File Coverage

blib/lib/ICC/Profile/mAB_.pm

Criterion	Covered	Total	%
statement	206	457	45.0
branch	48	220	21.8
condition	11	98	11.2
subroutine	11	35	31.4
pod	2	21	9.5
total	278	831	33.4

line	stmt	bran	cond	sub	pod	time	code
1							package ICC::Profile::mAB_;
2
3	2			2		73949	use strict;
	2					4
	2					46
4	2			2		8	use Carp;
	2					4
	2					108
5
6							our $VERSION = 2.51;
7
8							# revised 2018-08-07
9							#
10							# Copyright © 2004-2020 by William B. Birkett
11
12							# inherit from Shared
13	2			2		10	use parent qw(ICC::Shared);
	2					4
	2					14
14
15							# use POSIX math
16	2			2		88	use POSIX ();
	2					3
	2					8659
17
18							# create new mAB_ object
19							# hash may contain pointers to B-curves, matrix, M-curves, CLUT, or A-curves
20							# keys are: ('b_curves', 'matrix', 'm_curves', 'clut', 'a_curves')
21							# tag elements not specified in the hash are left empty
22							# parameters: ()
23							# parameters: (ref_to_attribute_hash)
24							# parameters: (ref_to_matrix-based_profile_object)
25							# returns: (ref_to_object)
26							sub new {
27
28							# get object class
29	1			1	0	926	my $class = shift();
30
31							# create empty mAB_ object
32	1					3	my $self = [
33							{}, # object header
34							[], # processing elements
35							0x00, # transform mask
36							0x00 # clipping mask
37							];
38
39							# if there are parameters
40	1	50				4	if (@_) {
41
42							# if one parameter, a hash reference
43	0	0	0			0	if (@_ == 1 && ref($_[0]) eq 'HASH') {
		0	0
44
45							# make new mAB_ tag from attribute hash
46	0					0	_new_from_hash($self, @_);
47
48							# if one parameter, an ICC::Profile object
49							} elsif (@_ == 1 && UNIVERSAL::isa($_[0], 'ICC::Profile')) {
50
51							# make new mAB_ tag from ICC::Profile object
52	0					0	_newICCmatrix($self, @_);
53
54							} else {
55
56							# error
57	0					0	croak('parameter must be a hash reference or a display matrix profile');
58
59							}
60
61							}
62
63							# bless object
64	1					1	bless($self, $class);
65
66							# return object reference
67	1					3	return($self);
68
69							}
70
71							# get/set reference to header hash
72							# parameters: ([ref_to_new_hash])
73							# returns: (ref_to_hash)
74							sub header {
75
76							# get object reference
77	0			0	0	0	my $self = shift();
78
79							# if there are parameters
80	0	0				0	if (@_) {
81
82							# if one parameter, a hash reference
83	0	0	0			0	if (@_ == 1 && ref($_[0]) eq 'HASH') {
84
85							# set header to new hash
86	0					0	$self->[0] = shift();
87
88							} else {
89
90							# error
91	0					0	croak('parameter must be a hash reference');
92
93							}
94
95							}
96
97							# return reference
98	0					0	return($self->[0]);
99
100							}
101
102							# get/set processing element array reference
103							# parameters: ([ref_to_array])
104							# returns: (ref_to_array)
105							sub array {
106
107							# get object reference
108	0			0	0	0	my $self = shift();
109
110							# if parameter
111	0	0				0	if (@_) {
112
113							# verify array reference
114	0	0				0	(ref($_[0]) eq 'ARRAY') or croak('not an array reference');
115
116							# set array reference
117	0					0	$self->[1] = [@{shift()}];
	0					0
118
119							}
120
121							# return array reference
122	0					0	return($self->[1]);
123
124							}
125
126							# get/set reference to B-curves 'cvst' object
127							# parameters: ([ref_to_new_object])
128							# returns: (ref_to_object)
129							sub b_curves {
130
131							# get object reference
132	0			0	0	0	my $self = shift();
133
134							# if there are parameters
135	0	0				0	if (@_) {
136
137							# if one parameter, a 'cvst' object
138	0	0	0			0	if (@_ == 1 && UNIVERSAL::isa($_[0], 'ICC::Profile::cvst')) {
139
140							# set B-curves to new object
141	0					0	$self->[1][0] = shift();
142
143							# set transform mask bit
144	0					0	$self->[2] \|= 0x01;
145
146							} else {
147
148							# error
149	0					0	croak('parameter must be a \'cvst\' object');
150
151							}
152
153							}
154
155							# return object reference
156	0					0	return($self->[1][0]);
157
158							}
159
160							# get/set reference to matrix 'matf' object
161							# parameters: ([ref_to_new_object])
162							# returns: (ref_to_object)
163							sub matrix {
164
165							# get object reference
166	0			0	0	0	my $self = shift();
167
168							# if there are parameters
169	0	0				0	if (@_) {
170
171							# if one parameter, an 'matf' object
172	0	0	0			0	if (@_ == 1 && UNIVERSAL::isa($_[0], 'ICC::Profile::matf')) {
173
174							# set matrix to new object
175	0					0	$self->[1][1] = shift();
176
177							# set transform mask bit
178	0					0	$self->[2] \|= 0x02;
179
180							} else {
181
182							# error
183	0					0	croak('parameter must be an \'matf\' object');
184
185							}
186
187							}
188
189							# return object reference
190	0					0	return($self->[1][1]);
191
192							}
193
194							# get/set reference to M-curves 'cvst' object
195							# parameters: ([ref_to_new_object])
196							# returns: (ref_to_object)
197							sub m_curves {
198
199							# get object reference
200	0			0	0	0	my $self = shift();
201
202							# if there are parameters
203	0	0				0	if (@_) {
204
205							# if one parameter, a 'cvst' object
206	0	0	0			0	if (@_ == 1 && UNIVERSAL::isa($_[0], 'ICC::Profile::cvst')) {
207
208							# set M-curves to new object
209	0					0	$self->[1][2] = shift();
210
211							# set transform mask bit
212	0					0	$self->[2] \|= 0x04;
213
214							} else {
215
216							# error
217	0					0	croak('parameter must be a \'cvst\' object');
218
219							}
220
221							}
222
223							# return object reference
224	0					0	return($self->[1][2]);
225
226							}
227
