1MATLAB(1)             User Contributed Perl Documentation            MATLAB(1)
2
3
4

NAME

6       PDL::MATLAB - A guide for MATLAB users.
7

INTRODUCTION

9       If you are a MATLAB user, this page is for you. It explains the key
10       differences between MATLAB and PDL to help you get going as quickly as
11       possible.
12
13       This document is not a tutorial. For that, go to PDL::QuickStart. This
14       document complements the Quick Start guide, as it highlights the key
15       differences between MATLAB and PDL.
16

Perl

18       The key difference between MATLAB and PDL is Perl.
19
20       Perl is a general purpose programming language with thousands of
21       modules freely available on the web. PDL is an extension of Perl. This
22       gives PDL programs access to more features than most numerical tools
23       can dream of.  At the same time, most syntax differences between MATLAB
24       and PDL are a result of its Perl foundation.
25
26       You do not have to learn much Perl to be effective with PDL. But if you
27       wish to learn Perl, there is excellent documentation available on-line
28       (<http://perldoc.perl.org>) or through the command "perldoc perl".
29       There is also a beginner's portal (<http://perl-begin.org>).
30
31       Perl's module repository is called CPAN (<http://www.cpan.org>) and it
32       has a vast array of modules. Run "perldoc cpan" for more information.
33

TERMINOLOGY: PIDDLE

35       MATLAB typically refers to vectors, matrices, and arrays. Perl already
36       has arrays, and the terms "vector" and "matrix" typically refer to one-
37       and two-dimensional collections of data. Having no good term to
38       describe their object, PDL developers coined the term "piddle" to give
39       a name to their data type.
40
41       A piddle consists of a series of numbers organized as an N-dimensional
42       data set. Piddles provide efficient storage and fast computation of
43       large N-dimensional matrices. They are highly optimized for numerical
44       work.
45
46       For more information, see "Piddles vs Perl Arrays" later in this
47       document.
48

COMMAND WINDOW AND IDE

50       Unlike MATLAB, PDL does not come with a dedicated IDE. It does however
51       come with an interactive shell and you can use a Perl IDE to develop
52       PDL programs.
53
54   PDL interactive shell
55       To start the interactive shell, open a terminal and run "perldl" or
56       "pdl2".  As in MATLAB, the interactive shell is the best way to learn
57       the language. To exit the shell, type "exit", just like MATLAB.
58
59   Writing PDL programs
60       One popular IDE for Perl is called Padre (<http://padre.perlide.org>).
61       It is cross platform and easy to use.
62
63       Whenever you write a stand-alone PDL program (i.e. outside the "perldl"
64       or "pdl2" shell) you must start the program with "use PDL;".  This
65       command imports the PDL module into Perl. Here is a sample PDL program:
66
67         use PDL;             # Import main PDL module.
68         use PDL::NiceSlice;  # Import additional PDL module.
69         use PDL::AutoLoader; # Import additional PDL module.
70
71         $y = pdl [2,3,4];              # Statements end in semicolon.
72         $A = pdl [ [1,2,3],[4,5,6] ];  # 2-dimensional matrix.
73
74         print $A x $y->transpose;
75
76       Save this file as "myprogram.pl" and run it with:
77
78         perl myprogram.pl
79
80   New: Flexible syntax
81       In current versions of PDL (version 2.4.7 or later) there is a flexible
82       matrix syntax that can look extremely similar to MATLAB:
83
84       1) Use a ';' to delimit rows:
85
86         $y = pdl q[ 2,3,4 ];
87         $A = pdl q[ 1,2,3 ; 4,5,6 ];
88
89       2) Use spaces to separate elements:
90
91         $y = pdl q[ 2 3 4 ];
92         $A = pdl q[ 1 2 3 ; 4 5 6 ];
93
94       Basically, as long as you put a "q" in front of the opening bracket,
95       PDL should "do what you mean". So you can write in a syntax that is
96       more comfortable for you.
97

MODULES FOR MATLAB USERS

99       There are two modules that MATLAB users will want to use:
100
101       PDL::NiceSlice
102            Gives PDL a syntax for slices (sub-matrices) that is shorter and
103            more familiar to MATLAB users.
104
105              % MATLAB
106              b(1:5)            -->  Selects the first 5 elements from b.
107
108              # PDL without NiceSlice
109              $y->slice("0:4")  -->  Selects the first 5 elements from $y.
110
111              # PDL with NiceSlice
112              $y(0:4)           -->  Selects the first 5 elements from $y.
113
114       PDL::AutoLoader
115            Provides a MATLAB-style autoloader for PDL. If an unknown function
116            "foo()" is called, PDL looks for a file called "foo.pdl". If it
117            finds one, it reads it.
118

