[ViewVC] Diff of: radiance/src/util/rmatrix.c

Comparing src/util/rmatrix.c (file contents):
Revision 2.86 by greg, Fri Mar 28 00:06:36 2025 UTC vs.
Revision 2.102 by greg, Thu Oct 30 16:47:54 2025 UTC

#	Line 16 \| Line 16 \| static const char RCSid[] = "$Id$";
16		#include <sys/mman.h>
17		#endif
18
19	–	#ifndef MAXCOMP
20	–	#define MAXCOMP MAXCSAMP /* #components we support */
21	–	#endif
22	–
19		static const char rmx_mismatch_warn[] = "WARNING: data type mismatch\n";
20
21		/* Initialize a RMATRIX struct but don't allocate array space */
22		RMATRIX *
23	<	rmx_new(int nr, int nc, int n)
23	>	rmx_new(int nr, int nc, int ncomp)
24		{
25		RMATRIX *dnew;
26
27	<	if (n <= 0)
27	>	if (ncomp <= 0)
28		return(NULL);
29
30		dnew = (RMATRIX *)calloc(1, sizeof(RMATRIX));
#	Line 38 \| Line 34 \| rmx_new(int nr, int nc, int n)
34		dnew->dtype = DTrmx_native;
35		dnew->nrows = nr;
36		dnew->ncols = nc;
37	<	dnew->ncomp = n;
37	>	dnew->ncomp = ncomp;
38		setcolor(dnew->cexp, 1.f, 1.f, 1.f);
39		memcpy(dnew->wlpart, WLPART, sizeof(dnew->wlpart));
40
#	Line 61 \| Line 57 \| *rmx_prepare(RMATRIX rm)**
57
58		/* Call rmx_new() and rmx_prepare() */
59		RMATRIX *
60	<	rmx_alloc(int nr, int nc, int n)
60	>	rmx_alloc(int nr, int nc, int ncomp)
61		{
62	<	RMATRIX *dnew = rmx_new(nr, nc, n);
62	>	RMATRIX *dnew = rmx_new(nr, nc, ncomp);
63
64		if (!rmx_prepare(dnew)) {
65		rmx_free(dnew);
#	Line 198 \| Line 194 \| *rmx_load_ascii(rmx_dtype drp, const RMATRIX rm, FILE*
194
195		for (j = 0; j < rm->ncols; j++)
196		for (k = rm->ncomp; k-- > 0; )
197	<	if (fscanf(fp, "%lf", drp++) != 1)
197	>	if (fscanf(fp, rmx_scanfmt, drp++) != 1)
198		return(0);
199		return(1);
200		}
#	Line 206 \| Line 202 \| *rmx_load_ascii(rmx_dtype drp, const RMATRIX rm, FILE*
202		static int
203		rmx_load_float(rmx_dtype drp, const RMATRIX rm, FILE *fp)
204		{
205	+	#if DTrmx_native==DTfloat
206	+	if (getbinary(drp, sizeof(drp)rm->ncomp, rm->ncols, fp) != rm->ncols)
207	+	return(0);
208	+	if (rm->pflags & RMF_SWAPIN)
209	+	swap32((char )drp, rm->ncolsrm->ncomp);
210	+	#else
211		int j, k;
212		float val[MAXCOMP];
213
#	Line 221 \| Line 223 \| *rmx_load_float(rmx_dtype drp, const RMATRIX rm, FILE*
223		for (k = 0; k < rm->ncomp; k++)
224		*drp++ = val[k];
225		}
226	+	#endif
227		return(1);
228		}
229
230		static int
231		rmx_load_double(rmx_dtype drp, const RMATRIX rm, FILE *fp)
232		{
233	+	#if DTrmx_native==DTdouble
234		if (getbinary(drp, sizeof(drp)rm->ncomp, rm->ncols, fp) != rm->ncols)
235		return(0);
236		if (rm->pflags & RMF_SWAPIN)
237		swap64((char )drp, rm->ncolsrm->ncomp);
238	+	#else
239	+	int j, k;
240	+	double val[MAXCOMP];