228							# get/set reference to CLUT 'clut' object
229							# parameters: ([ref_to_new_object])
230							# returns: (ref_to_object)
231							sub clut {
232
233							# get object reference
234	0			0	0	0	my $self = shift();
235
236							# if there are parameters
237	0	0				0	if (@_) {
238
239							# if one parameter, a 'clut' object
240	0	0	0			0	if (@_ == 1 && UNIVERSAL::isa($_[0], 'ICC::Profile::clut')) {
241
242							# set CLUT to new object
243	0					0	$self->[1][3] = shift();
244
245							# set transform mask bit
246	0					0	$self->[2] \|= 0x08;
247
248							} else {
249
250							# error
251	0					0	croak('parameter must be a \'clut\' object');
252
253							}
254
255							}
256
257							# return object reference
258	0					0	return($self->[1][3]);
259
260							}
261
262							# get/set reference to A-curves 'cvst' object
263							# parameters: ([ref_to_new_object])
264							# returns: (ref_to_object)
265							sub a_curves {
266
267							# get object reference
268	0			0	0	0	my $self = shift();
269
270							# if there are parameters
271	0	0				0	if (@_) {
272
273							# if one parameter, a 'cvst' object
274	0	0	0			0	if (@_ == 1 && UNIVERSAL::isa($_[0], 'ICC::Profile::cvst')) {
275
276							# set A-curves to new object
277	0					0	$self->[1][4] = shift();
278
279							# set transform mask bit
280	0					0	$self->[2] \|= 0x10;
281
282							} else {
283
284							# error
285	0					0	croak('parameter must be a \'cvst\' object');
286
287							}
288
289							}
290
291							# return object reference
292	0					0	return($self->[1][4]);
293
294							}
295
296							# get/set transform mask
297							# bits 4-3-2-1-0 correpsond to A-CLUT-M-MATRIX-B
298							# parameters: ([new_mask_value])
299							# returns: (mask_value)
300							sub mask {
301
302							# get object reference
303	0			0	0	0	my $self = shift();
304
305							# if there are parameters
306	0	0				0	if (@_) {
307
308							# if one parameter
309	0	0				0	if (@_ == 1) {
310
311							# set object transform mask value
312	0					0	$self->[2] = shift();
313
314							} else {
315
316							# error
317	0					0	croak('more than one parameter');
318
319							}
320
321							}
322
323							# return transform mask value
324	0					0	return($self->[2]);
325
326							}
327
328							# get/set clipping mask
329							# bits 4-3-2-1-0 correpsond to A-CLUT-M-MATRIX-B
330							# parameters: ([new_mask_value])
331							# returns: (mask_value)
332							sub clip {
333
334							# get object reference
335	0			0	1	0	my $self = shift();
336
337							# if there are parameters
338	0	0				0	if (@_) {
339
340							# if one parameter
341	0	0				0	if (@_ == 1) {
342
343							# set object clipping mask value
344	0					0	$self->[3] = shift();
345
346							} else {
347
348							# error
349	0					0	croak('more than one parameter');
350
351							}
352
353							}
354
355							# return clipping mask value
356	0					0	return($self->[3]);
357
358							}
359
360							# create mAB_ tag object from ICC profile
361							# parameters: (ref_to_parent_object, file_handle, ref_to_tag_table_entry)
362							# returns: (ref_to_object)
363							sub new_fh {
364
365							# get object class
366	1			1	0	537	my $class = shift();
367
368							# create empty mAB_ object
369	1					4	my $self = [
370							{}, # object header
371							[], # processing elements
372							0x00, # transform mask
373							0x00 # clipping mask
374							];
375
376							# verify 3 parameters
377	1	50				5	(@_ == 3) or croak('wrong number of parameters');
378
379							# read mAB_ data from profile
380	1					4	_readICCmAB_($self, @_);
381
382							# bless object
383	1					3	bless($self, $class);
384
385							# return object reference
386	1					9	return($self);
387
388							}
389
390							# writes mAB_ tag object to ICC profile
391							# parameters: (ref_to_parent_object, file_handle, ref_to_tag_table_entry)
392							sub write_fh {
393
394							# verify 4 parameters
395	1	50		1	0	988	(@_ == 4) or croak('wrong number of parameters');
396
397							# write mAB_ data to profile
398	1					5	goto &_writeICCmAB_;
399
400							}
401
402							# get tag size (for writing to profile)
403							# returns: (tag_clut_size)
404							sub size {
405
406							# get parameters
407	3			3	0	454	my ($self) = @_;
408
409							# local variables
410	3					5	my ($size);
411
412							# set header size
413	3					5	$size = 32;
414
415							# for each B-curve
416	3					5	for my $curve (@{$self->[1][0]->array()}) {
	3					15
417
418							# add curve size
419	9					24	$size += $curve->size;
420
421							# pad to 4-bytes
422	9					36	$size += (-$size % 4);
423
424							}
425
426							# if matrix defined
427	3	50				13	if (defined($self->[1][1])) {
428
429							# add matrix size (48 bytes)
430	3					5	$size += 48;
431
432							}
433
434							# if M-curves defined
435	3	50				7	if (defined($self->[1][2])) {
436
437							# for each M-curve
438	3					5	for my $curve (@{$self->[1][2]->array()}) {
	3					7
439
440							# add curve size
441	9					16	$size += $curve->size;
442
443							# pad to 4-bytes
444	9					13	$size += (-$size % 4);
445
446							}
447
448							}
449
450							# if CLUT defined
451	3	50				8	if (defined($self->[1][3])) {
452
453							# add CLUT size (nCLUT object)
454	3		50			29	$size += 20 + $self->[1][3]->_clut_size($self->[1][3][0]{'clut_bytes'} \|\| 2);
455
456							# pad to 4-byte boundary
457	3					13	$size += (-$size % 4);
458
459							}
460
461							# if A-curves defined
462	3	50				8	if (defined($self->[1][4])) {
463
464							# for each A-curve
465	3					4	for my $curve (@{$self->[1][4]->array()}) {
	3					7
466
467							# add curve size
468	9					19	$size += $curve->size;
469
470							# pad to 4-bytes
471	9					11	$size += (-$size % 4);
472
473							}
