File Coverage

blib/lib/PDL/Basic.pm

Criterion	Covered	Total	%
statement	131	162	80.8
branch	57	92	61.9
condition	15	24	62.5
subroutine	27	30	90.0
pod	5	25	20.0
total	235	333	70.5

line	stmt	bran	cond	sub	pod	time	code
1
2							=head1 NAME
3
4							PDL::Basic -- Basic utility functions for PDL
5
6							=head1 DESCRIPTION
7
8							This module contains basic utility functions for
9							creating and manipulating piddles. Most of these functions
10							are simplified interfaces to the more flexible functions in
11							the modules
12							L
13							and
14							L.
15
16							=head1 SYNOPSIS
17
18							use PDL::Basic;
19
20							=head1 FUNCTIONS
21
22							=cut
23
24							package PDL::Basic;
25	122			122		917	use PDL::Core '';
	122					265
	122					804
26	122			122		791	use PDL::Types;
	122					254
	122					17464
27	122			122		858	use PDL::Exporter;
	122					311
	122					759
28	122			122		717	use PDL::Options;
	122					278
	122					339069
29
30							@ISA=qw/PDL::Exporter/;
31							@EXPORT_OK = qw/ ndcoords rvals axisvals allaxisvals xvals yvals zvals sec ins hist whist
32							similar_assign transpose sequence xlinvals ylinvals
33							zlinvals axislinvals/;
34							%EXPORT_TAGS = (Func=>[@EXPORT_OK]);
35
36							# Exportable functions
37							*axisvals = \&PDL::axisvals;
38							*allaxisvals = \&PDL::allaxisvals;
39							*sec = \&PDL::sec;
40							*ins = \&PDL::ins;
41							*hist = \&PDL::hist;
42							*whist = \&PDL::whist;
43							*similar_assign = \&PDL::similar_assign;
44							*transpose = \&PDL::transpose;
45							*xlinvals = \&PDL::xlinvals;
46							*ylinvals = \&PDL::ylinvals;
47							*zlinvals = \&PDL::zlinvals;
48
49							=head2 xvals
50
51							=for ref
52
53							Fills a piddle with X index values. Uses similar specifications to
54							L and L.
55
56							CAVEAT:
57
58							If you use the single argument piddle form (top row
59							in the usage table) the output will have the same type as the input;
60							this may give surprising results if, e.g., you have a byte array with
61							a dimension of size greater than 256. To force a type, use the third form.
62
63							=for usage
64
65							$x = xvals($somearray);
66							$x = xvals([OPTIONAL TYPE],$nx,$ny,$nz...);
67							$x = xvals([OPTIONAL TYPE], $somarray->dims);
68
69							etc. see L.
70
71							=for example
72
73							pdl> print xvals zeroes(5,10)
74							[
75							[0 1 2 3 4]
76							[0 1 2 3 4]
77							[0 1 2 3 4]
78							[0 1 2 3 4]
79							[0 1 2 3 4]
80							[0 1 2 3 4]
81							[0 1 2 3 4]
82							[0 1 2 3 4]
83							[0 1 2 3 4]
84							[0 1 2 3 4]
85							]
86
87							=head2 yvals
88
89							=for ref
90
91							Fills a piddle with Y index values. See the CAVEAT for L.
92
93							=for usage
94
95							$x = yvals($somearray); yvals(inplace($somearray));
96							$x = yvals([OPTIONAL TYPE],$nx,$ny,$nz...);
97
98							etc. see L.
99
100							=for example
101
102							pdl> print yvals zeroes(5,10)
103							[
104							[0 0 0 0 0]
105							[1 1 1 1 1]
106							[2 2 2 2 2]
107							[3 3 3 3 3]
108							[4 4 4 4 4]
109							[5 5 5 5 5]
110							[6 6 6 6 6]
111							[7 7 7 7 7]
112							[8 8 8 8 8]
113							[9 9 9 9 9]
114							]
115
116							=head2 zvals
117
118							=for ref
119
120							Fills a piddle with Z index values. See the CAVEAT for L.
121
122							=for usage
123
124							$x = zvals($somearray); zvals(inplace($somearray));
125							$x = zvals([OPTIONAL TYPE],$nx,$ny,$nz...);
126
127							etc. see L.
