File Coverage

blib/lib/PDLA/Complex.pm

Criterion	Covered	Total	%
statement	266	321	82.8
branch	111	208	53.3
condition	25	54	46.3
subroutine	84	88	95.4
pod	15	29	51.7
total	501	700	71.5

line	stmt	bran	cond	sub	pod	time	code
1
2							#
3							# GENERATED WITH PDLA::PP! Don't modify!
4							#
5							package PDLA::Complex;
6
7							@EXPORT_OK = qw( Ctan Catan re im i cplx real PDLA::PP r2C PDLA::PP i2C PDLA::PP Cr2p PDLA::PP Cp2r PDLA::PP Cadd PDLA::PP Csub PDLA::PP Cmul PDLA::PP Cprodover PDLA::PP Cscale PDLA::PP Cdiv PDLA::PP Ccmp PDLA::PP Cconj PDLA::PP Cabs PDLA::PP Cabs2 PDLA::PP Carg PDLA::PP Csin PDLA::PP Ccos PDLA::PP Cexp PDLA::PP Clog PDLA::PP Cpow PDLA::PP Csqrt PDLA::PP Casin PDLA::PP Cacos PDLA::PP Csinh PDLA::PP Ccosh PDLA::PP Ctanh PDLA::PP Casinh PDLA::PP Cacosh PDLA::PP Catanh PDLA::PP Cproj PDLA::PP Croots PDLA::PP rCpolynomial );
8							%EXPORT_TAGS = (Func=>[@EXPORT_OK]);
9
10	3			3		594	use PDLA::Core;
	3					5
	3					18
11	3			3		23	use PDLA::Exporter;
	3					6
	3					17
12	3			3		19	use DynaLoader;
	3					7
	3					187
13
14
15							BEGIN {
16
17	3			3		66	@ISA = ( 'PDLA::Exporter','DynaLoader','PDLA' );
18	3					12	push @PDLA::Core::PP, __PACKAGE__;
19	3					1534	bootstrap PDLA::Complex ;
20							}
21
22
23
24							our $VERSION = "2.019000";
25	3			3		167	use PDLA::Slices;
	3					6
	3					27
26	3			3		22	use PDLA::Types;
	3					5
	3					372
27	3			3		22	use PDLA::Bad;
	3					6
	3					18
28
29	3			3		23	use vars qw($sep $sep2);
	3					6
	3					268
30
31
32
33							=encoding iso-8859-1
34
35							=head1 NAME
36
37							PDLA::Complex - handle complex numbers
38
39							=head1 SYNOPSIS
40
41							use PDLA;
42							use PDLA::Complex;
43
44							=head1 DESCRIPTION
45
46							This module features a growing number of functions manipulating complex
47							numbers. These are usually represented as a pair C<[ real imag ]> or
48							C<[ magnitude phase ]>. If not explicitly mentioned, the functions can work
49							inplace (not yet implemented!!!) and require rectangular form.
50
51							While there is a procedural interface available (C<< $x/$y*$c <=> Cmul
52							(Cdiv ($x, $y), $c) >>), you can also opt to cast your pdl's into the
53							C datatype, which works just like your normal piddles, but
54							with all the normal perl operators overloaded.
55
56							The latter means that C will be evaluated using the
57							normal rules of complex numbers, while other pdl functions (like C)
58							just treat the piddle as a real-valued piddle with a lowest dimension of
59							size 2, so C will return the maximum of all real and imaginary parts,
60							not the "highest" (for some definition)
61
62							=head1 TIPS, TRICKS & CAVEATS
63
64							=over 4
65
66							=item *
67
68							C is a constant exported by this module, which represents
69							C<-1**0.5>, i.e. the imaginary unit. it can be used to quickly and
70							conveniently write complex constants like this: C<4+3*i>.
71
72							=item *
73
74							Use C to convert from real to complex, as in C<$r
75							= Cpow $cplx, r2C 2>. The overloaded operators automatically do that for
76							you, all the other functions, do not. So C will return all
77							the fifths roots of 1+1*i (due to threading).
78
79							=item *
80
81							use C to cast from normal piddles into the
82							complex datatype. Use C to cast back. This
83							requires a copy, though.
84
85							=item *
86
87							This module has received some testing by Vanuxem Gr�gory
88							(g.vanuxem at wanadoo dot fr). Please report any other errors you
89							come across!
90
91							=back
92
93							=head1 EXAMPLE WALK-THROUGH
94
95							The complex constant five is equal to C:
96
97							pdla> p $x = r2C 5
98							5 +0i
99
100							Now calculate the three cubic roots of of five:
101
102							pdla> p $r = Croots $x, 3
103							[1.70998 +0i -0.854988 +1.48088i -0.854988 -1.48088i]
104
105							Check that these really are the roots:
106
107							pdla> p $r ** 3
108							[5 +0i 5 -1.22465e-15i 5 -7.65714e-15i]
109
110							Duh! Could be better. Now try by multiplying C<$r> three times with itself:
111
112							pdla> p $r$r$r
113							[5 +0i 5 -4.72647e-15i 5 -7.53694e-15i]
114
115							Well... maybe C (which is used by the C<**> operator) isn't as
116							bad as I thought. Now multiply by C and negate, which is just a very
117							expensive way of swapping real and imaginary parts.