474
475							}
476
477							# return size
478	3					120	return($size);
479
480							}
481
482							# get number of input channels
483							# returns: (number)
484							sub cin {
485
486							# get object reference
487	0			0	0	0	my $self = shift();
488
489							# return
490	0					0	return($self->[1][-1]->cin());
491
492							}
493
494							# get number of output channels
495							# returns: (number)
496							sub cout {
497
498							# get object reference
499	0			0	0	0	my $self = shift();
500
501							# return
502	0					0	return($self->[1][0]->cout());
503
504							}
505
506							# transform data
507							# transform mask enables/disables individual tag elements
508							# clipping mask enables/disables individual tag output clipping
509							# supported input types:
510							# parameters: (list, [hash])
511							# parameters: (vector, [hash])
512							# parameters: (matrix, [hash])
513							# parameters: (Math::Matrix_object, [hash])
514							# parameters: (structure, [hash])
515							# returns: (same_type_as_input)
516							sub transform {
517
518							# set hash value (0 or 1)
519	0	0		0	0	0	my $h = ref($_[-1]) eq 'HASH' ? 1 : 0;
520
521							# if input a 'Math::Matrix' object
522	0	0	0			0	if (@_ == $h + 2 && UNIVERSAL::isa($_[1], 'Math::Matrix')) {
		0	0
		0
523
524							# call matrix transform
525	0					0	&_trans2;
526
527							# if input an array reference
528							} elsif (@_ == $h + 2 && ref($_[1]) eq 'ARRAY') {
529
530							# if array contains numbers (vector)
531	0	0	0			0	if (! ref($_[1][0]) && @{$_[1]} == grep {Scalar::Util::looks_like_number($_)} @{$_[1]}) {
	0	0	0			0
	0					0
	0					0
532
533							# call vector transform
534	0					0	&_trans1;
535
536							# if array contains vectors (2-D array)
537	0	0				0	} elsif (ref($_[1][0]) eq 'ARRAY' && @{$_[1]} == grep {ref($_) eq 'ARRAY' && Scalar::Util::looks_like_number($_->[0])} @{$_[1]}) {
	0					0
	0					0
538
539							# call matrix transform
540	0					0	&_trans2;
541
542							} else {
543
544							# call structure transform
545	0					0	&_trans3;
546
547							}
548
549							# if input a list (of numbers)
550	0					0	} elsif (@_ == $h + 1 + grep {Scalar::Util::looks_like_number($_)} @_) {
551
552							# call list transform
553	0					0	&_trans0;
554
555							} else {
556
557							# error
558	0					0	croak('invalid transform input');
559
560							}
561
562							}
563
564							# inverse transform
565							# note: number of undefined output values must equal number of defined input values
566							# note: the input and output vectors contain the final solution on return
567							# hash key 'init' specifies initial value vector
568							# hash key 'ubox' enables unit box extrapolation
569							# parameters: (input_vector, output_vector, [hash])
570							# returns: (RMS_error_value)
571							sub inverse {
572
573							# get parameters
574	0			0	0	0	my ($self, $in, $out, $hash) = @_;
575
576							# local variables
577	0					0	my ($i, $j, @si, @so, $init);
578	0					0	my ($int, $jac, $mat, $delta);
579	0					0	my ($max, $elim, $dlim, $accum, $error);
580
581							# initialize indices
582	0					0	$i = $j = -1;
583
584							# build slice arrays while validating input and output arrays
585	0	0				0	((grep {$i++; defined() && push(@si, $i)} @{$in}) == (grep {$j++; ! defined() && push(@so, $j)} @{$out})) or croak('wrong number of undefined values');
	0	0				0
	0	0				0
	0					0
	0					0
	0					0
	0					0
586
587							# get init array
588	0					0	$init = $hash->{'init'};
589
590							# for each undefined output value
591	0					0	for my $i (@so) {
592
593							# set to supplied initial value or 0.5
594	0	0				0	$out->[$i] = defined($init->[$i]) ? $init->[$i] : 0.5;
595
596							}
597
598							# set maximum loop count
599	0		0			0	$max = $hash->{'inv_max'} \|\| 10;
600
601							# loop error limit
602	0		0			0	$elim = $hash->{'inv_elim'} \|\| 1E-6;
603
604							# set delta limit
605	0		0			0	$dlim = $hash->{'inv_dlim'} \|\| 0.5;
606
607							# create empty solution matrix
608	0					0	$mat = Math::Matrix->new([]);
609
610							# compute initial transform values
611	0					0	($jac, $int) = jacobian($self, $out, $hash);
612
613							# solution loop
614	0					0	for (1 .. $max) {
615
616							# for each input
617	0					0	for my $i (0 .. $#si) {
618
619							# for each output
620	0					0	for my $j (0 .. $#so) {
621
622							# copy Jacobian value to solution matrix
623	0					0	$mat->[$i][$j] = $jac->[$si[$i]][$so[$j]];
624
625							}
626
627							# save residual value to solution matrix
628	0					0	$mat->[$i][$#si + 1] = $in->[$si[$i]] - $int->[$si[$i]];
629
630							}
631
632							# solve for delta values
633	0					0	$delta = $mat->solve;
634
635							# for each output value
636	0					0	for my $i (0 .. $#so) {
637
638							# add delta (limited using hyperbolic tangent)
639	0					0	$out->[$so[$i]] += POSIX::tanh($delta->[$i][0]/$dlim) * $dlim;
640
641							}
642
643							# compute updated transform values
644	0					0	($jac, $int) = jacobian($self, $out, $hash);
645
646							# initialize error accumulator
647	0					0	$accum = 0;
648
649							# for each input
650	0					0	for my $i (0 .. $#si) {
651
652							# accumulate delta squared
653	0					0	$accum += ($in->[$si[$i]] - $int->[$si[$i]])**2;
654
655							}
656
657							# compute RMS error
658	0					0	$error = sqrt($accum/@si);
659
660							# if error less than limit
661	0	0				0	last if ($error < $elim);
662
663							}
664
665							# update input vector with final values
666	0					0	@{$in} = @{$int};
	0					0
	0					0
667
668							# return
669	0					0	return($error);
670
671							}
672
673							# compute Jacobian matrix
674							# transform mask enables/disables individual tag elements
675							# parameters: (input_vector, [hash])