128
129							=for example
130
131							pdl> print zvals zeroes(3,4,2)
132							[
133							[
134							[0 0 0]
135							[0 0 0]
136							[0 0 0]
137							[0 0 0]
138							]
139							[
140							[1 1 1]
141							[1 1 1]
142							[1 1 1]
143							[1 1 1]
144							]
145							]
146
147							=head2 xlinvals
148
149							=for ref
150
151							X axis values between endpoints (see L).
152
153							=for usage
154
155							$w = zeroes(100,100);
156							$x = $w->xlinvals(0.5,1.5);
157							$y = $w->ylinvals(-2,-1);
158							# calculate Z for X between 0.5 and 1.5 and
159							# Y between -2 and -1.
160							$z = f($x,$y);
161
162							C, C and C return a piddle with the same shape
163							as their first argument and linearly scaled values between the two other
164							arguments along the given axis.
165
166							=head2 ylinvals
167
168							=for ref
169
170							Y axis values between endpoints (see L).
171
172							See L for more information.
173
174							=head2 zlinvals
175
176							=for ref
177
178							Z axis values between endpoints (see L).
179
180							See L for more information.
181
182							=head2 xlogvals
183
184							=for ref
185
186							X axis values logarithmically spaced between endpoints (see L).
187
188							=for usage
189
190							$w = zeroes(100,100);
191							$x = $w->xlogvals(1e-6,1e-3);
192							$y = $w->ylinvals(1e-4,1e3);
193							# calculate Z for X between 1e-6 and 1e-3 and
194							# Y between 1e-4 and 1e3.
195							$z = f($x,$y);
196
197							C, C and C return a piddle with the same shape
198							as their first argument and logarithmically scaled values between the two other
199							arguments along the given axis.
200
201							=head2 ylogvals
202
203							=for ref
204
205							Y axis values logarithmically spaced between endpoints (see L).
206
207							See L for more information.
208
209							=head2 zlogvals
210
211							=for ref
212
213							Z axis values logarithmically spaced between endpoints (see L).
214
215							See L for more information.
216
217							=cut
218
219							# Conveniently named interfaces to axisvals()
220
221	140	100	100	140	1	4628	sub xvals { ref($_[0]) && ref($_[0]) ne 'PDL::Type' ? $_[0]->xvals : PDL->xvals(@_) }
222	28	100	100	28	1	387	sub yvals { ref($_[0]) && ref($_[0]) ne 'PDL::Type' ? $_[0]->yvals : PDL->yvals(@_) }
223	3	100	66	3	1	40	sub zvals { ref($_[0]) && ref($_[0]) ne 'PDL::Type' ? $_[0]->zvals : PDL->zvals(@_) }
224							sub PDL::xvals {
225	368			368	0	768	my $class = shift;
226	368	100				1530	my $pdl = scalar(@_)? $class->new_from_specification(@_) : $class->new_or_inplace;
227	368					1416	axisvals2($pdl,0);
228	368					6585	return $pdl;
229							}
230							sub PDL::yvals {
231	35			35	0	92	my $class = shift;
232	35	100				182	my $pdl = scalar(@_)? $class->new_from_specification(@_) : $class->new_or_inplace;
233	35					129	axisvals2($pdl,1);
234	35					4653	return $pdl;
235							}
236							sub PDL::zvals {
237	5			5	0	12	my $class = shift;
238	5	100				26	my $pdl = scalar(@_)? $class->new_from_specification(@_) : $class->new_or_inplace;
239	5					21	axisvals2($pdl,2);
240	5					3704	return $pdl;
241							}
242
243							sub PDL::xlinvals {
244	1			1	0	10	my $dim = $_[0]->getdim(0);
245	1	50				5	barf "Must have at least two elements in dimension for xlinvals"