118
119							pdla> p -($r*i)
120							[0 -1.70998i 1.48088 +0.854988i -1.48088 +0.854988i]
121
122							Now plot the magnitude of (part of) the complex sine. First generate the
123							coefficients:
124
125							pdla> $sin = i * zeroes(50)->xlinvals(2,4) + zeroes(50)->xlinvals(0,7)
126
127							Now plot the imaginary part, the real part and the magnitude of the sine
128							into the same diagram:
129
130							pdla> use PDLA::Graphics::Gnuplot
131							pdla> gplot( with => 'lines',
132							PDLA::cat(im ( sin $sin ),
133							re ( sin $sin ),
134							abs( sin $sin ) ))
135
136							An ASCII version of this plot looks like this:
137
138							30 ++-----+------+------+------+------+------+------+------+------+-----++
139							+ + + + + + + + + + +
140							\| $$\|
141							\| $ \|
142							25 ++ $$ ++
143							\| *** \|
144							\| * \|
145							\| $$* *\|
146							20 ++ $** ++
147							\| $$$* #\|
148							\| $$$ * # \|
149							\| $$ * # \|
150							15 ++ $$$ * # ++
151							\| $$$ ** # \|
152							\| $$$$ * # \|
153							\| $$$$ * # \|
154							10 ++ $$$$$ * # ++
155							\| $$$$$ * # \|
156							\| $$$$$$$ * # \|
157							5 ++ $$$############ * # ++
158							\|****$$$### ### # \|
159							* #***** # * # \|
160							\| ### * ### # \|
161							0 ## *** # * # ++
162							\| * # * # \|
163							\| * # # \|
164							\| * # * # \|
165							-5 ++ ** # * # ++
166							\| * ## # \|
167							\| * #* # \|
168							\| ** *## # \|
169							-10 ++ **** # # ++
170							\| # # \|
171							\| ## ## \|
172							+ + + + + + + ### + ### + + +
173							-15 ++-----+------+------+------+------+------+-----###-----+------+-----++
174							0 5 10 15 20 25 30 35 40 45 50
175
176
177							=head1 OPERATORS
178
179							The following operators are overloaded:
180
181							=over 4
182
183							=item +, += (addition)
184
185							=item -, -= (subtraction)
186
187							=item , = (multiplication; L)
188
189							=item /, /= (division; L)
190
191							=item , = (exponentiation; L)
192
193							=item atan2 (4-quadrant arc tangent)
194
195							=item <=> (nonsensical comparison operator; L)
196
197							=item sin (L)
198
199							=item cos (L)
200
201							=item exp (L)
202
203							=item abs (L)
204
205							=item log (L)
206
207							=item sqrt (L)
208
209							=item <, <=, ==, !=, >=, > (just as nonsensical as L)
210
211							=item ++, -- (increment, decrement; they affect the real part of the complex number only)
212
213							=item "" (stringification)
214
215							=back
216
217							=cut
218
219							my $i;
220	3			3		32	BEGIN { $i = bless pdl 0,1 }
221	53			53	0	7200	sub i () { $i->copy };
222
223
224
225
226
227
228							=head1 FUNCTIONS
229
230
231
232							=cut
233
234
235
236
237
238							=head2 cplx
239
240							=for ref
241
242							Cast a real-valued piddle to the complex datatype.
243
244							The first dimension of the piddle must be of size 2. After this the
245							usual (complex) arithmetic operators are applied to this pdl, rather
246							than the normal elementwise pdl operators. Dataflow to the complex
247							parent works. Use C on the result if you don't want this.
248
249							=for usage
250
251							cplx($real_valued_pdl)
252
253							=head2 complex
254
255							=for ref
256
257							Cast a real-valued piddle to the complex datatype I dataflow
258							and I.
259
260							Achieved by merely reblessing a piddle. The first dimension of the
261							piddle must be of size 2.
262
263							=for usage
264
265							complex($real_valued_pdl)
266
267							=head2 real
268
269							=for ref
270
271							Cast a complex valued pdl back to the "normal" pdl datatype.
272
273							Afterwards the normal elementwise pdl operators are used in
274							operations. Dataflow to the real parent works. Use C on the
275							result if you don't want this.
276
277							=for usage
278
279							real($cplx_valued_pdl)
280
281							=cut
282
283	3			3		22	use Carp;
	3					7
	3					1114
284							sub cplx($) {
285	4	50		4	1	634	return $_[0] if UNIVERSAL::isa($_[0],'PDLA::Complex'); # NOOP if just piddle
286	4	50	33			20	croak "first dimsize must be 2" unless $_[0]->dims > 0 && $_[0]->dim(0) == 2;
287	4					19	bless $_[0]->slice('');
288							}
289
290							sub complex($) {
291	10	100		10	1	642	return $_[0] if UNIVERSAL::isa($_[0],'PDLA::Complex'); # NOOP if just piddle
292	8	50	33			25	croak "first dimsize must be 2" unless $_[0]->dims > 0 && $_[0]->dim(0) == 2;
293	8					49	bless $_[0];
294							}
295
296							*PDLA::cplx = \&cplx;
297							*PDLA::complex = \&complex;
298
299							sub real($) {
300	62	50		62	1	2530	return $_[0] unless UNIVERSAL::isa($_[0],'PDLA::Complex'); # NOOP unless complex
301	62					197	bless $_[0]->slice(''), 'PDLA';
302							}
303
304
305
306
307
308							=head2 r2C
309
310							=for sig
311
312							Signature: (r(); [o]c(m=2))
313
314							=for ref
315
316							convert real to complex, assuming an imaginary part of zero
317
318							=for bad
319
320							r2C does not process bad values.
321							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
322
323
324							=cut
325
326
327
328
329
330							*PDLA::r2C = \&PDLA::Complex::r2C;
331							sub PDLA::Complex::r2C($) {
332	73	50		73	1	1155	return $_[0] if UNIVERSAL::isa($_[0],'PDLA::Complex');
333	73					175	my $r = __PACKAGE__->initialize;
334	73					809	&PDLA::Complex::_r2C_int($_[0], $r);
335	73					788	$r }
336
337
338
339	3			3		269	BEGIN {*r2C = \&PDLA::Complex::r2C;
340							}
341
342
343
344
345							=head2 i2C
346
347							=for sig
348
349							Signature: (r(); [o]c(m=2))
350
351							=for ref
352
353							convert imaginary to complex, assuming a real part of zero
354
355							=for bad
356
357							i2C does not process bad values.