BASIC FEATURES

120       This section explains how PDL's syntax differs from MATLAB. Most MATLAB
121       users will want to start here.
122
123   General "gotchas"
124       Indices
125            In PDL, indices start at '0' (like C and Java), not 1 (like MATLAB
126            or FORTRAN).  For example, if $y is an array with 5 elements, the
127            elements would be numbered from 0 to 4.
128
129       Displaying an object
130            MATLAB normally displays object contents automatically. In the PDL
131            shells you display objects explicitly with the "print" command or
132            the shortcut "p":
133
134            MATLAB:
135
136             >> a = 12
137             a =  12
138             >> b = 23;       % Suppress output.
139             >>
140
141            PDL Shell (perldl or pdl2):
142
143             pdl> $x = 12    # No output.
144             pdl> print $x   # Print object.
145             12
146             pdl> p $x       # "p" is a shorthand for "print" in the shell.
147             12
148             pdl>
149
150   Creating Piddles
151       Variables in PDL
152            Variables always start with the '$' sign.
153
154             MATLAB:    value  = 42
155             PerlDL:    $value = 42
156
157       Basic syntax
158            Use the "pdl" constructor to create a new piddle.
159
160             MATLAB:    v  = [1,2,3,4]
161             PerlDL:    $v = pdl [1,2,3,4]
162
163             MATLAB:    A  =      [ 1,2,3  ;  3,4,5 ]
164             PerlDL:    $A = pdl [ [1,2,3] , [3,4,5] ]
165
166       Simple matrices
167                                  MATLAB       PDL
168                                  ------       ------
169              Matrix of ones      ones(5)      ones 5,5
170              Matrix of zeros     zeros(5)     zeros 5,5
171              Random matrix       rand(5)      random 5,5
172              Linear vector       1:5          sequence 5
173
174            Notice that in PDL the parenthesis in a function call are often
175            optional.  It is important to keep an eye out for possible
176            ambiguities. For example:
177
178              pdl> p zeros 2, 2 + 2
179
180            Should this be interpreted as "zeros(2,2) + 2" or as "zeros 2,
181            (2+2)"?  Both are valid statements:
182
183              pdl> p zeros(2,2) + 2
184              [
185               [2 2]
186               [2 2]
187              ]
188              pdl> p zeros 2, (2+2)
189              [
190               [0 0]
191               [0 0]
192               [0 0]
193               [0 0]
194              ]
195
196            Rather than trying to memorize Perl's order of precedence, it is
197            best to use parentheses to make your code unambiguous.
198
199       Linearly spaced sequences
200              MATLAB:   >> linspace(2,10,5)
201                        ans = 2 4 6 8 10
202
203              PerlDL:   pdl> p zeroes(5)->xlinvals(2,10)
204                        [2 4 6 8 10]
205
206            Explanation: Start with a 1-dimensional piddle of 5 elements and
207            give it equally spaced values from 2 to 10.
208
209            MATLAB has a single function call for this. On the other hand,
210            PDL's method is more flexible:
211
212              pdl> p zeros(5,5)->xlinvals(2,10)
213              [
214               [ 2  4  6  8 10]
215               [ 2  4  6  8 10]
216               [ 2  4  6  8 10]
217               [ 2  4  6  8 10]
218               [ 2  4  6  8 10]
219              ]
220              pdl> p zeros(5,5)->ylinvals(2,10)
221              [
222               [ 2  2  2  2  2]
223               [ 4  4  4  4  4]
224               [ 6  6  6  6  6]
225               [ 8  8  8  8  8]
226               [10 10 10 10 10]
227              ]
228              pdl> p zeros(3,3,3)->zlinvals(2,6)
229              [
230               [
231                [2 2 2]
232                [2 2 2]
233                [2 2 2]
234               ]
235               [
236                [4 4 4]
237                [4 4 4]
238                [4 4 4]
239               ]
240               [
241                [6 6 6]
242                [6 6 6]
243                [6 6 6]
244               ]
245              ]
246
247       Slicing and indices
248            Extracting a subset from a collection of data is known as slicing.
249            PDL and MATLAB have a similar syntax for slicing, but there are
250            two important differences:
251
252            1) PDL indices start at 0, as in C and Java. MATLAB starts indices
253            at 1.
254
255            2) In MATLAB you think "rows and columns". In PDL, think "x and
256            y".
257
258              MATLAB                         PerlDL
259              ------                         ------
260              >> A                           pdl> p $A
261              A =                            [
262                   1   2   3                  [1 2 3]
263                   4   5   6                  [4 5 6]
264                   7   8   9                  [7 8 9]
265                                             ]
266              -------------------------------------------------------
267              (row = 2, col = 1)             (x = 0, y = 1)
268              >> A(2,1)                      pdl> p $A(0,1)
269              ans =                          [
270                     4                        [4]
271                                             ]
272              -------------------------------------------------------
273              (row = 2 to 3, col = 1 to 2)   (x = 0 to 1, y = 1 to 2)
274              >> A(2:3,1:2)                  pdl> p $A(0:1,1:2)
275              ans =                          [
276                     4   5                    [4 5]