246							if $dim <= 1;
247	1					4	return $_[0]->xvals * (($_[2] - $_[1]) / ($dim-1)) + $_[1];
248							}
249
250							sub PDL::ylinvals {
251	1			1	0	113	my $dim = $_[0]->getdim(1);
252	1	50				5	barf "Must have at least two elements in dimension for ylinvals"
253							if $dim <= 1;
254	1					3	return $_[0]->yvals * (($_[2] - $_[1]) / ($dim-1)) + $_[1];
255							}
256
257							sub PDL::zlinvals {
258	1			1	0	36	my $dim = $_[0]->getdim(2);
259	1	50				5	barf "Must have at least two elements in dimension for zlinvals"
260							if $dim <= 1;
261	1					5	return $_[0]->zvals * (($_[2] - $_[1]) / ($dim-1)) + $_[1];
262							}
263
264							sub PDL::xlogvals {
265	1			1	0	14	my $dim = $_[0]->getdim(0);
266	1	50				5	barf "Must have at least two elements in dimension for xlogvals"
267							if $dim <= 1;
268	1					4	my ($xmin,$xmax) = @_[1,2];
269	1	50	33			8	barf "xmin and xmax must be positive"
270							if $xmin <= 0 \|\| $xmax <= 0;
271	1					7	my ($lxmin,$lxmax) = (log($xmin), log($xmax));
272	1					5	return exp($_[0]->xvals * (($lxmax - $lxmin) / ($dim-1)) + $lxmin);
273							}
274
275							sub PDL::ylogvals {
276	1			1	0	29	my $dim = $_[0]->getdim(1);
277	1	50				6	barf "Must have at least two elements in dimension for xlogvals"
278							if $dim <= 1;
279	1					5	my ($xmin,$xmax) = @_[1,2];
280	1	50	33			10	barf "xmin and xmax must be positive"
281							if $xmin <= 0 \|\| $xmax <= 0;
282	1					4	my ($lxmin,$lxmax) = (log($xmin), log($xmax));
283	1					5	return exp($_[0]->yvals * (($lxmax - $lxmin) / ($dim-1)) + $lxmin);
284							}
285
286							sub PDL::zlogvals {
287	1			1	0	11	my $dim = $_[0]->getdim(2);
288	1	50				6	barf "Must have at least two elements in dimension for xlogvals"
289							if $dim <= 1;
290	1					4	my ($xmin,$xmax) = @_[1,2];
291	1	50	33			9	barf "xmin and xmax must be positive"
292							if $xmin <= 0 \|\| $xmax <= 0;
293	1					5	my ($lxmin,$lxmax) = (log($xmin), log($xmax));
294	1					4	return exp($_[0]->zvals * (($lxmax - $lxmin) / ($dim-1)) + $lxmin);
295							}
296
297
298							=head2 allaxisvals
299
300							=for ref
301
302							Synonym for L - enumerates all coordinates in a
303							PDL or dim list, adding an extra dim on the front to accommodate
304							the vector coordinate index (the form expected by L,
305							L, and L). See L for more detail.
306
307							=for usage
308
309							$indices = allaxisvals($pdl);
310							$indices = allaxisvals(@dimlist);
311							$indices = allaxisvals($type,@dimlist);
312
313							=cut
314
315							=head2 ndcoords
316
317							=for ref
318
319							Enumerate pixel coordinates for an N-D piddle
320
321							Returns an enumerated list of coordinates suitable for use in
322							L or L: you feed
323							in a dimension list and get out a piddle whose 0th dimension runs over
324							dimension index and whose 1st through Nth dimensions are the
325							dimensions given in the input. If you feed in a piddle instead of a
326							perl list, then the dimension list is used, as in L etc.
327
328							Unlike L etc., if you supply a piddle input, you get
329							out a piddle of the default piddle type: double. This causes less
330							surprises than the previous default of keeping the data type of
331							the input piddle since that rarely made sense in most usages.