676							# returns: (Jacobian_matrix, [output_vector])
677							sub jacobian {
678
679							# get parameters
680	0			0	0	0	my ($self, $data, $hash) = @_;
681
682							# local variables
683	0					0	my ($jac, $jaci);
684
685							# for each processing element (note: sequence is from the last element to the first)
686	0					0	for my $i (reverse(0 .. $#{$self->[1]})) {
	0					0
687
688							# if processing element defined, and transform mask bit set
689	0	0	0			0	if (defined($self->[1][$i]) && $self->[2] & 0x01 << $i) {
690
691							# compute Jacobian matrix and transform data
692	0					0	($jaci, $data) = $self->[1][$i]->jacobian($data, $hash);
693
694							# multiply Jacobian matrices
695	0	0				0	$jac = defined($jac) ? $jaci * $jac : $jaci;
696
697							}
698
699							}
700
701							# if Jacobian matrix is undefined, use identity matrix
702	0	0				0	$jac = Math::Matrix->diagonal((1) x @{$data}) if (! defined($jac));
	0					0
703
704							# if output values wanted
705	0	0				0	if (wantarray) {
706
707							# return Jacobian and output values
708	0					0	return($jac, $data);
709
710							} else {
711
712							# return Jacobian only
713	0					0	return($jac);
714
715							}
716
717							}
718
719							# get/set PCS encoding
720							# for use with ICC::Support::PCS objects
721							# parameters: ([PCS_encoding])
722							# returns: (PCS_encoding)
723							sub pcs {
724
725							# get parameters
726	0			0	0	0	my ($self, $pcs) = @_;
727
728							# if PCS parameter is supplied
729	0	0				0	if (defined($pcs)) {
730
731							# if a valid PCS encoding
732	0	0				0	if (grep {$pcs == $_} (3, 8)) {
	0					0
733
734							# copy to tag header hash
735	0					0	$self->[0]{'pcs_encoding'} = $pcs;
736
737							# return PCS encoding
738	0					0	return($pcs);
739
740							} else {
741
742							# error
743	0					0	croak('invalid PCS encoding');
744
745							}
746
747							} else {
748
749							# if PCS is defined in tag header
750	0	0				0	if (defined($self->[0]{'pcs_encoding'})) {
751
752							# return PCS encoding
753	0					0	return($self->[0]{'pcs_encoding'});
754
755							} else {
756
757							# error
758	0					0	croak('can\'t determine PCS encoding');
759
760							}
761
762							}
763
764							}
765
766							# get/set white point
767							# parameters: ([white_point])
768							# returns: (white_point)
769							sub wtpt {
770
771							# get parameters
772	0			0	0	0	my ($self, $wtpt) = @_;
773
774							# if white point parameter is supplied
775	0	0				0	if (defined($wtpt)) {
776
777							# if an array of three scalars
778	0	0	0			0	if (@{$wtpt} == 3 && 3 == grep {! ref()} @{$wtpt}) {
	0					0
	0					0
	0					0
779
780							# copy to tag header hash
781	0					0	$self->[0]{'wtpt'} = $wtpt;
782
783							# return white point
784	0					0	return($wtpt);
785
786							} else {
787
788							# error
789	0					0	croak('invalid white point');
790
791							}
792
793							} else {
794
795							# if white point is defined in tag header
796	0	0				0	if (defined($self->[0]{'wtpt'})) {
797
798							# return return white point
799	0					0	return($self->[0]{'wtpt'});
800
801							} else {
802
803							# error
804	0					0	croak('can\'t determine white point');
805
806							}
807
808							}
809
810							}
811
812							# print object contents to string
813							# format is an array structure
814							# parameter: ([format])
815							# returns: (string)
816							sub sdump {
817
818							# get parameters
819	0			0	1	0	my ($self, $p) = @_;
820
821							# local variables
822	0					0	my ($element, $fmt, $s, $pt, $st);
823
824							# resolve parameter to an array reference
825	0	0				0	$p = defined($p) ? ref($p) eq 'ARRAY' ? $p : [$p] : [];
		0
826
827							# get format string
828	0	0	0			0	$fmt = defined($p->[0]) && ! ref($p->[0]) ? $p->[0] : 's';
829
830							# set string to object ID
831	0					0	$s = sprintf("'%s' object, (0x%x)\n", ref($self), $self);
832
833							# if format contains 'o'
834	0	0				0	if ($fmt =~ m/s/) {
835
836							# get default parameter
837	0					0	$pt = $p->[-1];
838
839							# for each processing element
840	0					0	for my $i (0 .. $#{$self->[1]}) {
	0					0
841
842							# get element reference
843	0					0	$element = $self->[1][$i];
844
845							# if processing element is undefined
846	0	0				0	if (! defined($element)) {
		0
		0
847
848							# append message
849	0					0	$s .= "\tprocessing element is undefined\n";
850
851							# if processing element is not a blessed object
852							} elsif (! Scalar::Util::blessed($element)) {
853
854							# append message
855	0					0	$s .= "\tprocessing element is not a blessed object\n";
856
857							# if processing element has an 'sdump' method
858							} elsif ($element->can('sdump')) {
859
860							# get 'sdump' string
861	0	0				0	$st = $element->sdump(defined($p->[$i + 1]) ? $p->[$i + 1] : $pt);
862
863							# prepend tabs to each line
864	0					0	$st =~ s/^/\t/mg;
865
866							# append 'sdump' string
867	0					0	$s .= $st;
868
869							# processing element is object without an 'sdump' method
870							} else {
871
872							# append object info
873	0					0	$s .= sprintf("\t'%s' object, (0x%x)\n", ref($element), $element);
874
875							}
876
877							}
878
879							}
880
881							# return
882	0					0	return($s);
883
884							}
885
886							# transform list
887							# parameters: (object_reference, list, [hash])
888							# returns: (list)
889							sub _trans0 {
890
891							# local variables
892	0			0		0	my ($self, $hash, $data);
893
894							# get object reference
895	0					0	$self = shift();
896
897							# get optional hash
898	0	0				0	$hash = pop() if (ref($_[-1]) eq 'HASH');
899
900							# process data
901	0					0	$data = _trans1($self, [@_], $hash);