277                     7   8                    [7 8]
278                                             ]
279
280            Warning
281                 When you write a stand-alone PDL program you have to include
282                 the PDL::NiceSlice module. See the previous section "MODULES
283                 FOR MATLAB USERS" for more information.
284
285                   use PDL;             # Import main PDL module.
286                   use PDL::NiceSlice;  # Nice syntax for slicing.
287                   use PDL::AutoLoader; # MATLAB-like autoloader.
288
289                   $A = random 4,4;
290                   print $A(0,1);
291
292   Matrix Operations
293       Matrix multiplication
294                  MATLAB:    A * B
295                  PerlDL:    $A x $B
296
297       Element-wise multiplication
298                  MATLAB:    A .* B
299                  PerlDL:    $A * $B
300
301       Transpose
302                  MATLAB:    A'
303                  PerlDL:    $A->transpose
304
305   Functions that aggregate data
306       Some functions (like "sum", "max" and "min") aggregate data for an
307       N-dimensional data set. This is a place where MATLAB and PDL take a
308       different approach:
309
310       In MATLAB, these functions all work along one dimension.
311                   >> A = [ 1,5,4  ;  4,2,1 ]
312                   A = 1  5  4
313                       4  2  1
314                   >> max(A)
315                   ans = 4  5  4
316                   >> max(A')
317                   ans = 5  4
318
319                 If you want the maximum for the entire data set, you can use
320                 the special A(:) notation which basically turns the entire
321                 data set into a single 1-dimensional vector.
322
323                   >> max(A(:))
324                   ans =  5
325                   >> A = ones(2,2,2,2)
326                   >> max(A(:))
327                   ans = 1
328
329       PDL offers two functions for each feature.
330                   sum   vs   sumover
331                   avg   vs   average
332                   max   vs   maximum
333                   min   vs   minimum
334
335                 The long name works over a dimension, while the short name
336                 works over the entire piddle.
337
338                   pdl> p $A = pdl [ [1,5,4] , [4,2,1] ]
339                   [
340                    [1 5 4]
341                    [4 2 1]
342                   ]
343                   pdl> p $A->maximum
344                   [5 4]
345                   pdl> p $A->transpose->maximum
346                   [4 5 4]
347                   pdl> p $A->max
348                   5
349                   pdl> p ones(2,2,2)->max
350                   1
351                   pdl> p ones(2,2,2,2)->max
352                   1
353
354       Note Notice that PDL aggregates horizontally while MATLAB aggregates
355            vertically. In other words:
356
357              MATLAB              PerlDL
358              max(A)       ==     $A->transpose->maximum
359              max(A')      ==     $A->maximum
360
361            TIP: In MATLAB you think "rows and columns". In PDL, think "x and
362            y".
363
364   Higher dimensional data sets
365       A related issue is how MATLAB and PDL understand data sets of higher
366       dimension. MATLAB was designed for 1D vectors and 2D matrices. Higher
367       dimensional objects ("N-D arrays") were added on top. In contrast, PDL
368       was designed for N-dimensional piddles from the start. This leads to a
369       few surprises in MATLAB that don't occur in PDL:
370
371       MATLAB sees a vector as a 2D matrix.
372              MATLAB                       PerlDL
373              ------                       ------
374              >> vector = [1,2,3,4];       pdl> $vector = pdl [1,2,3,4]
375              >> size(vector)              pdl> p $vector->dims
376              ans = 1 4                    4
377
378            MATLAB sees "[1,2,3,4]" as a 2D matrix (1x4 matrix). PDL sees it
379            as a 1D vector: A single dimension of size 4.
380
381       But MATLAB ignores the last dimension of a 4x1x1 matrix.
382              MATLAB                       PerlDL
383              ------                       ------
384              >> A = ones(4,1,1);          pdl> $A = ones 4,1,1
385              >> size(A)                   pdl> p $A->dims
386              ans = 4 1                    4 1 1
387
388       And MATLAB treats a 4x1x1 matrix differently from a 1x1x4 matrix.
389              MATLAB                       PerlDL
390              ------                       ------
391              >> A = ones(1,1,4);          pdl> $A = ones 1,1,4
392              >> size(A)                   pdl> p $A->dims
393              ans = 1 1 4                  1 1 4
394
395       MATLAB has no direct syntax for N-D arrays.
396              pdl> $A = pdl [ [[1,2,3],[4,5,6]], [[2,3,4],[5,6,7]] ]
397              pdl> p $A->dims
398              3 2 2
399
400       Feature support.
401            In MATLAB, several features such as sparse matrix support are not
402            available for N-D arrays. In PDL, just about any feature supported
403            by 1D and 2D piddles, is equally supported by N-dimensional
404            piddles.  There is usually no distinction.
405
406   Loop Structures
407       Perl has many loop structures, but we will only show the one that is
408       most familiar to MATLAB users:
409
410         MATLAB              PerlDL
411         ------              ------
412         for i = 1:10        for $i (1..10) {
413             disp(i)             print $i
414         endfor              }
415
416       Note Never use for-loops for numerical work. Perl's for-loops are
417            faster than MATLAB's, but they both pale against a "vectorized"