332
333							=for usage
334
335							$indices = ndcoords($pdl);
336							$indices = ndcoords(@dimlist);
337							$indices = ndcoords($type,@dimlist);
338
339							=for example
340
341							pdl> print ndcoords(2,3)
342
343							[
344							[
345							[0 0]
346							[1 0]
347							]
348							[
349							[0 1]
350							[1 1]
351							]
352							[
353							[0 2]
354							[1 2]
355							]
356							]
357
358							pdl> $w = zeroes(byte,2,3); # $w is a 2x3 byte piddle
359							pdl> $y = ndcoords($w); # $y inherits $w's type
360							pdl> $c = ndcoords(long,$w->dims); # $c is a long piddle, same dims as $y
361							pdl> help $y;
362							This variable is Byte D [2,2,3] P 0.01Kb
363							pdl> help $c;
364							This variable is Long D [2,2,3] P 0.05Kb
365
366
367							=cut
368
369							sub PDL::ndcoords {
370	44			44	0	83	my $type;
371	44	50				128	if(ref $_[0] eq 'PDL::Type') {
372	0					0	$type = shift;
373							}
374
375	44	50				151	my @dims = (ref $_[0]) ? (shift)->dims : @_;
376	44					102	my @d = @dims;
377	44					102	unshift(@d,scalar(@dims));
378	44	50				129	unshift(@d,$type) if defined($type);
379
380	44					147	$out = PDL->zeroes(@d);
381
382	44					165	for my $d(0..$#dims) {
383	88					1122	my $w = $out->index($d)->mv($d,0);
384	88					780	$w .= xvals($w);
385							}
386
387	44					264	$out;
388							}
389							*ndcoords = \&PDL::ndcoords;
390							*allaxisvals = \&PDL::ndcoords;
391							*PDL::allaxisvals = \&PDL::ndcoords;
392
393
394							=head2 hist
395
396							=for ref
397
398							Create histogram of a piddle
399
400							=for usage
401
402							$hist = hist($data);
403							($xvals,$hist) = hist($data);
404
405							or
406
407							$hist = hist($data,$min,$max,$step);
408							($xvals,$hist) = hist($data,[$min,$max,$step]);
409
410							If C is run in list context, C<$xvals> gives the
411							computed bin centres as double values.
412
413							A nice idiom (with
414							L) is
415
416							bin hist $data; # Plot histogram
417
418							=for example
419
420							pdl> p $y
421							[13 10 13 10 9 13 9 12 11 10 10 13 7 6 8 10 11 7 12 9 11 11 12 6 12 7]
422							pdl> $h = hist $y,0,20,1; # hist with step 1, min 0 and 20 bins
423							pdl> p $h
424							[0 0 0 0 0 0 2 3 1 3 5 4 4 4 0 0 0 0 0 0]
425
426							=cut
427
428							sub PDL::hist {
429
430	2			2	0	17	my $usage = "\n" . ' Usage: $hist = hist($data)' . "\n" .
431							' $hist = hist($data,$min,$max,$step)' . "\n" .
432							' ($xvals,$hist) = hist($data)' . "\n" .
433							' ($xvals,$hist) = hist($data,$min,$max,$step)' . "\n" ;
434	2	50				11	barf($usage) if $#_<0;
435
436	2					10	my($pdl,$min,$max,$step)=@_;
437	2					4	my $xvals;
438
439	2					11	($step, $min, $bins, $xvals) =
440							_hist_bin_calc($pdl, $min, $max, $step, wantarray());
441
442	2					11	PDL::Primitive::histogram($pdl->clump(-1),(my $hist = null),
443							$step,$min,$bins);
444
445	2	100				29	return wantarray() ? ($xvals,$hist) : $hist;
446							}
447
448							=head2 whist
449
450							=for ref
451
452							Create a weighted histogram of a piddle
453
454							=for usage
455
456							$hist = whist($data, $wt, [$min,$max,$step]);
457							($xvals,$hist) = whist($data, $wt, [$min,$max,$step]);
458
459							If requested, C<$xvals> gives the computed bin centres
460							as type double values. C<$data> and C<$wt> should have
461							the same dimensionality and extents.