241	+
242	+	if (rm->ncomp > MAXCOMP) {
243	+	fputs("Unsupported # components in rmx_load_double()\n", stderr);
244	+	exit(1);
245	+	}
246	+	for (j = 0; j < rm->ncols; j++) {
247	+	if (getbinary(val, sizeof(val[0]), rm->ncomp, fp) != rm->ncomp)
248	+	return(0);
249	+	if (rm->pflags & RMF_SWAPIN)
250	+	swap64((char *)val, rm->ncomp);
251	+	for (k = 0; k < rm->ncomp; k++)
252	+	*drp++ = (float)val[k];
253	+	}
254	+	#endif
255		return(1);
256		}
257
#	Line 257 \| Line 278 \| *rmx_load_rgbe(rmx_dtype drp, const RMATRIX rm, FILE*
278		return(1);
279		}
280
281	+	#if DTrmx_native==DTfloat
282		static int
283		rmx_load_spec(rmx_dtype drp, const RMATRIX rm, FILE *fp)
284		{
285		COLRV *scan;
286	+	int j;
287	+
288	+	if ((rm->ncomp < 3) \| (rm->ncomp > MAXCOMP))
289	+	return(0);
290	+	scan = (COLRV )tempbuffer((rm->ncomp+1)rm->ncols);
291	+	if (!scan)
292	+	return(0);
293	+	if (freadscolrs(scan, rm->ncomp, rm->ncols, fp) < 0)
294	+	return(0);
295	+	for (j = 0; j < rm->ncols; j++, drp += rm->ncomp)
296	+	scolr2scolor(drp, scan+j*(rm->ncomp+1), rm->ncomp);
297	+	return(1);
298	+	}
299	+	#else
300	+	static int
301	+	rmx_load_spec(rmx_dtype drp, const RMATRIX rm, FILE *fp)
302	+	{
303	+	COLRV *scan;
304		COLORV scol[MAXCOMP];
305		int j, k;
306
#	Line 278 \| Line 318 \| *rmx_load_spec(rmx_dtype drp, const RMATRIX rm, FILE*
318		}
319		return(1);
320		}
321	+	#endif
322
323		/* Read matrix header from input stream (cannot be XML) */
324		int
#	Line 368 \| Line 409 \| *rmx_load_data(RMATRIX rm, FILE fp)*
409
410		/* Load matrix from supported file type */
411		RMATRIX *
412	<	rmx_load(const char *inspec, RMPref rmp)
412	>	rmx_load(const char *inspec)
413		{
414		FILE *fp;
415		RMATRIX *dnew;
#	Line 382 \| Line 423 \| *rmx_load(const char inspec, RMPref rmp)**
423		fp = stdin;
424		else if (inspec[0] == '!')
425		fp = popen(inspec+1, "r");
426	<	else { /* check suffix */
386	<	const char *sp = strrchr(inspec, '.');
387	<	if (sp > inspec && !strcasecmp(sp+1, "XML")) { /* BSDF? */
388	<	CMATRIX cm = rmp==RMPnone ? (CMATRIX )NULL :
389	<	rmp==RMPtrans ? cm_loadBTDF(inspec) :
390	<	cm_loadBRDF(inspec, rmp==RMPreflB) ;
391	<	if (!cm)
392	<	return(NULL);
393	<	dnew = rmx_from_cmatrix(cm);
394	<	cm_free(cm);
395	<	dnew->dtype = DTascii;
396	<	return(dnew); /* return here */
397	<	} /* else open it ourselves */
426	>	else
427		fp = fopen(inspec, "r");
399	–	}
428		if (!fp) {
429		fprintf(stderr, "Cannot open for reading: %s\n", inspec);
430		return(NULL);
#	Line 416 \| Line 444 \| *rmx_load(const char inspec, RMPref rmp)**
444
445		if (fp != stdin) { /* close input stream */
446		if (inspec[0] == '!')