358							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
359
360
361							=cut
362
363
364
365
366	3			3	1	14	*PDLA::i2C = \&PDLA::Complex::i2C; sub PDLA::Complex::i2C($) { my $r = __PACKAGE__->initialize; &PDLA::Complex::_i2C_int($_[0], $r); $r }
	3					52
	3					22
367
368	3			3		93	BEGIN {*i2C = \&PDLA::Complex::i2C;
369							}
370
371
372
373
374							=head2 Cr2p
375
376							=for sig
377
378							Signature: (r(m=2); float+ [o]p(m=2))
379
380							=for ref
381
382							convert complex numbers in rectangular form to polar (mod,arg) form. Works inplace
383
384							=for bad
385
386							Cr2p does not process bad values.
387							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
388
389
390							=cut
391
392
393
394
395
396
397	3			3		94	BEGIN {*Cr2p = \&PDLA::Complex::Cr2p;
398							}
399
400
401
402
403							=head2 Cp2r
404
405							=for sig
406
407							Signature: (r(m=2); [o]p(m=2))
408
409							=for ref
410
411							convert complex numbers in polar (mod,arg) form to rectangular form. Works inplace
412
413							=for bad
414
415							Cp2r does not process bad values.
416							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
417
418
419							=cut
420
421
422
423
424
425
426	3			3		68	BEGIN {*Cp2r = \&PDLA::Complex::Cp2r;
427							}
428
429
430
431
432	3			3		78	BEGIN {*Cadd = \&PDLA::Complex::Cadd;
433							}
434
435
436
437
438	3			3		75	BEGIN {*Csub = \&PDLA::Complex::Csub;
439							}
440
441
442
443
444							=head2 Cmul
445
446							=for sig
447
448							Signature: (a(m=2); b(m=2); [o]c(m=2))
449
450							=for ref
451
452							complex multiplication
453
454							=for bad
455
456							Cmul does not process bad values.
457							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
458
459
460							=cut
461
462
463
464
465
466
467	3			3		85	BEGIN {*Cmul = \&PDLA::Complex::Cmul;
468							}
469
470
471
472
473							=head2 Cprodover
474
475							=for sig
476
477							Signature: (a(m=2,n); [o]c(m=2))
478
479							=for ref
480
481							Project via product to N-1 dimension
482
483							=for bad
484
485							Cprodover does not process bad values.
486							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
487
488
489							=cut
490
491
492
493
494
495
496	3			3		93	BEGIN {*Cprodover = \&PDLA::Complex::Cprodover;
497							}
498
499
500
501
502							=head2 Cscale
503
504							=for sig
505
506							Signature: (a(m=2); b(); [o]c(m=2))
507
508							=for ref
509
510							mixed complex/real multiplication
511
512							=for bad
513
514							Cscale does not process bad values.
515							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
516
517
518							=cut
519
520
521
522
523
524
525	3			3		87	BEGIN {*Cscale = \&PDLA::Complex::Cscale;
526							}
527
528
529
530
531							=head2 Cdiv
532
533							=for sig
534
535							Signature: (a(m=2); b(m=2); [o]c(m=2))
536
537							=for ref
538
539							complex division
540
541							=for bad
542
543							Cdiv does not process bad values.
544							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
545
546
547							=cut
548
549
550
551
552
553
554	3			3		138	BEGIN {*Cdiv = \&PDLA::Complex::Cdiv;
555							}
556
557
558
559
560							=head2 Ccmp
561
562							=for sig
563
564							Signature: (a(m=2); b(m=2); [o]c())
565
566							=for ref
567
568							Complex comparison operator (spaceship).
569
570							Ccmp orders by real first, then by imaginary. Hm, but it is mathematical nonsense! Complex numbers cannot be ordered.
571
572							=for bad
573
574							Ccmp does not process bad values.
575							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
576
577
578							=cut
579
580
581
582
583
584
585	3			3		72	BEGIN {*Ccmp = \&PDLA::Complex::Ccmp;
586							}
587
588
589
590
591							=head2 Cconj
592
593							=for sig
594
595							Signature: (a(m=2); [o]c(m=2))
596
597							=for ref
598
599							complex conjugation. Works inplace
600
601							=for bad
602
603							Cconj does not process bad values.
604							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
605
606
607							=cut
608
609
610
611
612
613
614	3			3		227	BEGIN {*Cconj = \&PDLA::Complex::Cconj;
615							}
616
617
618
619
620							=head2 Cabs
621
622							=for sig
623
624							Signature: (a(m=2); [o]c())
625
626							=for ref
627
628							complex C (also known as I)
629
630							=for bad
631
632							Cabs does not process bad values.
633							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
634
635
636							=cut
637
638
639
640
641							sub PDLA::Complex::Cabs($) {
642	8			8	1	34	my $pdl= shift;
643	8					27	my $abs = PDLA->null;
644	8					126	&PDLA::Complex::_Cabs_int($pdl, $abs);
645	8					132	$abs;
646							}
647
648	3			3		202	BEGIN {*Cabs = \&PDLA::Complex::Cabs;
649							}
650
651
652
653
654							=head2 Cabs2
655
656							=for sig
657
658							Signature: (a(m=2); [o]c())
659
660							=for ref
661
662							complex squared C (also known I)
663
664							=for bad
665
666							Cabs2 does not process bad values.
667							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
668
669
670							=cut
671
672
673
674
675							sub PDLA::Complex::Cabs2($) {
676	2			2	1	314	my $pdl= shift;
677	2					7	my $abs2 = PDLA->null;
678	2					26	&PDLA::Complex::_Cabs2_int($pdl, $abs2);
679	2					10	$abs2;
680							}
681
682	3			3		279	BEGIN {*Cabs2 = \&PDLA::Complex::Cabs2;
683							}
684
685
686
687
688							=head2 Carg
689
690							=for sig
691
692							Signature: (a(m=2); [o]c())
693
694							=for ref
695
696							complex argument function ("angle")