462
463							A nice idiom (with
464							L) is
465
466							bin whist $data, $wt; # Plot histogram
467
468							=for example
469
470							pdl> p $y
471							[13 10 13 10 9 13 9 12 11 10 10 13 7 6 8 10 11 7 12 9 11 11 12 6 12 7]
472							pdl> $wt = grandom($y->nelem)
473							pdl> $h = whist $y, $wt, 0, 20, 1 # hist with step 1, min 0 and 20 bins
474							pdl> p $h
475							[0 0 0 0 0 0 -0.49552342 1.7987439 0.39450696 4.0073722 -2.6255299 -2.5084501 2.6458365 4.1671676 0 0 0 0 0 0]
476
477
478							=cut
479
480							sub PDL::whist {
481	1	50		1	0	9	barf('Usage: ([$xvals],$hist) = whist($data,$wt,[$min,$max,$step])')
482							if @_ < 2;
483	1					4	my($pdl,$wt,$min,$max,$step)=@_;
484	1					3	my $xvals;
485
486	1					3	($step, $min, $bins, $xvals) =
487							_hist_bin_calc($pdl, $min, $max, $step, wantarray());
488
489	1					7	PDL::Primitive::whistogram($pdl->clump(-1),$wt->clump(-1),
490							(my $hist = null), $step, $min, $bins);
491	1	50				15	return wantarray() ? ($xvals,$hist) : $hist;
492							}
493
494							sub _hist_bin_calc {
495	3			3		13	my($pdl,$min,$max,$step,$wantarray)=@_;
496	3	50				12	$min = $pdl->min() unless defined $min;
497	3	50				10	$max = $pdl->max() unless defined $max;
498	3					29	my $nelem = $pdl->nelem;
499	3	50				13	barf "empty piddle, no values to work with" if $nelem == 0;
500
501	3	0				9	$step = ($max-$min)/(($nelem>10_000) ? 100 : sqrt($nelem)) unless defined $step;
		50
502	3	50				13	barf "step is zero (or all data equal to one value)" if $step == 0;
503
504	3					14	my $bins = int(($max-$min)/$step+0.5);
505	3	50				9	print "hist with step $step, min $min and $bins bins\n"
506							if $PDL::debug;
507							# Need to use double for $xvals here
508	3	100				33	my $xvals = $min + $step/2 + sequence(PDL::Core::double,$bins)*$step if $wantarray;
509
510	3					40	return ( $step, $min, $bins, $xvals );
511							}
512
513
514							=head2 sequence
515
516							=for ref
517
518							Create array filled with a sequence of values
519
520							=for usage
521
522							$w = sequence($y); $w = sequence [OPTIONAL TYPE], @dims;
523
524							etc. see L.
525
526							=for example
527
528							pdl> p sequence(10)
529							[0 1 2 3 4 5 6 7 8 9]
530							pdl> p sequence(3,4)
531							[
532							[ 0 1 2]
533							[ 3 4 5]
534							[ 6 7 8]
535							[ 9 10 11]
536							]
537
538							=cut
539
540	139	50	66	139	1	3125461	sub sequence { ref($_[0]) && ref($_[0]) ne 'PDL::Type' ? $_[0]->sequence : PDL->sequence(@_) }
541							sub PDL::sequence {
542	144			144	0	1301	my $class = shift;
543	144	100				1655	my $pdl = scalar(@_)? $class->new_from_specification(@_) : $class->new_or_inplace;
544	144					695	my $bar = $pdl->clump(-1)->inplace;
545	144					548	my $foo = $bar->xvals;
546	144					2495	return $pdl;