447	<	pclose(fp);
447	>	ok &= pclose(fp)==0;
448		else
449		fclose(fp);
450		}
#	Line 451 \| Line 479 \| *rmx_load(const char inspec, RMPref rmp)**
479		return(dnew);
480		}
481
482	+	#if DTrmx_native==DTdouble
483		static int
484	<	rmx_write_ascii(const rmx_dtype dp, int nc, int len, FILE fp)
484	>	rmx_write_float(const rmx_dtype dp, int len, FILE fp)
485		{
486	<	while (len-- > 0) {
487	<	int k = nc;
488	<	while (k-- > 0)
489	<	fprintf(fp, " %.7e", *dp++);
490	<	fputc('\t', fp);
486	>	float val;
487	>
488	>	while (len--) {
489	>	val = (float)*dp++;
490	>	if (putbinary(&val, sizeof(val), 1, fp) != 1)
491	>	return(0);
492		}
493	<	return(fputc('\n', fp) != EOF);
493	>	return(1);
494		}
495	<
495	>	#else
496		static int
497	<	rmx_write_float(const rmx_dtype dp, int len, FILE fp)
497	>	rmx_write_double(const rmx_dtype dp, int len, FILE fp)
498		{
499	<	float val;
499	>	double val;
500
501		while (len--) {
502		val = *dp++;
503	<	if (putbinary(&val, sizeof(float), 1, fp) != 1)
503	>	if (putbinary(&val, sizeof(val), 1, fp) != 1)
504		return(0);
505		}
506		return(1);
507		}
508	+	#endif
509
510		static int
511	<	rmx_write_rgbe(const rmx_dtype dp, int nc, int len, FILE fp)
511	>	rmx_write_ascii(const rmx_dtype dp, int ncomp, int len, FILE fp)
512		{
513	+	while (len-- > 0) {
514	+	int k = ncomp;
515	+	while (k-- > 0)
516	+	fprintf(fp, " %.7e", *dp++);
517	+	fputc('\t', fp);
518	+	}
519	+	return(fputc('\n', fp) != EOF);
520	+	}
521	+
522	+	static int
523	+	rmx_write_rgbe(const rmx_dtype dp, int ncomp, int len, FILE fp)
524	+	{
525		COLR *scan;
526		int j;
527
528	<	if ((nc != 1) & (nc != 3)) return(0);
528	>	if ((ncomp != 1) & (ncomp != 3)) return(0);
529		scan = (COLR )tempbuffer(sizeof(COLR)len);
530		if (!scan) return(0);
531
532	<	for (j = 0; j < len; j++, dp += nc)
533	<	if (nc == 1)
532	>	for (j = 0; j < len; j++, dp += ncomp)
533	>	if (ncomp == 1)
534		setcolr(scan[j], dp[0], dp[0], dp[0]);
535		else
536		setcolr(scan[j], dp[0], dp[1], dp[2]);
#	Line 495 \| Line 538 \| *rmx_write_rgbe(const rmx_dtype dp, int nc, int len, F**
538		return(fwritecolrs(scan, len, fp) >= 0);
539		}
540
541	+	#if DTrmx_native==DTfloat
542		static int
543	<	rmx_write_spec(const rmx_dtype dp, int nc, int len, FILE fp)
543	>	rmx_write_spec(const rmx_dtype dp, int ncomp, int len, FILE fp)
544		{
545		COLRV *scan;
546	+	int j;
547	+
548	+	if ((ncomp < 3) \| (ncomp > MAXCOMP)) return(0);
549	+	scan = (COLRV )tempbuffer((ncomp+1)len);
550	+	if (!scan) return(0);
551	+	for (j = 0; j < len; j++, dp += ncomp)
552	+	scolor2scolr(scan+j*(ncomp+1), dp, ncomp);
553	+