697
698							=for bad
699
700							Carg does not process bad values.
701							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
702
703
704							=cut
705
706
707
708
709							sub PDLA::Complex::Carg($) {
710	2			2	1	5	my $pdl= shift;
711	2					6	my $arg = PDLA->null;
712	2					42	&PDLA::Complex::_Carg_int($pdl, $arg);
713	2					11	$arg;
714							}
715
716	3			3		138	BEGIN {*Carg = \&PDLA::Complex::Carg;
717							}
718
719
720
721
722							=head2 Csin
723
724							=for sig
725
726							Signature: (a(m=2); [o]c(m=2))
727
728							=for ref
729
730							sin (a) = 1/(2i) (exp (ai) - exp (-ai)). Works inplace
731
732							=for bad
733
734							Csin does not process bad values.
735							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
736
737
738							=cut
739
740
741
742
743
744
745	3			3		84	BEGIN {*Csin = \&PDLA::Complex::Csin;
746							}
747
748
749
750
751							=head2 Ccos
752
753							=for sig
754
755							Signature: (a(m=2); [o]c(m=2))
756
757							=for ref
758
759							cos (a) = 1/2 * (exp (ai) + exp (-ai)). Works inplace
760
761							=for bad
762
763							Ccos does not process bad values.
764							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
765
766
767							=cut
768
769
770
771
772
773
774	3			3		205	BEGIN {*Ccos = \&PDLA::Complex::Ccos;
775							}
776
777
778
779							=head2 Ctan
780
781							=for ref
782
783							Complex tangent
784
785							tan (a) = -i * (exp (ai) - exp (-ai)) / (exp (ai) + exp (-ai))
786
787							Does not work inplace.
788
789							=cut
790
791	5			5	1	26	sub Ctan($) { Csin($_[0]) / Ccos($_[0]) }
792
793
794
795
796
797
798							=head2 Cexp
799
800							=for sig
801
802							Signature: (a(m=2); [o]c(m=2))
803
804							=for ref
805
806							exp (a) = exp (real (a)) * (cos (imag (a)) + i * sin (imag (a))). Works inplace
807
808							=for bad
809
810							Cexp does not process bad values.
811							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
812
813
814							=cut
815
816
817
818
819
820
821	3			3		87	BEGIN {*Cexp = \&PDLA::Complex::Cexp;
822							}
823
824
825
826
827							=head2 Clog
828
829							=for sig
830
831							Signature: (a(m=2); [o]c(m=2))
832
833							=for ref
834
835							log (a) = log (cabs (a)) + i * carg (a). Works inplace
836
837							=for bad
838
839							Clog does not process bad values.
840							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
841
842
843							=cut
844
845
846
847
848
849
850	3			3		81	BEGIN {*Clog = \&PDLA::Complex::Clog;
851							}
852
853
854
855
856							=head2 Cpow
857
858							=for sig
859
860							Signature: (a(m=2); b(m=2); [o]c(m=2))
861
862							=for ref
863
864							complex C (C<**>-operator)
865
866							=for bad
867
868							Cpow does not process bad values.
869							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
870
871
872							=cut
873
874
875
876
877
878
879	3			3		133	BEGIN {*Cpow = \&PDLA::Complex::Cpow;
880							}
881
882
883
884
885							=head2 Csqrt
886
887							=for sig
888
889							Signature: (a(m=2); [o]c(m=2))
890
891							=for ref
892
893							Works inplace
894
895							=for bad
896
897							Csqrt does not process bad values.
898							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
899
900
901							=cut
902
903
904
905
906
907
908	3			3		69	BEGIN {*Csqrt = \&PDLA::Complex::Csqrt;
909							}
910
911
912
913
914							=head2 Casin
915
916							=for sig
917
918							Signature: (a(m=2); [o]c(m=2))
919
920							=for ref
921
922							Works inplace
923
924							=for bad
925
926							Casin does not process bad values.
927							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
928
929
930							=cut
931
932
933
934
935
936
937	3			3		78	BEGIN {*Casin = \&PDLA::Complex::Casin;
938							}
939
940
941
942
943							=head2 Cacos
944
945							=for sig
946
947							Signature: (a(m=2); [o]c(m=2))
948
949							=for ref
950
951							Works inplace
952
953							=for bad
954
955							Cacos does not process bad values.
956							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
957
958
959							=cut
960
961
962
963
964
965
966	3			3		257	BEGIN {*Cacos = \&PDLA::Complex::Cacos;
967							}
968
969
970
971							=head2 Catan
972
973							=for ref
974
975							Return the complex C.
976
977							Does not work inplace.
978
979							=cut
980
981							sub Catan($) {
982	2			2	1	305	my $z = shift;
983	2					7	Cmul Clog(Cdiv (PDLA::Complex::i+$z, PDLA::Complex::i-$z)), pdl(0, 0.5);
984							}
985
986
987
988
989
990							=head2 Csinh
991
992							=for sig
993
994							Signature: (a(m=2); [o]c(m=2))
995
996							=for ref
997
998							sinh (a) = (exp (a) - exp (-a)) / 2. Works inplace
999
1000							=for bad
1001
1002							Csinh does not process bad values.
1003							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1004
1005
1006							=cut
1007
1008
1009
1010
1011
1012
1013	3			3		88	BEGIN {*Csinh = \&PDLA::Complex::Csinh;
1014							}
1015
1016
1017
1018
1019							=head2 Ccosh
1020
1021							=for sig
1022
1023							Signature: (a(m=2); [o]c(m=2))
1024
1025							=for ref
1026
1027							cosh (a) = (exp (a) + exp (-a)) / 2. Works inplace
1028
1029							=for bad
1030
1031							Ccosh does not process bad values.
1032							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1033
1034
1035							=cut
1036
1037
1038
1039
1040
1041
1042	3			3		82	BEGIN {*Ccosh = \&PDLA::Complex::Ccosh;