547							}
548
549							=head2 rvals
550
551							=for ref
552
553							Fills a piddle with radial distance values from some centre.
554
555							=for usage
556
557							$r = rvals $piddle,{OPTIONS};
558							$r = rvals [OPTIONAL TYPE],$nx,$ny,...{OPTIONS};
559
560							=for options
561
562							Options:
563
564							Centre => [$x,$y,$z...] # Specify centre
565							Center => [$x,$y.$z...] # synonym.
566
567							Squared => 1 # return distance squared (i.e., don't take the square root)
568
569							=for example
570
571							pdl> print rvals long,7,7,{Centre=>[2,2]}
572							[
573							[2 2 2 2 2 3 4]
574							[2 1 1 1 2 3 4]
575							[2 1 0 1 2 3 4]
576							[2 1 1 1 2 3 4]
577							[2 2 2 2 2 3 4]
578							[3 3 3 3 3 4 5]
579							[4 4 4 4 4 5 5]
580							]
581
582							If C is not specified, the midpoint for a given dimension of
583							size C is given by C< int(N/2) > so that the midpoint always falls
584							on an exact pixel point in the data. For dimensions of even size,
585							that means the midpoint is shifted by 1/2 pixel from the true center
586							of that dimension.
587
588							Also note that the calculation for C for integer values
589							does not promote the datatype so you will have wraparound when
590							the value calculated for C< r**2 > is greater than the datatype
591							can hold. If you need exact values, be sure to use large integer
592							or floating point datatypes.
593
594							For a more general metric, one can define, e.g.,
595
596							sub distance {
597							my ($w,$centre,$f) = @_;
598							my ($r) = $w->allaxisvals-$centre;
599							$f->($r);
600							}
601							sub l1 { sumover(abs($_[0])); }
602							sub euclid { use PDL::Math 'pow'; pow(sumover(pow($_[0],2)),0.5); }
603							sub linfty { maximum(abs($_[0])); }
604
605							so now
606
607							distance($w, $centre, \&euclid);
608
609							will emulate rvals, while C<\&l1> and C<\&linfty> will generate other
610							well-known norms.
611
612							=cut
613
614	14	50	66	14	1	2858	sub rvals { ref($_[0]) && ref($_[0]) ne 'PDL::Type' ? $_[0]->rvals(@_[1..$#_]) : PDL->rvals(@_) }
615							sub PDL::rvals { # Return radial distance from given point and offset
616	14			14	0	31	my $class = shift;
617	14	100				51	my $opt = pop @_ if ref($_[$#_]) eq "HASH";
618	14	100				72	my %opt = defined $opt ?
619							iparse( {
620							CENTRE => undef, # needed, otherwise centre/center handling painful
621							Squared => 0,
622							}, $opt ) : ();
623	14	50				79	my $r = scalar(@_)? $class->new_from_specification(@_) : $class->new_or_inplace;
624
625	14					25	my @pos;
626	14	100				40	@pos = @{$opt{CENTRE}} if defined $opt{CENTRE};
	7					20
627	14					24	my $offset;
628
629	14					88	$r .= 0.0;
630	14					56	my $tmp = $r->copy;
631	14					29	my $i;
632	14					75	for ($i=0; $i<$r->getndims; $i++) {
633	28	100				129	$offset = (defined $pos[$i] ? $pos[$i] : int($r->getdim($i)/2));
634							# Note careful coding for speed and min memory footprint
635	28					529	PDL::Primitive::axisvalues($tmp->xchg(0,$i));
636	28					201	$tmp -= $offset; $tmp *= $tmp;
	28					84
637	28					67	$r += $tmp;
638							}
639	14	100				77	return $opt{Squared} ? $r : $r->inplace->sqrt;
640							}
641
642							=head2 axisvals
643
644							=for ref
645
646							Fills a piddle with index values on Nth dimension
647
648							=for usage
649
650							$z = axisvals ($piddle, $nth);
651
652							This is the routine, for which L, L etc
653							are mere shorthands. C can be used to fill along any dimension,
654							using a parameter.