418            operation.  PDL has many tools that facilitate writing vectorized
419            programs.  These are beyond the scope of this guide. To learn
420            more, see: PDL::Indexing, PDL::Threading, and PDL::PP.
421
422            Likewise, never use 1..10 for numerical work, even outside a for-
423            loop.  1..10 is a Perl array. Perl arrays are designed for
424            flexibility, not speed. Use piddles instead. To learn more, see
425            the next section.
426
427   Piddles vs Perl Arrays
428       It is important to note the difference between a Piddle and a Perl
429       array. Perl has a general-purpose array object that can hold any type
430       of element:
431
432         @perl_array = 1..10;
433         @perl_array = ( 12, "Hello" );
434         @perl_array = ( 1, 2, 3, \@another_perl_array, sequence(5) );
435
436       Perl arrays allow you to create powerful data structures (see Data
437       structures below), but they are not designed for numerical work.  For
438       that, use piddles:
439
440         $pdl = pdl [ 1, 2, 3, 4 ];
441         $pdl = sequence 10_000_000;
442         $pdl = ones 600, 600;
443
444       For example:
445
446         $points =  pdl  1..10_000_000    # 4.7 seconds
447         $points = sequence 10_000_000    # milliseconds
448
449       TIP: You can use underscores in numbers ("10_000_000" reads better than
450       10000000).
451
452   Conditionals
453       Perl has many conditionals, but we will only show the one that is most
454       familiar to MATLAB users:
455
456         MATLAB                          PerlDL
457         ------                          ------
458         if value > MAX                  if ($value > $MAX) {
459             disp("Too large")               print "Too large\n";
460         elseif value < MIN              } elsif ($value < $MIN) {
461             disp("Too small")               print "Too small\n";
462         else                            } else {
463             disp("Perfect!")                print "Perfect!\n";
464         end                             }
465
466       Note Here is a "gotcha":
467
468              MATLAB:  elseif
469              PerlDL:  elsif
470
471            If your conditional gives a syntax error, check that you wrote
472            your "elsif"'s correctly.
473
474   TIMTOWDI (There Is More Than One Way To Do It)
475       One of the most interesting differences between PDL and other tools is
476       the expressiveness of the Perl language. TIMTOWDI, or "There Is More
477       Than One Way To Do It", is Perl's motto.
478
479       Perl was written by a linguist, and one of its defining properties is
480       that statements can be formulated in different ways to give the
481       language a more natural feel. For example, you are unlikely to say to a
482       friend:
483
484        "While I am not finished, I will keep working."
485
486       Human language is more flexible than that. Instead, you are more likely
487       to say:
488
489        "I will keep working until I am finished."
490
491       Owing to its linguistic roots, Perl is the only programming language
492       with this sort of flexibility. For example, Perl has traditional while-
493       loops and if-statements:
494
495         while ( ! finished() ) {
496             keep_working();
497         }
498
499         if ( ! wife_angry() ) {
500             kiss_wife();
501         }
502
503       But it also offers the alternative until and unless statements:
504
505         until ( finished() ) {
506             keep_working();
507         }
508
509         unless ( wife_angry() ) {
510             kiss_wife();
511         }
512
513       And Perl allows you to write loops and conditionals in "postfix" form:
514
515         keep_working() until finished();
516
517         kiss_wife() unless wife_angry();
518
519       In this way, Perl often allows you to write more natural, easy to
520       understand code than is possible in more restrictive programming
521       languages.
522
523   Functions
524       PDL's syntax for declaring functions differs significantly from
525       MATLAB's.
526
527         MATLAB                          PerlDL
528         ------                          ------
529         function retval = foo(x,y)      sub foo {
530             retval = x.**2 + x.*y           my ($x, $y) = @_;
531         endfunction                         return $x**2 + $x*$y;
532                                         }
533
534       Don't be intimidated by all the new syntax. Here is a quick run through
535       a function declaration in PDL:
536
537       1) "sub" stands for "subroutine".
538
539       2) "my" declares variables to be local to the function.
540
541       3) "@_" is a special Perl array that holds all the function parameters.
542       This might seem like a strange way to do functions, but it allows you
543       to make functions that take a variable number of parameters. For
544       example, the following function takes any number of parameters and adds
545       them together:
546
547         sub mysum {
548             my ($i, $total) = (0, 0);
549             for $i (@_) {
550                 $total += $i;
551             }
552             return $total;
553         }
554
555       4) You can assign values to several variables at once using the syntax:
556
557         ($x, $y, $z) = (1, 2, 3);
558
559       So, in the previous examples:
560
561         # This declares two local variables and initializes them to 0.
562         my ($i, $total) = (0, 0);
563
564         # This takes the first two elements of @_ and puts them in $x and $y.
565         my ($x, $y) = @_;
566
567       5) The "return" statement gives the return value of the function, if
568       any.
569