902
903							# return list
904	0					0	return(@{$data});
	0					0
905
906							}
907
908							# transform vector
909							# parameters: (object_reference, vector, [hash])
910							# returns: (vector)
911							sub _trans1 {
912
913							# get parameters
914	0			0		0	my ($self, $data, $hash) = @_;
915
916							# for each processing element (note: sequence is from the last element to the first)
917	0					0	for my $i (reverse(0 .. $#{$self->[1]})) {
	0					0
918
919							# if processing element defined, and transform mask bit set
920	0	0	0			0	if (defined($self->[1][$i]) && $self->[2] & 0x01 << $i) {
921
922							# transform data
923	0					0	$data = $self->[1][$i]->_trans1($data, $hash);
924
925							# clip output values if clipping mask bit set
926	0	0				0	ICC::Shared::clip_struct($data) if ($self->[3] & 0x01 << $i);
927
928							}
929
930							}
931
932							# return
933	0					0	return($data);
934
935							}
936
937							# transform matrix (2-D array -or- Math::Matrix object)
938							# parameters: (object_reference, matrix, [hash])
939							# returns: (matrix)
940							sub _trans2 {
941
942							# get parameters
943	0			0		0	my ($self, $data, $hash) = @_;
944
945							# for each processing element (note: sequence is from the last element to the first)
946	0					0	for my $i (reverse(0 .. $#{$self->[1]})) {
	0					0
947
948							# if processing element defined, and transform mask bit set
949	0	0	0			0	if (defined($self->[1][$i]) && $self->[2] & 0x01 << $i) {
950
951							# transform data
952	0					0	$data = $self->[1][$i]->_trans2($data, $hash);
953
954							# clip output values if clipping mask bit set
955	0	0				0	ICC::Shared::clip_struct($data) if ($self->[3] & 0x01 << $i);
956
957							}
958
959							}
960
961							# return
962	0					0	return($data);
963
964							}
965
966							# transform structure
967							# parameters: (object_reference, structure, [hash])
968							# returns: (structure)
969							sub _trans3 {
970
971							# get parameters
972	0			0		0	my ($self, $in, $hash) = @_;
973
974							# transform the array structure
975	0					0	_crawl($self, $in, my $out = [], $hash);
976
977							# return
978	0					0	return($out);
979
980							}
981
982							# recursive transform
983							# array structure is traversed until scalar arrays are found and transformed
984							# parameters: (ref_to_object, input_array_reference, output_array_reference, hash)
985							sub _crawl {
986
987							# get parameters
988	0			0		0	my ($self, $in, $out, $hash) = @_;
989
990							# if input is a vector (reference to a scalar array)
991	0	0				0	if (@{$in} == grep {! ref()} @{$in}) {
	0					0
	0					0
	0					0
992
993							# transform input vector and copy to output
994	0					0	@{$out} = @{_trans1($self, $in, $hash)};
	0					0
	0					0
995
996							} else {
997
998							# for each input element
999	0					0	for my $i (0 .. $#{$in}) {
	0					0
1000
1001							# if an array reference
1002	0	0				0	if (ref($in->[$i]) eq 'ARRAY') {
1003
1004							# transform next level
1005	0					0	_crawl($self, $in->[$i], $out->[$i] = [], $hash);
1006
1007							} else {
1008
1009							# error
1010	0					0	croak('invalid transform input');
1011
1012							}
1013
1014							}
1015
1016							}
1017
1018							}
1019
1020							# check object structure
1021							# parameter: (ref_to_object)
1022							# returns: (number_input_channels, number_output_channels)
1023							sub _check {
1024
1025							# get object reference
1026	1			1		2	my $self = shift();
1027
1028							# local variables
1029	1					2	my (@class, $ci, $co);
1030
1031							# make object class array
1032	1					3	@class = qw(ICC::Profile::cvst ICC::Profile::matf ICC::Profile::cvst ICC::Profile::clut ICC::Profile::cvst);
1033
1034							# verify number of processing elements
1035	1	50				1	($#{$self->[1]} <= 4) or croak('\'mAB_\' object has too many processing elements');
	1					4
1036
1037							# for each processing element (note: sequence is from the last element to the first)
1038	1					3	for my $i (reverse(0 .. $#{$self->[1]})) {
	1					4
1039
1040							# if element is defined (matrix and M-curves to may be undefined)
1041	5	50				9	if (defined($self->[1][$i])) {
1042
1043							# verify element has correct class
1044	5	50				20	(ref($self->[1][$i]) eq $class[$i]) or croak("'mAB_' processing element $i has wrong class");
1045
1046							# if element has 'cin' method
1047	5	50				25	if ($self->[1][$i]->can('cin')) {
1048
1049							# if number of input channels is undefined
1050	5	100				10	if (! defined($ci)) {
1051
1052							# set number of input channels
1053	1					5	$ci = $self->[1][$i]->cin();
1054
1055							}
1056
1057							# if number of output channels is defined
1058	5	100				14	if (defined($co)) {
1059
1060							# verify input channels of this element match output channels of previous element
1061	4	50				10	($self->[1][$i]->cin() == $co) or croak("'mAB_' processing element $i has wrong number of channels");
1062
1063							}
1064
1065							}
1066
1067							# if element has 'cout' method
1068	5	50				27	if ($self->[1][$i]->can('cout')) {
1069
1070							# set number of output channels
1071	5					13	$co = $self->[1][$i]->cout();
1072
1073							}
1074
1075							}
1076
1077							}
1078
1079							# verify B-curves are defined
1080	1	50				10	(defined($self->[1][0])) or croak('B-curves are required');
1081
1082							# verify matrix and M-curves are both defined, or neither
1083	1	50	25			8	(defined($self->[1][1]) xor defined($self->[1][2])) && croak('matrix and M-curves must both be defined, or neither');
1084
1085							# verify CLUT and A-curves are both defined, or neither
1086	1	50	25			4	(defined($self->[1][3]) xor defined($self->[1][4])) && croak('CLUT and A-curves must both be defined, or neither');
