source(); /* before hemispheres & labels */
809		put_hemispheres();
810		put_scale();
811		if (inpXML && myBSDF.mgf)
812		convert_mgf(myBSDF.mgf);
813	<	if (!put_BSDFs())
813	>	if (!put_BSDFs()) /* most of the output happens here */
814		return(1);
815		cleanup_tmp();
816		return(0);

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Comparing ray/src/cv/bsdf2rad.c (file contents): Revision 2.23 by greg, Tue Apr 11 03:47:23 2017 UTC vs. Revision 2.36 by greg, Fri Jul 19 17:37:56 2019 UTC

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Comparing ray/src/cv/bsdf2rad.c (file contents):
Revision 2.23 by greg, Tue Apr 11 03:47:23 2017 UTC vs.
Revision 2.36 by greg, Fri Jul 19 17:37:56 2019 UTC