554	+	return(fwritescolrs(scan, ncomp, len, fp) >= 0);
555	+	}
556	+	#else
557	+	static int
558	+	rmx_write_spec(const rmx_dtype dp, int ncomp, int len, FILE fp)
559	+	{
560	+	COLRV *scan;
561		COLORV scol[MAXCOMP];
562		int j, k;
563
564	<	if ((nc < 3) \| (nc > MAXCOMP)) return(0);
565	<	scan = (COLRV )tempbuffer((nc+1)len);
564	>	if ((ncomp < 3) \| (ncomp > MAXCOMP)) return(0);
565	>	scan = (COLRV )tempbuffer((ncomp+1)len);
566		if (!scan) return(0);
567	<	for (j = 0; j < len; j++, dp += nc) {
568	<	for (k = nc; k--; )
567	>	for (j = 0; j < len; j++, dp += ncomp) {
568	>	for (k = ncomp; k--; )
569		scol[k] = dp[k];
570	<	scolor2scolr(scan+j*(nc+1), scol, nc);
570	>	scolor2scolr(scan+j*(ncomp+1), scol, ncomp);
571		}
572	<	return(fwritescolrs(scan, nc, len, fp) >= 0);
572	>	return(fwritescolrs(scan, ncomp, len, fp) >= 0);
573		}
574	+	#endif
575
576		/* Check if CIE XYZ primaries were specified */
577		static int
#	Line 538 \| Line 598 \| *rmx_write_header(const RMATRIX rm, int dtype, FILE f*
598		return(0);
599		if (rm->info)
600		fputs(rm->info, fp);
601	<	if (dtype == DTfromHeader)
601	>	if (dtype == DTfromHeader) {
602		dtype = rm->dtype;
603	<	else if (dtype == DTrgbe && (rm->dtype == DTxyze \|\|
603	>	#if DTrmx_native==DTfloat
604	>	if (dtype == DTdouble) /* but stored as float? */
605	>	dtype = DTfloat;
606	>	#endif
607	>	} else if (dtype == DTrgbe && (rm->dtype == DTxyze \|\|
608		findCIEprims(rm->info)))
609		dtype = DTxyze;
610		else if ((dtype == DTxyze) & (rm->dtype == DTrgbe))
#	Line 584 \| Line 648 \| *rmx_write_header(const RMATRIX rm, int dtype, FILE f*
648
649		/* Write out matrix data (usually by row) */
650		int
651	<	rmx_write_data(const rmx_dtype dp, int nc, int len, int dtype, FILE fp)
651	>	rmx_write_data(const rmx_dtype dp, int ncomp, int len, int dtype, FILE fp)
652		{
653		switch (dtype) {
654	<	case DTascii:
591	<	return(rmx_write_ascii(dp, nc, len, fp));
654	>	#if DTrmx_native==DTdouble
655		case DTfloat:
656	<	return(rmx_write_float(dp, nc*len, fp));
656	>	return(rmx_write_float(dp, ncomp*len, fp));
657	>	#else
658	>	case DTdouble:
659	>	return(rmx_write_double(dp, ncomp*len, fp));
660	>	#endif
661		case DTrmx_native:
662	<	return(putbinary(dp, sizeof(dp)nc, len, fp) == len);
662	>	return(putbinary(dp, sizeof(dp)ncomp, len, fp) == len);
663	>	case DTascii:
664	>	return(rmx_write_ascii(dp, ncomp, len, fp));
665		case DTrgbe:
666		case DTxyze:
667	<	return(rmx_write_rgbe(dp, nc, len, fp));
667	>	return(rmx_write_rgbe(dp, ncomp, len, fp));
668		case DTspec:
669	<	return(rmx_write_spec(dp, nc, len, fp));