1087
1088							# if matrix defined
1089	1	50				5	if (defined($self->[1][1])) {
1090
1091							# verify object has 3 output channels
1092	1	50				4	($co == 3) or croak("matrix processing element not permitted with $co output channels");
1093
1094							# verify matrix size (3x3)
1095	1	50	33			4	($self->[1][1]->cin() == 3 && $self->[1][1]->cout() == 3) or croak('matrix processing element matrix wrong size');
1096
1097							# verify offset size (undefined, 0 or 3)
1098	1	50	33			10	(! defined($self->[1][1][2]) \|\| @{$self->[1][1][2]} == 0 \|\| @{$self->[1][1][2]} == 3) or croak('matrix processing element offset wrong size');
	1		33			7
	1					8
1099
1100							}
1101
1102							# return
1103	1					6	return($ci, $co);
1104
1105							}
1106
1107							# set M-curves, matrix, and B-curves
1108							# equivalent to a matrix-based display profile
1109							# parameters: (ref_to_object, ref_to_profile_object)
1110							sub _newICCmatrix {
1111
1112							# get parameters
1113	0			0		0	my ($self, $disp) = @_;
1114
1115							# local variables
1116	0					0	my (@XYZ, @TRC, $wtpt, $bkpt, $id, $mat);
1117
1118							# verify an RGB/XYZ display profile
1119	0	0	0			0	(UNIVERSAL::isa($disp, 'ICC::Profile') && $disp->profile_header->[3] eq 'mntr' && $disp->profile_header->[4] eq 'RGB ' && $disp->profile_header->[5] eq 'XYZ ') or croak('not an RGB-XYZ display profile');
			0
			0
1120
1121							# get primary tags
1122	0					0	@XYZ = $disp->tag(qw(rXYZ gXYZ bXYZ));
1123
1124							# get TRC tags
1125	0					0	@TRC = $disp->tag(qw(rTRC gTRC bTRC));
1126
1127							# verify a matrix profile
1128	0	0	0			0	(@XYZ == 3 && @TRC == 3) or croak('not a matrix profile');
1129
1130							# set input colorspace
1131	0					0	$self->[0]{'input_cs'} = 'RGB ';
1132
1133							# set output colorspace
1134	0					0	$self->[0]{'output_cs'} = 'XYZ ';
1135
1136							# set PCS encoding
1137	0					0	$self->[0]{'pcs_encoding'} = 7;
1138
1139							# get white point tag
1140	0					0	$wtpt = $disp->tag('wtpt');
1141
1142							# set white point value
1143	0	0				0	$self->[0]{'wtpt'} = [@{$wtpt->XYZ}] if (defined($wtpt));
	0					0
1144
1145							# get black point tag
1146	0					0	$bkpt = $disp->tag('bkpt');
1147
1148							# set black point value
1149	0	0				0	$self->[0]{'bkpt'} = [@{$bkpt->XYZ}] if (defined($bkpt));
	0					0
1150
1151							# make identity curve
1152	0					0	$id = ICC::Profile::curv->new();
1153
1154							# make Math::Matrix object from primary tags
1155	0					0	$mat = Math::Matrix->new(map {$_->XYZ()} @XYZ)->transpose->multiply_scalar(32768/65535);
	0					0
1156
1157							# set B-curves
1158	0					0	$self->[1][0] = ICC::Profile::cvst->new([$id, $id, $id]);
1159
1160							# set matrix
1161	0					0	$self->[1][1] = ICC::Profile::matf->new({'matrix' => $mat});
1162
1163							# set M-curves
1164	0					0	$self->[1][2] = ICC::Profile::cvst->new(Storable::dclone(\@TRC));
1165
1166							# set transform mask
1167	0					0	$self->[2] = 0x07;
1168
1169							}
1170
1171							# make new mAB_ tag from attribute hash
1172							# hash may contain pointers to B-curves, matrix, M-curves, CLUT, or A-curves
1173							# keys are: ('b_curves', 'matrix', 'm_curves', 'clut', 'a_curves')
1174							# tag elements not specified in the hash are left empty
1175							# parameters: (ref_to_object, ref_to_attribute_hash)
1176							sub _new_from_hash {
1177
1178							# get parameters
1179	0			0		0	my ($self, $hash) = @_;
1180
1181							# set attribute list (key => [reference_type, array_index])
1182	0					0	my %list = ('b_curves' => ['ICC::Profile::cvst', 0], 'matrix' => ['ICC::Profile::matf', 1], 'm_curves' => ['ICC::Profile::cvst', 2], 'clut' => ['ICC::Profile::clut', 3], 'a_curves' => ['ICC::Profile::cvst', 4]);
1183
1184							# for each attribute
1185	0					0	for my $attr (keys(%{$hash})) {
	0					0
1186
1187							# if value defined
1188	0	0				0	if (defined($hash->{$attr})) {
1189
1190							# if correct reference type
1191	0	0				0	if (ref($hash->{$attr}) eq $list{$attr}[0]) {
1192
1193							# set tag element
1194	0					0	$self->[1][$list{$attr}[1]] = $hash->{$attr};
1195
1196							# set transform mask bit
1197	0					0	$self->[2] \|= (0x01 << $list{$attr}[1]);
1198
1199							} else {
1200
1201							# error
1202	0					0	croak("wrong object type for $attr key");
1203
1204							}
1205
1206							}
1207
1208							}
1209
1210							}
1211
1212							# read mAB_ tag from ICC profile
1213							# parameters: (ref_to_object, ref_to_parent_object, file_handle, ref_to_tag_table_entry)
1214							sub _readICCmAB_ {
1215
1216							# get parameters
1217	1			1		3	my ($self, $parent, $fh, $tag) = @_;
1218
1219							# local variables
1220	1					3	my ($buf, @mft, $pel, $mark, @mat, $bytes, $gsa);
1221
1222							# set tag signature
1223	1					2	$self->[0]{'signature'} = $tag->[0];
1224
1225							# set input colorspace
1226	1					2	$self->[0]{'input_cs'} = $parent->[1][4];
1227
1228							# set output colorspace
1229	1					3	$self->[0]{'output_cs'} = $parent->[1][5];
1230
1231							# seek start of tag
1232	1					9	seek($fh, $tag->[1], 0);
1233
1234							# read tag header
1235	1					9	read($fh, $buf, 32);
1236
1237							# unpack header
1238	1					6	@mft = unpack('a4 x4 C2 x2 N5', $buf);
1239
1240							# verify tag signature
1241	1	50				3	($mft[0] eq 'mAB ') or croak('wrong tag type');
1242
1243							# verify number input channels (1 to 15)
1244	1	50	33			7	($mft[1] > 0 && $mft[1] < 16) or croak('unsupported number of input channels');
1245
1246							# verify number output channels (1 to 15)
1247	1	50	33			6	($mft[2] > 0 && $mft[2] < 16) or croak('unsupported number of output channels');
1248
1249							# if B-curves are defined
1250	1	50				4	if ($mft[3]) {
1251
1252							# make 'cvst' object for B-curves