1043							}
1044
1045
1046
1047
1048							=head2 Ctanh
1049
1050							=for sig
1051
1052							Signature: (a(m=2); [o]c(m=2))
1053
1054							=for ref
1055
1056							Works inplace
1057
1058							=for bad
1059
1060							Ctanh does not process bad values.
1061							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1062
1063
1064							=cut
1065
1066
1067
1068
1069
1070
1071	3			3		88	BEGIN {*Ctanh = \&PDLA::Complex::Ctanh;
1072							}
1073
1074
1075
1076
1077							=head2 Casinh
1078
1079							=for sig
1080
1081							Signature: (a(m=2); [o]c(m=2))
1082
1083							=for ref
1084
1085							Works inplace
1086
1087							=for bad
1088
1089							Casinh does not process bad values.
1090							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1091
1092
1093							=cut
1094
1095
1096
1097
1098
1099
1100	3			3		80	BEGIN {*Casinh = \&PDLA::Complex::Casinh;
1101							}
1102
1103
1104
1105
1106							=head2 Cacosh
1107
1108							=for sig
1109
1110							Signature: (a(m=2); [o]c(m=2))
1111
1112							=for ref
1113
1114							Works inplace
1115
1116							=for bad
1117
1118							Cacosh does not process bad values.
1119							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1120
1121
1122							=cut
1123
1124
1125
1126
1127
1128
1129	3			3		72	BEGIN {*Cacosh = \&PDLA::Complex::Cacosh;
1130							}
1131
1132
1133
1134
1135							=head2 Catanh
1136
1137							=for sig
1138
1139							Signature: (a(m=2); [o]c(m=2))
1140
1141							=for ref
1142
1143							Works inplace
1144
1145							=for bad
1146
1147							Catanh does not process bad values.
1148							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1149
1150
1151							=cut
1152
1153
1154
1155
1156
1157
1158	3			3		81	BEGIN {*Catanh = \&PDLA::Complex::Catanh;
1159							}
1160
1161
1162
1163
1164							=head2 Cproj
1165
1166							=for sig
1167
1168							Signature: (a(m=2); [o]c(m=2))
1169
1170							=for ref
1171
1172							compute the projection of a complex number to the riemann sphere. Works inplace
1173
1174							=for bad
1175
1176							Cproj does not process bad values.
1177							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1178
1179
1180							=cut
1181
1182
1183
1184
1185
1186
1187	3			3		242	BEGIN {*Cproj = \&PDLA::Complex::Cproj;
1188							}
1189
1190
1191
1192
1193							=head2 Croots
1194
1195							=for sig
1196
1197							Signature: (a(m=2); [o]c(m=2,n); int n => n)
1198
1199							=for ref
1200
1201							Compute the C roots of C. C must be a positive integer. The result will always be a complex type!
1202
1203							=for bad
1204
1205							Croots does not process bad values.
1206							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1207
1208
1209							=cut
1210
1211
1212
1213
1214							sub PDLA::Complex::Croots($$) {
1215	3			3	1	611	my ($pdl, $n) = @_;
1216	3					11	my $r = PDLA->null;
1217	3					117	&PDLA::Complex::_Croots_int($pdl, $r, $n);
1218	3					20	bless $r;
1219							}
1220
1221	3			3		437	BEGIN {*Croots = \&PDLA::Complex::Croots;
1222							}
1223
1224
1225
1226							=head2 re, im
1227
1228							Return the real or imaginary part of the complex number(s) given.
1229
1230							These are slicing operators, so data flow works. The real and
1231							imaginary parts are returned as piddles (ref eq PDLA).
1232
1233							=cut
1234
1235	21			21	1	68	sub re($) { bless $_[0]->slice("(0)"), 'PDLA'; }
1236	19			19	1	362	sub im($) { bless $_[0]->slice("(1)"), 'PDLA'; }
1237
1238							*PDLA::Complex::re = \&re;
1239							*PDLA::Complex::im = \&im;
1240
1241
1242
1243
1244
1245							=head2 rCpolynomial
1246
1247							=for sig
1248
1249							Signature: (coeffs(n); x(c=2,m); [o]out(c=2,m))
1250
1251							=for ref
1252
1253							evaluate the polynomial with (real) coefficients C at the (complex) position(s) C. C is the constant term.
1254
1255							=for bad
1256
1257							rCpolynomial does not process bad values.
1258							It will set the bad-value flag of all output piddles if the flag is set for any of the input piddles.
1259
1260
1261							=cut
1262
1263
1264
1265
1266
1267							sub rCpolynomial {
1268	2			2	1	6	my $coeffs = shift;
1269	2					3	my $x = shift;
1270	2					6	my $out = $x->copy;
1271	2					26	_rCpolynomial_int($coeffs,$x,$out);
1272	2					7	return PDLA::complex($out);
1273							}
1274
1275
1276	3			3		2540	BEGIN {*rCpolynomial = \&PDLA::Complex::rCpolynomial;
1277							}
1278
1279
1280							;
1281
1282
1283							# overload must be here, so that all the functions can be seen
1284
1285							# undocumented compatibility functions (thanks to Luis Mochan!)
1286	1			1	0	4	sub Catan2($$) { Clog( $_[1] + i*$_[0])/i }
1287	0			0	1	0	sub atan2($$) { Clog( $_[1] + i*$_[0])/i }
1288
1289
1290							=begin comment
1291
1292							In _gen_biop, the '+' or '-' between the operator (e.g., '*') and the
1293							function that it overloads (e.g., 'Cmul') flags whether the operation
1294							is ('+') or is not ('-') commutative. See the discussion of argument
1295							swapping in the section "Calling Conventions and Magic Autogeneration"
1296							in "perldoc overload".
1297
1298							This is a great example of taking almost as many lines to write cute
1299							generating code as it would take to just clearly and explicitly write
1300							down the overload.
1301
1302							=end comment
1303
1304							=cut
1305
1306							sub _gen_biop {
1307	21			21		47	local $_ = shift;
1308	21					28	my $sub;
1309	21	100				124	if (/(\S+)\+(\w+)/) { #commutes
		50
1310	6	100		35		639	$sub = eval 'sub { '.$2.' $_[0], ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1] }';
	35	100				207
	28					185
1311							} elsif (/(\S+)\-(\w+)/) { #does not commute
1312	15	50		10		1672	$sub = eval 'sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
	10	50				43
	10	100				68
	5	50				197
	5	50				35
	1	50				8
	1	50				7
	7	50				31
	7	100				52
	16	100				278
	16					136
1313							$_[2] ? '.$2.' $y, $_[0] : '.$2.' $_[0], $y }'; #need to swap?