669	>	return(rmx_write_spec(dp, ncomp, len, fp));
670		}
671		return(0);
672		}
#	Line 680 \| Line 749 \| *rmx_copy(const RMATRIX rm)**
749		int
750		rmx_transfer_data(RMATRIX rdst, RMATRIX rsrc, int dometa)
751		{
752	<	if (!rdst \| !rsrc \|\| (rdst->nrows != rsrc->nrows) \|
684	<	(rdst->ncols != rsrc->ncols) \|
685	<	(rdst->ncomp != rsrc->ncomp))
752	>	if (!rdst \| !rsrc)
753		return(0);
687	–
754		if (dometa) { /* transfer everything? */
755		rmx_reset(rdst);
756		rdst = rsrc;
757		rsrc->info = NULL; rsrc->mapped = NULL; rsrc->mtx = NULL;
758		return(1);
759		}
760	<	#ifdef MAP_FILE /* just matrix data -- leave metadata */
760	>	/* just matrix data -- leave metadata */
761	>	if ((rdst->nrows != rsrc->nrows) \|
762	>	(rdst->ncols != rsrc->ncols) \|
763	>	(rdst->ncomp != rsrc->ncomp))
764	>	return(0);
765	>	#ifdef MAP_FILE
766		if (rdst->mapped)
767		munmap(rdst->mapped, rmx_mapped_size(rdst));
768		else
#	Line 707 \| Line 778 \| *rmx_transfer_data(RMATRIX rdst, RMATRIX rsrc, int do*
778		return(1);
779		}
780
781	<	/* Allocate and assign transposed matrix */
782	<	RMATRIX *
783	<	rmx_transpose(const RMATRIX *rm)
781	>	/* Transpose the given matrix */
782	>	int
783	>	rmx_transpose(RMATRIX *rm)
784		{
785	<	RMATRIX *dnew;
786	<	int i, j;
785	>	uby8 *bmap;
786	>	rmx_dtype val[MAXCOMP];
787	>	RMATRIX dold;
788	>	int i, j;
789
790	<	if (!rm \|\| !rm->mtx)
790	>	if (!rm \|\| !rm->mtx \| (rm->ncomp > MAXCOMP))
791		return(0);
792	<	if ((rm->nrows == 1) \| (rm->ncols == 1)) {
793	<	dnew = rmx_copy(rm);
794	<	if (!dnew)
795	<	return(NULL);
796	<	dnew->nrows = rm->ncols;
797	<	dnew->ncols = rm->nrows;
798	<	return(dnew);
792	>	if (rm->info)
793	>	rmx_addinfo(rm, "Transposed rows and columns\n");
794	>	if ((rm->nrows == 1) \| (rm->ncols == 1)) { /* vector? */
795	>	j = rm->ncols;
796	>	rm->ncols = rm->nrows;
797	>	rm->nrows = j;
798	>	return(1);
799		}
800	<	dnew = rmx_alloc(rm->ncols, rm->nrows, rm->ncomp);
801	<	if (!dnew)
802	<	return(NULL);
803	<	if (rm->info) {
804	<	rmx_addinfo(dnew, rm->info);
805	<	rmx_addinfo(dnew, "Transposed rows and columns\n");
800	>	if (rm->nrows == rm->ncols) { /* square matrix case */
801	>	for (i = rm->nrows; --i > 0; )
802	>	for (j = i; j-- > 0; ) {
803	>	memcpy(val, rmx_val(rm,i,j),
804	>	sizeof(rmx_dtype)*rm->ncomp);
805	>	memcpy(rmx_lval(rm,i,j), rmx_val(rm,j,i),
806	>	sizeof(rmx_dtype)*rm->ncomp);
807	>	memcpy(rmx_lval(rm,j,i), val,
808	>	sizeof(rmx_dtype)*rm->ncomp);
809	>	}
810	>	return(1);
811		}
812	<	dnew->dtype = rm->dtype;
813	<	copycolor(dnew->cexp, rm->cexp);
814	<	memcpy(dnew->wlpart, rm->wlpart, sizeof(dnew->wlpart));