1253	1					6	$pel = ICC::Profile::cvst->new();
1254
1255							# set file pointer to start of first B-curve
1256	1					2	$mark = $tag->[1] + $mft[3];
1257
1258							# for each output channel
1259	1					6	for my $i (0 .. $mft[2] - 1) {
1260
1261							# adjust file pointer to 4-byte boundary
1262	3					6	$mark += (-$mark % 4);
1263
1264							# seek to start of curve
1265	3					23	seek($fh, $mark, 0);
1266
1267							# read curve type
1268	3					20	read($fh, $buf, 4);
1269
1270							# if 'curv' type
1271	3	50				10	if ($buf eq 'curv') {
		50
1272
1273							# parse 'curv' object
1274	0					0	$pel->[1][$i] = ICC::Profile::curv->new_fh($self, $fh, ['cvst', $mark, 0, 0]);
1275
1276							} elsif ($buf eq 'para') {
1277
1278							# parse 'para' object
1279	3					16	$pel->[1][$i] = ICC::Profile::para->new_fh($self, $fh, ['cvst', $mark, 0, 0]);
1280
1281							} else {
1282
1283							# error
1284	0					0	croak('unsupported curve type or invalid tag structure');
1285
1286							}
1287
1288							# mark current file pointer location
1289	3					9	$mark = tell($fh);
1290
1291							}
1292
1293							# set signature
1294	1					3	$pel->[0]{'signature'} = 'mAB_';
1295
1296							# add processing element
1297	1					3	$self->[1][0] = $pel;
1298
1299							# set transform mask
1300	1					2	$self->[2] \|= 0x01;
1301
1302							}
1303
1304							# if matrix is defined
1305	1	50				3	if ($mft[4]) {
1306
1307							# make 'matf' object for matrix
1308	1					5	$pel = ICC::Profile::matf->new();
1309
1310							# seek to start of matrix
1311	1					9	seek($fh, $tag->[1] + $mft[4], 0);
1312
1313							# read matrix
1314	1					7	$pel->_read_matf($fh, 3, 3, 1, 2);
1315
1316							# set signature
1317	1					3	$pel->[0]{'signature'} = 'mAB_';
1318
1319							# add processing element
1320	1					2	$self->[1][1] = $pel;
1321
1322							# set transform mask
1323	1					2	$self->[2] \|= 0x02;
1324
1325							}
1326
1327							# if M-curves are defined
1328	1	50				2	if ($mft[5]) {
1329
1330							# make 'cvst' object for M-curves
1331	1					4	$pel = ICC::Profile::cvst->new();
1332
1333							# set file pointer to start of first M-curve
1334	1					3	$mark = $tag->[1] + $mft[5];
1335
1336							# for each output channel
1337	1					2	for my $i (0 .. $mft[2] - 1) {
1338
1339							# adjust file pointer to 4-byte boundary
1340	3					13	$mark += (-$mark % 4);
1341
1342							# seek to start of curve
1343	3					24	seek($fh, $mark, 0);
1344
1345							# read curve type
1346	3					23	read($fh, $buf, 4);
1347
1348							# if 'curv' type
1349	3	50				12	if ($buf eq 'curv') {
		50
1350
1351							# parse 'curv' object
1352	0					0	$pel->[1][$i] = ICC::Profile::curv->new_fh($self, $fh, ['cvst', $mark, 0, 0]);
1353
1354							} elsif ($buf eq 'para') {
1355
1356							# parse 'para' object
1357	3					11	$pel->[1][$i] = ICC::Profile::para->new_fh($self, $fh, ['cvst', $mark, 0, 0]);
1358
1359							} else {
1360
1361							# error
1362	0					0	croak('unsupported curve type or invalid tag structure');
1363
1364							}
1365
1366							# mark current file pointer location
1367	3					8	$mark = tell($fh);
1368
1369							}
1370
1371							# set signature
1372	1					6	$pel->[0]{'signature'} = 'mAB_';
1373
1374							# add processing element
1375	1					7	$self->[1][2] = $pel;
1376
1377							# set transform mask
1378	1					5	$self->[2] \|= 0x04;
1379
1380							}
1381
1382							# if CLUT defined
1383	1	50				3	if ($mft[6]) {
1384
1385							# make 'clut' object for CLUT
1386	1					10	$pel = ICC::Profile::clut->new();
1387
1388							# seek to start of CLUT
1389	1					9	seek($fh, $tag->[1] + $mft[6], 0);
1390
1391							# read header
1392	1					7	read($fh, $buf, 20);
1393
1394							# unpack header
1395	1					5	@mat = unpack('C17', $buf);
1396
1397							# get CLUT byte width
1398	1					2	$bytes = pop(@mat);
1399
1400							# save CLUT byte width
1401	1					6	$pel->[0]{'clut_bytes'} = $bytes;
1402
1403							# set number of input channels
1404	1					2	$pel->[0]{'input_channels'} = $mft[1];
1405
1406							# set number of output channels
1407	1					2	$pel->[0]{'output_channels'} = $mft[2];
1408
1409							# make grid size array
1410	1					8	$gsa = [grep {$_} @mat];
	16					22
1411
1412							# read 'clut' data
1413	1					10	$pel->_read_clut($fh, $mft[2], $gsa, $bytes);
1414
1415							# save grid size array
1416	1					2	$pel->[2] = [@{$gsa}];
	1					3
1417
1418							# set signature
1419	1					4	$pel->[0]{'signature'} = 'mAB_';
1420
1421							# add processing element
1422	1					2	$self->[1][3] = $pel;
1423
1424							# set transform mask
1425	1					2	$self->[2] \|= 0x08;
1426
1427							}
1428
1429							# if A-curves are defined
1430	1	50				4	if ($mft[7]) {
1431
1432							# make 'cvst' object for A-curves
1433	1					6	$pel = ICC::Profile::cvst->new();
1434
1435							# set file pointer to start of first A-curve
1436	1					2	$mark = $tag->[1] + $mft[7];
1437
1438							# for each input channel
1439	1					5	for my $i (0 .. $mft[1] - 1) {
1440
1441							# adjust file pointer to 4-byte boundary
1442	3					6	$mark += (-$mark % 4);
1443
1444							# seek to start of curve
1445	3					23	seek($fh, $mark, 0);
1446
1447							# read curve type
1448	3					21	read($fh, $buf, 4);
1449
1450							# if 'curv' type
1451	3	50				10	if ($buf eq 'curv') {
		0
1452
1453							# parse 'curv' object
1454	3					15	$pel->[1][$i] = ICC::Profile::curv->new_fh($self, $fh, ['cvst', $mark, 0, 0]);
1455
1456							} elsif ($buf eq 'para') {
1457
1458							# parse 'para' object
1459	0					0	$pel->[1][$i] = ICC::Profile::para->new_fh($self, $fh, ['cvst', $mark, 0, 0]);
1460
1461							} else {
1462
1463							# error
1464	0					0	croak('unsupported curve type or invalid tag structure');
1465
1466							}
1467
1468							# mark current file pointer location
1469	3					8	$mark = tell($fh);