ADDITIONAL FEATURES

571   ASCII File IO
572       To read data files containing whitespace separated columns of numbers
573       (as would be read using the MATLAB load command) one uses the PDL rcols
574       in PDL::IO::Misc.  For a general review of the IO functionality
575       available in PDL, see the documentation for PDL::IO, e.g., "help
576       PDL::IO" in the pdl2 shell or " pdldoc PDL::IO " from the shell command
577       line.
578
579   Data structures
580       To create complex data structures, MATLAB uses "cell arrays" and
581       "structure arrays". Perl's arrays and hashes offer similar
582       functionality but are more powerful and flexible. This section is only
583       a quick overview of what Perl has to offer. To learn more about this,
584       please go to <http://perldoc.perl.org/perldata.html> or run the command
585       "perldoc perldata".
586
587       Arrays
588            Perl arrays are similar to MATLAB's cell arrays, but more
589            flexible. For example, in MATLAB, a cell array is still
590            fundamentally a matrix. It is made of rows, and rows must have the
591            same length.
592
593              MATLAB
594              ------
595              array = {1, 12, 'hello'; rand(3, 2), ones(3), 'junk'}
596              => OK
597              array = {1, 12, 'hello'; rand(3, 2), ones(3) }
598              => ERROR
599
600            A Perl array is a general purpose, sequential data structure. It
601            can contain any data type.
602
603              PerlDL
604              ------
605              @array = ( [1, 12, 'hello'] , [ random(3,2), ones(3,3), 'junk' ] )
606              => OK
607              @array = ( [1, 12, 'hello'] , [ random(3,2), ones(3,3) ] )
608              => OK
609              @array = ( 5 , {'name' => 'Mike'} , [1, 12, 'hello'] )
610              => OK
611
612            Notice that Perl array's start with the "@" prefix instead of the
613            "$" used by piddles.
614
615            To learn about Perl arrays, please go to
616            <http://perldoc.perl.org/perldata.html> or run the command
617            "perldoc perldata".
618
619       Hashes
620            Perl hashes are similar to MATLAB's structure arrays:
621
622              MATLAB
623              ------
624              >> drink = struct('type', 'coke', 'size', 'large', 'myarray', {1,2,3})
625              >> drink.type = 'sprite'
626              >> drink.price = 12          % Add new field to structure array.
627
628              PerlDL
629              ------
630              pdl> %drink = ( type => 'coke' , size => 'large', mypiddle => ones(3,3,3) )
631              pdl> $drink{type} = 'sprite'
632              pdl> $drink{price} = 12   # Add new field to hash.
633
634            Notice that Perl hashes start with the "%" prefix instead of the
635            "@" for arrays and "$" used by piddles.
636
637            To learn about Perl hashes, please go to
638            <http://perldoc.perl.org/perldata.html> or run the command
639            "perldoc perldata".
640
641   Performance
642       PDL has powerful performance features, some of which are not normally
643       available in numerical computation tools. The following pages will
644       guide you through these features:
645
646       PDL::Indexing
647            Level: Beginner
648
649            This beginner tutorial covers the standard "vectorization" feature
650            that you already know from MATLAB. Use this page to learn how to
651            avoid for-loops to make your program more efficient.
652
653       PDL::Threading
654            Level: Intermediate
655
656            PDL's "vectorization" feature goes beyond what most numerical
657            software can do. In this tutorial you'll learn how to "thread"
658            over higher dimensions, allowing you to vectorize your program
659            further than is possible in MATLAB.
660
661       Benchmarks
662            Level: Intermediate
663
664            Perl comes with an easy to use benchmarks module to help you find
665            how long it takes to execute different parts of your code. It is a