1314							} else {
1315	0					0	die;
1316							}
1317	21	100	100			151	if($1 eq "atan2" \|\| $1 eq "<=>") { return ($1, $sub) }
	6					33
1318	15					81	($1, $sub, "$1=", $sub);
1319							}
1320
1321							sub _gen_unop {
1322	18			18		102	my ($op, $func) = ($_[0] =~ /(.+)@(\w+)/);
1323	18	50				138	*$op = \&$func if $op =~ /\w+/; # create an alias
1324	18			0		1155	($op, eval 'sub { '.$func.' $_[0] }');
	0					0
	4					19
	0					0
	0					0
	0					0
	0					0
1325							}
1326
1327							#sub _gen_cpop {
1328							# ($_[0], eval 'sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
1329							# ($_[2] ? $y <=> $_[0] : $_[0] <=> $y) '.$_[0].' 0 }');
1330							#}
1331
1332							sub initialize {
1333							# Bless a null PDLA into the supplied 1st arg package
1334							# If 1st arg is a ref, get the package from it
1335	521	100		521	0	6299	bless PDLA->null, ref($_[0]) ? ref($_[0]) : $_[0];
1336							}
1337
1338							use overload
1339							(map _gen_biop($_), qw(++Cadd --Csub +Cmul /-Cdiv *-Cpow atan2-Catan2 <=>-Ccmp)),
1340							(map _gen_unop($_), qw(sin@Csin cos@Ccos exp@Cexp abs@Cabs log@Clog sqrt@Csqrt)),
1341							# (map _gen_cpop($_), qw(< <= == != >= >)), #segfaults with infinite recursion of the operator.
1342							#final ternary used to make result a scalar, not a PDLA:::Complex (thx CED!)
1343	2	50		2		19	"<" => sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
1344	2	50				52	PDLA::lt( ($_[2] ? $y <=> $_[0] : $_[0] <=> $y), 0, 0) ? 1 : 0;},
		50
1345	1	50		1		8	"<=" => sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
1346	1	50				28	PDLA::le( ($_[2] ? $y <=> $_[0] : $_[0] <=> $y), 0, 0) ? 1 : 0;},
		50
1347	1	50		1		7	"==" => sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
1348	1	50				29	PDLA::eq( ($_[2] ? $y <=> $_[0] : $_[0] <=> $y), 0, 0) ? 1 : 0;},
		50
1349	1	50		1		7	"!=" => sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
1350	1	50				28	PDLA::ne( ($_[2] ? $y <=> $_[0] : $_[0] <=> $y), 0, 0) ? 1 : 0;},
		50
1351	1	50		1		7	">=" => sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
1352	1	50				28	PDLA::ge( ($_[2] ? $y <=> $_[0] : $_[0] <=> $y), 0, 0) ? 1 : 0;},
		50
1353	1	50		1		6	">" => sub { my $y = ref $_[1] eq __PACKAGE__ ? $_[1] : r2C $_[1];
1354	1	50				59	PDLA::gt( ($_[2] ? $y <=> $_[0] : $_[0] <=> $y), 0, 0) ? 1 : 0;},
		50
1355	1			1		4	'++' => sub { $_[0] += 1 },
1356	0			0		0	'--' => sub { $_[0] -= 1 },
1357	3					18	'""' => \&PDLA::Complex::string
1358	3			3		28	;
	3					7
1359
1360							# overwrite PDLA's overloading to honour subclass methods in + - * /
1361							{ package PDLA;
1362							my $warningFlag;
1363							# This strange usage of BEGINs is to ensure the
1364							# warning messages get disabled and enabled in the
1365							# proper order. Without the BEGIN's the 'use overload'
1366							# would be called first.
1367	3			3		1185	BEGIN {$warningFlag = $^W; # Temporarily disable warnings caused by
1368	3					1172	$^W = 0; # redefining PDLA's subs
1369							}
1370
1371
1372							sub cp(;@) {
1373	8			8	0	18	my $foo;
1374	8	100	100			55	if (ref $_[1]
			66
1375							&& (ref $_[1] ne 'PDLA')
1376							&& defined ($foo = overload::Method($_[1],'+')))
1377	2					166	{ &$foo($_[1], $_[0], !$_[2])}
1378	6					159	else { PDLA::plus (@_)}
1379							}
1380
1381							sub cm(;@) {
1382	8			8	0	18	my $foo;
1383	8	50	66			47	if (ref $_[1]
			33
1384							&& (ref $_[1] ne 'PDLA')
1385							&& defined ($foo = overload::Method($_[1],'*')))
1386	0					0	{ &$foo($_[1], $_[0], !$_[2])}
1387	8					306	else { PDLA::mult (@_)}
1388							}
1389
1390							sub cmi(;@) {
1391	58			58	0	367	my $foo;
1392	58	100	100			317	if (ref $_[1]
			66
1393							&& (ref $_[1] ne 'PDLA')
1394							&& defined ($foo = overload::Method($_[1],'-')))
1395	1					94	{ &$foo($_[1], $_[0], !$_[2])}
1396	57					1026	else { PDLA::minus (@_)}
1397							}
1398
1399							sub cd(;@) {
1400	0			0	0	0	my $foo;
1401	0	0	0			0	if (ref $_[1]
			0
1402							&& (ref $_[1] ne 'PDLA')
1403							&& defined ($foo = overload::Method($_[1],'/')))
1404	0					0	{ &$foo($_[1], $_[0], !$_[2])}
1405	0					0	else { PDLA::divide (@_)}
1406							}
1407
1408
1409							# Used in overriding standard PDLA +, -, *, / ops in the complex subclass.