815	<	for (j = dnew->ncols; j--; )
816	<	for (i = dnew->nrows; i--; )
817	<	memcpy(rmx_lval(dnew,i,j), rmx_val(rm,j,i),
818	<	sizeof(rmx_dtype)*dnew->ncomp);
819	<	return(dnew);
812	>	#define bmbyte(r,c) bmap[((r)*rm->ncols+(c))>>3]
813	>	#define bmbit(r,c) (1 << ((r)*rm->ncols+(c) & 7))
814	>	#define bmop(r,c, op) (bmbyte(r,c) op bmbit(r,c))
815	>	#define bmtest(r,c) bmop(r,c,&)
816	>	#define bmset(r,c) bmop(r,c,\|=)
817	>	/* loop completion bitmap */
818	>	bmap = (uby8 )calloc(((size_t)rm->nrowsrm->ncols+7)>>3, 1);
819	>	if (!bmap)
820	>	return(0);
821	>	dold = *rm;
822	>	rm->ncols = dold.nrows; rm->nrows = dold.ncols;
823	>	for (i = rm->nrows; i--; ) /* try every starting point */
824	>	for (j = rm->ncols; j--; ) {
825	>	int i0, j0;
826	>	int i1 = i;
827	>	size_t j1 = j;
828	>	if (bmtest(i, j))
829	>	continue; /* traversed loop earlier */
830	>	memcpy(val, rmx_val(rm,i,j),
831	>	sizeof(rmx_dtype)*rm->ncomp);
832	>	for ( ; ; ) { /* new transpose loop */
833	>	const rmx_dtype *ds;
834	>	i0 = i1; j0 = j1;
835	>	ds = rmx_val(&dold, j0, i0);
836	>	j1 = (ds - dold.mtx)/dold.ncomp;
837	>	i1 = j1 / rm->ncols;
838	>	j1 -= (size_t)i1*rm->ncols;
839	>	bmset(i1, j1); /* mark as done */
840	>	if ((i1 == i) & (j1 == j))
841	>	break; /* back at start */
842	>	memcpy(rmx_lval(rm,i0,j0), ds,
843	>	sizeof(rmx_dtype)*rm->ncomp);
844	>	} /* complete the loop */
845	>	memcpy(rmx_lval(rm,i0,j0), val,
846	>	sizeof(rmx_dtype)*rm->ncomp);
847	>	}
848	>	free(bmap); /* all done! */
849	>	return(1);
850	>	#undef bmbyte
851	>	#undef bmbit
852	>	#undef bmop
853	>	#undef bmtest
854	>	#undef bmset
855		}
856
857		/* Multiply (concatenate) two matrices and allocate the result */
#	Line 762 \| Line 875 \| *rmx_multiply(const RMATRIX m1, const RMATRIX m2)*
875		for (i = mres->nrows; i--; )
876		for (j = mres->ncols; j--; )
877		for (k = mres->ncomp; k--; ) {
878	<	rmx_dtype d = 0;
878	>	double d = 0;
879		for (h = m1->ncols; h--; )
880	<	d += rmx_val(m1,i,h)[k] * rmx_val(m2,h,j)[k];
881	<	rmx_lval(mres,i,j)[k] = d;
880	>	d += (double)rmx_val(m1,i,h)[k] *
881	>	rmx_val(m2,h,j)[k];
882	>	rmx_lval(mres,i,j)[k] = (rmx_dtype)d;
883		}
884		return(mres);
885		}
#	Line 857 \| Line 971 \| *rmx_sum(RMATRIX msum, const RMATRIX madd, const doub*
971		const rmx_dtype *da = rmx_val(madd,i,j);
972		rmx_dtype *ds = rmx_lval(msum,i,j);
973		for (k = msum->ncomp; k--; )
974	<	ds[k] += sf[k] * da[k];
974	>	ds[k] += (rmx_dtype)sf[k] * da[k];
975		}
976		if (mysf)
977		free(mysf);
#	Line 876 \| Line 990 \| *rmx_scale(RMATRIX rm, const double sf[])**
990		for (j = rm->ncols; j--; ) {