1470
1471							}
1472
1473							# set signature
1474	1					4	$pel->[0]{'signature'} = 'mAB_';
1475
1476							# add processing element
1477	1					2	$self->[1][4] = $pel;
1478
1479							# set transform mask
1480	1					4	$self->[2] \|= 0x10;
1481
1482							}
1483
1484							}
1485
1486							# write mAB_ tag to ICC profile
1487							# parameters: (ref_to_object, ref_to_parent_object, file_handle, ref_to_tag_table_entry)
1488							sub _writeICCmAB_ {
1489
1490							# get parameters
1491	1			1		3	my ($self, $parent, $fh, $tag) = @_;
1492
1493							# local variables
1494	1					3	my (@mft, $offset, @mat, $bytes, $size);
1495
1496							# set tag type
1497	1					2	$mft[0] = 'mAB ';
1498
1499							# check object structure
1500	1					4	@mft[1, 2] = _check($self);
1501
1502							# initialize offset
1503	1					2	$offset = 32;
1504
1505							# set offset to B-curves
1506	1					2	$mft[3] = 32;
1507
1508							# if B-curves defined
1509	1	50				8	if (defined($self->[1][0])) {
1510
1511							# for each B-curve
1512	1					2	for my $curve (@{$self->[1][0]->array()}) {
	1					36
1513
1514							# add curve size
1515	3					10	$offset += $curve->size;
1516
1517							# pad to 4-bytes
1518	3					31	$offset += (-$offset % 4);
1519
1520							}
1521
1522							} else {
1523
1524							# error
1525	0					0	croak('B-curves are required');
1526
1527							}
1528
1529							# if matrix is defined
1530	1	50				4	if (defined($self->[1][1])) {
1531
1532							# verify output channels
1533	1	50				3	($mft[2] == 3) or croak('3 output channels required for matrix');
1534
1535							# set offset
1536	1					2	$mft[4] = $offset;
1537
1538							# increment offset for matrix size
1539	1					2	$offset += 48;
1540
1541							} else {
1542
1543							# set offset
1544	0					0	$mft[4] = 0;
1545
1546							}
1547
1548							# if M-curves defined
1549	1	50				2	if (defined($self->[1][2])) {
1550
1551							# verify output channels
1552	1	50				3	($mft[2] == 3) or croak('3 output channels required for M-curves');
1553
1554							# set offset
1555	1					2	$mft[5] = $offset;
1556
1557							# for each M-curve
1558	1					1	for my $curve (@{$self->[1][2]->array()}) {
	1					3
1559
1560							# add curve size
1561	3					6	$offset += $curve->size;
1562
1563							# pad to 4-bytes
1564	3					6	$offset += (-$offset % 4);
1565
1566							}
1567
1568							} else {
1569
1570							# set offset
1571	0					0	$mft[5] = 0;
1572
1573							}
1574
1575							# if CLUT defined
1576	1	50				4	if (defined($self->[1][3])) {
1577
1578							# set offset
1579	1					2	$mft[6] = $offset;
1580
1581							# get CLUT data size
1582	1		50			4	$bytes = $self->[1][3][0]{'clut_bytes'} \|\| 2;
1583
1584							# add CLUT size to offset
1585	1					3	$offset += 20 + $self->[1][3]->_clut_size($bytes);
1586
1587							# pad to 4-byte boundary
1588	1					3	$offset += (-$offset % 4);
1589
1590							} else {
1591
1592							# set offset
1593	0					0	$mft[6] = 0;
1594
1595							}
1596
1597							# if A-curves defined
1598	1	50				2	if (defined($self->[1][4])) {
1599
1600							# set offset
1601	1					2	$mft[7] = $offset;
1602
1603							} else {
1604
1605							# set offset
1606	0					0	$mft[7] = 0;
1607
1608							}
1609
1610							# seek start of tag
1611	1					8	seek($fh, $tag->[1], 0);
1612
1613							# write header
1614	1					20	print $fh pack('a4 x4 C2 x2 N5', @mft);
1615
1616							# seek start of B-curves
1617	1					45	seek($fh, $tag->[1] + $mft[3], 0);
1618
1619							# for each B-curve
1620	1					3	for my $curve (@{$self->[1][0]->array()}) {
	1					4
1621
1622							# write curve object
1623	3					16	$curve->write_fh($self->[1][0], $fh, ['cvst', tell($fh), 0, 0]);
1624
1625							# add padding to 4-byte boundary
1626	3					37	seek($fh, (-tell($fh) % 4), 1);
1627
1628							}
1629
1630							# if matrix is defined
1631	1	50				5	if (defined($self->[1][1])) {
1632
1633							# seek start of matrix
1634	1					6	seek($fh, $tag->[1] + $mft[4], 0);
1635
1636							# write matrix
1637	1					6	$self->[1][1]->_write_matf($fh, 1, 2);
1638
1639							}
1640
1641							# if M-curves are defined
1642	1	50				3	if (defined($self->[1][2])) {
1643
1644							# seek start of M-curves
1645	1					12	seek($fh, $tag->[1] + $mft[5], 0);
1646
1647							# for each M-curve
1648	1					3	for my $curve (@{$self->[1][2]->array()}) {
	1					5
1649
1650							# write curve object
1651	3					21	$curve->write_fh($self->[1][2], $fh, ['cvst', tell($fh), 0, 0]);
1652
1653							# add padding to 4-byte boundary
1654	3					34	seek($fh, (-tell($fh) % 4), 1);
1655
1656							}
1657
1658							}
1659
1660							# if CLUT is defined
1661	1	50				5	if (defined($self->[1][3])) {
1662
1663							# for each possible input channel
1664	1					8	for my $i (0 .. 15) {
1665
1666							# set grid size
1667	16		100			29	$mat[$i] = $self->[1][3]->gsa->[$i] \|\| 0;
1668
1669							}
1670
1671							# set CLUT byte width
1672	1					2	$mat[16] = $bytes;
1673
1674							# seek start of CLUT
1675	1					6	seek($fh, $tag->[1] + $mft[6], 0);
1676
1677							# write CLUT header
1678	1					5	print $fh pack('C17 x3', @mat);
1679
1680							# write CLUT
1681	1					4	$self->[1][3]->_write_clut($fh, $self->[1][3]->gsa(), $bytes);
1682
1683							}
1684
1685							# if A-curves are defined
1686	1	50				8	if (defined($self->[1][4])) {
1687
1688							# seek start of A-curves
1689	1					25	seek($fh, $tag->[1] + $mft[7], 0);
1690
1691							# for each M-curve
1692	1					5	for my $curve (@{$self->[1][4]->array()}) {
	1					9
1693
1694							# write curve object
1695	3					20	$curve->write_fh($self->[1][4], $fh, ['cvst', tell($fh), 0, 0]);
1696
1697							# add padding to 4-byte boundary
1698	3					41	seek($fh, (-tell($fh) % 4), 1);
1699
1700							}
1701
1702							}
1703
1704							}
1705
1706							1;