1410							use overload (
1411	3					16	'+' => \&cp,
1412							'*' => \&cm,
1413							'-' => \&cmi,
1414							'/' => \&cd,
1415	3			3		24	);
	3					5
1416
1417
1418
1419	3			3		5283	BEGIN{ $^W = $warningFlag;} # Put Back Warnings
1420							};
1421
1422
1423							{
1424
1425							our $floatformat = "%4.4g"; # Default print format for long numbers
1426							our $doubleformat = "%6.6g";
1427
1428							$PDLA::Complex::_STRINGIZING = 0;
1429
1430							sub PDLA::Complex::string {
1431	7			7	0	3831	my($self,$format1,$format2)=@_;
1432	7					24	my @dims = $self->dims;
1433	7	50				19	return PDLA::string($self) if ($dims[0] != 2);
1434
1435	7	50				14	if($PDLA::Complex::_STRINGIZING) {
1436	0					0	return "ALREADY_STRINGIZING_NO_LOOPS";
1437							}
1438	7					14	local $PDLA::Complex::_STRINGIZING = 1;
1439	7					16	my $ndims = $self->getndims;
1440	7	50				25	if($self->nelem > $PDLA::toolongtoprint) {
1441	0					0	return "TOO LONG TO PRINT";
1442							}
1443	7	50				13	if ($ndims==0){
1444	0					0	PDLA::Core::string($self,$format1);
1445							}
1446	7	50				28	return "Null" if $self->isnull;
1447	7	50				21	return "Empty" if $self->isempty; # Empty piddle
1448	7	50				18	local $sep = $PDLA::use_commas ? ", " : " ";
1449	7	50				14	local $sep2 = $PDLA::use_commas ? ", " : "";
1450	7	100				16	if ($ndims < 3) {
1451	6					14	return str1D($self,$format1,$format2);
1452							}
1453							else{
1454	1					4	return strND($self,$format1,$format2,0);
1455							}
1456							}
1457
1458
1459							sub sum {
1460	5			5	0	20	my($x) = @_;
1461	5	50				29	return $x if $x->dims==1;
1462	5					33	my $tmp = $x->mv(0,-1)->clump(-2)->mv(1,0)->sumover;
1463	5					78	return $tmp;
1464							}
1465
1466							sub sumover{
1467	14			14	0	342	my $m = shift;
1468	14					71	PDLA::Ufunc::sumover($m->xchg(0,1));
1469							}
1470
1471							*PDLA::Complex::Csumover=\&sumover; # define through alias
1472
1473							*PDLA::Complex::prodover=\&Cprodover; # define through alias
1474
1475							sub prod {
1476	4			4	0	15	my($x) = @_;
1477	4	50				13	return $x if $x->dims==1;
1478	4					25	my $tmp = $x->mv(0,-1)->clump(-2)->mv(1,0)->prodover;
1479	4					52	return $tmp;
1480							}
1481
1482
1483
1484							sub strND {
1485	1			1	0	3	my($self,$format1,$format2,$level)=@_;
1486	1					4	my @dims = $self->dims;
1487
1488	1	50				18	if ($#dims==2) {
1489	1					10	return str2D($self,$format1,$format2,$level);
1490							}
1491							else {
1492	0					0	my $secbas = join '',map {":,"} @dims[0..$#dims-1];
	0					0
1493	0					0	my $ret="\n"." "x$level ."["; my $j;
	0					0
1494	0					0	for ($j=0; $j<$dims[$#dims]; $j++) {
1495	0					0	my $sec = $secbas . "($j)";
1496
1497	0					0	$ret .= strND($self->slice($sec),$format1,$format2, $level+1);
1498	0					0	chop $ret; $ret .= $sep2;
	0					0
1499							}
1500	0	0				0	chop $ret if $PDLA::use_commas;
1501	0					0	$ret .= "\n" ." "x$level ."]\n";
1502	0					0	return $ret;
1503							}
1504							}
1505
1506
1507							# String 1D array in nice format
1508							#
1509							sub str1D {
1510	6			6	0	15	my($self,$format1,$format2)=@_;
1511	6	50				20	barf "Not 1D" if $self->getndims() > 2;
1512	6					28	my $x = PDLA::Core::listref_c($self);
1513	6					12	my ($ret,$dformat,$t, $i);
1514
1515	6					14	my $dtype = $self->get_datatype();
1516	6	50				14	$dformat = $PDLA::Complex::floatformat if $dtype == $PDLA_F;
1517	6	50				17	$dformat = $PDLA::Complex::doubleformat if $dtype == $PDLA_D;
1518
1519	6	100				17	$ret = "[" if $self->getndims() > 1;
1520	6					15	my $badflag = $self->badflag();
1521	6					16	for($i=0; $i<=$#$x; $i++){
1522	20					38	$t = $$x[$i];
1523	20	50	33			45	if ( $badflag and $t eq "BAD" ) {
		50
1524							# do nothing
1525							} elsif ($format1) {
1526	0					0	$t = sprintf $format1,$t;
1527							} else{ # Default
1528	20	50	33			83	if ($dformat && length($t)>7) { # Try smaller
1529	0					0	$t = sprintf $dformat,$t;
1530							}
1531							}
1532	20	100				128	$ret .= $i % 2 ?