655
656							See also L, which generates all axis values
657							simultaneously in a form useful for L, L,
658							L, etc.
659
660							Note the 'from specification' style (see L) is
661							not available here, for obvious reasons.
662
663							=cut
664
665							sub PDL::axisvals {
666	1			1	0	3	my($this,$nth) = @_;
667	1					5	my $dummy = $this->new_or_inplace;
668	1	50				9	if($dummy->getndims() <= $nth) {
669							# This is 'kind of' consistency...
670	0					0	$dummy .= 0;
671	0					0	return $dummy;
672							# barf("Too few dimensions given to axisvals $nth\n");
673							}
674	1					8	my $bar = $dummy->xchg(0,$nth);
675	1					16	PDL::Primitive::axisvalues($bar);
676	1					7	return $dummy;
677							}
678
679							# We need this version for xvals etc to work in place
680							sub axisvals2 {
681	408			408	0	956	my($this,$nth) = @_;
682	408					662	my $dummy = shift;
683	408	50				2206	if($dummy->getndims() <= $nth) {
684							# This is 'kind of' consistency...
685	0					0	$dummy .= 0;
686	0					0	return $dummy;
687							# barf("Too few dimensions given to axisvals $nth\n");
688							}
689	408					3377	my $bar = $dummy->xchg(0,$nth);
690	408					22585	PDL::Primitive::axisvalues($bar);
691	408					3108	return $dummy;
692							}
693							sub PDL::sec {
694	0			0	0	0	my($this,@coords) = @_;
695	0					0	my $i; my @maps;
696	0					0	while($#coords > -1) {
697	0					0	$i = int(shift @coords) ;
698	0					0	push @maps, "$i:".int(shift @coords);
699							}
700	0					0	my $tmp = PDL->null;
701	0					0	$tmp .= $this->slice(join ',',@maps);
702	0					0	return $tmp;
703							}
704
705							sub PDL::ins {
706	0			0	0	0	my($this,$what,@coords) = @_;
707	0					0	my $w = PDL::Core::alltopdl($PDL::name,$what);
708	0					0	my $tmp;
709	0	0				0	if($this->is_inplace) {
710	0					0	$this->set_inplace(0);
711							} else {
712	0					0	$this = $this->copy;
713							}
714							($tmp = $this->slice(
715	0	0				0	(join ',',map {int($coords[$_]).":".
	0					0
716							((int($coords[$_])+$w->getdim($_)-1)<$this->getdim($_) ?
717							(int($coords[$_])+$w->getdim($_)-1):$this->getdim($_))
718							}
719							0..$#coords)))
720							.= $w;
721	0					0	return $this;
722							}
723
724							sub PDL::similar_assign {
725	0			0	0	0	my($from,$to) = @_;
726	0	0				0	if((join ',',@{$from->dims}) ne (join ',',@{$to->dims})) {
	0					0
	0					0
727							barf "Similar_assign: dimensions [".
728	0					0	(join ',',@{$from->dims})."] and [".
729	0					0	(join ',',@{$to->dims})."] do not match!\n";
	0					0
730							}
731	0					0	$to .= $from;
732							}
733
734							=head2 transpose
735
736							=for ref
737
738							transpose rows and columns.
739
740							=for usage
741
742							$y = transpose($w);
743
744							=for example
745
746							pdl> $w = sequence(3,2)
747							pdl> p $w
748							[
749							[0 1 2]
750							[3 4 5]
751							]
752							pdl> p transpose( $w )
753							[
754							[0 3]
755							[1 4]
756							[2 5]
757							]
758
759							=cut
760
761							sub PDL::transpose {
762	13			13	0	54	my($this) = @_;
763	13	100				179	if($this->getndims <= 1) {
764	6	50				29	if($this->getndims==0) {
765	0					0	return pdl $this->dummy(0)->dummy(0);
766							} else {
767	6					24	return pdl $this->dummy(0);
768							}
769							}
770	7					76	return $this->xchg(0,1);
771							}
772
773							1;
774