666            great tool to help you focus your optimization efforts. You can
667            read about it online (<http://perldoc.perl.org/Benchmark.html>) or
668            through the command "perldoc Benchmark".
669
670       PDL::PP
671            Level: Advanced
672
673            PDL's Pre-Processor is one of PDL's most powerful features. You
674            write a function definition in special markup and the pre-
675            processor generates real C code which can be compiled. With PDL:PP
676            you get the full speed of native C code without having to deal
677            with the full complexity of the C language.
678
679   Plotting
680       PDL has full-featured plotting abilities. Unlike MATLAB, PDL relies
681       more on third-party libraries (pgplot and PLplot) for its 2D plotting
682       features.  Its 3D plotting and graphics uses OpenGL for performance and
683       portability.  PDL has three main plotting modules:
684
685       PDL::Graphics::PGPLOT
686            Best for: Plotting 2D functions and data sets.
687
688            This is an interface to the venerable PGPLOT library. PGPLOT has
689            been widely used in the academic and scientific communities for
690            many years. In part because of its age, PGPLOT has some
691            limitations compared to newer packages such as PLplot (e.g. no RGB
692            graphics).  But it has many features that still make it popular in
693            the scientific community.
694
695       PDL::Graphics::PLplot
696            Best for: Plotting 2D functions as well as 2D and 3D data sets.
697
698            This is an interface to the PLplot plotting library. PLplot is a
699            modern, open source library for making scientific plots.  It
700            supports plots of both 2D and 3D data sets. PLplot is best
701            supported for unix/linux/macosx platforms. It has an active
702            developers community and support for win32 platforms is improving.
703
704       PDL::Graphics::TriD
705            Best for: Plotting 3D functions.
706
707            The native PDL 3D graphics library using OpenGL as a backend for
708            3D plots and data visualization. With OpenGL, it is easy to
709            manipulate the resulting 3D objects with the mouse in real time.
710
711   Writing GUIs
712       Through Perl, PDL has access to all the major toolkits for creating a
713       cross platform graphical user interface. One popular option is wxPerl
714       (<http://wxperl.sourceforge.net>). These are the Perl bindings for
715       wxWidgets, a powerful GUI toolkit for writing cross-platform
716       applications.
717
718       wxWidgets is designed to make your application look and feel like a
719       native application in every platform. For example, the Perl IDE Padre
720       is written with wxPerl.
721
722   Simulink
723       Simulink is a graphical dynamical system modeler and simulator. It can
724       be purchased separately as an add-on to MATLAB.  PDL and Perl do not
725       have a direct equivalent to MATLAB's Simulink.  If this feature is
726       important to you, then take a look at Scilab:
727
728       <http://www.scilab.org>
729
730       Scilab is another numerical analysis software. Like PDL, it is free and
731       open source. It doesn't have PDL's unique features, but it is very
732       similar to MATLAB. Scilab comes with Xcos (previously Scicos), a
733       graphical system modeler and simulator similar to Simulink.
734
736       Copyright 2010 Daniel Carrera (dcarrera@gmail.com). You can distribute
737       and/or modify this document under the same terms as the current Perl
738       license.
739
740       See: http://dev.perl.org/licenses/
741
742       Acknowledgements
743            I'd like to thank David Mertens, Chris Marshall and Sigrid Carrera
744            for their immense help reviewing earlier drafts of this guide.
745            Without their hours of work, this document would not be remotely
746            as useful to MATLAB users as it is today.
747
748
749
750perl v5.30.2                      2020-04-02                         MATLAB(1)
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