991		rmx_dtype *dp = rmx_lval(rm,i,j);
992		for (k = rm->ncomp; k--; )
993	<	dp[k] *= sf[k];
993	>	dp[k] *= (rmx_dtype)sf[k];
994		}
995		if (rm->info)
996		rmx_addinfo(rm, "Applied scalar\n");
#	Line 908 \| Line 1022 \| *rmx_transform(const RMATRIX msrc, int n, const double**
1022		for (j = dnew->ncols; j--; ) {
1023		const rmx_dtype *ds = rmx_val(msrc,i,j);
1024		for (kd = dnew->ncomp; kd--; ) {
1025	<	rmx_dtype d = 0;
1025	>	double d = 0;
1026		for (ks = msrc->ncomp; ks--; )
1027		d += cmat[kdmsrc->ncomp + ks] ds[ks];
1028	<	rmx_lval(dnew,i,j)[kd] = d;
1028	>	rmx_lval(dnew,i,j)[kd] = (rmx_dtype)d;
1029		}
1030		}
1031		return(dnew);
1032		}
1033
920	–	/* Convert a color matrix to newly allocated RMATRIX buffer */
921	–	RMATRIX *
922	–	rmx_from_cmatrix(const CMATRIX *cm)
923	–	{
924	–	int i, j;
925	–	RMATRIX *dnew;
926	–
927	–	if (!cm)
928	–	return(NULL);
929	–	dnew = rmx_alloc(cm->nrows, cm->ncols, 3);
930	–	if (!dnew)
931	–	return(NULL);
932	–	dnew->dtype = DTfloat;
933	–	for (i = dnew->nrows; i--; )
934	–	for (j = dnew->ncols; j--; ) {
935	–	const COLORV *cv = cm_lval(cm,i,j);
936	–	rmx_dtype *dp = rmx_lval(dnew,i,j);
937	–	dp[0] = cv[0];
938	–	dp[1] = cv[1];
939	–	dp[2] = cv[2];
940	–	}
941	–	return(dnew);
942	–	}
943	–
944	–	/* Convert general matrix to newly allocated CMATRIX buffer */
945	–	CMATRIX *
946	–	cm_from_rmatrix(const RMATRIX *rm)
947	–	{
948	–	int i, j;
949	–	CMATRIX *cnew;
950	–
951	–	if (!rm \|\| !rm->mtx \| (rm->ncomp == 2) \| (rm->ncomp > MAXCOMP))
952	–	return(NULL);
953	–	cnew = cm_alloc(rm->nrows, rm->ncols);
954	–	if (!cnew)
955	–	return(NULL);
956	–	for (i = cnew->nrows; i--; )
957	–	for (j = cnew->ncols; j--; ) {
958	–	const rmx_dtype *dp = rmx_val(rm,i,j);
959	–	COLORV *cv = cm_lval(cnew,i,j);
960	–	switch (rm->ncomp) {
961	–	case 3:
962	–	setcolor(cv, dp[0], dp[1], dp[2]);
963	–	break;
964	–	case 1:
965	–	setcolor(cv, dp[0], dp[0], dp[0]);
966	–	break;
967	–	default: {
968	–	COLORV scol[MAXCOMP];
969	–	int k;
970	–	for (k = rm->ncomp; k--; )
971	–	scol[k] = dp[k];
972	–	scolor2color(cv, scol, rm->ncomp, rm->wlpart);
973	–	} break;
974	–	}
975	–	}
976	–	return(cnew);
977	–	}

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Comparing src/util/rmatrix.c (file contents): Revision 2.86 by greg, Fri Mar 28 00:06:36 2025 UTC vs. Revision 2.102 by greg, Thu Oct 30 16:47:54 2025 UTC

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Comparing src/util/rmatrix.c (file contents):
Revision 2.86 by greg, Fri Mar 28 00:06:36 2025 UTC vs.
Revision 2.102 by greg, Thu Oct 30 16:47:54 2025 UTC