		50
		100
1533							$i<$#$x ? $t."i$sep" : $t."i"
1534							: substr($$x[$i+1],0,1) eq "-" ? "$t " : $t." +";
1535							}
1536	6	100				23	$ret.="]" if $self->getndims() > 1;
1537	6					43	return $ret;
1538							}
1539
1540
1541							sub str2D {
1542	1			1	0	5	my($self,$format1,$format2,$level)=@_;
1543	1					5	my @dims = $self->dims();
1544	1	50				5	barf "Not 2D" if scalar(@dims)!=3;
1545	1					12	my $x = PDLA::Core::listref_c($self);
1546	1					3	my ($i, $f, $t, $len1, $len2, $ret);
1547
1548	1					5	my $dtype = $self->get_datatype();
1549	1					6	my $badflag = $self->badflag();
1550
1551	1					10	my $findmax = 0;
1552
1553	1	0	33			7	if (!defined $format1 \|\| !defined $format2 \|\|
			33
			33
1554							$format1 eq '' \|\| $format2 eq '') {
1555	1					3	$len1= $len2 = 0;
1556
1557	1	50				3	if ( $badflag ) {
1558	0					0	for ($i=0; $i<=$#$x; $i++) {
1559	0	0				0	if ( $$x[$i] eq "BAD" ) {
1560	0					0	$f = 3;
1561							}
1562							else {
1563	0					0	$f = length($$x[$i]);
1564							}
1565	0	0				0	if ($i % 2) {
1566	0	0				0	$len2 = $f if $f > $len2;
1567							}
1568							else {
1569	0	0				0	$len1 = $f if $f > $len1;
1570							}
1571							}
1572							} else {
1573	1					6	for ($i=0; $i<=$#$x; $i++) {
1574	2					15	$f = length($$x[$i]);
1575	2	100				6	if ($i % 2){
1576	1	50				5	$len2 = $f if $f > $len2;
1577							}
1578							else{
1579	1	50				4	$len1 = $f if $f > $len1;
1580							}
1581							}
1582							}
1583
1584	1					4	$format1 = '%'.$len1.'s';
1585	1					4	$format2 = '%'.$len2.'s';
1586
1587	1	50				10	if ($len1 > 5){
1588	1	50				7	if ($dtype == $PDLA_F) {
		50
1589	0					0	$format1 = $PDLA::Complex::floatformat;
1590	0					0	$findmax = 1;
1591							} elsif ($dtype == $PDLA_D) {
1592	1					2	$format1 = $PDLA::Complex::doubleformat;
1593	1					3	$findmax = 1;
1594							} else {
1595	0					0	$findmax = 0;
1596							}
1597							}
1598	1	50				3	if($len2 > 5){
1599	1	50				4	if ($dtype == $PDLA_F) {
		50
1600	0					0	$format2 = $PDLA::Complex::floatformat;
1601	0					0	$findmax = 1;
1602							} elsif ($dtype == $PDLA_D) {
1603	1					2	$format2 = $PDLA::Complex::doubleformat;
1604	1					3	$findmax = 1;
1605							} else {
1606	0	0				0	$findmax = 0 unless $findmax;
1607							}
1608							}
1609							}
1610
1611	1	50				4	if($findmax) {
1612	1					9	$len1 = $len2=0;
1613
1614	1	50				3	if ( $badflag ) {
1615	0					0	for($i=0; $i<=$#$x; $i++){
1616	0					0	$findmax = $i % 2;
1617	0	0				0	if ( $$x[$i] eq 'BAD' ){
1618	0					0	$f = 3;
1619							}
1620							else{
1621	0	0				0	$f = $findmax ? length(sprintf $format2,$$x[$i]) :
1622							length(sprintf $format1,$$x[$i]);
1623							}
1624	0	0				0	if ($findmax){
1625	0	0				0	$len2 = $f if $f > $len2;
1626							}
1627							else{
1628	0	0				0	$len1 = $f if $f > $len1;
1629							}
1630							}
1631							} else {
1632	1					18	for ($i=0; $i<=$#$x; $i++) {
1633	2	100				7	if ($i % 2){
1634	1					5	$f = length(sprintf $format2,$$x[$i]);
1635	1	50				6	$len2 = $f if $f > $len2;
1636							}
1637							else{
1638	1					10	$f = length(sprintf $format1,$$x[$i]);
1639	1	50				14	$len1 = $f if $f > $len1;
1640							}
1641							}
1642							}
1643
1644
1645							} # if: $findmax
1646
1647	1					5	$ret = "\n" . ' 'x$level . "[\n";
1648							{
1649	1					2	my $level = $level+1;
	1					3
1650	1					3	$ret .= ' 'x$level .'[';
1651	1					2	$len2 += 2;
1652
1653	1					4	for ($i=0; $i<=$#$x; $i++) {
1654	2					3	$findmax = $i % 2;
1655	2	100				11	if ($findmax){
1656	1	50	33			4	if ( $badflag and $$x[$i] eq 'BAD' ){
1657							#\|\|
1658							#($findmax && $$x[$i - 1 ] eq 'BAD') \|\|
1659							#(!$findmax && $$x[$i +1 ] eq 'BAD')){
1660	0					0	$f = "BAD";
1661							}
1662							else{
1663	1					5	$f = sprintf $format2, $$x[$i];
1664	1	50				6	if (substr($$x[$i],0,1) eq '-'){
1665	0					0	$f.='i';
1666							}
1667							else{
1668	1					12	$f =~ s/(\s)(.)/+$2i/;
1669							}
1670							}
1671	1					3	$t = $len2-length($f);
1672							}
1673							else{
1674	1	50	33			5	if ( $badflag and $$x[$i] eq 'BAD' ){
1675	0					0	$f = "BAD";
1676							}
1677							else{
1678	1					6	$f = sprintf $format1, $$x[$i];
1679	1					4	$t = $len1-length($f);
1680							}
1681							}
1682
1683	2	50				6	$f = ' 'x$t.$f if $t>0;
1684
1685	2					3	$ret .= $f;
1686	2	100				6	if (($i+1)%($dims[1]*2)) {
1687	1	50				4	$ret.=$sep if $findmax;
1688							}
1689							else{ # End of output line
1690	1					2	$ret.=']';
1691	1	50				3	if ($i==$#$x) { # very last number
1692	1					3	$ret.="\n";
1693							}
1694							else{
1695	0					0	$ret.= $sep2."\n" . ' 'x$level .'[';
1696							}
1697							}
1698							}
1699							}
1700	1					4	$ret .= ' 'x$level."]\n";
1701	1					8	return $ret;
1702							}
1703
1704							}
1705
1706							=head1 AUTHOR
1707
1708							Copyright (C) 2000 Marc Lehmann .
1709							All rights reserved. There is no warranty. You are allowed
1710							to redistribute this software / documentation as described
1711							in the file COPYING in the PDLA distribution.
1712
1713							=head1 SEE ALSO
1714
1715							perl(1), L.
1716
1717							=cut
1718
1719
1720
1721
1722
1723
1724							# Exit with OK status
1725
1726							1;
1727
1728